GP3000S30-0.125-02-4/4 - BERGQUIST

Table of Contents

Introduction 2

Thermal Properties and Testing 4

Interface Material Selection Guide 5

Gap Pad®Thermally Conductive Materials 6

Gap Pad Comparison Data 7

Frequently Asked Questions 8

Gap Pad VO®9

Gap Pad VO Soft®10

Gap Pad VO Ultra Soft 11

Gap Pad 1000SF 12

Gap Pad HC1000 13

Gap Pad 1500 14

Gap Pad 1500R 15

Gap Pad A2000 16

Gap Pad 2000S40 17

Gap Pad 2500S20 18

Gap Pad 2500 19

Gap Pad A3000 20

Gap Pad 3000S30 21

Gap Pad 5000S35 22

Gap Filler 1000 (Two-Part)23

Gap Filler 1100SF (Two-Part)24

Gap Filler Gel 1500 (One-Part) 25

Gap Filler 2000 (Two-Part)26

Gap Filler 3500S35 (Two-Part) 27

TIC™Thermal Interface Compound 28

Comparison Data and Frequently Asked Questions 28

TIC 1000G 29

TIC 1000A 30

TIC 4000 31

Hi-Flow®Phase Change Interface Materials 32

Hi-Flow Comparison Data 33

Frequently Asked Questions 34

Hi-Flow 105 35

Hi-Flow 115-AC 36

Hi-Flow 225F-AC 37

Hi-Flow 225FT 38

Hi-Flow 225UF 39

Hi-Flow 225UT 40

Hi-Flow 225U 41

Hi-Flow 625 42

Hi-Flow 300P 43

Hi-Flow 300G 44

Sil-Pad®Thermally Conductive Insulators 45

Sil-Pad Comparison Data 46

Frequently Asked Questions 47

Choosing Sil-Pad Thermally Conductive Insulators 48

Mechanical, Electrical and Thermal Properties 50

Sil-Pad Applications 52

Sil-Pad Selection Table 52

Sil-Pad 400 54

Sil-Pad 800 55

Sil-Pad 900S 56

Sil-Pad 980 57

Sil-Pad 1100ST 58

Sil-Pad A1500 59

Sil-Pad 1500ST 60

Sil-Pad 1750 61

Sil-Pad 2000 62

Sil-Pad A2000 63

Sil-Pad K-4 64

Sil-Pad K-6 65

Sil-Pad K-10 66

Q-Pad®II 67

Q-Pad 3 68

Poly-Pad®400 69

Poly-Pad 1000 70

Poly-Pad K-4 71

Poly-Pad K-10 72

Sil-Pad Tubes 73

Sil-Pad Shield 74

Bond-Ply®and Liqui-Bond®Adhesives 75

Bond-Ply and Liqui-Bond Comparison Data 76

Frequently Asked Questions 76

Bond-Ply 100 77

Bond-Ply 400 78

Bond-Ply 660B 79

Liqui-Bond SA 1000 (One-Part) 80

Liqui-Bond SA 2000 (One-Part)81

Solutions for Surface Mount Applications 83

Ordering Information 85

Sil-Pad Configurations - Imperial 87

Hi-Flow Configurations - Imperial 90

Sil-Pad Configurations - Metric 91

Hi-Flow Configurations - Metric 94

Sil-Pad Shield Configurations - Imperial 95

SEL_SP_0906_Chpt1.qxp 10/20/2006 4:13 PM Page 1

INTRODUCTION

At Bergquist, developing high quality

components for the electronics

industry is our first priority. As a

world-leading manufacturer with

state-of-the-art facilities, we serve a

multitude of industries worldwide

including automotive, computer,

consumer electronics, military,

motor control, power conversion,

telecommunications and more.

We make it our business to know

your business. We understand your

problems. We also know that there

will always be a better way to help

you reach your goals and objectives.

To that end, our company continually

invests considerable time and money

into research and development. The

Bergquist Company is focused on a

single purpose – discovering the

need, then developing and delivering

technologically advanced solutions

backed by superior service.

World Leader in

Thermal Management Through

Technology, Innovation and Service

Bergquist Takes

the Heat

Thermal Management Products

Bergquist's Thermal Products Group is a world-

leading developer and manufacturer of thermal

management materials which provide product

solutions to control and manage heat in

electronic assemblies and printed circuit

boards. Used by many of the world’s largest

OEMs in various industries including auto-

motive, computer, power supply, military and

motor control, these materials include:

Sil-Pad®– Thermally Conductive Insulators

Bond-Ply®and Liqui-Bond®– Thermally

Conductive Adhesives

Gap Pad®– Thermally Conductive

Gap Filling Materials

Hi-Flow®– Phase Change Interface Materials

TIC™– Thermal Interface Compounds

Thermal Clad®– Insulated Metal Substrates

World Class Operations

Around the Globe

Worldwide Locations

In the United States, the Thermal Products

Group’s 90,000 square-foot manufacturing

facility is located in Cannon Falls, Minnesota.

A 40,000 square-foot facility in Prescott,

Wisconsin houses the Thermal Clad printed

circuit board operations. A130,000 square-

foot facility in Chanhassen, Minnesota is the

location for Bergquist’s corporate headquarters

and state-of-the-art research and development

facilities.Worldwide, Bergquist has facilities in

The Netherlands, Germany, the United

Kingdom,Taiwan, South Korea, Hong Kong

and China with sales representatives in 30

countries to support worldwide growth.

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INTRODUCTION GAP PAD TIC HI--FLOW SIL-PAD BOND-PLY ORDERING

A Legacy of Industry-

Leading Technology

New Product Innovation

For over 40 years, outstanding quality,

innovation and engineering have been hall-

marks of The Bergquist Company.Today,

developing innovative products for the

electronics industry remains our first priority.

Bergquist has developed over 260 materials

which provide thermal solutions for a wide

variety of electronic applications. Many of our

products were originally developed to satisfy

a customer request for a specific material

designed to perform to their particular

specifications.This “can do” attitude and

customized technology has earned The

Bergquist Company its ISO 9001:2000

certification.

Research and Development

at the Speed of Change

R&D Facilities

Keeping pace in today’s aggressive electronics

industry demands continual anticipation of

change and the ability to develop customer-

driven solutions quickly and efficiently. Our

Chanhassen headquarters features a

state-of-the-art development laboratory and

engineering department staffed with highly

skilled chemical engineers, laboratory

technicians and manufacturing engineers –

all dedicated to researching, developing and

testing new materials. From such dedication

have come many industry-standard proprietary

products including Thermal Clad, Sil-Pad,

Gap Pad, Bond-Ply and Hi-Flow materials.

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Thermal Properties and Testing

INTRODUCTION

Thermal Conductivity

The time rate of heat flow through a unit area producing a unit

temperature difference across a unit thickness.

Thermal conductivity is an inherent or absolute property of the material.

Thermal Impedance

A property of a particular assembly measured by the ratio of the

temperature difference between two surfaces to the steady-state heat

flow through them.

Factors affecting thermal impedance include:

Area: Increasing the area of thermal contact decreases

thermal impedance.

Thickness: Increasing the insulator thickness increases

thermal impedance.

Pressure: Increasing mounting pressure under ideal conditions

decreases thermal impedance.

Time: Thermal impedance decreases over time.

Measurement: Thermal impedance is affected by the method of

temperature measurement.

Thermal Impedance Per Bergquist TO-220 Thermal

Performance (25oC Cold Plate Testing)

Thermal Resistance

The opposition to the flow of heat through a unit area of material

across an undefined thickness.

Thermal resistance varies with thickness.

Test Methods – ASTM D5470

2 in. diameter stack (ref. 3.14 in2) – 10-500 psi, 1 hour per layer

SEL_SP_0906_Chpt1.qxp 10/20/2006 10:18 AM Page 4

Interface Material Selection Guide

INTRODUCTION

Sil-Pad A1500

T = Typical; AS = Application-Specific (contact Bergquist Sales); A = Available; * = Roll stock configurations are limited — contact your Bergquist Sales Representative for more

information. Note: For Hi-Flow 225UT, Hi-Flow 225FT, and Hi-Flow 225F-AC, the adhesive is not a pressure sensitive adhesive (PSA).

SEL_SP_0906_Chpt1.qxp 10/20/2006 10:18 AM Page 5

Gap Pad

Thermally Conductive Materials

GAP PAD

Solution-Driven Thermal Management Products for Electronic Devices

The Bergquist Company, a world leader in thermal interface materials,

developed the Gap Pad family to meet the electronic industry’s

growing need for interface materials with greater conformability,

higher thermal performance and easier application.

The extensive Gap Pad family provides an effective thermal interface

between heat sinks and electronic devices where uneven surface

topography, air gaps and rough surface textures are present. Bergquist

application specialists work closely with customers to specify the proper

Gap Pad material for each unique thermal management requirement.

A Complete Range of Choices for Filling Air Gaps and Enhancing Thermal Conductivity

Features

Each of the many products within

the Gap Pad family is unique in

its construction, properties and

performance. Following is an

overview of the important

features offered by the

Gap Pad family.

• Low-modulus polymer material

• Available with fiberglass/rubber

carriers or in a non-reinforced

version

• Special fillers to achieve specific

thermal and conformability

characteristics

• Highly conformable to uneven

and rough surfaces

• Electrically isolating

• Natural tack on one or both

sides with protective liner

• Variety of thicknesses and

hardnesses

• Range of thermal conductivities

• Available in sheets and

die-cut parts

Benefits

Gap Pad thermal products are

designed to improve an assembly’s

thermal performance and reliability

while saving time and money.

Specifically:

• Eliminates air gaps to reduce

thermal resistance

• High conformability reduces

interfacial resistance

• Low-stress vibration dampening

• Shock absorbing

• Easy material handling

• Simplified application

• Puncture, shear and tear

resistance

• Improved performance for

high-heat assemblies

• Compatible with automated

dispensing equipment

Options

Some Gap Pad products have

special features for particular

applications, including:

• Available with or without

adhesive

• Rubber-coated fiberglass

reinforcement

• Thicknesses from 0.010"

to 0.250"

• Available in custom die-cut

parts, sheets and rolls

(converted or unconverted)

• Custom thicknesses and

constructions

• Adhesive or natural

inherent tack

• Silicone-free Gap Pad available

in thicknesses of 0.010" - 0.125"

• Gap Fillers are well suited for

automated dispensing

We produce thousands of specials.

Tooling charges vary depending

on tolerance and complexity of

the part.

Applications

Gap Pad products are well suited

to a wide variety of electronics,

automotive, medical, aerospace

and military applications such as:

• Between an IC and a heat sink

or chassis.Typical packages

include BGA’s, QFP, SMT power

components and magnetics

• Between a semiconductor and

heat sink

• CD-ROM/DVD cooling

• Heat pipe assemblies

• RDRAM memory modules

• DDR SDRAM

• Hard drive cooling

• Power supply

• Signal amplifiers

• Between other heat-generating

devices and chassis

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Gap Pad

Comparison Data

GAP PAD

Conductivity, Hardness and General Overview

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GAP PAD

Frequently Asked Questions

Q: What thermal conductivity test method was used to

achieve the values given on the data sheets?

A: A test fixture is utilized that meets the specifications outlined in

ASTM D5470.

Q: Is Gap Pad offered with an adhesive?

A: Currently, Gap Pad VO, Gap Pad VO Soft, and Gap Pad VO Ultra

Soft are offered with or without an adhesive on the Sil-Pad

800/900 carrier-side of the material.The remaining surface has

natural inherent tack. All other Gap Pads have inherent tack.

Q: Is the adhesive repositionable?

A: Depending on the surface being applied to, if care is taken, the

pad may be repositioned. Special care should be taken when

removing the pad from aluminum or anodized surfaces to avoid

tearing or delamination.

Q: What is meant by “natural tack”?

A: The characteristic of the rubber itself has a natural inherent tack,

without the addition of an adhesive. As with adhesive-backed

products, the surfaces with natural tack may help in the assembly

process to temporarily hold the pad in place while the application

is being assembled. Unlike adhesive-backed products, inherent tack

does not have a thermal penalty since the rubber itself has the

tack.Tack strength varies from one Gap Pad product to the next.

Q: Can Gap Pad with natural tack be repositioned?

A: Again, depending on the material that the pad is applied to, in

most cases they are repositionable. Care should be taken when

removing the pad from aluminum or anodized surfaces as to

avoid tearing or delaminating the pad.The side with natural tack

is always easier to reposition than an adhesive side.

Q: Is Gap Pad reworkable?

A: Depending on the application and the pad being used, Gap Pad

has been reworked in the past. Bergquist has customers that are

currently using the same pad for reassembling their applications

after burn-in processes and after fieldwork repairs. However, this

is left up to the design engineer’s judgment as to whether or not

the Gap Pad will withstand reuse.

Q: Is liquid Gap Filler reworkable?

A: It is highly dependent on the application and its surface topography.

Liquid Gap Filler will cure with low adhesive strength to the

application surfaces.

Q: Will heat make the material softer?

A: From -60°C to 200°C, there is no significant variance in hardness

for silicone Gap Pads and Gap Fillers.

Q: What is the shelf life of Gap Pad?

A: Shelf life for Gap Pad is one (1) year after date of manufacture.

For Gap Pad with adhesive, the shelf life is six (6) months after

the date of manufacture. After these dates, inherent tack and

adhesive properties should be recharacterized.

Q: How is extraction testing performed?

A: The test method used is the Bellcore Extraction method

#TR-NWT-000930; refer to Bergquist Application Note #56.

Q: What are the upper processing temperature limits

for Gap Pad and for how long can Gap Pad be exposed

to them?

A: Gap Pad VO materials and Gap Pad A3000 are more stable at

elevated temperatures. Gap Pad in general can be exposed to

temporary processing temperatures of 250°C for five minutes

and 300°C for one minute.

Q: Is Gap Pad electrically isolating?

A: Yes, all Gap Pad materials are electrically isolating. However,

keep in mind that Gap Pad is designed to FILL gaps and is not

recommended for applications where high mounting pressure is

exerted on the Gap Pad.

Q: How much force will the pad place on my device?

A: Refer to the Pressure vs. Deflection charts in Bergquist

Application Note #116.

Q: Will Gap Pad and Gap Filler work in my application?

What size gaps will Gap Pad and Gap Filler

accommodate?

A: Gap Pad and Gap Filler can be used wherever air can be

replaced, such as between a heat-generating device and a heat

sink, heat spreader or housing.This can be done using one sheet

of Gap Pad or individual pieces of appropriate thicknesses, or by

using Gap Filler if stack-up tolerances and height variations

are significant.

Q: What is meant by “compliance” and “conformability,”

and why is this important?

A: The better a Gap Pad complies and conforms to a rough or

stepped surface, the less interfacial resistance will be present due

to air voids and air gaps.This leads to a lower overall thermal

resistance of the pad between the two interfaces.

Q: Is anything given off by the material

(e.g. extractables, outgassing)?

A: 1) Silicone Gap Pad and Gap Fillers, like all soft silicone materials,

can extract silicone fluid (refer to Bergquist Application Note

#56). Also note that Gap Pad and Gap Filler have some of the

lowest extraction values for silicone-based gap filling products on

the market and if your application requires no silicone, see our

line of Sil-Free material.

2) Primarily for aerospace applications, outgassing data is detailed

in Bergquist Application Note #117, tested per ASTM E595.

Q: Why does the data sheet describe the hardness rating

as a bulk rubber hardness?

A: A reinforcement carrier is generally utilized in Bergquist Gap Pads

for ease of handling.When testing hardness, the reinforcement

carrier can alter the test results and incorrectly depict thinner

materials as being harder.To eliminate this error, a 250 mil rubber

puck is molded with no reinforcement carrier.The puck is then

tested for hardness.The Shore hardness is recorded after a 30

second delay.

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GAP PAD

Gap Pad VO

Features and Benefits

• Thermal conductivity: 0.8 W/m-K

• Enhanced puncture, shear and tear resistance

• Conformable gap filling material

• Electrically isolating

Gap Pad VO is a cost-effective, thermally

conductive interface material.The material is a

filled, thermally conductive polymer supplied

on a rubber-coated fiberglass carrier allowing

for easy material handling.The conformable

nature of Gap Pad VO allows the pad to fill in

air gaps between PC boards and heat sinks

or a metal chassis.

Note: Resultant thickness is defined as the final gap

thickness of the application.

Conformable,Thermally Conductive Material for Filling Air Gaps

Typical Applications Include:

• Telecommunications

• Computer and peripherals

• Power conversion

• Between heat-generating semiconductors and a heat sink

• Area where heat needs to be transferred to a frame, chassis, or other type of heat spreader

• Between heat-generating magnetic components and a heat sink

Configurations Available:

• Sheet form and die-cut parts

Building a Part Number Standard Options

Gap Pad®: U.S. Patent 5,679,457 and others.

135791113

250

200

150

100

Thickness vs. Thermal Resistance

Gap Pad VO

Thermal Resistance (C-in2/W)

Resultant Thickness (mils)

Section A

Section B

Section C

Section D

Section E

NA = Selected standard option. If not selecting a standard

option, insert company name, drawing number, and

revision level.

GPVO = Gap Pad VO Material

GPVO 0.040 AC 0816 NA

Note: To build a part number, visit our website at www.bergquistcompany.com.

Standard thicknesses available: 0.020", 0.040", 0.060",

0.080", 0.100", 0.125", 0.160", 0.200", 0.250"

AC = Adhesive, one side

00 = No pressure sensitive adhesive

0816 = Standard sheet size 8" x 16" or

00 = custom configuration

––––

TYPICAL PROPERTIES OF GAP PAD VO

PROPERTY IMPERIAL VALUE METRIC VALUE TEST METHOD

Color Gold/Pink Gold/Pink Visual

Reinforcement Carrier Sil-Pad Sil-Pad —

Thickness (inch) / (mm) 0.020 to 0.250 0.508 to 6.350 ASTM D374

Inherent Surface Tack (1- or 2-sided) 1 1 —

Density (g/cc) 1.6 1.6 ASTM D792

Heat Capacity (J/g-K) 1.0 1.0 ASTM E1269

Hardness, Bulk Rubber (Shore 00) (1) 40 40 ASTM D2240

Young’s Modulus (psi) / (kPa) (2) 100 689 ASTM D575

Continuous Use Temp (°F) / (°C) -76 to 392 -60 to 200 —

ELECTRICAL

Dielectric Breakdown Voltage (Vac) >6000 >6000 ASTM D149

Dielectric Constant (1000 Hz) 5.5 5.5 ASTM D150

Volume Resistivity (Ohm-meter) 1011 1011 ASTM D257

Flame Rating V-O V-O U.L. 94

THERMAL

Thermal Conductivity (W/m-K) 0.8 0.8 ASTM D5470

1) Thirty second delay value Shore 00 hardness scale.

2) Young's Modulus, calculated using 0.01 in/min. step rate of strain with a sample size of 0.79 inch2. For more information on Gap Pad

modulus, refer to Bergquist Application Note #116.

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GAP PAD

Features and Benefits

• Thermal conductivity: 0.8 W/m-K

• Conformable, low hardness

• Enhanced puncture, shear and tear resistance

• Electrically isolating

Gap Pad VO Soft is recommended for

applications that require a minimum amount

of pressure on components. Gap Pad VO

Soft is a highly conformable, low-modulus,

filled-silicone polymer on a rubber-coated

fiberglass carrier. The material can be used

as an interface where one side is in contact

with a leaded device.

Note: Resultant thickness is defined as the final gap

thickness of the application.

Gap Pad VO Soft

Highly Conformable,Thermally Conductive Material for Filling Air Gaps

1234 8765910

200

180

160

140

120

100

Thickness vs. Thermal Resistance

Gap Pad VO Soft

Thermal Resistance (C-in2/W)

Resultant Thickness (mils)

Typical Applications Include:

• Telecommunications

• Computer and peripherals

• Power conversion

• Between heat-generating semiconductors or magnetic components and a heat sink

• Area where heat needs to be transferred to a frame, chassis, or other type of heat spreader

Configurations Available:

• Sheet form and die-cut parts

Building a Part Number Standard Options

Gap Pad®: U.S. Patent 5,679,457 and others.

Section A

Section B

Section C

Section D

Section E

NA = Selected standard option. If not selecting a standard

option, insert company name, drawing number, and

revision level.

GPVOS = Gap Pad VO Soft Material

GPVOS 0.060 AC 00 ACME10256 Rev. a

Note: To build a part number, visit our website at www.bergquistcompany.com.

Standard thicknesses available: 0.020", 0.040", 0.060",

0.080", 0.100", 0.125", 0.160", 0.200"

AC = Pressure sensitive adhesive, one side

00 = No pressure sensitive adhesive

0816 = Standard sheet size 8" x 16", or

00 = custom configuration

––––

TYPICAL PROPERTIES OF GAP PAD VO SOFT

PROPERTY IMPERIAL VALUE METRIC VALUE TEST METHOD

Color Mauve/Pink Mauve/Pink Visual

Reinforcement Carrier Sil-Pad Sil-Pad —

Thickness (inch) / (mm) 0.020 to 0.200 0.508 to 5.080 ASTM D374

Inherent Surface Tack (1- or 2-sided) 1 1 —

Density (g/cc) 1.6 1.6 ASTM D792

Heat Capacity (J/g-K) 1.0 1.0 ASTM E1269

Hardness, Bulk Rubber (Shore 00) (1) 25 25 ASTM D2240

Young’s Modulus (psi) / (kPa) (2) 40 275 ASTM D575

Continuous Use Temp (°F) / (°C) -76 to 392 -60 to 200 —

ELECTRICAL

Dielectric Breakdown Voltage (Vac) >6000 >6000 ASTM D149

Dielectric Constant (1000 Hz) 5.5 5.5 ASTM D150

Volume Resistivity (Ohm-meter) 1011 1011 ASTM D257

Flame Rating V-O V-O U.L. 94

THERMAL

Thermal Conductivity (W/m-K) 0.8 0.8 ASTM D5470

1) Thirty second delay value Shore 00 hardness scale.

2) Young's Modulus, calculated using 0.01 in/min. step rate of strain with a sample size of 0.79 inch2. For more information on Gap Pad

modulus, refer to Bergquist Application Note #116.

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GAP PAD

Gap Pad

VO Ultra Soft

Ultra Conformable,Thermally Conductive Material for Filling Air Gaps

Features and Benefits

• Thermal conductivity: 1.0 W/m-K

• Highly conformable, low hardness

• “Gel-like” modulus

• Designed for low-stress applications

• Puncture, shear and tear resistant

Gap Pad VO Ultra Soft is recommended for

applications that require a minimum amount

of pressure on components.The viscoelastic

nature of the material also gives excellent

low-stress vibration dampening and shock

absorbing characteristics. Gap Pad VO Ultra

Soft is an electrically isolating material, which

allows its use in applications requiring

isolation between heat sinks and high-voltage,

bare-leaded devices.

Note: Resultant thickness is defined as the final gap

thickness of the application.

Typical Applications Include:

• Telecommunications

• Computer and peripherals

• Power conversion

• Between heat-generating semiconductors or magnetic components and a heat sink

• Area where heat needs to be transferred to a frame, chassis, or other type of heat spreader

Configurations Available:

• Sheet form and die-cut parts

Building a Part Number Standard Options

Gap Pad®: U.S. Patent 5,679,457 and others.

123 5 846 9710

250

200

150

100

Thickness vs. Thermal Resistance

Gap Pad VO Ultra Soft

Thermal Resistance (C-in2/W)

Resultant Thickness (mils)

Section A

Section B

Section C

Section D

Section E

NA = Selected standard option. If not selecting a standard

option, insert company name, drawing number, and

revision level.

GPVOUS = Gap Pad VO Ultra Soft Material

GPVOUS 0.100 AC 0816 NA

Note: To build a part number, visit our website at www.bergquistcompany.com.

Standard thicknesses available: 0.020", 0.040", 0.060",

0.080", 0.100", 0.125", 0.160", 0.200", 0.250"

AC = Adhesive, one side

00 = No adhesive

0816 = Standard sheet size 8" x 16", or

00 = custom configuration

––––

TYPICAL PROPERTIES OF GAP PAD VO ULTRA SOFT

PROPERTY IMPERIAL VALUE METRIC VALUE TEST METHOD

Color Mauve/Pink Mauve/Pink Visual

Reinforcement Carrier Sil-Pad Sil-Pad —

Thickness (inch) / (mm) 0.020 to 0.250 0.508 to 6.350 ASTM D374

Inherent Surface Tack (1- or 2-sided) 1 1 —

Density (g/cc) 1.6 1.6 ASTM D792

Heat Capacity (J/g-K) 1.0 1.0 ASTM E1269

Hardness, Bulk Rubber (Shore 00) (1) 5 5 ASTM D2240

Young’s Modulus (psi) / (kPa) (2) 8 55 ASTM D575

Continuous Use Temp (°F) / (°C) -76 to 392 -60 to 200 —

ELECTRICAL

Dielectric Breakdown Voltage (Vac) >6000 >6000 ASTM D149

Dielectric Constant (1000 Hz) 5.5 5.5 ASTM D150

Volume Resistivity (Ohm-meter) 1011 1011 ASTM D257

Flame Rating V-O V-O U.L. 94

THERMAL

Thermal Conductivity (W/m-K) 1.0 1.0 ASTM D5470

1) Thirty second delay value Shore 00 hardness scale.

2) Young's Modulus, calculated using 0.01 in/min. step rate of strain with a sample size of 0.79 inch2. For more information on Gap Pad

modulus, refer to Bergquist Application Note #116.

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GAP PAD

Gap Pad

1000SF

Thermally Conductive, Silicone-Free Gap Filling Material

Features and Benefits

• Thermal conductivity: 0.9 W/m-K

• No silicone outgassing

• No silicone extraction

• Reduced tack on one side to aid in

application assembly

The new Gap Pad 1000SF is a thermally

conductive, electrically insulating, silicone-

free polymer specially designed for

silicone-sensitive applications.The material

is ideal for applications with high standoff

and flatness tolerances. Gap Pad 1000SF is

reinforced for easy material handling and

added durability during assembly.The

material is available with a protective liner

on both sides of the material.

Note: Resultant thickness is defined as the final gap

thickness of the application.

012 435

125

100

Thickness vs. Thermal Resistance

Gap Pad 1000SF

Thermal Resistance (C-in2/W)

Resultant Thickness (mils)

Typical Applications Include:

• Digital disk drives / CD-ROM

• Automotive modules

• Fiber optics modules

Configurations Available:

• Sheet form

• Die-cut parts

Building a Part Number Standard Options

Gap Pad®: U.S. Patent 5,679,457 and others.

Section A

Section B

Section C

Section D

Section E

NA = Selected standard option. If not selecting a standard

option, insert company name, drawing number, and

revision level.

GP1000SF = Gap Pad 1000SF Material

GP1000SF 0.010 02 0816 NA

Note: To build a part number, visit our website at www.bergquistcompany.com.

Standard thicknesses available: 0.010", 0.015", 0.020",

0.040", 0.060", 0.080", 0.100", 0.125"

02 = Natural tack, both sides

0806: = Standard sheet size 8" x 16", or

00 = custom configuration

––––

TYPICAL PROPERTIES OF GAP PAD 1000SF

PROPERTY IMPERIAL VALUE METRIC VALUE TEST METHOD

Color Green Green Visual

Reinforcement Carrier Fiberglass Fiberglass —

Thickness (inch) / (mm) 0.010 to 0.125 0.254 to 3.175 ASTM D374

Inherent Surface Tack (1- or 2-sided) 2 2 —

Density (g/cc) 2.0 2.0 ASTM D792

Heat Capacity (J/g-K) 1.1 1.1 ASTM E1269

Hardness, Bulk Rubber (Shore 00) (1) 40 40 ASTM D2240

Young’s Modulus (psi) / (kPa) (2) 34 234 ASTM D575

Continuous Use Temp (°F) / (°C) -76 to 257 -60 to 125 —

ELECTRICAL

Dielectric Breakdown Voltage (Vac) >6000 >6000 ASTM D149

Dielectric Constant (1000 Hz) 5.0 5.0 ASTM D150

Volume Resistivity (Ohm-meter) 1010 1010 ASTM D257

Flame Rating V- 1 V-1 U.L. 94

THERMAL

Thermal Conductivity (W/m-K) 0.9 0.9 ASTM D5470

1) Thirty second delay value Shore 00 hardness scale.

2) Young's Modulus, calculated using 0.01 in/min. step rate of strain with a sample size of 0.79 inch2. For more information on Gap Pad

modulus, refer to Bergquist Application Note #116.

SEL_SP_0906_Chpt1.qxp 10/20/2006 10:19 AM Page 12

GAP PAD

Gap Pad

HC1000

“Gel-Like” Modulus Gap Filling Material

Features and Benefits

• Thermal conductivity: 1.0 W/m-K

• Highly conformable, low hardness

• “Gel-like” modulus

• Fiberglass reinforced for puncture,

shear and tear resistance

Gap Pad HC 1000 is an extremely conformable,

low-modulus polymer that acts as a thermal

interface and electrical insulator between

electronic components and heat sinks.The

“gel-like” modulus allows this material to fill

air gaps to enhance the thermal performance

of electronic systems. Gap Pad HC1000 is

offered with removable protective liners on

both sides of the material.

Note: Resultant thickness is defined as the final gap

thickness of the application.

0.25 0.30 0.400.35 0.500.45 0.55

Thickness vs. Thermal Resistance

Gap Pad HC100

Thermal Resistance (C-in2/W)

Resultant Thickness (mils)

Typical Applications Include:

• Computer and peripherals

• Telecommunications

• Heat interfaces to frames, chassis, or other heat spreading devices

• RDRAM™ memory modules / chip scale packages

• CDROM / DVD cooling

• Areas where irregular surfaces need to make a thermal interface to a heat sink

• DDR SDRAM memory modules

• FBDIMM modules

Configurations Available:

• Sheet form, die-cut parts, and roll form (converted or unconverted)

Building a Part Number Standard Options

Gap Pad®: U.S. Patent 5,679,457 and others.

Section A

Section B

Section C

Section D

Section E

NA = Selected standard option. If not selecting a standard

option, insert company name, drawing number, and

revision level.

HC1000 = High Compliance 1000 Material

HC1000 0.015 02 0816 NA

Note: To build a part number, visit our website at www.bergquistcompany.com.

Standard thicknesses available: 0.010", 0.015", 0.020"

02 = Natural tack, both sides

0816 = Standard sheet size 8" x 16", or

00 = custom configuration

––––

TYPICAL PROPERTIES OF GAP PAD HC1000

PROPERTY IMPERIAL VALUE METRIC VALUE TEST METHOD

Color Gray Gray Visual

Reinforcement Carrier Fiberglass Fiberglass —

Thickness (inch) / (mm) 0.010 to 0.020 0.254 to 0.508 ASTM D374

Inherent Surface Tack (1- or 2-sided) 2 2 —

Density (g/cc) 1.6 1.6 ASTM D792

Heat Capacity (J/g-K) 1.0 1.0 ASTM E1269

Hardness, Bulk Rubber (Shore 00) (1) 25 25 ASTM D2240

Young’s Modulus (psi) / (kPa) (2) 40 275 ASTM D575

Continuous Use Temp (°F) / (°C) -76 to 392 -60 to 200 —

ELECTRICAL

Dielectric Breakdown Voltage (Vac) >5000 >5000 ASTM D149

Dielectric Constant (1000 Hz) 5.5 5.5 ASTM D150

Volume Resistivity (Ohm-meter) 1011 1011 ASTM D257

Flame Rating V-O V-O U.L. 94

THERMAL

Thermal Conductivity (W/m-K) 1.0 1.0 ASTM D5470

1) Thirty second delay value Shore 00 hardness scale.

2) Young's Modulus, calculated using 0.01 in/min. step rate of strain with a sample size of 0.79 inch2and 0.020 inches thick. For more

information on Gap Pad modulus, refer to Bergquist Application Note #116.

SEL_SP_0906_Chpt1.qxp 10/20/2006 10:19 AM Page 13

GAP PAD

Gap Pad

1500

Thermally Conductive, Unreinforced Gap Filling Material

Features and Benefits

• Thermal conductivity: 1.5 W/m-K

• Unreinforced construction for additional

compliancy

• Conformable, low hardness

• Electrically isolating

Gap Pad 1500 has an ideal filler blend that

gives it a low-modulus characteristic that

maintains optimal thermal performance yet

still allows for easy handling.The natural tack

on both sides of the material allows for

good compliance to adjacent surfaces of

components, minimizing interfacial resistance.

Note: Resultant thickness is defined as the final gap

thickness of the application.

01 32546

200

150

100

Thickness vs. Thermal Resistance

Gap Pad 1500

Thermal Resistance (C-in2/W)

Resultant Thickness (mils)

Typical Applications Include:

• Telecommunications

• Computer and peripherals

• Power conversion

• RDRAM™ memory modules / chip scale packages

• Areas where heat needs to be transferred to a frame chassis or other type of heat spreader

Configurations Available:

• Sheet form and die-cut parts

Building a Part Number Standard Options

Gap Pad®: U.S. Patent 5,679,457 and others.

Section A

Section B

Section C

Section D

Section E

NA = Selected standard option. If not selecting a standard

option, insert company name, drawing number, and

revision level.

GP1500 = Gap Pad 1500 Material

GP1500 0.100 02 0816 NA

Note: To build a part number, visit our website at www.bergquistcompany.com.

Standard thicknesses available: 0.020", 0.040", 0.060",

0.080", 0.100", 0.125", 0.160", 0.200"

02 = Natural tack, both sides

0816 = Standard sheet size 8" x 16", or

00 = custom configuration

––––

TYPICAL PROPERTIES OF GAP PAD 1500

PROPERTY IMPERIAL VALUE METRIC VALUE TEST METHOD

Color Black Black Visual

Reinforcement Carrier ———

Thickness (inch) / (mm) 0.020 to 0.200 0.508 to 5.080 ASTM D374

Inherent Surface Tack (1- or 2-sided) 2 2 —

Density (g/cc) 2.1 2.1 ASTM D792

Heat Capacity (J/g-K) 1.0 1.0 ASTM E1269

Hardness, Bulk Rubber (Shore 00) (1) 40 40 ASTM D2240

Young’s Modulus (psi) / (kPa) (2) 45 310 ASTM D575

Continuous Use Temp (°F) / (°C) -76 to 392 -60 to 200 —

ELECTRICAL

Dielectric Breakdown Voltage (Vac) >6000 >6000 ASTM D149

Dielectric Constant (1000 Hz) 5.5 5.5 ASTM D150

Volume Resistivity (Ohm-meter) 1011 1011 ASTM D257

Flame Rating V-O V-O U.L. 94

THERMAL

Thermal Conductivity (W/m-K) 1.5 1.5 ASTM D5470

1) Thirty second delay value Shore 00 hardness scale.

2) Young's Modulus, calculated using 0.01 in/min. step rate of strain with a sample size of 0.79 inch2. For more information on Gap Pad

modulus, refer to Bergquist Application Note #116.

SEL_SP_0906_Chpt1.qxp 10/20/2006 10:19 AM Page 14

GAP PAD

Gap Pad

1500R

Features and Benefits

• Thermal conductivity: 1.5 W/m-K

• Fiberglass reinforced for puncture, shear

and tear resistance

• Easy release construction

• Electrically isolating

Gap Pad 1500R has the same highly

conformable, low-modulus polymer as the

standard Gap Pad 1500.The fiberglass

reinforcement allows for easy material handling

and enhances puncture, shear and tear

resistance.The natural tack on both sides of

the material allows for good compliance to

mating surfaces of components, further

reducing thermal resistance.

Note: Resultant thickness is defined as the final gap

thickness of the application.

Thermally Conductive, Reinforced Gap Filling Material

0.25 0.30 0.400.35 0.500.45 0.55

Thickness vs. Thermal Resistance

Gap Pad 1500R

Thermal Resistance (C-in2/W)

Resultant Thickness (mils)

Typical Applications Include:

• Telecommunications

• Computer and peripherals

• Power conversion

• RDRAM™ memory modules / chip scale packages

• Areas where heat needs to be transferred to a frame chassis or other type of heat spreader

Configurations Available:

• Sheet form, die-cut parts, and roll form (converted or unconverted)

Building a Part Number Standard Options

Gap Pad®: U.S. Patent 5,679,457 and others.

Section A

Section B

Section C

Section D

Section E

NA = Selected standard option. If not selecting a standard

option, insert company name, drawing number, and

revision level.

GP1500R = Gap Pad 1500R Material

GP1500R 0.020 02 00 ACME10256 Rev. A

Note: To build a part number, visit our website at www.bergquistcompany.com.

Standard thicknesses available: 0.010", 0.015", 0.020"

02 = Natural tack, both sides

0816 = Standard sheet size 8" x 16", or

00 = custom configuration

––––

TYPICAL PROPERTIES OF GAP PAD 1500R

PROPERTY IMPERIAL VALUE METRIC VALUE TEST METHOD

Color Black Black Visual

Reinforcement Carrier Fiberglass Fiberglass —

Thickness (inch) / (mm) 0.010 to 0.020 0.254 to 0.508 ASTM D374

Inherent Surface Tack (1- or 2-sided) 2 2 —

Density (g/cc) 2.1 2.1 ASTM D792

Heat Capacity (J/g-K) 1.3 1.3 ASTM E1269

Hardness, Bulk Rubber (Shore 00) (1) 40 40 ASTM D2240

Young’s Modulus (psi) / (kPa) (2) 45 310 ASTM D575

Continuous Use Temp (°F) / (°C) -76 to 392 -60 to 200 —

ELECTRICAL

Dielectric Breakdown Voltage (Vac) >6000 >6000 ASTM D149

Dielectric Constant (1000 Hz) 6.0 6.0 ASTM D150

Volume Resistivity (Ohm-meter) 1011 1011 ASTM D257

Flame Rating V-O V-O U.L. 94

THERMAL

Thermal Conductivity (W/m-K) 1.5 1.5 ASTM D5470

1) Thirty second delay value Shore 00 hardness scale.

2) Young's Modulus, calculated using 0.01 in/min. step rate of strain with a sample size of 0.79 inch2. For more information on Gap Pad

modulus, refer to Bergquist Application Note #116.

SEL_SP_0906_Chpt1.qxp 10/20/2006 10:19 AM Page 15

GAP PAD

Gap Pad

A2000

High Performance,Thermally Conductive Gap Filling Material

Features and Benefits

• Thermal conductivity: 2.0 W/m-K

• Fiberglass reinforced for puncture, shear

and tear resistance

• Electrically isolating

Gap Pad A2000 acts as a thermal interface

and electrical insulator between electronic

components and heat sinks. In the thickness

range of 10 to 40 mil, Gap Pad A2000 is

supplied with natural tack on both sides,

allowing for excellent compliance to the

adjacent surfaces of components.The 40 mil

material thickness is supplied with lower tack

on one side, allowing for burn-in processes

and easy rework.

Note: Resultant thickness is defined as the final gap

thickness of the application.

Typical Applications Include:

• Computer and peripherals; between CPU and heat spreader

• Telecommunications

• Heat pipe assemblies

• RDRAM™ memory modules

• CDROM / DVD cooling

• Areas where heat needs to be transferred to a frame chassis or other type of heat spreader

• DDR SDRAM memory modules

Configurations Available:

• Sheet form, die-cut parts and roll form (converted or unconverted)

Building a Part Number Standard Options

Gap Pad®: U.S. Patent 5,679,457 and others.

0.20 0.30 0.500.40 0.700.60 0.80

Thickness vs. Thermal Resistance

Gap Pad A2000

Thermal Resistance (C-in2/W)

Resultant Thickness (mils)

Section A

Section B

Section C

Section D

Section E

NA = Selected standard option. If not selecting a standard

option, insert company name, drawing number, and

revision level.

GPA2000 = Gap Pad A2000 Material

GPA2000 0.010 02 0816 NA

Note: To build a part number, visit our website at www.bergquistcompany.com.

Standard thicknesses available: 0.010", 0.015", 0.020"

0.040"

02 = Natural tack, both sides

0816 = Standard sheet size 8" x 16", or

00 = custom configuration

––––

TYPICAL PROPERTIES OF GAP PAD A2000

PROPERTY IMPERIAL VALUE METRIC VALUE TEST METHOD

Color Gray Gray Visual

Reinforcement Carrier Fiberglass Fiberglass —

Thickness (inch) / (mm) 0.010 to 0.040 0.254 to 1.016 ASTM D374

Inherent Surface Tack (1- or 2-sided) 2 2 —

Density (g/cc) 2.9 2.9 ASTM D792

Heat Capacity (J/g-K) 1.0 1.0 ASTM E1269

Hardness, Bulk Rubber (Shore 00) (1) 80 80 ASTM D2240

Young’s Modulus (psi) / (kPa) (2) 55 379 ASTM D575

Continuous Use Temp (°F) / (°C) -76 to 392 -60 to 200 —

ELECTRICAL

Dielectric Breakdown Voltage (Vac) >4000 >4000 ASTM D149

Dielectric Constant (1000 Hz) 6.0 6.0 ASTM D150

Volume Resistivity (Ohm-meter) 1011 1011 ASTM D257

Flame Rating V-O V-O U.L. 94

THERMAL

Thermal Conductivity (W/m-K) 2.0 2.0 ASTM D5470

1) Thirty second delay value Shore 00 hardness scale.

2) Young's Modulus, calculated using 0.01 in/min. step rate of strain with a sample size of 0.79 inch2. For more information on Gap Pad

modulus, refer to Bergquist Application Note #116.

SEL_SP_0906_Chpt1.qxp 10/20/2006 10:19 AM Page 16

GAP PAD

Gap Pad

2000S40

Highly Conformable,Thermally Conductive, Reinforced “S-Class” Gap Filling Material

Features and Benefits

• Thermal conductivity: 2.0 W/m-K

• Low “S-Class” thermal resistance at very

low pressures

• Highly conformable, low hardness

• Designed for low-stress applications

• Fiberglass reinforced for puncture, shear

and tear resistance

Gap Pad 2000S40 is recommended for low-

stress applications that require a mid to high

thermally conductive interface material.The

highly conformable nature of the material

allows the pad to fill in air voids and air gaps

between PC boards and heat sinks or metal

chassis with stepped topography, rough

surfaces and high stack-up tolerances.

Gap Pad 2000S40 is electrically isolating, and

well suited for applications requiring electrical

isolation between heat sinks and high-voltage,

bare-leaded devices. Gap Pad 2000S40 is a

filled, thermally conductive polymer reinforced

with a fiberglass carrier on one side, allowing

for easy material handling and enhanced

puncture, shear and tear resistance.

Note: Resultant thickness is defined as the final gap

thickness of the application.

Typical Applications Include:

• Power electronics DC/DC; 1/4, 1/2, full bricks, etc.

• Mass storage devices

• Graphics card/processor/ASIC

• Wireline/wireless communications hardware

• Automotive engine/transmission controls

Configurations Available:

• Sheet form and die-cut parts

Building a Part Number Standard Options

Gap Pad®: U.S. Patent 5,679,457 and others.

Section A

Section B

Section C

Section D

Section E

NA = Selected standard option. If not selecting a standard

option, insert company name, drawing number, and

revision level.

GP2000S40 = Gap Pad 2000S40 Material

GP2000S40 0.020 02 0816 NA

Note: To build a part number, visit our website at www.bergquistcompany.com.

Standard thicknesses available: 0.020", 0.040", 0.060",

0.080", 0.100", 0.125"

02 = Natural tack, both sides

0816 = Standard sheet size 8" x 16", or

00 = custom configuration

––––

TYPICAL PROPERTIES OF GAP PAD 2000S40

PROPERTY IMPERIAL VALUE METRIC VALUE TEST METHOD

Color Gray Gray Visual

Reinforcement Carrier Fiberglass Fiberglass —

Thickness (inch) / (mm) 0.020 to 0.125 0.508 to 3.175 ASTM D374

Inherent Surface Tack (1- or 2-sided) 2 2 —

Density (g/cc) 2.9 2.9 ASTM D792

Heat Capacity (J/g-K) 0.6 0.6 ASTM E1269

Hardness, Bulk Rubber (Shore 00) (1) 30 30 ASTM D2240

Young’s Modulus (psi) / (kPa) (2) 45 310 ASTM D575

Continuous Use Temp (°F) / (°C) -76 to 392 -60 to 200 —

ELECTRICAL

Dielectric Breakdown Voltage (Vac) >5000 >5000 ASTM D149

Dielectric Constant (1000 Hz) 6.0 6.0 ASTM D150

Volume Resistivity (Ohm-meter) 1011 1011 ASTM D257

Flame Rating V-O V-O U.L. 94

THERMAL

Thermal Conductivity (W/m-K) 2.0 2.0 ASTM D5470

1) Thirty second delay value Shore 00 hardness scale.

2) Young's Modulus, calculated using 0.01 in/min. step rate of strain with a sample size of 0.79 inch2. For more information on Gap Pad

modulus, refer to Bergquist Application Note #116.

0 0.50 1.501.00 2.00 2.50

125

100

Thickness vs. Thermal Resistance

Gap Pad 2000S40

Thermal Resistance (C-in2/W)

Resultant Thickness (mils)

SEL_SP_0906_Chpt1.qxp 10/20/2006 10:19 AM Page 17

GAP PAD

Gap Pad

2500S20

Features and Benefits

• Thermal conductivity: 2.4 W/m-K

• Low “S-Class” thermal resistance at

ultra-low pressures

• Ultra conformable, “gel-like” modulus

• Designed for low-stress applications

• Fiberglass reinforced for puncture, shear

and tear resistance

Gap Pad 2500S20 is a thermally conductive,

reinforced material rated at a thermal

conductivity of 2.4 W/m-K.The material is a

filled-polymer material yielding extremely soft,

elastic characteristics.The material is reinforced

to provide easy handling, converting, added

electrical isolation and tear resistance. Gap

Pad 2500S20 is well suited for low-pressure

applications that typically use fixed standoff or

clip mounting.The material maintains a

conformable, yet elastic nature that allows for

excellent interfacing and wet-out

characteristics, even to surfaces with high

roughness and/or topography.

Gap Pad 2500S20 is offered with inherent

natural tack on both sides of the material

allowing for stick-in-place characteristics during

application assembly.The material is supplied

with protective liners on both sides.

Note: Resultant thickness is defined as the final gap

thickness of the application.

Typical Applications

• Between processors and heat sinks

• Between graphics chips and heat sinks

• DVD and CDROM electronics cooling

• Areas where heat needs to be transferred to a frame, chassis or other type of heat spreader

Configurations Available:

• Sheet form and die-cut parts

Building a Part Number Standard Options

Gap Pad®: U.S. Patent 5,679,457 and others.

Highly Conformable,Thermally Conductive, Reinforced “S-Class” Gap Filling Material

Section A

Section B

Section C

Section D

Section E

NA = Selected standard option. If not selecting a standard

option, insert company name, drawing number, and

revision level.

GP2500S20 = Gap Pad 2500S20 Material

GP2500S20 0.100 02 00 ACME 89302 Rev a

Note: To build a part number, visit our website at www.bergquistcompany.com.

Standard thicknesses available: 0.010", 0.015", 0.020",

0.040", 0.060", 0.080", 0.100", 0.125"

02 = Natural tack, both sides

0816 = Standard sheet size 8" x 16", or

00 = custom configuration

––––

TYPICAL PROPERTIES OF GAP PAD 2500S20

PROPERTY IMPERIAL VALUE METRIC VALUE TEST METHOD

Color Light Yellow Light Yellow Visual

Reinforcement Carrier Fiberglass Fiberglass —

Thickness (inch) / (mm) 0.010 to 0.125 0.254 to 3.175 ASTM D374

Inherent Surface Tack (1- or 2-sided) 2 2 —

Density (g/cc) 3.1 3.1 ASTM D792

Heat Capacity (J/g-K) 1.0 1.0 ASTM E1269

Hardness, Bulk Rubber (Shore 00) (1) 20 20 ASTM D2240

Young’s Modulus (psi) / (kPa) (2) 5 35 ASTM D575

Continuous Use Temp (°F) / (°C) -76 to 392 -60 to 200 —

ELECTRICAL

Dielectric Breakdown Voltage (Vac) >3000 >3000 ASTM D149

Dielectric Constant (1000 Hz) 6.6 6.6 ASTM D150

Volume Resistivity (Ohm-meter) 1011 1011 ASTM D257

Flame Rating V-O V-O U.L. 94

THERMAL

Thermal Conductivity (W/m-K) 2.4 2.4 ASTM D5470

1) Thirty second delay value Shore 00 hardness scale.

2) Young's Modulus, calculated using 0.01 in/min. step rate of strain with a sample size of 0.79 inch2. For more information on Gap Pad

modulus, refer to Bergquist Application Note #116.

0.18 0.43 1.180.68 0.93 1.43 1.68 1.93 2.18

130

110

Thickness vs. Thermal Resistance

Gap Pad 2500S20

Thermal Resistance (C-in2/W)

Resultant Thickness (mils)

SEL_SP_0906_Chpt1.qxp 10/20/2006 10:19 AM Page 18

GAP PAD

Gap Pad

2500

Features and Benefits

• Thermal conductivity: 2.7 W/m-K

• High thermal performance, cost-effective

solution

• Unreinforced construction for additional

compliancy

• Medium compliancy and conformability

Gap Pad 2500 is a thermally conductive,

electrically insulating, unreinforced gap filling

material. Gap Pad 2500 is a filled-polymer

material yielding an elastic polymer that allows

for easy handling and converting without the

need for reinforcement.These properties also

allow for good wet-out and interfacing char-

acteristics to surfaces with roughness

and/or topography. All these characteristics

make this material ideal for applications using

either clip or screw-mounted assemblies.

Gap Pad 2500 is offered with inherent

natural tack on both sides of the material

allowing for stick-in-place characteristics

during application assembly.The material is

supplied with protective liners on both sides.

Note: Resultant thickness is defined as the final gap

thickness of the application.

Thermally Conductive, Unreinforced Gap Filling Material

Typical Applications Include:

• Multiple heat-generating components to a common heat sink

• Graphics chips to heat sinks

• Processors to heat sinks

• Mass storage drives

• Wireline / wireless communications hardware

Configurations Available:

• Sheet form and die-cut parts

Building a Part Number Standard Options

Gap Pad®: U.S. Patent 5,679,457 and others.

Section A

Section B

Section C

Section D

Section E

NA = Selected standard option. If not selecting a standard

option, insert company name, drawing number, and

revision level.

GP2500 = Gap Pad 2500 Material

GP2500 0.100 02 00 ACME 89302 Rev a

Note: To build a part number, visit our website at www.bergquistcompany.com.

Standard thicknesses available: 0.020", 0.040", 0.060",

0.080", 0.100", 0.125"

02 = Natural tack, both sides

0816 = Standard sheet size 8" x 16", or

00 = custom configuration

––––

TYPICAL PROPERTIES OF GAP PAD 2500

PROPERTY IMPERIAL VALUE METRIC VALUE TEST METHOD

Color Light Brown Light Brown Visual

Reinforcement Carrier ———

Thickness (inch) / (mm) 0.020 to 0.125 0.508 to 3.175 ASTM D374

Inherent Surface Tack (1- or 2-sided) 2 2 —

Density (g/cc) 3.1 3.1 ASTM D792

Heat Capacity (J/g-K) 1.0 1.0 ASTM E1269

Hardness, Bulk Rubber (Shore 00) (1) 80 80 ASTM D2240

Young’s Modulus (psi) / (kPa) (2) 113 779 ASTM D575

Continuous Use Temp (°F) / (°C) -76 to 392 -60 to 200 —

ELECTRICAL

Dielectric Breakdown Voltage (Vac) >6000 >6000 ASTM D149

Dielectric Constant (1000 Hz) 6.8 6.8 ASTM D150

Volume Resistivity (Ohm-meter) 1011 1011 ASTM D257

Flame Rating V-O V-O U.L. 94

THERMAL

Thermal Conductivity (W/m-K) 2.7 2.7 ASTM D5470

1) Thirty second delay value Shore 00 hardness scale.

2) Young's Modulus, calculated using 0.01 in/min. step rate of strain with a sample size of 0.79 inch2. For more information on Gap Pad

modulus, refer to Bergquist Application Note #116.

0.20 0.60 1.00 1.40 1.80

120

100

Thickness vs. Thermal Resistance

Gap Pad 2500

Thermal Resistance (C-in2/W)

Resultant Thickness (mils)

SEL_SP_0906_Chpt1.qxp 10/20/2006 10:19 AM Page 19

GAP PAD

Gap Pad

A3000

Features and Benefits

• Thermal conductivity: 2.6 W/m-K

• Fiberglass reinforced for puncture, shear

and tear resistance

• Reduced tack on one side to aid in

application assembly

• Electrically isolating

Gap Pad A3000 is a thermally conductive,

filled-polymer laminate, supplied on a

reinforcing mesh for added electrical isolation,

easy material handling and enhanced puncture,

shear and tear resistance. Gap Pad A3000

has a reinforcement layer on the dark gold

side of the material that assists in burn-in

and rework processes while the light gold

and soft side of the material allows for

added compliance.

Note: Resultant thickness is defined as the final gap

thickness of the application.

Typical Applications Include:

• Computer and peripherals • Telecommunications

• Heat pipe assemblies • RDRAM™ memory modules

• CDROM / DVD cooling • Between CPU and heat spreader

• Area where heat needs to be transferred to a frame, chassis or other type of heat spreader

Configurations Available:

• Sheet form, die-cut parts and roll form (converted or unconverted)

Building a Part Number Standard Options

Gap Pad®: U.S. Patent 5,679,457 and others.

Thermally Conductive, Reinforced Gap Filling Material

0.10 0.30 0.50 0.70 1.100.90 1.501.30 1.70

125

115

105

Thickness vs. Thermal Resistance

Gap Pad A3000

Thermal Resistance (C-in2/W)

Resultant Thickness (mils)

Section A

Section B

Section C

Section D

Section E

NA = Selected standard option. If not selecting a standard

option, insert company name, drawing number, and

revision level.

GPA3000 = Gap Pad A3000 Material

GPA3000 0.015 01 0816 NA

Note: To build a part number, visit our website at www.bergquistcompany.com.

Standard thicknesses available: 0.015", 0.020", 0.040",

0.060", 0.080", 0.100", 0.125"

01 = Natural tack, one side

0816 = Standard sheet size 8" x 16", or

00 = custom configuration

––––

TYPICAL PROPERTIES OF GAP PAD A3000

PROPERTY IMPERIAL VALUE METRIC VALUE TEST METHOD

Color Gold Gold Visual

Reinforcement Carrier Fiberglass Fiberglass —

Thickness (inch) / (mm) 0.015 to 0.125 0.381 to 3.175 ASTM D374

Inherent Surface Tack (1- or 2-sided) 1 1 —

Density (g/cc) 3.2 3.2 ASTM D792

Heat Capacity (J/g-K) 1.0 1.0 ASTM E1269

Hardness, Bulk Rubber (Shore 00) (1) 80 80 ASTM D2240

Young’s Modulus (psi) / (kPa) (2) 50 344 ASTM D575

Continuous Use Temp (°F) / (°C) -76 to 392 -60 to 200 —

ELECTRICAL

Dielectric Breakdown Voltage (Vac) >5000 >5000 ASTM D149

Dielectric Constant (1000 Hz) 7.0 7.0 ASTM D150

Volume Resistivity (Ohm-meter) 1010 1010 ASTM D257

Flame Rating V-O V-O U.L. 94

THERMAL

Thermal Conductivity (W/m-K) 2.6 2.6 ASTM D5470

1) Thirty second delay value Shore 00 hardness scale.

2) Young's Modulus, calculated using 0.01 in/min. step rate of strain with a sample size of 0.79 inch2. For more information on Gap Pad

modulus, refer to Bergquist Application Note #116.

SEL_SP_0906_Chpt1.qxp 10/20/2006 10:20 AM Page 20

GAP PAD

Gap Pad

3000S30

Features and Benefits

• Thermal conductivity: 3.0 W/m-K

• Low “S-Class” thermal resistance at very

low pressures

• Highly conformable, “S-Class” softness

• Designed for low-stress applications

• Fiberglass reinforced for puncture, shear

and tear resistance

Gap Pad 3000S30 is a soft gap filling material

rated at a thermal conductivity of 3 W/m-K.

The material offers exceptional thermal

performance at low pressures due to an all-

new 3 W/m-K filler package and low-modulus

resin formulation. It is reinforced to enhance

material handling, puncture, shear and tear

resistance. It is well suited for high perform-

ance, low-stress applications that typically use

fixed standoff or clip mounting. Gap Pad

3000S30 maintains a conformable yet elastic

nature that allows for excellent interfacing

and wet-out characteristics, even to surfaces

with high roughness and/or topography.

Gap Pad 3000S30 is offered with natural

inherent tack on both sides of the material,

eliminating the need for thermally-impeding

adhesive layers.The material’s natural inherent

tack allows for stick-in-place characteristics

during assembly. Gap Pad 3000S30 is supplied

with protective liners on both sides.

Note: Resultant thickness is defined as the final gap

thickness of the application.

Thermally Conductive, Reinforced, Soft “S-Class” Gap Filling Material

Typical Applications:

• Processors • Notebook computers

• Server S-RAMs • BGA packages

• Mass storage drives • Power conversion

• Wireline / wireless communications hardware

Configurations Available:

• Sheet form and die-cut parts available

Building a Part Number Standard Options

Gap Pad®: U.S. Patent 5,679,457 and others.

Section A

Section B

Section C

Section D

Section E

NA = Selected standard option. If not selecting a standard

option, insert company name, drawing number, and

revision level.

GP3000S30 = Gap Pad 3000S30 Material

GP3000S30 0.020 02 0816 ACME 89302 Rev a

Note: To build a part number, visit our website at www.bergquistcompany.com.

Standard thicknesses available: 0.010", 0.015", 0.020",

0.040", 0.060", 0.080", 0.100", 0.125"

02 = Natural tack, both sides

0816 = Standard sheet size 8" x 16", or

00 = custom configuration

––––

0.10 1.701.501.301.100.900.700.500.30

130

110

Thickness vs. Thermal Resistance

Gap Pad 3000S30

Thermal Resistance

(

C-in2/W

)

Resultant Thickness (mils)

TYPICAL PROPERTIES OF GAP PAD 3000S30

PROPERTY IMPERIAL VALUE METRIC VALUE TEST METHOD

Color Light Blue Light Blue Visual

Reinforcement Carrier Fiberglass Fiberglass —

Thickness (inch) / (mm) 0.010 to 0.125 0.254 to 3.175 ASTM D374

Inherent Surface Tack (1- or 2-sided) 2 2 —

Density (g/cc) 3.2 3.2 ASTM D792

Heat Capacity (J/g-K) 1.0 1.0 ASTM E1269

Hardness, Bulk Rubber (Shore 00) (1) 30 30 ASTM D2240

Young’s Modulus (psi) / (kPa) (2) 26 180 ASTM D575

Continuous Use Temp (°F) / (°C) -76 to 392 -60 to 200 —

ELECTRICAL

Dielectric Breakdown Voltage (Vac) >3000 >3000 ASTM D149

Dielectric Constant (1000 Hz) 7.0 7.0 ASTM D150

Volume Resistivity (Ohm-meter) 109109ASTM D257

Flame Rating V-O V-O U.L. 94

THERMAL

Thermal Conductivity (W/m-K) 3.0 3.0 ASTM D5470

1) Thirty second delay value Shore 00 hardness scale.

2) Young's Modulus, calculated using 0.01 in/min. step rate of strain with a sample size of 0.79 inch2. For more information on Gap Pad

modulus, refer to Bergquist Application Note #116.

SEL_SP_0906_Chpt1.qxp 10/20/2006 10:20 AM Page 21

GAP PAD

Gap Pad

5000S35

High thermal conductivity plus “S-Class” softness and conformability

Features and Benefits

• High thermal conductivity: 5 W/m-K

• Highly conformable,“S-Class” softness

• Natural inherent tack reduces interfacial

thermal resistance

• Conforms to demanding contours

and maintains structural integrity with

little or no stress applied to fragile

component leads

• Fiberglass reinforced for puncture, shear

and tear resistance

• Excellent thermal performance at

low pressures

Gap Pad 5000S35 is a fiberglass-reinforced

filler and polymer featuring a high thermal

conductivity.The material yields extremely

soft characteristics while maintaining elasticity

and conformability.The fiberglass reinforcement

provides easy handling and converting, added

electrical isolation and tear resistance.The

inherent natural tack on both sides assists in

application and allows the product to effec-

tively fill air gaps, enhancing the overall ther-

mal performance. Gap Pad 5000S35 is ideal

for high-performance applications at low mount-

ing pressures.

Typical Applications

• CDROM / DVD ROM

• Voltage Regulator Modules ( VRMs) and POLs

• Thermally-enhanced BGAs

Configurations Available:

• Die-cut parts are available in any shape or size, separated or in sheet form

• Standard material thicknesses of 20, 40, 60, 80, 100 and 125 mil

• Custom thicknesses available upon request

Building a Part Number Standard Options

Gap Pad®: U.S. Patent 5,679,457 and others.

• Memory packages / modules

• PC Board to chassis

• ASICs and DSPs

TYPICAL PROPERTIES OF GAP PAD 5000S35

PROPERTY IMPERIAL VALUE METRIC VALUE TEST METHOD

Color Light Green Light Green Visual

Reinforcement Carrier Fiberglass Fiberglass —

Thickness (inch) / (mm) 0.02 to 0.125 0.508 to 3.175 ASTM D374

Inherent Surface Tack (1or 2 sided) 2 2 —

Density (g/cc) 3.6 3.6 ASTM D792

Heat Capacity (J/g-K) 1.0 1.0 ASTM C351

Hardness Bulk Rubber (Shore 00) (1) 35 35 ASTM D2240

Young’s Modulus (psi) / (kPa) (2) 17.5 121 ASTM D575

Continuous Use Temp (°F) / (°C) -76 to 392 -60 to 200 —

ELECTRICAL

Dielectric Breakdown Voltage (Vac) >5000 >5000 ASTM D149

Dielectric Constant (1000 Hz) 7.5 7.5 ASTM D150

Volume Resistivity (Ohm-meter) 109109ASTM D257

Flame Rating V-O V-O U.L. 94

THERMAL

Thermal Conductivity (W/m-K) 5.0 5.0 ASTM D5470

THERMAL PERFORMANCE VS. PRESSURE

Pressure (psi) 10 25 50 100 200

TO-220 Thermal Performance (ºC/W) (20 mil) 1.18 1.10 0.99 0.84 0.72

Thermal Impedance (ºC-in2/W) (3) 0.21 0.18 0.15 0.14 0.12

TO-220 Thermal Performance (ºC/W) (40 mil) 1.54 1.34 1.15 1.00 0.90

Thermal Impedance (ºC-in2/W) (3) 0.30 0.28 0.25 0.22 0.13

1) One second delay value Shore 00 hardness scale. 2) Young's Modulus, calculated using 0.01 in/min. step rate of strain with a sample

size of 0.79 inch2. For more information on Gap Pad modulus, refer to Bergquist Application Note #116. 3) The ASTM D5470 test fix-

ture was used.The recorded value includes interfacial thermal resistance.These values are provided for reference only. Actual applica-

tion performance is directly related to the surface roughness, flatness and pressure applied.

Note: Resultant thickness is defined as the final gap thickness of

the application.

SEL_SP_0906_Chpt1.qxp 10/20/2006 10:20 AM Page 22

GAP PAD

Gap Filler 1000 (Two-Part)

Features and Benefits

• Thermal conductivity: 1.0 W/m-K

• Ultra-conforming, designed for fragile and

low-stress applications

• Ambient and accelerated cure schedules

• 100% solids – no cure by-products

• Excellent low and high temperature

mechanical and chemical stability

Gap Filler 1000 is a thermally conductive, liquid

gap filling material. It is supplied as a two-

component, room or elevated temperature

curing system.The material is formulated to

provide a balance of cured material properties

highlighted by “gel-like” modulus and good

compression set (memory).The result is a

soft, thermally conductive, form-in-place

elastomer ideal for coupling “hot” electronic

components mounted on PC boards with an

adjacent metal case or heat sink. Before cure,

Gap Filler 1000 flows under pressure like a

grease. After cure, it does not pump from the

interface as a result of thermal cycling. Unlike

thermal grease, the cured product is dry to

the touch. Unlike cured gap filling materials,

the liquid approach offers infinite thickness

with little or no stress during displacement

and eliminates the need for specific pad thick-

ness and die-cut shapes for individual applica-

tions. Gap Filler 1000 is intended for use in

thermal interface applications when a strong

structural bond is not required.

Note: Resultant thickness is defined as the final gap

thickness of the application.

Typical Applications Include:

• Automotive electronics • Telecommunications

• Computer and peripherals • Thermally conductive vibration dampening

• Between any heat-generating semiconductor and a heat sink

Configurations Available:

• For smaller quantity packaging, please contact Bergquist Sales

Building a Part Number Standard Options

Gap Pad®: U.S. Patent 5,679,457 and others.

Thermally Conductive, Liquid Gap Filling Material

01 531072649811

300

250

200

150

Thickness vs. Thermal Resistance

Gap Filler 1000

Thermal Resistance (C-in2/W)

Resultant Thickness (mils)

Section A

Section B

Section C

Section D

Section E

NA = Selected standard option. If not selecting a standard

option, insert company name, drawing number, and

revision level.

GF1000 = Gap Filler 1000 Material

GF1000 00 15 50cc NA

Note: To build a part number, visit our website at www.bergquistcompany.com.

00 = No spacer beads

07 = 0.007" spacer beads

Pot Life: 15 = 15 minutes

Cartridges: 50cc = 50.0cc, 400cc = 400.0cc

Kits: 1200cc = 1200.0cc, or 10G = 10 gallon

––––

TYPICAL PROPERTIES OF GAP FILLER 1000

PROPERTY IMPERIAL VALUE METRIC VALUE TEST METHOD

Color / Part A Gray Gray Visual

Color / Part B White White Visual

Viscosity as Mixed (cps) (1) 100,000 100,000 ASTM D2196

Density (g/cc) 1.6 1.6 ASTM D792

Mix Ratio 1:1 1:1 —

Shelf Life @ 25°C (months) 6 6 —

PROPERTY AS CURED

Color Gray Gray Visual

Hardness (Shore 00) (2) 30 30 ASTM D2240

Heat Capacity (J/g-K) 1.0 1.0 ASTM E1269

Continuous Use Temp (°F) / (°C) -76 to 347 -60 to 175 —

ELECTRICAL AS CURED

Dielectric Strength (V/mil) 500 500 ASTM D149

Dielectric Constant (1000 Hz) 5.0 5.0 ASTM D150

Volume Resistivity (Ohm-meter) 1011 1011 ASTM D257

Flame Rating V-O V-O U.L. 94

THERMAL AS CURED

Thermal Conductivity (W/m-K) 1.0 1.0 ASTM D5470

CURE SCHEDULE

Pot Life @ 25°C (min) (3) 15 15 —

Cure @ 25°C (min) (4) 60 - 120 60 - 120 —

Cure @ 100°C (min) (4) 5 5 —

1) Brookfield RV, Heli-Path, Spindle TF @ 20 rpm, 25°C.

2) Thirty second delay value Shore 00 hardness scale.

3) Time for viscosity to double.

4) Cure schedule (rheometer - time to read 90% cure)

SEL_SP_0906_Chpt1.qxp 10/20/2006 10:20 AM Page 23

GAP PAD

Features and Benefits

• Thermal conductivity: 1.1 W/m-K

• No silicone outgassing or extraction

• Ultra-conforming, designed for fragile and

low-stress applications

• Ambient and accelerated cure schedules

• 100% solids – no cure by-products

Gap Filler 1100SF is the thermal solution for

silicone-sensitive applications.The material is

supplied as a two-part component, curing at

room or elevated temperatures.The material

exhibits “gel-like” properties then cures to a

soft, flexible elastomer, helping reduce thermal

cycling stresses during operation and virtually

eliminating stress during assembly of low-

stress applications.

The two components are colored to assist

as a mix indicator (1:1 by volume).The mixed

system will cure at ambient temperature.

Unlike cured thermal pad materials, the liquid

approach offers infinite thickness variations with

little or no stress during assembly displacement.

Gap Filler 1100SF, although exhibiting some

natural tack characteristics, is not intended for

use in thermal interface applications requiring

a mechanical structural bond.

Application

Gap Filler 1100SF can be mixed and dispensed

using dual-tube cartridge packs with static

mixers and manual or pneumatic gun or high

volume mixing and dispensing equipment

(application of heat may be used to

reduce viscosity).

Typical Applications Include:

• Silicone-sensitive optic components • Hard disk assemblies

• Silicone-sensitive electronics • Dielectric for bare-leaded devices

• Filling various gaps between heat-generating devices to heat sinks and housings

• Mechanical switching relay

Configurations Available:

• Supplied in cartridge or kit form

Building a Part Number Standard Options

Gap Pad®: U.S. Patent 5,679,457 and others.

Thermally Conductive, Silicone-Free, Liquid Gap Filling Material

Section A

Section B

Section C

Section D

Section E

NA = Selected standard option. If not selecting a standard

option, insert company name, drawing number, and

revision level.

GF1100SF = Gap Filler 1100SF Material

GF1100SF 00 15 400cc NA

Note: To build a part number, visit our website at www.bergquistcompany.com.

00 = No spacer beads

07 = 0.007" spacer beads

Pot Life: 15 = 15 minutes

Cartridges: 400cc = 400.0cc

Kits: 1200cc = 1200.0cc, or 10G = 10 gallon

––––

TYPICAL PROPERTIES OF GAP FILLER 1100SF

PROPERTY IMPERIAL VALUE METRIC VALUE TEST METHOD

Color / Part A Yellow Yellow Visual

Color / Part B Red Red Visual

Viscosity as Mixed (cps) (1) 450,000 450,000 ASTM D2196

Density (g/cc) 2.0 2.0 ASTM D792

Mix Ratio 1:1 1:1 —

Shelf Life @ 25°C (months) 6 6 —

PROPERTY AS CURED

Color Orange Orange Visual

Hardness (Shore 00) (2) 60 60 ASTM D2240

Heat Capacity (J/g-K) 0.9 0.9 ASTM E1269

Continuous Use Temp (°F) / (°C) -76 to 257 -60 to 125 —

ELECTRICAL AS CURED

Dielectric Strength (V/mil) 400 400 ASTM D149

Dielectric Constant (1000 Hz) 5.0 5.0 ASTM D150

Volume Resistivity (Ohm-meter) 1010 1010 ASTM D257

Flame Rating V-O V-O U.L. 94

THERMAL AS CURED

Thermal Conductivity (W/m-K) 1.1 1.1 ASTM D5470

CURE SCHEDULE

Pot Life @ 25°C (min) (3) 10-15 10-15 —

Cure @ 25°C (hrs) (4) 4 4 —

Cure @ 100°C (min) (4) 45 45 —

1) Brookfield RV, Heli-Path, Spindle TF @ 2 rpm, 25°C.

2) Thirty second delay value Shore 00 hardness scale.

3) Time for viscosity to double.

4) Cure schedule (rheometer - time to read 90% cure)

TEMPERATURE DEPENDENCE OF VISCOSITY

The viscosity of the Gap Filler 1100SF material is tempera-

ture dependent.The table below provides the multiplication

factor to obtain viscosity at various temperatures.To obtain

the viscosity at a given temperature, look up the multiplica-

tion factor at that temperature and multiply the correspon-

ding viscosity at 25°C.

Temperature Multiplication Factor

°C Part A Part B

20 1.43 1.57

25 1.00 1.00

35 0.58 0.50

45 0.39 0.30

50 0.32 0.24

Example - Viscosity of Part A @ 45°:

Viscosity of Part A at 25°C is 450,000 cp. The multipli-

cation factor for part A at 45°C is 0.39. Therefore:

(450,000) x (0.39) = 175,500 cps

Gap Filler 1100SF (Two-Part)

GAP PAD

SEL_SP_0906_Chpt1.qxp 10/20/2006 10:20 AM Page 24

GAP PAD

Gap Filler Gel 1500

Features and Benefits

• Highly conformable and requires no curing,

mixing or refrigeration

• Excellent high and low temperature

mechanical and chemical stability

• Storage stability of up to one year without

filler settling issues

• Reworkable

• Good thermal performance: 1.4 W/mK

• Stress conforming through low modulus

Gap Filler Gel 1500 is the first member in

Bergquist’s new family of pre-cured gap filling

materials.The product is a highly conformable

gel which requires no curing, mixing or refrig-

eration. It’s unique formulation assures excel-

lent thermal conductivity, stress conformance

through low modulus, excellent high and low

temperature chemical storage and storage

stability up to one year. Gap Filler Gel 1500 is

ideal for thermal interface applications where

highly variable gaps and tolerances exist in

electronic components, where only minimal

stress on components is permissible and re-

work may be required.

The first in a new family of highly-conformable gels requiring no curing, mixing or refrigeration

Typical Applications Include:

• Automotive electronics • Telecommunications

• Computer and peripherals • Thermally conductive vibration dampening

• Between any heat-generating semiconductor and a heat sink

Configurations Available:

• 30cc, 310cc and 600cc tubes

• 5-gallon containers

• 7 mil spacer beads

Building a Part Number Standard Options

Gap Pad®: U.S. Patent 5,679,457 and others.

TYPICAL PROPERTIES OF GAP FILLER GEL 1500

PROPERTY IMPERIAL VALUE METRIC VALUE TEST METHOD

Color Gray Gray Visual

Shear Modulus (Pa) (1) 1000 - 10,000 1000 - 10,000 ASTM D4473

Viscosity (Pa-sec) (2) 200 200 ASTM D5099

Density (g/cc) 1.8 1.8 ASTM D792

Heat Capacity (J/g-K) 1.3 1.3 ASTM E1269

Continuous Use Temp (°F) / (°C) -76 to 347 -60 to 175 _

Shelf Life at 25ºC (months) 12 12 _

ELECTRICAL

Dielectric Strength (V/mil) 250 250 ASTM D149

Dielectric Constant (1000 Hz) 6 6 ASTM D150

Volume Resistivity (Ohm-meter) 1011 1011 ASTM D257

Flame Rating V-O V-O U.L. 94

THERMAL

Thermal Conductivity (W/m-K) 1.4 1.4 ASTM D5470

1) Parallel plate rheometer at 1 Hz and 0.1% strain.

2) Capillary rheometer at 900 sec-1.

SEL_SP_0906_Chpt1.qxp 10/20/2006 3:50 PM Page 25

GAP PAD

Features and Benefits

• Thermal conductivity: 2.0 W/m-K

• Ultra-conforming, designed for fragile and

low-stress applications

• Ambient and accelerated cure schedules

• 100% solids – no cure by-products

• Excellent low and high temperature

mechanical and chemical stability

Gap Filler 2000 is a high performance, thermally

conductive, liquid gap filling material supplied

as a two-component, room or elevated

temperature curing system.The material

provides a balance of cured material properties

and good compression set (memory).The

result is a soft, form-in-place elastomer ideal

for coupling “hot” electronic components

mounted on PC boards with an adjacent

metal case or heat sink. Before cure, it flows

under pressure like grease. After cure, it won't

pump from the interface as a result of thermal

cycling and is dry to the touch.

Unlike cured Gap Filling materials, the liquid

approach offers infinite thickness with little or no

stress during displacement and assembly. It also

eliminates the need for specific pad thickness

and die-cut shapes for individual applications.

Gap Filler 2000 is intended for use in thermal

interface applications when a strong structural

bond is not required. Gap Filler 2000 is formu-

lated for low-modulus,“gel-like” properties.

Note: Resultant thickness is defined as the final gap

thickness of the application.

High Thermally Conductive, Liquid Gap Filling Material

Typical Applications Include:

• Automotive electronics • Telecommunications

• Computer and peripherals • Thermally conductive vibration dampening

• Between any heat-generating semiconductor and a heat sink

Configurations Available:

• For smaller quantity packaging, please contact Bergquist Sales

Building a Part Number Standard Options

Gap Pad®: U.S. Patent 5,679,457 and others.

01 32465

300

250

200

150

Thickness vs. Thermal Resistance

Gap Filler 2000

Thermal Resistance (C-in2/W)

Resultant Thickness (mils)

Section A

Section B

Section C

Section D

Section E

NA = Selected standard option. If not selecting a standard

option, insert company name, drawing number, and

revision level.

GF2000 = Gap Filler 2000 Material

GF2000 00 60 10G NA

Note: To build a part number, visit our website at www.bergquistcompany.com.

00 = No spacer beads

07 = 0.007" spacer beads

Pot Life: 15 = 15 minutes, 60 = 60 minutes

Cartridges: 50cc = 50.0cc, 400cc = 400.0cc

Kits: 1200cc = 1200.0cc, or 10G = 10 gallon

––––

TYPICAL PROPERTIES OF GAP FILLER 2000

PROPERTY IMPERIAL VALUE METRIC VALUE TEST METHOD

Color / Part A Pink Pink Visual

Color / Part B White White Visual

Viscosity as Mixed (cps) (1) 300,000 300,000 ASTM D2196

Density (g/cc) 2.9 2.9 ASTM D792

Mix Ratio 1:1 1:1 —

Shelf Life @ 25°C (months) 6 6 —

PROPERTY AS CURED

Color Pink Pink Visual

Hardness (Shore 00) (2) 70 70 ASTM D2240

Heat Capacity (J/g-K) 1.0 1.0 ASTM E1269

Continuous Use Temp (°F) / (°C) -76 to 392 -60 to 200 —

ELECTRICAL AS CURED

Dielectric Strength (V/mil) 500 500 ASTM D149

Dielectric Constant (1000 Hz) 7.0 7.0 ASTM D150

Volume Resistivity (Ohm-meter) 1011 1011 ASTM D257

Flame Rating V-O V-O U.L. 94

THERMAL AS CURED

Thermal Conductivity (W/m-K) 2.0 2.0 ASTM D5470

CURE SCHEDULE

Pot Life @ 25°C (min) (3) 15 15 —

Cure @ 25°C (min) (4) 60 - 120 60 - 120 —

Cure @ 100°C (min) (4) 5 5 —

1) Brookfield RV, Heli-Path, Spindle TF @ 20 rpm, 25°C.

2) Thirty second delay value Shore 00 hardness scale.

3) Time for viscosity to double.

4) Cure schedule (rheometer - time to read 90% cure)

Gap Filler 2000 (Two-Part)

SEL_SP_0906_Chpt1.qxp 10/20/2006 10:20 AM Page 26

GAP PAD

Gap Filler 3500S35 (Two-Part)

Features and Benefits

• Thermal Conductivity: 3.6 W/m-K

• Thixotropic nature makes it easy to

dispense

• Two-part formulation for easy storage

• Ultra-conforming - designed for fragile and

low stress applications

• Ambient or accelerated cure schedules

Gap Filler 3500S35 is the technology leader

in thermally conductive, liquid gap filling mate-

rials, featuring ultra-high thermal performance

and superior softness.The material is two-

component, cured either at room or elevated

temperature. Prior to curing, the material

maintains good thixotropic characteristics as

well as low viscosity.The result is a gel-like

liquid material designed to fill air gaps and

voids yet flow when acted upon by an

external force (e.g. dispensing or assembly

process).The material is an excellent solution

for interfacing fragile components with high

topography and/or stack-up tolerances to a

universal heat sink or housing. Once cured, it

remains a low modulus elastomer designed

to assist in relieving CTE stresses during ther-

mal cycling yet maintain enough modulus to

prevent pump-out from the interface. Gap

Filler 3500S35 will lightly adhere to surfaces,

thus improving surface area contact. Gap

Filler 3500S35 is not designed to be a

structural adhesive.

Thermally Conductive Liquid Gap Filling Material

Typical Applications Include:

• Automotive electronics • PCBA to housing

• Discrete components to housing • Fiber optic telecommunications equipment

Configurations Available:

• Supplied in cartridge or kit form

Building a Part Number Standard Options

Gap Pad®: U.S. Patent 5,679,457 and others.

TYPICAL PROPERTIES OF GAP FILLER 3500S35

PROPERTY IMPERIAL VALUE METRIC VALUE TEST METHOD

Color / Part A White White Visual

Color / Part B Blue Blue Visual

Viscosity as Mixed (cps) (1) 150,000 150,000 ASTM D2196

Density (g/cc) 1.0 1.0 ASTM D792

Mix Ratio 1:1 1:1 —

Shelf Life @ 25°C (months) 5 5 —

PROPERTY AS CURED

Color Blue Blue Visual

Hardness (Shore 00) (2) 32 32 ASTM D2240

Continuous Use Temp (°F) / (°C) -76 to 392 -60 to 200 —

ELECTRICAL AS CURED

Dielectric Strength (V/mil) 275 275 ASTM D149

Dielectric Constant (1000 Hz) 8.0 8.0 ASTM D150

Volume Resistivity (Ohm-meter) 109109ASTM D257

Flame Rating V-O V-O U.L. 94

THERMAL AS CURED

Thermal Conductivity (W/m-K) 3.6 3.6 ASTM D5470

CURE SCHEDULE

Pot Life @ 25°C (min) (3) 60 60 —

Cure @ 25°C (min) (4) 15 15 —

Cure @ 100°C (min) (4) 30 30 —

1) Brookfield RV, Heli-Path, Spindle TF @ 20 rpm, 25°C.

2) Thirty second delay value Shore 00 hardness scale.

3) Time for viscosity to double.

4) Cure schedule (rheometer - time to read 90% cure)

0.25

0.20

0.15

0.10

0.05

0.00

0.0 0.5 1.0 1.5 2.0 2.5 3.0

Thermal Resistance (C-in2/W)

Thickness vs.Thermal Resistance

Gap Filler 3500S35

Thickness (inch)

SEL_SP_0906_Chpt1.qxp 10/20/2006 10:20 AM Page 27

TIC

™

- Thermal Interface Compound

Thermally Conductive Grease Compounds

Bergquist’s line of thermally conductive thermal interface compounds

will flow under assembly pressure to wet-out the thermal interface

surfaces and produce very low thermal impedance. TIC products are

designed for use between a high-end computer processor and a heat

sink or other high watt density applications.

Features

The TIC portfolio has diverse

thermal and electrical

characteristics. Key criteria when

selecting TIC products include:

• Viscosity

• Volume resistivity

• Thermal conductivity

• Thermal performance

• Filler size

Benefits

TIC products are ideal for high

watt density applications. Primary

benefits include:

• Low interfacial resistance

• Low thermal impedance

• Resists dripping

• Ideally suited to screen printing

applications

• No post “cure” conditioning

required

Options

TIC products can be obtained

with application-specific options

such as:

• Containers

Applications

TIC has a variety of applications

such as:

• CPU

• GPU

• IGBT

• High power density applications

Comparison Data and FAQ’s

Q: What is the best fastening method for a TIC interface?

A: A constant-pressure fastener is preferred when using TIC for high

performance applications.The constant pressure from a clip or

spring washer will ensure adequate pressure is being applied with

varying bond line thickness.

Q: How should the TIC be applied?

A: Screenprinting the TIC is a fast, low-cost method that delivers

a consistent and accurate amount of material on each application.

Alternate methods include stenciling, pin transfer and needle

dispensing.

Q: Will the grease stay in the interface?

A: All the TIC materials were specifically designed to resist pump-out

of the interface, even after many hours of thermal and power

cycling.

SEL_SP_0906_Chpt1.qxp 10/23/2006 10:00 AM Page 28

TIC

™

1000G

Features and Benefits

• Thermal performance: 0.29°C/W (@ 50 psi)

• Excellent screenability

• No post “cure” required

• Cost vs. performance leader

TIC 1000G is a high performance, thermally

conductive compound intended for use as a

thermal interface material between a high-

end computer processor and a heat sink.

Other high watt density applications will

benefit from the extremely low thermal

impedance of TIC 1000G.

TIC 1000G compound wets-out the thermal

interface surfaces and flows to produce the

lowest thermal impedance.The compound

requires pressure of the assembly to cause

flow.The compound will resist dripping.

For microprocessor applications, traditional

screw fastening or spring clamping methods

will provide adequate force to optimize the

thermal performance of TIC 1000G.

An optimized application would utilize the

minimum volume of TIC 1000G compound

necessary to ensure complete wet-out of

both mechanical interfaces.

Note: TIC 1000G is ideally suited for screen-

printing applications. Please contact Bergquist

Sales for application notes related to screen-

printing.

Assembly – No Post Screen Cure

TIC 1000G has excellent screenability. No

solvent is used to reduce the viscosity, so no

post “cure” conditioning is required.

High Performance,Value Compound for High-End Computer Processors

Application Cleanliness

Pre-clean heat sink and component interface with isopropyl alcohol prior to assembly or repair.

Be sure heat sink is dry before applying TIC 1000G.

Application Methods

1. Dispense and/or screenprint TIC 1000G compound onto the processor or heat sink surface

like thermal grease (see a Bergquist Representative for application information).

2. Assemble the processor and heat sink with spring clips or constant-pressure fasteners.

Typical Applications Include:

• High performance CPU's

• High performance GPU's

Building a Part Number Standard Options

TIC™: U.S. Patents 6,797,758; 6,624,224; 6,339,120.

TYPICAL PROPERTIES OF TIC 1000G

PROPERTY IMPERIAL VALUE METRIC VALUE TEST METHOD

Color Black Black Visual

Density (g/cc) 1.2 1.2 ASTM D792

Continuous Use Temp (°F) / (°C) 302 150 —

ELECTRICAL

Electrical Resistivity (Ohm-meter) (1) N/A N/A ASTM D257

THERMAL

Thermal Conductivity (W/m-K) 0.7 0.7 ASTM D5470

THERMAL PERFORMANCE vs PRESSURE

Pressure (psi) 10 25 50 100 200

TO-220 Thermal Performance (°C/W) (2) 0.32 0.30 0.29 0.27 0.26

1) The compound contains an electrically conductive filler surrounded by electrically non-conductive resin.

2) TO-220 performance data is provided as a reference to compare material thermal performance.

SEL_SP_0906_Chpt1.qxp 10/20/2006 10:20 AM Page 29

TIC

™

1000A

High Performance,Value Compound for High-End Computer Processors

Features and Benefits

• High thermal performance:

0.32°C/W (@ 50 psi)

• Good screenability

• Room temperature storage

• No post “cure” required

• Exceptional value

TIC 1000A is a high performance, thermally

conductive compound intended for use as a

thermal interface material between a high-

end computer processor and a heat sink.

Other high watt density applications will also

benefit from the extremely low thermal

impedance of TIC 1000A.

TIC 1000A compound wets-out the thermal

interface surfaces and flows to produce the

lowest thermal impedance.The compound

requires pressure of the assembly to cause

flow.The TIC 1000A compound will resist

dripping.

For microprocessor applications, traditional

screw fastening or spring clamping methods

will provide adequate force to optimize the

thermal performance of TIC 1000A.

An optimized application would utilize the

minimum volume of TIC 1000A material

necessary to ensure complete wet-out of

both mechanical interfaces.

Assembly – No Post Screen Cure

TIC 1000A has good screenability. No

solvent is used to reduce the viscosity, so

no post “cure” conditioning is required.

Application Cleanliness

1. Pre-clean heat sink and component interface with isopropyl alcohol prior to assembly or

repair. Ensure heat sink is dry before applying TIC 1000A.

Application Methods

1. Dispense and/or screenprint TIC 1000A compound onto the processor or heat sink surface

like thermal grease (see a Bergquist Representative for application information).

2. Assemble the processor and heat sink with spring clips or constant-pressure fasteners.

Typical Applications Include:

• High performance CPUs

• High performance GPUs

Building a Part Number Standard Options

TIC™: U.S. Patents 6,797,758; 6,624,224; 6,339,120.

TYPICAL PROPERTIES OF TIC 1000A

PROPERTY IMPERIAL VALUE METRIC VALUE TEST METHOD

Color Gray Gray Visual

Density (g/cc) 2.1 2.1 ASTM D792

Continuous Use Temp (°F) / (°C) 302 150 —

ELECTRICAL

Electrical Resistivity (Ohm-meter) (1) N/A N/A ASTM D257

THERMAL

Thermal Conductivity (W/m-K) 1.5 1.5 ASTM D5470

THERMAL PERFORMANCE vs PRESSURE

Pressure (psi) 10 25 50 100 200

TO-220 Thermal Performance (°C/W) (2) 0.32 0.32 0.32 0.31 0.28

1) The compound contains an electrically conductive filler surrounded by electrically non-conductive resin.

2) TO-220 performance data is provided as a reference to compare material thermal performance.

SEL_SP_0906_Chpt1.qxp 10/23/2006 9:45 AM Page 30

TIC

™

4000

Features and Benefits

• Thermal conductivity: 4.0 W/m-K

• Exceptional thermal performance:

0.19°C/W @ 50 psi

TIC 4000 is a thermally conductive grease

compound designed for use as a thermal inter-

face material between a computer processor

and a copper-based heat sink. Other high

watt density applications will benefit from the

extremely low thermal impedance of TIC 4000.

TIC 4000 compound wets-out the thermal

interface surfaces and flows to produce low

thermal impedance.The compound requires

pressure of the assembly to cause flow.

TIC 4000 compound will not drip.

For a typical 0.5" x 0.5" application at 0.005"

thick, Bergquist estimates approximately

0.02 ml (cc) of TIC 4000.

Although Bergquist estimates a 0.02 ml (cc)

volumetric requirement for a 0.5" x 0.5"

component interface, dispensed at a thickness

of 0.005", Bergquist also recognizes that an

optimized application would utilize the

minimum volume of TIC 4000 material

necessary to ensure complete wet-out of

both mechanical interfaces.

High Performance Thermal Interface Compound for Copper-Based Heat Sinks

Application Methods

1. Pre-clean heat sink and component interface with isopropyl alcohol prior to

assembly or repair. Ensure heat sink is dry before applying TIC 4000.

2. Dispense TIC 4000 compound onto the processor or heat sink surface like thermal grease.

3. Assemble the processor and heat sink with clip or constant-pressure fasteners.

Typical Applications Include:

• High performance computer processors (traditional screw fastening or clamping methods will

provide adequate force to optimize the thermal performance of TIC 4000)

• High watt density applications where the lowest thermal resistance interface is required

Building a Part Number Standard Options

TIC™: U.S. Patents 6,797,758; 6,624,224; 6,339,120.

TIC

TYPICAL PROPERTIES OF TIC 4000

PROPERTY IMPERIAL VALUE METRIC VALUE TEST METHOD

Color Gray Gray Visual

Density (g/cc) 4.0 4.0 ASTM D792

Continuous Use Temp (°F) / (°C) 302 150 —

ELECTRICAL

Electrical Resistivity (Ohm-meter) (1) N/A N/A ASTM D257

THERMAL

Thermal Conductivity (W/m-K) 4.0 4.0 ASTM D5470

THERMAL PERFORMANCE vs PRESSURE

Pressure (psi) 10 25 50 100 200

TO-220 Thermal Performance (°C/W) (2) 0.21 0.20 0.19 0.19 0.18

1) The compound contains an electrically conductive filler surrounded by electrically non-conductive resin.

2) TO-220 performance data is provided as a reference to compare material thermal performance.

SPDG_Chapter2_10.06.qxp 10/20/2006 11:24 AM Page 29

HI-FLOW

Hi-Flow

Phase Change Interface Materials

Solutions-Driven Thermal Management Products for Electronic Devices

Hi-Flow phase change materials are an excellent replacement for

grease as a thermal interface between a CPU or power device and a

heat sink.The materials change from a solid at specific phase change

temperatures and flow to assure a total wet-out of the interface

without overflow.The result is a thermal interface comparable to

grease, without the mess, contamination and hassle.

The Hi-Flow family of phase change thermal interface materials covers a

wide range of applications.The Bergquist Company is a leader in thermal

management solutions and works closely with customers to ensure

that the proper Hi-Flow material is specified.

Use phase change materials for excellent thermal performance without the mess of grease.

U.S. Patent 5,679,457 and others.

Features

Hi-Flow handles like Bergquist’s

famed Sil-Pad materials at room

temperature, but flows like grease

at its designed phase change

temperature.The following is an

overview of the important features

shared by the Hi-Flow family:

• Comparable thermal

performance to grease in

most applications

• Thermally conductive phase

change compound

• Aluminum, film or fiberglass

carriers and non-reinforced

versions

• Low volatility

• Easy to handle and apply in the

manufacturing environment

• Tackified or tack-free at room

temperature

Benefits

Using Hi-Flow materials instead

of grease can save time and money

without sacrificing thermal

performance. Here are some

other benefits:

• No mess – thixotropic charac-

teristics of the materials keep it

from flowing out of the interface

• Easier handling – tackified or

tack-free at room temperature

• Does not require protective

liner

• High thermal performance

helps ensure CPU reliability

• Does not attract contaminants

• Easier material handling and

shipping

• Simplified application process

Options

The broad Hi-Flow family offers

a variety of choices to meet the

customer’s performance, handling

and process needs. Some of the

choices include:

• Some Hi-Flows are available

with or without adhesive

• Aluminum carrier for

applications not requiring

electrical isolation

• Film or fiberglass carrier for

electrical isolation

• Dry, non-reinforced material

• Tackified or tack-free at room

temperature

• Tabbed parts, die-cut parts,

sheets or bulk rolls

• Adhesive specifically for cold

application without preheating

heat sink

We produce thousands of specials.

Tooling charges vary depending

on the complexity of the part.

Applications

Hi-Flow materials are suited for

consumer and industrial

electronics, automotive, medical,

aerospace and telecommunica-

tions applications such as:

• UPS and SMPS AC/DC, DC/DC

or linear power supplies

• Between a CPU and heat sink

• Power conversion devices

• Fractional and integral motor

control

• Leaded, surface mount and

power module assemblies

SPDG_Chapter2_10.06.qxp 10/20/2006 11:24 AM Page 30

Hi-Flow

Comparison Data

HI-FLOW

TO-220 Thermal Performance

SPDG_Chapter2_10.06.qxp 10/20/2006 11:24 AM Page 31

Frequently Asked Questions

HI-FLOW

How is the ASTM D5470 test modified to character-

ize phase change thermal performance?

ASTM classifies a phase change as a Type 1, viscous liquid that

exhibits unlimited deformation when a stress is applied. Bergquist

utilizes test equipment that is designed to meet ASTM D5470

specifications for Type 1, which requires a shim or mechanical

stop to precisely control the thickness.The phase change material

is conditioned at 5oC over the stated phase change temperature.

Understanding that time is also a key variable for material flow,

the over-temperature condition is limited to 10 minutes and then

allowed to cool, prior to initiating the actual test at the given

pressure.The 10 minute time has been demonstrated to be an

acceptable time period for the thermal mass inherent in the test

setup. Note: Actual application testing may require more or

less time to condition, depending upon the heat transfer and

associated thermal mass.The performance values are recorded

and published at 10, 25, 50, 100 and 200 psi to give the design-

er a broad-based understanding of Hi-Flow’s performance.

Q: What is the minimum pressure required to optimize

the thermal performance of the Hi-Flow material?

Upon achieving phase change temperature (e.g. pre-conditioning),

Bergquist has demonstrated that 10 psi provides adequate

pressure to achieve exceptional thermal performance. Bergquist

continues to research lower pressure wet-out characteristics in

an effort to minimize interfacial losses associated with ultra-thin

material interfaces.

Will the Hi-Flow replace a mechanical fastener?

Mechanical fasteners are required. Bergquist recommends the

use of spring clips to maintain consistent pressure over time.

Can I use screw-mount devices with Hi-Flow material?

Hi-Flow works best with a clip or spring washer-mounted

assembly.The continuous force applied by these devices allows

the Hi-Flow material to flow and reduce the cross sectional gap.

Bergquist suggests that design engineers evaluate whether a

screw-mount assembly will have acceptable performance. See

TO-220 Technical Note.

Q: Is the adhesive in Hi-Flow 225F-AC repositionable?

The adhesive in the current construction does adhere more to

the heat sink aluminum than to the Hi-Flow material.There is the

potential that the adhesive will be removed by the heat sink

surface when it is removed to reposition on the heat sink.Time

and/or pressure will increase the bond to the aluminum increasing

the potential for the adhesive to adhere to the heat sink.

Q: Is there any surface preparation required before

applying the adhesive-backed Hi-Flow to the heat sink?

Standard electronics industry cleaning procedures apply. Remove

dirt or other debris. Best results are attained when the Hi-Flow

material is applied to a heat sink at a temperature of 25° +/- 10°C.

If the heat sink has been surface treated (e.g. anodized or

chromated), it is typically ready for assembly. For bare aluminum,

mild soap and water wash cleaning processes are typically used

to eliminate machine oils and debris.

Q: Is Hi-Flow material reworkable?

If the material has not gone through phase change, the material

will readily release from the device surface. For this situation, the

Hi-Flow material will not likely have to be replaced.

If the material has gone through the phase change, it will adhere

very well to both surfaces. In this case, Bergquist suggests warming

the heat sink to soften the Hi-Flow compound for easier removal

from the processor. Replace with a new piece of Hi-Flow material.

What is meant by “easy to handle” in manufacturing?

Insulated Hi-Flow products are manufactured with inner film

support.This film stiffens the material, allowing parts to be more

readily die-cut as well as making the material easier to handle in

manual or automated assembly.

What is meant by “tack free” and why is this impor-

tant?

Many Hi-Flow materials have no surface tack at room temperature.

The softer materials will pick up dirt more readily. Softer resins

are more difficult to clean if any dirt is on the surface. If you try

to rub the dirt away, the dirt is easily pushed into the soft phase

change materials. Hi-Flow coatings are typically hard at room

temperature rendering them easier to clean off without

embedding dirt.

What does “more scratch resistance” mean on

Hi-Flow 625?

Hi-Flow 625 does not require a protective film during shipment.

There are two issues with competitors’ materials:

1) Melt point of the material is low enough that it can go

through phase change in shipment and be very tacky.

Hi-Flow has a higher phase change temperature and

remains hard to a higher temperature.

2) The Hi-Flow material is harder and is not as easy to

scratch or dent in shipping and handling.

Why is Hi-Flow phase change temperature 65oC?

The 65oC phase change temperature was selected for two reasons.

First, it was a low enough temperature for the phase change to

occur in applications. Second, it would not phase change in

transport. Bergquist studies show that shipping containers can

reach 60oC in domestic and international shipments.The higher

phase change temperature eliminates the possibility of a product

being ruined in shipment.We offer a standard line of Hi-Flow 225

and 300 series products with 55oC phase change for those

customers wanting the lower phase change temperature.

Q: In

which applications should I avoid using Hi-Flow?

A: Avoid using Hi-Flow in

applications in which the device will

not reach operation at or above phase change temperature. Also

avoid applications in which the operating temperature exceeds the

maximum recommended operating temperature of the com-

pound.

SPDG_Chapter2_10.06.qxp 10/20/2006 4:20 PM Page 32

Hi-Flow

105

Features and Benefits

• Thermal impedance:

0.37°C-in2/W (@25 psi)

• Used where electrical isolation is

not required

• Low volatility – less than 1%

• Easy to handle in the manufacturing

environment

• Flows but doesn’t run like grease

Hi-Flow 105 is a phase change material coated

on both sides of an aluminum substrate. It is

designed specifically to replace grease as a

thermal interface, eliminating the mess,

contamination and difficult handling associated

with grease. Hi-Flow 105 is tack-free and

scratch resistant at room temperature and

does not require a protective liner in shipment

when attached to a heat sink.

At 65°C (phase change temperature),

Hi-Flow 105 changes from a solid and flows,

thereby assuring total wet-out of the interface.

The thixotropic characteristics of Hi-Flow 105

reduce the pump-out from the interface.

Hi-Flow 105 has thermal performance equal

to grease with 0.10°C-in2/W contact thermal

resistance.

Phase Change Coated Aluminum

Typical Applications Include:

• Power semiconductors

• Microprocessors mounted on a heat sink

• Power conversion modules

• Spring or clip mount applications where thermal grease is used

Configurations Available:

• Sheet form, die-cut parts and roll form

• With or without pressure sensitive adhesive

Building a Part Number Standard Options

Hi- Flow®: U.S. Patents 6,197,859 and 5,950,066.

HI-FLOW

Section A

Section B

Section C

Section D

Section E

NA = Selected standard option. If not selecting a standard

option, insert company name, drawing number, and

revision level.

HF105 = Hi-Flow 105 Phase Change Material

HF105 0.0055 AC 12/250 NA

Note: To build a part number, visit our website at www.bergquistcompany.com.

Standard thicknesses available: 0.0055"

AC = Adhesive, one side

00 = No adhesive

_ _ _ = Standard configuration dash number,

1212 = 12" x 12" sheets, 12/250 = 12" x 250' rolls, or

00 = custom configuration

––––

TYPICAL PROPERTIES OF HI-FLOW 105

PROPERTY IMPERIAL VALUE METRIC VALUE TEST METHOD

Color Dark Gray Dark Gray Visual

Reinforcement Carrier Aluminum Aluminum —

Thickness (inch) / (mm) 0.0055 0.139 ASTM D374

Continuous Use Temp (°F) / (°C) 266 130 —

Phase Change Temp (°F) / (°C) 149 65 ASTM D3418

ELECTRICAL

Dielectric Constant (1000 (Hz) 3.2 3.2 ASTM D150

Flame Rating V-O V- O U.L. 94

THERMAL

Thermal Conductivity (W/m-K) (1) 0.9 0.9 ASTM D5470

THERMAL PERFORMANCE vs PRESSURE

Pressure (psi) 10 25 50 100 200

TO-220 Thermal Performance (°C/W) 0.95 0.80 0.74 0.69 0.64

Thermal Impedance (°C-in2/W) (2) 0.39 0.37 0.36 0.33 0.30

1) This is the measured thermal conductivity of the Hi-Flow coating. It represents one conducting layer in a three-layer laminate.The

Hi-Flow coatings are phase change compounds.These layers will respond to heat and pressure induced stresses.The overall conductivity

of the material in post-phase change, thin film products is highly dependent upon the heat and pressure applied.This characteristic is

not accounted for in ASTM D5470. Please contact Bergquist Product Management if additional specifications are required.

2) The ASTM D5470 test fixture was used and the test sample was conditioned at 70°C prior to test.The recorded value includes

interfacial thermal resistance.These values are provided for reference only. Actual application performance is directly related to the

surface roughness, flatness and pressure applied.

SPDG_Chapter2_10.06.qxp 10/20/2006 11:25 AM Page 33

Hi-Flow

115-AC

Fiberglass-Reinforced, Phase Change Thermal Interface Material

Features and Benefits

• Thermal impedance:

0.37°C-in2/W (@25 psi)

• Can be applied directly to a cold heat sink

• One side adhesive-coated to aid

in positioning

• Fiberglass reinforced

Bergquist Hi-Flow 115-AC is a thermally

conductive fiber reinforced phase change

material.The product consists of a thermally

conductive 65°C phase change compound

coated on a fiberglass web, and an adhesive

coating on one side for attachment to a cold

heat sink.There is no need to preheat the

heat sink to apply the Hi-Flow 115-AC.

Hi-Flow 115-AC is designed as a thermal

interface material between a computer

processor and a heat sink.The pressure

sensitive adhesive makes it simple to apply in

high volume to heat sinks and the 65°C phase

change temperature eliminates shipping and

handling problems.

Hi-Flow 115-AC requires no protective liner

for shipping or handling.The Hi-Flow coating

has excellent handling characteristics at room

temperature, and can withstand the handling

and shipping process without protection.

Hi-Flow 115-AC handles like a Sil-Pad at

room temperature and flows like high-quality

grease at elevated temperatures.

Typical Applications Include:

• Computer and peripherals

• As a thermal interface where bare die is exposed and needs to be heat sinked

Configurations Available:

• Sheet form, die-cut parts and roll form

• With pressure sensitive adhesive

Building a Part Number Standard Options

Hi- Flow®: U.S. Patents 6,197,859 and 5,950,066.

HI-FLOW

Section A

Section B

Section C

Section D

Section E

NA = Selected standard option. If not selecting a standard

option, insert company name, drawing number, and

revision level.

HF115AC = Hi-Flow 115-AC Phase Change Material

HF115AC 0.0055 AC 12/250 NA

Note: To build a part number, visit our website at www.bergquistcompany.com.

Standard thicknesses available: 0.0055"

AC = Adhesive, one side

00 = No adhesive

_ _ _ = Standard configuration dash number,

1212 = 12" x 12" sheets, 12/250 = 12" x 250' rolls, or

00 = custom configuration

––––

TYPICAL PROPERTIES OF HI-FLOW 115-AC

PROPERTY IMPERIAL VALUE METRIC VALUE TEST METHOD

Color Gray Gray Visual

Reinforcement Carrier Fiberglass Fiberglass —

Thickness (inch) / (mm) 0.0055 0.139 ASTM D374

Elongation (%45° to Warp and Fill) 40 40 ASTM D882A

Tensile Strength (psi) / (MPa) 900 6 ASTM D882A

Continuous Use Temp (°F) / (°C) 302 150 —

Phase Change Temp (°F) / (°C) 149 65 ASTM D3418

ELECTRICAL

Dielectric Breakdown Voltage (Vac) 300 300 ASTM D149

Dielectric Constant (1000 Hz) 3.5 3.5 ASTM D150

Volume Resistivity (Ohm-meter) 1010 1010 ASTM D257

Flame Rating V-O V- O U.L. 94

THERMAL

Thermal Conductivity (W/m-K) (1) 0.8 0.8 ASTM D5470

THERMAL PERFORMANCE vs PRESSURE

Pressure (psi) 10 25 50 100 200

TO-220 Thermal Performance (°C/W) 1.28 1.16 1.04 0.94 0.85

Thermal Impedance (°C-in2/W) (2) 0.44 0.37 0.35 0.27 0.15

1) This is the measured thermal conductivity of the Hi-Flow coating. It represents one conducting layer in a three-layer laminate.The

Hi-Flow coatings are phase change compounds.These layers will respond to heat and pressure induced stresses.The overall conductivity

of the material in post-phase change, thin film products is highly dependent upon the heat and pressure applied.This characteristic is

not accounted for in ASTM D5470. Please contact Bergquist Product Management if additional specifications are required.

2) The ASTM D5470 test fixture was used and the test sample was conditioned at 70°C prior to test.The recorded value includes

interfacial thermal resistance.These values are provided for reference only. Actual application performance is directly related to the

surface roughness, flatness and pressure applied.

SPDG_Chapter2_10.06.qxp 10/20/2006 11:25 AM Page 34

HI-FLOW

Hi-Flow

225F-AC

Reinforced, Phase Change Thermal Interface Material

Features and Benefits

• Thermal impedance:

0.10°C-in2/W (@25 psi)

• Can be manually or automatically applied

to the surfaces of room-temperature

heat sinks

• Foil reinforced, adhesive-coated

• Soft, thermally conductive 55°C phase

change compound

Hi-Flow 225F-AC is a high performance,

thermal interface material for use between a

computer processor and a heat sink. Hi-Flow

225F-AC consists of a soft, thermally

conductive 55°C phase change compound

coated to the top surface of an aluminum

carrier with a soft, thermally conductive

adhesive compound coated to the bottom

surface to improve adhesion to the heat sink.

Above the 55°C phase change temperature,

Hi-Flow 225F-AC wets-out the thermal

interface surfaces and flows to produce low

thermal impedance.

Hi-Flow 225F-AC requires pressure from the

assembly to cause material flow.The Hi-Flow

coatings resist dripping in vertical orientation.

The material includes a base carrier liner with

differential release properties to facilitate

simplicity in roll form packaging and application

assembly. Please contact Bergquist Product

Management for applications that are less than

0.07" square.

Typical Applications Include:

• Computer and peripherals

• Power conversion

• High performance computer processors

• Power semiconductors

• Power modules

Configurations Available:

• Roll form, kiss-cut parts, and sheet form

Building a Part Number Standard Options

Hi- Flow®: U.S. Patent 6,197,859 and others

TYPICAL PROPERTIES OF HI-FLOW 225F-AC

PROPERTY IMPERIAL VALUE METRIC VALUE TEST METHOD

Color Black Black Visual

Reinforcement Carrier Aluminum Aluminum —

Thickness (inch) / (mm) 0.004 0.102 ASTM D374

Carrier Thickness (inch) / (mm) 0.0015 0.038 ASTM D374

Continuous Use Temp (°F) / (°C) 248 120 —

Phase Change Temp (°F) / (°C) 131 55 ASTM D3418

ELECTRICAL

Flame Rating V-O V- O U.L. 94

THERMAL

Thermal Conductivity (W/m-K) (1) 1.0 1.0 ASTM D5470

THERMAL PERFORMANCE vs PRESSURE

Pressure (psi) 10 25 50 100 200

TO-220 Thermal Performance (°C/W) 0.87 0.68 0.57 0.50 0.45

Thermal Impedance (°C-in2/W) (2) 0.12 0.10 0.09 0.08 0.07

1) This is the measured thermal conductivity of the Hi-Flow coating. It represents one conducting layer in a three-layer laminate.The

Hi-Flow coatings are phase change compounds.These layers will respond to heat and pressure induced stresses.The overall conductivity

of the material in post-phase change, thin film products is highly dependent upon the heat and pressure applied.This characteristic is

not accounted for in ASTM D5470. Please contact Bergquist Product Management if additional specifications are required.

2) The ASTM D5470 test fixture was used and the test sample was conditioned at 70°C prior to test.The recorded value includes

interfacial thermal resistance.These values are provided for reference only. Actual application performance is directly related to the

surface roughness, flatness and pressure applied.

Section A

Section B

Section C

Section D

Section E

NA = Selected standard option. If not selecting a standard

option, insert company name, drawing number, and

revision level.

HF225FAC = Hi-Flow 225F-AC Phase Change Material

HF225FAC 0.004 AC 11/250 NA

Note: To build a part number, visit our website at www.bergquistcompany.com.

Standard thicknesses available: 0.004"

AC = Adhesive, one side

_ _ _ = Standard configuration dash number,

1112 = 11" x 12" sheets, 11/250 = 11" x 250' rolls, or

00 = custom configuration

––––

SPDG_Chapter2_10.06.qxp 10/20/2006 11:25 AM Page 35

HI-FLOW

Hi-Flow

225FT

Features and Benefits

• Thermal impedance:

0.10°C-in2/W (@25 psi)

• Reworkable pressure sensitive

• Tabbed parts for easy application

• Compliant foil allows easy release

and rework

Bergquist reworkable Hi-Flow 225FT thermal

interface material provides a low thermal

resistance path between hot components

such as high performance processors and

heat sinks.The material consists of a 55°C

phase change compound bonded to one side

of a conformable metal foil.This pressure

sensitive material is easily applied to the heat

sink and securely conforms to many mounting

surfaces. Its compliant foil allows for easy

release and reworking without leaving residue

on CPU surfaces.

Above the 55°C phase change temperature,

Hi-Flow 225FT wets-out the heat sink

interface and flows to produce exceptional

thermal performance.The thixotropic design

of Hi-Flow 225FT requires pressure of the

assembly to cause displacement and/or flow.

Application Methods

1. Hi-Flow 225FT pads are easily removed

from the carrier liner and can be hand-

applied to a room temperature heat sink,

foil-side exposed.To reposition the heat

sink assembly, simply lift gently to remove

and reapply.

Reworkable, Pressure Sensitive Phase Change Material

Typical Applications Include:

• Computer and peripherals

• High performance computer processors

• Burn-in testing

• Heat pipes

• Mobile processors

Configurations Available:

• Roll form with tabs and kiss-cut parts – no holes

• Custom thicknesses available

Hi-Flow 225FT is limited to a square or rectangular part design. Dimensional tolerance is

+/- 0.020 inch (0.5mm).

Building a Part Number Standard Options

Hi- Flow®: U.S. Patent 6,197,859 and others

Clear Polyester

Carrier Liner

HF 225FT

Roll Form,

Kiss-Cut Parts

Compliant Foil

Protects Hi-Flow

Low Adhesion to the Liner

for Ease of Removal

Section A

Section B

Section C

Section D

Section E

NA = Selected standard option. If not selecting a standard

option, insert company name, drawing number, and

revision level.

HF225FT = Hi-Flow 225FT Phase Change Material

HF225FT 0.004 01 1112 NA

Note: To build a part number, visit our website at www.bergquistcompany.com.

Standard thicknesses available: 0.004"

01 = Reworkable adhesive, one side

_ _ _ = Standard Hi-Flow 225FT configuration,

11/250 = 11" x 250' rolls, or 00 = custom configuration

––––

TYPICAL PROPERTIES OF HI-FLOW 225FT

PROPERTY IMPERIAL VALUE METRIC VALUE TEST METHOD

Color Black Black Visual

Reinforcement Carrier Aluminum Aluminum —

Thickness (inch) / (mm) 0.004 0.102 ASTM D374

Carrier Thickness (inch) / (mm) 0.001 0.025 ASTM D374

Continuous Use Temp (°F) / (°C) 248 120 —

Phase Change Temp (°F) / (°C) 131 55 ASTM D3418

ELECTRICAL

Flame Rating V-O V- O U.L. 94

THERMAL

Thermal Conductivity (W/m-K) (1) 0.7 0.7 ASTM D5470

THERMAL PERFORMANCE vs PRESSURE

Pressure (psi) 10 25 50 100 200

TO-220 Thermal Performance (°C/W) 0.93 0.74 0.63 0.52 0.42

Thermal Impedance (°C-in2/W) (2) 0.13 0.10 0.09 0.07 0.06

1) This is the measured thermal conductivity of the Hi-Flow coating. It represents one conducting layer in a three-layer laminate.The

Hi-Flow coatings are phase change compounds.These layers will respond to heat and pressure induced stresses.The overall conductivity

of the material in post-phase change, thin film products is highly dependent upon the heat and pressure applied.This characteristic is

not accounted for in ASTM D5470. Please contact Bergquist Product Management if additional specifications are required.

2) The ASTM D5470 test fixture was used and the test sample was conditioned at 70°C prior to test.The recorded value includes

interfacial thermal resistance.These values are provided for reference only. Actual application performance is directly related to the

surface roughness, flatness and pressure applied.

SPDG_Chapter2_10.06.qxp 10/20/2006 11:25 AM Page 36

HI-FLOW

Hi-Flow

225UF

Features and Benefits

• Thermal impedance:

0.08°C-in2/W (@25 psi)

• Reworkable

• Easy release from CPU

• Easy to handle / assemble

Bergquist’s reworkable Hi-Flow 225UF thermal

interface material provides a low thermal

resistance path between hot components

such as high-performance processors and

heat sinks.

Hi-Flow 225UF consists of a 55°C phase

change compound bonded to one side of a

conformable aluminum foil.This phase change

material is easily applied to a nominal 45°C

heat sink and securely conforms to many

mounting surfaces.The compliant foil allows

for easy release from the CPU/socket

assembly, leaving the surface clean and

residue-free. Hi-Flow 225UF is supplied in

kiss-cut form with a carrier liner protecting the

phase change material from contaminants.

Above the 55°C phase change temperature,

Hi-Flow 225UF wets-out the heat sink

interface and flows to produce exceptional

thermal performance. Hi-Flow 225UF’s

thixotropic design requires pressure of the

assembly to cause displacement and/or flow.

Unsupported,Thermally Conductive Phase Change Material

Typical Applications Include:

• Spring / clip mounted:

- Digital / high power CPU’s

- Power modules

Configurations Available:

• Sheet form, kiss-cut or bulk

- Preferred form: squares / rectangles

• Singulated die-cut parts

- Preferred form: squares / rectangles

• Bulk roll form

Building a Part Number Standard Options

Hi- Flow®: U.S. Patent 6,197,859 and others

Section A

Section B

Section C

Section D

Section E

NA = Selected standard option. If not selecting a standard

option, insert company name, drawing number, and

revision level.

HF225UF = Hi-Flow 225UF Phase Change Material

HF225UF 0.0045 00 11/250 NA

Note: To build a part number, visit our website at www.bergquistcompany.com.

Standard thicknesses available: 0.0045"

00 = No adhesive

1112 = 11" x 12" sheets, 11/250 = 11" x 250' rolls, or

00 = custom configuration

––––

TYPICAL PROPERTIES OF HI-FLOW 225UF

PROPERTY IMPERIAL VALUE METRIC VALUE TEST METHOD

Color Black Black Visual

Reinforcement Carrier Aluminum Aluminum —

Thickness (inch) / (mm) 0.0045 0.114 ASTM D374

Carrier Thickness (inch) / (mm) 0.001 0.025 ASTM D374

Continuous Use Temp (°F) / (°C) 248 120 —

Phase Change Temp (°F) / (°C) 131 55 ASTM D3418

THERMAL

Thermal Conductivity (W/m-K) (1) 1.0 1.0 ASTM D5470

THERMAL PERFORMANCE vs PRESSURE

Pressure (psi) 10 25 50 100 200

TO-220 Thermal Performance (°C/W) 0.70 0.58 0.52 0.43 0.37

Thermal Impedance (°C-in2/W) (2) 0.10 0.08 0.07 0.06 0.05

1) This is the measured thermal conductivity of the Hi-Flow coating. It represents one conducting layer in a three-layer laminate.The

Hi-Flow coatings are phase change compounds.These layers will respond to heat and pressure induced stresses.The overall conductivity

of the material in post-phase change, thin film products is highly dependent upon the heat and pressure applied.This characteristic is

not accounted for in ASTM D5470. Please contact Bergquist Product Management if additional specifications are required.

2) The ASTM D5470 test fixture was used and the test sample was conditioned at 70°C prior to test.The recorded value includes

interfacial thermal resistance.These values are provided for reference only. Actual application performance is directly related to the

surface roughness, flatness and pressure applied.

SPDG_Chapter2_10.06.qxp 10/20/2006 11:25 AM Page 37

HI-FLOW

Hi-Flow

225UT

Non-Reinforced, Pressure Sensitive Phase Change Thermal Interface Material

Features and Benefits

• Thermal impedance:

0.08°C-in2/W (@25 psi)

• 55°C phase change composite with

inherent tack characteristics

• High-visibility protective tabs

• Pressure sensitive phase change thermal

interface material

Hi-Flow 225UT is designed as a pressure

sensitive thermal interface material for use

between a high performance processor and

a heat sink. Hi-Flow 225UT is a thermally

conductive 55°C phase change composite

with inherent tack.The material is supplied on

a polyester carrier liner and is available with

high-visibility protective tabs.

Above its phase change temperature, Hi-Flow

225UT wets-out the thermal interface surfaces

and flows to produce the lowest thermal

impedance.The material requires pressure of

the assembly to cause flow. Hi-Flow 225UT

coatings will resist dripping.

Application Methods:

1. Hand-apply Hi-Flow 225UT to a room-

temperature heat sink.The Hi-Flow 225UT

pad exhibits inherent tack and can be

hand-applied similar to an adhesive pad.

The tab liner can remain on the heat sink

and pad throughout shipping and handling

until is it is ready for final assembly.

Typical Applications Include:

• Computer and peripherals

• High performance computer processors

• Graphic cards

• Power modules

Configurations Available:

• Roll form with tabs and kiss-cut parts – no holes

Hi-Flow 225UT is limited to a square or rectangular part design. Dimensional tolerance is

+/- 0.020 inch (0.5mm).

Building a Part Number Standard Options

Hi- Flow®: U.S. Patent 6,197,859 and others

Clear Polyester

Carrier Liner

HF 225UT

Roll Form,

Kiss-Cut Parts

Clear/Colored

Protective Tab

Adhesive Strip

"Quick-Snap" High Visibility

Tab for Removal

TYPICAL PROPERTIES OF HI-FLOW 225UT

PROPERTY IMPERIAL VALUE METRIC VALUE TEST METHOD

Color Black Black Visual

Reinforcement Carrier None None —

Thickness (inch) / (mm) 0.003 0.077 ASTM D374

Continuous Use Temp (°F) / (°C) 248 120 —

Phase Change Temp (°F) / (°C) 131 55 ASTM D3418

ELECTRICAL

Flame Rating V-O V- O U.L. 94

THERMAL

Thermal Conductivity (W/m-K) (1) 0.7 0.7 ASTM D5470

THERMAL PERFORMANCE vs PRESSURE

Pressure (psi) 10 25 50 100 200

TO-220 Thermal Performance (°C/W) 0.60 0.53 0.46 0.40 0.35

Thermal Impedance (°C-in2/W) (2) 0.09 0.08 0.07 0.06 0.05

1) This is the measured thermal conductivity of the Hi-Flow coating. It represents one conducting layer in a three-layer laminate.The

Hi-Flow coatings are phase change compounds.These layers will respond to heat and pressure induced stresses.The overall conductivity

of the material in post-phase change, thin film products is highly dependent upon the heat and pressure applied.This characteristic is

not accounted for in ASTM D5470. Please contact Bergquist Product Management if additional specifications are required.

2) The ASTM D5470 test fixture was used and the test sample was conditioned at 70°C prior to test.The recorded value includes

interfacial thermal resistance.These values are provided for reference only. Actual application performance is directly related to the

surface roughness, flatness and pressure applied.

SPDG_Chapter2_10.06.qxp 10/20/2006 11:25 AM Page 38

Hi-Flow

225U

HI-FLOW

Non-Reinforced Phase Change Thermal Interface Material

Features and Benefits

• Thermal impedance: 0.07°C-in2/W (@25 psi)

• Hi-Flow coating will resist dripping

• Thermally conductive 55°C phase change

compound

• Available in roll form with kiss-cut parts

Hi-Flow 225U is designed for use as a thermal

interface material between a computer

processor and a heat sink.The product

consists of a thermally conductive 55°C

phase change compound coated on a release

liner and supplied on a carrier.

Above its phase change temperature, Hi-Flow

225U wets-out the thermal interface surfaces

and flows to produce low thermal impedance.

Hi-Flow 225U requires pressure of the

assembly to cause flow.

Application Methods:

1. Hand-apply to 35°- 45°C heat sink.The heat

sink is heated in an oven or via heat gun to

between 35°- 45°C.The Hi-Flow 225U part

is then applied like an adhesive pad.The heat

sink is cooled to room temperature and

packaged. A protective tab liner remains in

place until the unit is ready for final assembly.

The protective tab can be readily removed

from the applied Hi-Flow 225U pad at a

maximum temperature of 28°C.

2. Automated equipment with 30-psi pressure.

A pick-and-place automated dispensing unit

can be used to apply the Hi-Flow 225U

pad to a room-temperature heat sink.The

placement head should have a silicone

rubber pad, and should apply approximately

30-psi pressure to the pad on transfer to

the 25° – 35°C heat sink. Once applied,

the protective tab can be readily removed

from the Hi-Flow 225U pad at a maximum

temperature of 28°C.

Typical Applications Include:

• Computer and peripherals

• High performance computer processors

• Graphic cards

• Power modules

Configurations Available:

• Roll form with tabs and kiss-cut parts – no holes

Hi-Flow 225U is limited to a square or rectangular part design. Dimensional tolerance is

+/- 0.020 inch (0.5mm).

Building a Part Number Standard Options

Hi- Flow®: U.S. Patent 6,197,859 and others

Section A

Section B

Section C

Section D

Section E

NA = Selected standard option. If not selecting a standard

option, insert company name, drawing number, and

revision level.

HF225U = Hi-Flow 225U Phase Change Material

HF225U 0.0015 00 NA

Note: To build a part number, visit our website at www.bergquistcompany.com.

Standard thicknesses available: 0.0015"

00 = No adhesive

_ _ _ = Standard Hi-Flow 225U configuration,

11/500 = 11" x 500' rolls, or 00 = custom configuration

––––

11/500

TYPICAL PROPERTIES OF HI-FLOW 225U

PROPERTY IMPERIAL VALUE METRIC VALUE TEST METHOD

Color Black Black Visual

Reinforcement Carrier None None —

Thickness (inch) / (mm) 0.0015 0.036 ASTM D374

Continuous Use Temp (°F) / (°C) 302 150 —

Phase Change Temp (°F) / (°C) 131 55 ASTM D3418

ELECTRICAL

Flame Rating V-O V- O U.L. 94

THERMAL

Thermal Conductivity (W/m-K) (1) 1.0 1.0 ASTM D5470

THERMAL PERFORMANCE vs PRESSURE

Pressure (psi) 10 25 50 100 200

TO-220 Thermal Performance (°C/W) 0.53 0.47 0.39 0.34 0.32

Thermal Impedance (°C-in2/W) (2) 0.08 0.07 0.06 0.05 0.04

1) This is the measured thermal conductivity of the Hi-Flow coating. It represents one conducting layer in a three-layer laminate.The

Hi-Flow coatings are phase change compounds.These layers will respond to heat and pressure induced stresses.The overall conductivity

of the material in post-phase change, thin film products is highly dependent upon the heat and pressure applied.This characteristic is

not accounted for in ASTM D5470. Please contact Bergquist Product Management if additional specifications are required.

2) The ASTM D5470 test fixture was used and the test sample was conditioned at 70°C prior to test.The recorded value includes

interfacial thermal resistance.These values are provided for reference only. Actual application performance is directly related to the

surface roughness, flatness and pressure applied.

SPDG_Chapter2_10.06.qxp 10/20/2006 11:25 AM Page 39

Hi-Flow

625

Electrically Insulating,Thermally Conductive Phase Change Material

HI-FLOW

Features and Benefits

• Thermal impedance:

0.71°C-in2/W (@25 psi)

• Electrically isolating

• 65°C phase change compound coated

on PEN film

• Tack-free and scratch-resistant

Hi-Flow 625 is a film-reinforced phase change

material.The product consists of a thermally

conductive 65°C phase change compound

coated on PEN film. Hi-Flow 625 is designed

to be used as a thermal interface material

between electronic power devices that

require electrical isolation and a heat sink.The

reinforcement makes Hi-Flow 625 easy to

handle, and the 65°C phase change

temperature of the coating material eliminates

shipping and handling problems.The PEN film

has a continuous use temperature of 150°C.

Hi-Flow 625 is tack-free and scratch-resistant at

production temperature and does not require

a protective liner in most shipping situations.

The material has the thermal performance of

2-3 mil mica and grease assemblies.

Typical Applications Include:

• Spring / clip mounted

• Power semiconductors

• Power modules

Configurations Available:

• Sheet form, die-cut parts and roll form

• With or without pressure sensitive adhesive

Building a Part Number Standard Options

Hi- Flow®: U.S. Patents 6,197,859 and 5,950,066.

Section A

Section B

Section C

Section D

Section E

NA = Selected standard option. If not selecting a standard

option, insert company name, drawing number, and

revision level.

HF625 = Hi-Flow 625 Phase Change Material

HF625 0.005 AC––––1212 NA

Note: To build a part number, visit our website at www.bergquistcompany.com.

Standard thicknesses available: 0.005"

AC = Adhesive, one side

00 = No adhesive

_ _ _ = Standard configuration dash number,

1212 = 12" x 12" sheets, 12/250 = 12" x 250' rolls, or

00 = custom configuration

TYPICAL PROPERTIES OF HI-FLOW 625

PROPERTY IMPERIAL VALUE METRIC VALUE TEST METHOD

Color Green Green Visual

Reinforcement Carrier PEN Film PEN Film —

Thickness (inch) / (mm) 0.005 0.127 ASTM D374

Elongation (%45° to Warp and Fill) 60 60 ASTM D882A

Tensile Strength (psi) / (MPa) 30,000 206 ASTM D882A

Continuous Use Temp (°F) / (°C) 302 150 —

Phase Change Temp (°F) / (°C) 149 65 ASTM D3418

ELECTRICAL

Dielectric Breakdown Voltage (Vac) 4000 4000 ASTM D149

Dielectric Constant (1000 Hz) 3.5 3.5 ASTM D150

Volume Resistivity (Ohm-meter) 1010 1010 ASTM D257

Flame Rating V-O V- O U.L. 94

THERMAL

Thermal Conductivity (W/m-K) (1) 0.5 0.5 ASTM D5470

THERMAL PERFORMANCE vs PRESSURE

Pressure (psi) 10 25 50 100 200

TO-220 Thermal Performance (°C/W) 2.26 2.10 2.00 1.93 1.87

Thermal Impedance (°C-in2/W) (2) 0.79 0.71 0.70 0.67 0.61

1) This is the measured thermal conductivity of the Hi-Flow coating. It represents one conducting layer in a three-layer laminate.The

Hi-Flow coatings are phase change compounds.These layers will respond to heat and pressure induced stresses.The overall conductivity

of the material in post-phase change, thin film products is highly dependent upon the heat and pressure applied.This characteristic is

not accounted for in ASTM D5470. Please contact Bergquist Product Management if additional specifications are required.

2) The ASTM D5470 test fixture was used and the test sample was conditioned at 70°C prior to test.The recorded value includes

interfacial thermal resistance.These values are provided for reference only. Actual application performance is directly related to the

surface roughness, flatness and pressure applied.

SPDG_Chapter2_10.06.qxp 10/20/2006 11:25 AM Page 40

Hi-Flow

300P

HI-FLOW

Electrically Insulating,Thermally Conductive Phase Change Material

Features and Benefits

• Thermal impedance:

0.13°C-in2/W (@25 psi)

• Field-proven polyimide film

- excellent dielectric performance

- excellent cut-through resistance

• Outstanding thermal performance in an

insulated pad

Hi-Flow 300P consists of a thermally

conductive 55°C phase change compound

coated on a thermally conductive polyimide

film.The polyimide reinforcement makes the

material easy to handle and the 55°C phase

change temperature minimizes shipping and

handling problems.

Hi-Flow 300P achieves superior values in

voltage breakdown and thermal perform-

ance when compared to its competition.The

product is supplied on an easy release liner

for exceptional handling in high volume

manual assemblies. Hi-Flow 300P is designed

for use as a thermal interface material

between electronic power devices requiring

electrical isolation to the heat sink.

Bergquist suggests the use of spring clips to

assure constant pressure with the interface

and power source. Please refer to thermal

performance data to determine nominal

spring pressure for your application.

Typical Applications Include:

• Spring / clip mounted

• Discrete power semiconductors and modules

Configurations Available:

• Roll form, die-cut parts and sheet form, with or without pressure sensitive adhesive

Building a Part Number Standard Options

Hi- Flow®: U.S. Patent 6,197,859 and others

Section A

Section B

Section C

Section D

Section E

NA = Selected standard option. If not selecting a standard

option, insert company name, drawing number, and

revision level.

HF300P = Hi-Flow 300P Phase Change Material

HF300P 0.001 00––––00 ACME10256 Rev a

Note: To build a part number, visit our website at www.bergquistcompany.com.

Standard polyimide thicknesses available: 0.001", 0.0015",

0.002"

AC = Adhesive, one side

00 = No adhesive

_ _ _ = Standard configuration dash number,

1112 = 11" x 12" sheets, 11/250 = 11" x 250' rolls, or

00 = custom configuration

We produce thousands of specials. Tooling charges vary

depending on tolerances and complexity of the part.

TYPICAL PROPERTIES OF HI-FLOW 300P

PROPERTY IMPERIAL VALUE METRIC VALUE TEST METHOD

Color Green Green Visual

Reinforcement Carrier Polyimide Polyimide —

Thickness (inch) / (mm) 0.004 - 0.005 0.102 - 0.127 ASTM D374

Film Thickness (inch) / (mm) 0.001 - 0.002 0.025 - 0.050 ASTM D374

Elongation (%45° to Warp and Fill) 40 40 ASTM D882A

Tensile Strength (psi) / (MPa) 7000 48 ASTM D882A

Continuous Use Temp (°F) / (°C) 302 150 —

Phase Change Temp (°F) / (°C) 131 55 ASTM D3418

ELECTRICAL

Dielectric Breakdown Voltage (Vac) 5000 5000 ASTM D149

Dielectric Constant (1000 Hz) 4.5 4.5 ASTM D150

Volume Resistivity (Ohm-meter) 1012 1012 ASTM D257

Flame Rating V-O V- O U.L. 94

THERMAL

Thermal Conductivity (W/m-K) (1) 1.6 1.6 ASTM D5470

THERMAL PERFORMANCE vs PRESSURE

Pressure (psi) 10 25 50 100 200

TO-220 Thermal Performance (°C/W) 0.0010" 0.95 0.94 0.92 0.91 0.90

TO-220 Thermal Performance (°C/W) 0.0015" 1.19 1.17 1.16 1.14 1.12

TO-220 Thermal Performance (°C/W) 0.0020" 1.38 1.37 1.35 1.33 1.32

Thermal Impedance (°C-in2/W) 0.0010" (2) 0.13 0.13 0.12 0.12 0.12

Thermal Impedance (°C-in2/W) 0.0015" (2) 0.17 0.16 0.16 0.16 0.15

Thermal Impedance (°C-in2/W) 0.0020" (2) 0.19 0.19 0.19 0.18 0.18

1) This is the measured thermal conductivity of the Hi-Flow coating. It represents one conducting layer in a three-layer laminate.The

Hi-Flow coatings are phase change compounds.These layers will respond to heat and pressure induced stresses.The overall conductivity

of the material in post-phase change, thin film products is highly dependent upon the heat and pressure applied.This characteristic is

not accounted for in ASTM D5470. Please contact Bergquist Product Management if additional specifications are required.

2) The ASTM D5470 test fixture was used and the test sample was conditioned at 70°C prior to test.The recorded value includes

interfacial thermal resistance.These values are provided for reference only. Actual application performance is directly related to the

surface roughness, flatness and pressure applied.

SPDG_Chapter2_10.06.qxp 10/20/2006 11:25 AM Page 41

Hi-Flow

300G

HI-FLOW

Features and Benefits

• Thermal impedance:

0.20°C-in2/W (@25 psi)

• Will not drip or run like grease

• Phase change compound coated on

a fiberglass carrier

Hi-Flow 300G consists of a thermally conductive

55°C phase change compound coated on a

fiberglass web. Hi-Flow 300G is designed as a

thermal interface material between a computer

processor and a heat sink.

Above the phase change temperature,

Hi-Flow 300G wets-out the thermal interface

surfaces and flows to produce low thermal

impedance.The material requires pressure of

the assembly to cause flow. Hi-Flow 300G will

not drip or run like grease.

Application Methods

1. Hand-apply to 40°- 50°C heat sink.The heat

sink is heated in an oven or by a heat gun

to between 40°- 50°C allowing the Hi-Flow

300G pad to be applied like an adhesive

pad.The heat sink is then cooled to room

temperature and packaged.

2. Hand-apply to 20°- 35°C heat sink.

Hi-Flow 300G can be applied to a room

temperature heat sink with the assistance

of a foam roller.The pad is positioned on

the heat sink and a hand roller is used to

apply pressure of 30 psi.

3. Automated equipment with 30 psi pressure.

A pick-and-place automated dispensing unit

can be used to apply Hi-Flow 300G to a

room temperature heat sink.The placement

head should have a soft silicone rubber

pad, and apply 30 psi pressure to the pad

on transfer to the 20°- 35°C heat sink.

Fiberglass-Reinforced, Phase Change Thermal Interface Material

Typical Applications Include:

• Computer and peripherals

• As a thermal interface where bare die is exposed and needs to be heat sinked

Configurations Available:

• Sheet form, die-cut parts and roll form

• With or without pressure sensitive adhesive

Building a Part Number Standard Options

Hi- Flow®: U.S. Patent 6,197,859 and others

Section A

Section B

Section C

Section D

Section E

NA = Selected standard option. If not selecting a standard

option, insert company name, drawing number, and

revision level.

HF300G = Hi-Flow 300G Phase Change Material

HF300G 0.005 00––––1012 NA

Note: To build a part number, visit our website at www.bergquistcompany.com.

Standard thicknesses available: 0.005"

AC = Adhesive, one side

00 = No adhesive

_ _ _ = Standard configuration dash number,

1012 = 10" x 12" sheets, 10/250 = 10" x 250' rolls, or

00 = custom configuration

TYPICAL PROPERTIES OF HI-FLOW 300G

PROPERTY IMPERIAL VALUE METRIC VALUE TEST METHOD

Color Green Green Visual

Reinforcement Carrier Fiberglass Fiberglass —

Thickness (inch) / (mm) 0.005 0.127 ASTM D374

Elongation (%45° to Warp and Fill) 40 40 ASTM D882A

Tensile Strength (psi) / (MPa) 400 3 ASTM D882A

Continuous Use Temp (°F) / (°C) 212 100 —

Phase Change Temp (°F) / (°C) 131 55 ASTM 3418

ELECTRICAL

Dielectric Breakdown Voltage (Vac) 300 300 ASTM D149

Dielectric Constant (1000 Hz) 3.5 3.5 ASTM D150

Volume Resistivity (Ohm-meter) 108108ASTM D257

Flame Rating V-O V- O U.L. 94

THERMAL

Thermal Conductivity (W/m-K) (1) 1.6 1.6 ASTM D5470

THERMAL PERFORMANCE vs PRESSURE

Pressure (psi) 10 25 50 100 200

TO-220 Thermal Performance (°C/W) 0.96 0.92 0.88 0.85 0.84

Thermal Impedance (°C-in2/W) (2) 0.27 0.20 0.16 0.15 0.14

1) This is the measured thermal conductivity of the Hi-Flow coating. It represents one conducting layer in a three-layer laminate.The

Hi-Flow coatings are phase change compounds.These layers will respond to heat and pressure induced stresses.The overall conductivity

of the material in post-phase change, thin film products is highly dependent upon the heat and pressure applied.This characteristic is

not accounted for in ASTM D5470. Please contact Bergquist Product Management if additional specifications are required.

2) The ASTM D5470 test fixture was used and the test sample was conditioned at 70°C prior to test.The recorded value includes

interfacial thermal resistance.These values are provided for reference only. Actual application performance is directly related to the

surface roughness, flatness and pressure applied.

SPDG_Chapter2_10.06.qxp 10/20/2006 11:25 AM Page 42

SIL-PAD

Sil-Pad

Thermally Conductive Insulators

More than 25 years ago, Bergquist set the standard for elastomeric

thermal interface materials with the introduction of Sil-Pad.Today,

Bergquist is a world leader with a complete family of Sil-Pad materials

to meet the critical needs of a rapidly changing electronics industry.

Sil-Pad thermally conductive insulators, in their many forms, continue

to be a clean and efficient alternative to mica, ceramics or grease for a

wide range of electronic applications. Bergquist application specialists

work closely with customers to specify the proper Sil-Pad material for

each unique thermal management requirement.

Comprehensive choices for a cleaner and more efficient thermal interface

Solutions-Driven Thermal Management Products for Electronic Devices

Features

The Sil-Pad family encompasses

dozens of products, each with its

own unique construction, prop-

erties and performance. Here are

some of the important features

offered by the Sil-Pad family:

• Proven silicone rubber binders

• Fiberglass, dielectric film or

polyester film carriers

• Special fillers to achieve specific

performance characteristics

• Flexible and conformable

• Reinforcements to resist

cut-through

• Variety of thicknesses

• Wide range of thermal

conductivities and dielectric

strengths

Benefits

Choosing Sil-Pad thermal products

saves time and money while maxi-

mizing an assembly’s performance

and reliability. Specifically:

• Excellent thermal performance

• Eliminates the mess of grease

• More durable than mica

• Less costly than ceramic

• Resistant to electrical shorting

• Easier and cleaner to apply

• Under time and pressure,

thermal resistance will decrease

• Better performance for today’s

high-heat compacted assemblies

• A specific interfacial performance

that matches the need

• Efficient “total applied cost” that

compares favorably with other

alternatives

Options

Some Sil-Pad products have special

features for particular applications.

Options include:

• Available with or without

adhesive

• Some configurations are well

suited for automated

dispensing and/or placement

• Aluminum foil or imbedded

graphite construction for

applications not requiring

electrical insulation

• Copper shield layer

• Polyester binder material for

silicone-sensitive applications

• Polyimide film carrier for

increased voltage breakdown

• Materials with reduced moisture

sensitivity

• Available in rolls, sheets, tubes

and custom die-cut parts

• Custom thicknesses and

constructions

We produce thousands of specials.

Tooling charges vary depending

on the complexity of the part.

Applications

The large family of Sil-Pad

thermally conductive insulators is

extremely versatile. In today’s

marketplace, Sil-Pads are used in

virtually every component of the

electronics industry, including:

• Interface between a power

transistor, CPU or other heat-

generating component and a

heat sink or rail

• Isolate electrical components

and power sources from heat

sink and/or mounting bracket

• Interface for discrete semicon-

ductors requiring low-pressure

spring-clamp mounting

• Consumer electronics

• Automotive systems

• Telecommunications

• Aerospace

• Military

• Medical devices

• Industrial controls

SPDG_Chapter2_10.06.qxp 10/20/2006 11:25 AM Page 43

Sil-Pad

Comparison Data

SIL-PAD

TO-220 Thermal Performance

Thermal Performance (C/W)

Interface Pressure (psi)

Sil-Pad High Performance Materials

0 50 100 150 200

3.25

3.05

2.85

2.65

2.45

2.25

2.05

1.85

1.65

1.45

1.25

Sil-Pad 1750

Sil-Pad A1500, 10 mil

Sil-Pad 2000, 10 mil

Sil-Pad A2000, 20 mil

Sil-Pad 1500ST, 12 mil

Sil-Pad A2000, 15 mil

Sil-Pad 1500ST, 8 mil

0.00

0.25

0.50

0.75

1.00

1.25

1.50

1.75

2.00

2.25

2.50

2.75

0 50 100 150 200

Thermal Performance (C/W)

Interface Pressure (psi)

Q-Pad Materials

Non-Electrically Isolating

Q-Pad 3

Q-Pad II

1.25

2.25

3.25

4.25

5.25

6.25

7.25

8.25

9.25

0 50 100 150 200

Thermal Performance (C/W)

Interface Pressure (psi)

Sil-Pad High Value Materials

Sil-Pad 400, 9 mil

Sil-Pad 400, 7 mil

Sil-Pad 980

Sil-Pad 900S

Sil-Pad 800

Sil-Pad 1100ST

Sil-Pad Polyimide-Based Materials

4.25

4.00

3.75

3.50

3.25

3.00

2.75

2.50

2.25

2.00

1.75

1.50

1.25

Thermal Performance (C/W)

Interface Pressure (psi)

0 50 100 150 200

Sil-Pad K-4

Sil-Pad K-6

Sil-Pad K-10

SPDG_Chapter2_10.06.qxp 10/20/2006 11:25 AM Page 44

Frequently Asked Questions

SIL-PAD

Q: What is the primary difference between

Sil-Pad A2000 and Sil-Pad 2000 products?

A: Sil-Pad A2000 utilizes a different filler package than Sil-Pad 2000.

This change results in a more compliant Sil-Pad A2000 material

that inherently lowers interfacial resistance losses.This reduction

in interfacial resistance results in improved overall thermal

performance when measured at lower pressures in standard

ASTM D5470 and TO-220 testing.

Q: When should I choose Sil-Pad A2000

versus Sil-Pad 2000 for my application?

A: The answer is based on the assumption that the primary design

intent is to increase thermal performance. If your application

utilizes lower clamping pressures (e.g. 10 to 75 psi) you will find

the Sil-Pad A2000 to provide excellent thermal performance. In

contrast, if you are designing for higher clamping pressures (e.g.

100 psi or greater), it is likely that you will require the thermal

performance characteristics of the Sil-Pad 2000.

Q: Are there differences in electrical characteristics

between Sil-Pad A2000 and Sil-Pad 2000?

A: Yes. Bergquist evaluates and publishes voltage breakdown,

dielectric constant and volume resistivity data per ASTM

standards for these materials. Due to differences between

ASTM lab testing and actual application performance, for best

results, these characteristics should be evaluated within the

actual customer system.

Q: Can I get Sil-Pad A2000 in roll form?

A: Yes. With the new environmentally “green” process improvements

added with the introduction of Sil-Pad A2000 products, the

materials are now available in roll form.The original Sil-Pad 2000

material cannot be produced in continuous roll form.

Q: When should I choose Sil-Pad 800

versus Sil-Pad 900S for my application?

A: Sil-Pad 800 is specifically formulated to provide excellent thermal

performance for discrete semiconductor applications that utilize

low clamping pressures (e.g. spring clips at 10 to 50 psi). In con-

trast, if you are designing for higher clamping pressure applications

using discrete semi-conductors (e.g. 50 to 100 psi), it is likely that

you will prefer the combination of high thermal performance and

cut-through resistance inherent in Sil-Pad 900S material.

Q: When should I choose Sil-Pad 980

versus Sil-Pad 900S for my application?

A: Sil-Pad 980 is specifically formulated to provide superior cut-

through and crush resistance in combination with excellent heat

transfer and dielectric properties. Sil-Pad 980 has a proven history

of reliability in high-pressure applications where surface

imperfections such as burrs and dents are inherently common.

These applications often include heavily machined metal surfaces

manufactured from extrusions or castings. Sil-Pad 900S carries a

high level of crush resistance and is more likely to be used in

burr-free or controlled-surface finish applications.

Q: Is there an adhesive available for Sil-Pad 1500ST and

Sil-Pad 1100ST?

A: Sil-Pad 1500ST and Sil-Pad 1100ST have an inherent tack on

both sides of the material.This inherent tack is used instead of

an adhesive.The tack provides sufficient adhesive for dispensing

from the carrier liner and placement on the component. Sil-Pad

1500ST and Sil-Pad 1100ST can be repositioned after the initial

placement.

Q: Why is the thermal performance curves of Sil-Pad

1500ST and Sil-Pad 1100ST so flat when compared to

other Sil-Pads?

A: Sil-Pad 1500ST and Sil-Pad 1100ST wet-out the application

surfaces at a very low pressures. Optimal thermal performance

is achieved at pressures as low as 50 psi.

Q: How do I know which Sil-Pad is right for

my specific application?

A: Each application has specific characteristics (e.g. surface finish,

flatness tolerances, high pressure requirements, potential burrs,

etc.) that determine which Sil-Pad will optimize thermal

performance. Select a minimum of two pads that best fit the

application, then conduct testing to determine which material

performs the best.

Q: What is IS09001:2000?

A: The ISO certification is the adoption of a quality management

system that is a strategic decision of the organization.This

International Standard specifies requirements for a quality

management system where an organization: a) needs to

demonstrate its ability to consistently provide product that

meets customer and applicable regulatory requirements, and

b) aims to enhance customer satisfaction through the effective

application of the system, including processes for continual

improvement of the system and the assurance of conformity

to customer and regulatory requirements.

SPDG_Chapter2_10.06.qxp 10/20/2006 4:34 PM Page 45

Polyimide Films

Polyimide films can also be used as insulators and are often

combined with wax or grease to achieve a low thermal impedance.

These polyimide films are especially tough and have high dielectric

strength. Sil-Pad K-4, K-6 and K-10 incorporate polyimide film as

the carrier material.

Ceramic Insulators

Other insulation materials include ceramic wafer insulators which have

a higher thermal conductivity than mica.They are often used thicker

(20-60 mils), (.5 to 1.5 mm) to reduce capacitive coupling while

maintaining a low thermal impedance.

Drawbacks to ceramic insulators are their high cost and, like mica,

they are rigid and crack easily. Also, ceramic beryllia use requires

careful handling since inhalation of beryllia dust can cause lung

inflammation (berylliosis).

Why Choose Sil-Pad Thermally Conductive Insulators?

SIL-PAD

Overview

The Bergquist Company established the standard for elastomeric,

thermally conductive insulation materials with the development of

Sil-Pad over 25 years ago. Sil-Pad was developed as a clean, grease-

free alternative to mica and grease. Now, a complete family of materials

is available to meet the diverse and changing requirements of today’s

design engineer.

Mica and Grease

Mica insulators have been in use for over 35 years and are still

commonly used as an insulator. Mica is inexpensive and has excellent

dielectric strength, but it is brittle and is easily cracked or broken.

Because mica used by itself has high thermal impedance, thermal

grease is commonly applied to it.The grease flows easily and excludes

air from the interface to reduce the interfacial thermal resistance. If

the mica is also thin (2-3 mils [50-80 µm]), a low thermal impedance

can be achieved.

However, thermal

grease introduces a

number of problems to

the assembly process. It

is time-consuming to

apply, messy and difficult

to clean. Once thermal

grease has been applied

to an electronic assem-

bly, solder processes

must be avoided to

prevent contamination

of the solder. Cleaning

baths must also be avoided to prevent wash-out of the interface

grease, causing a dry joint and contamination of the bath. Assembly,

soldering and cleaning processes must be performed in one process

while the greased insulators are installed off-line in a secondary

process. If the grease is silicone-based, migration of silicone molecules

occurs over time, drying out the grease and contaminating the assembly.

Silicone migration onto electrical contacts can result in the loss of

electrical conductance. For this reason, silicone-based thermal grease

has not been used in telecommunications systems.

SPDG_Chapter2_10.06.qxp 10/20/2006 11:25 AM Page 46

SIL-PAD

Carriers

The carrier provides physical reinforcement and contributes to dielectric

strength. High dielectric and physical strength are obtained by using a

heavy, tight mesh, but thermal resistance will suffer. A light, open mesh

reduces thermal resistance, dielectric strength and cut-through resistance.

The carrier materials used in Sil-Pad materials include fiberglass and

dielectric film.

Fillers

The thermal conductivity of Sil-Pad products is improved by filling

them with ingredients of high thermal conductivity.The fillers change

the characteristics of the silicone rubber to enhance thermal and/or

physical characteristics.

For instance, some fillers make the silicone rubber hard and tough

while still retaining the ability to flow under pressure. A harder silicone

helps the material resist cut-through. In other applications a filler is

used to make the silicone rubber softer and more conformable to

rough surfaces.While the range in thermal resistance of greased mica

is quite large, the average is comparable to elastomeric insulators filled

with a blend of the appropriate ingredients.

Fiberglass-based insulators (Sil-Pad 400 and Sil-Pad 1500) have a rough

surface texture and will show a 15-20% decrease in thermal resistance

over a 24-hour period. Film-based insulators (Sil-Pad K-4, Sil-Pad K-6 and

Sil-Pad K-10) are smoother initially and show a 5% decrease over the

same period of time.

Sil-Pad Materials

Sil-Pad thermally conductive insulators are designed to be clean,

grease-free and flexible.The combination of a tough carrier material

such as fiberglass and silicone rubber which is conformable, provides

the engineer with a more versatile material than mica or ceramics

and grease. Sil-Pad products minimize the thermal resistance from the

case of a power semiconductor to the heat sink. Sil-Pad materials

electrically isolate the semiconductor from the heat sink and have suf-

fiicient dielectric strength to withstand high voltage.They are also

strong enough to resist puncture by the facing metal surface. With

more than 30 different Sil-Pad materials available, there is a Sil-Pad

matched to almost any application.

Sil-Pad Construction

Sil-Pad products are constructed with a variety of different materials

including fiberglass, silicone rubber, polyimide film, polyester film and

fillers used to enhance performance. Sil-Pad materials are typically

constructed with an elastomeric binder compounded with a thermally

conductive filler coated on a carrier.The characteristics of your

application often determine which Sil-Pad construction will produce

the best performance.

Binders

Most Sil-Pad products use silicone rubber as the binder. Silicone rubber

has a low dielectric constant, high dielectric strength, good chemical

resistance and high thermal stability.

Silicone rubber also exhibits cold flow, which excludes air from the

interface as it conforms to the mating surfaces.This flow eliminates

the need for thermal grease. A rough-surface-textured insulator needs

to flow more to exclude air than a smooth one.The smoother pads

also need less pressure to wet-out the surfaces and obtain optimum

thermal contact.

SPDG_Chapter2_10.06.qxp 10/20/2006 11:25 AM Page 47

Mechanical, Electrical and Thermal Properties

SIL-PAD

Devices with larger surface areas need more pressure to get the

insulator to conform to the interface than smaller devices. In most

screw-mount applications, the torque required to tighten the fastener

is sufficient to generate the pressure needed for optimum thermal

resistance.There are exceptions where the specified torque on the

fastener does not yield the optimum thermal resistance for the insula-

tor being used and either a different insulator or a

different mounting scheme should be used.

Interfacial thermal resistance decreases as time

under pressure increases. In applications where

high clamping forces cannot be used, time can be

substituted for pressure to achieve lower thermal

resistance.The only way to know precisely what

the thermal resistance of an insulator will be in

an application is to measure it in that application.

Electrical Properties

If your application does not require electrical insulation, Q-Pad II or

Q-Pad 3 are ideal grease replacement materials.These materials do

not provide electrical isolation but have excellent thermal properties.

Hi-Flow phase change materials should also be considered for these

applications. (Reference pages 32-44 of this guide.)

The most important electrical property in a typical assembly where a

Sil-Pad insulator is used is dielectric strength. In many cases the dielectric

strength of a Sil-Pad will be the determining factor in the design of

the apparatus in which it is to be used.

Here are some general guidelines regarding electrical properties to

consider when selecting a Sil-Pad material:

• Q-Pad II and Q-Pad 3 are used when electrical isolation is not

required.

• Dielectric breakdown voltage is the total voltage that a dielectric

material can withstand.When insulating electrical components from

each other and ground, it is desirable to use an insulator with a high

breakdown voltage.

Mechanical Properties

Woven fiberglass and films are used in Sil-Pad products to provide

mechanical reinforcement.The most important mechanical property

in Sil-Pad applications is resistance to cut-through to avoid electrical

shorting from the device to the heat sink.

Cut-Through Resistance - Bergquist introduced its TO-220 cut-through test

to help customers better understand typical application performance.

Mounting Techniques and Mounting Pressure

Typical mounting techniques include:

• A spring clip, which exerts a centralized clamping force on the body

of the transistor.The greater the mounting force of the spring, the

lower the thermal resistance of the insulator.

• A screw in the mounting tab.With a screw-mounted TO-220, the

force on the transistor is determined by the torque applied to the

fastener.

In extremely low-pressure applications, an insulator with pressure

sensitive adhesive on each side may give the lowest thermal resistance

since the adhesive wets-out the interface easier than the dry rubber.

This decreases the interfacial thermal resistance.

SIL-PAD TYPICAL ELECTRICAL PROPERTIES

BREAKDOWN VOLTAGE DIELECTRIC STRENGTH DIELECTRIC CONSTANT VOLUME RESISTIVITY

Material (kV) (Volts/mil) (kV/mm) (1000 Hz) (Ohm-Meter)

Sil-Pad 400 - 0.007 3.5 500 20 5.5 1011

Sil-Pad 400 - 0.009 4.5 500 20 5.5 1011

Sil-Pad 900S 5.5 600 24 6.0 1010

Sil-Pad A1500 6.0 600 24 7.0 1011

Sil-Pad 2000 4.0 400 16 4.0 1011

Sil-Pad K-4 6.0 1000 39 5.0 1012

Sil-Pad K-6 6.0 1000 39 4.0 1012

Sil-Pad K-10 6.0 1000 39 3.7 1012

Test Method ASTM D149*

* Method A,Type 3 Electrodes

ASTM D149*

* Method A,Type 3 Electrodes

ASTM D150 ASTM D257

SPDG_Chapter2_10.06.qxp 10/20/2006 11:25 AM Page 48

SIL-PAD

2.45

2.9

5.14

(0.010)(0.008)

1.51

2.0

3.13

2.76

1.86

2.21 2.01

1.23

1.76

1.51

• Breakdown voltage decreases as the area of the electrodes

increases.This area effect is more pronounced as the thickness

of the insulator decreases.

• Breakdown voltage decreases as temperature increases.

• Breakdown voltage decreases as humidity increases (Sil-Pad 1750

is less sensitive to moisture).

• Breakdown voltage decreases in the presence of partial discharge.

• Breakdown voltage decreases as the size of the voltage source (kVA

rating) increases.

• Breakdown voltage can be decreased by excessive mechanical stress

on the insulator.

Dielectric strength, dielectric constant and volume resistivity should

all be taken into consideration when selecting a Sil-Pad material.

If your application requires specific electrical performance, please

contact a Bergquist Sales Representative for more detailed

testing information.

Thermal Properties

The thermal properties of a Sil-Pad material and your requirements for

thermal performance probably have more to do with your selection of a

Sil-Pad than any other factor.

Discrete semiconductors, under normal operating conditions, dissipate

waste power which raises the junction temperature of the device. Unless

sufficient heat is conducted out of the device, its electrical performance

and parameters are changed. A 10°C rise in junction temperature can

reduce the mean-time-to-failure of a device by a factor of two. Also,

above 25°C, the semiconductor's total power handling capability will be

reduced by a derating factor inherent to the device.

The thermal properties of Sil-Pad products are thermal impedance,

thermal conductivity and thermal resistance. The thermal resistance

and conductivity of Sil-Pad products are inherent to the material and

do not change.Thermal resistance and thermal conductivity are

measured per ASTM D5470 and do not include the interfacial thermal

resistance effects.Thermal impedance applies to the thermal transfer in

an application and includes the effects of interfacial thermal resistance.

As the material is applied in different ways, the thermal impedance values

will vary from application to application.

• The original Sil-Pad material, Sil-Pad 400, continues to be Bergquist's

most popular material for many applications.

• Sil-Pad A1500 is chosen when greater thermal performance is

required. Sil-Pad A2000 is ideal for high performance, high reliability

applications.

Beyond these standard materials, many things can contribute to the

selection of the correct material for a particular application. Questions

regarding the amount of torque and clamping pressure are often

asked when selecting a Sil-Pad material. Here are some guidelines:

• Interfacial thermal resistance decreases as clamping pressure increases.

• The clamping pressure required to minimize interfacial thermal

resistance can vary with each type of insulator.

• Sil-Pad products with smooth surface finishes (Sil-Pad A1500, Sil-Pad

A2000, Sil-Pad K-4, Sil-Pad K-6 and Sil-Pad K-10) are less sensitive to

clamping pressure than Sil-Pads with rough surface finishes (Sil-Pad 400)

or smooth and tacky finishes (Sil-Pad 1500ST).

SPDG_Chapter2_10.06.qxp 10/20/2006 11:25 AM Page 49

Sil-Pad

Thermally Conductive Insu

SIL-PAD

Sil-Pad 400

.007 in.

Sil-Pad 400

.009 in.

Sil-Pad

800

Sil-Pad

900S

Sil-Pad

980

Sil-Pad

A1500

Sil-Pad

1100ST

Color Gray Gray Gold Pink Mauve Green Yellow

Thickness (in/mm) .007 ± .001

(.18 ± .025)

.009 ± .001

(.23 ± .025)

.005 ± .001

(.13 ± .025)

.009 ± .001

(.23 ± .025)

.009 ± .001

(.23 ± .025)

.010 ± .001

(.25 ± .025)

.012 ± .001

(.30 ± .025)

Thermal Performance

TO-220 Test @ 50 psi °C/W 5.14 6.61 2.45 2.90 4.52 2.21 1.51

Thermal Impedance (°C-in2/W) 1.13 1.45 0.45 0.61 1.07 0.42 0.66

Thermal Conductivity

(W/m-K nominal) 0.9 0.9 1.6 1.6 1.2 2.0 1.1

Voltage Breakdown (Vac) 3500 4500 3000 5500 4000 6000 5000

Continuous Use

Temperature (°C) -60 to 180 -60 to 180 -60 to 180 -60 to 180 -40 to 150 -60 to 180 -60 to 180

Construction Silicone/

Fiberglass

Silicone/

Fiberglass

Silicone/

Fiberglass

Silicone/

Fiberglass

Silicone/

Fiberglass

Silicone/

Fiberglass

Silicone/

Fiberglass

Sil-Pad Applications

Here, Sil-Pad 900S enhances the

thermal transfer from this FR-4

circuit board with thermal vias to

the metal base plate.

Sil-Pad is available in over 100

standard configurations for

common JEDEC package

outlines.

The circuit board above shows

punched parts interfacing screw-

mounted transistors to a finned

heat sink.

This application uses Sil-Pad to

isolate the mounting brackets from

the assembly frame.

A common Sil-Pad application

includes TO-220 transistors

mounted in a row on a heat rail.

These Sil-Pad applications show

clip mounting of transistors on the

left and screw mounting to an alu-

minum bracket on the right.

Choose a Sil-Pad that optimizes

thermal performance for your

mounting method — screw, clip,

spring, bar, etc.

Sil-Pad 980 is used extensively in

industrial applications having

excellent cut-through and abrasion

resistance.

SPDG_Chapter2_10.06.qxp 10/20/2006 11:26 AM Page 50

tive Insulator Selection Table

SIL-PAD

Sil-Pad

1500ST

Sil-Pad

A2000

Sil-Pad

K-4

Sil-Pad

K-6

Sil-Pad

K-10

Poly-Pad

1000

Poly-Pad

K-4

Poly-Pad

K-10

Test

Method

Blue White Gray Bluegreen Beige Yellow Tan Yellow Visual

.008 ± .001

(.20 ± .025)

.015 ± .001

(.38 ± .025)

.006 ± .001

(.15 ± .025)

.006 ± .001

(.15 ± .025)

.006 ± .001

(.15 ± .025)

.009 ± .001

(.23 ± .025)

.006 ± .001

(.15 ± .025)

.006 ± .001

(.15 ± .025) ASTM D374

1.51 1.86 3.13 2.76 2.01 3.74 4.34 2.75 ASTM D5470

0.23 0.32 0.48 0.49 0.41 0.82 0.95 0.60 ASTM D5470

1.8 3.0 0.9 1.1 1.3 1.2 0.9 1.3 ASTM D5470

3000 4000 6000 6000 6000 2500 6000 6000 ASTM D149

-60 to 180 -60 to 200 -60 to 180 -60 to 180 -60 to 180 -20 to 150 -20 to 150 -20 to 150 —

Silicone/

Fiberglass

Silicone/

Fiberglass

Silicone/

Film

Silicone/

Film

Silicone/

Film

Polyester/

Fiberglass

Polyester/

Film

Polyester/

Film —

Sil-Pad Comparison Made Simple!

Comparing thermally conductive interface

materials has never been easier.

Simply go to the “Thermal Materials” section of the

Bergquist website (www.bergquistcompany.com)

and select “Compare Material Properties.”Then

select up to three separate products and this handy

comparison tool will automatically chart thermal

resistance values and display a material properties

table of the selected materials.

The materials comparison tool can be used for

most Bergquist thermal materials, including Sil-Pad,

Hi-Flow, Gap Pad, Q-Pad, Bond-Ply and

Liqui-Bond products.

SPDG_Chapter2_10.06.qxp 10/20/2006 11:26 AM Page 51

Sil-Pad

400

The Original Sil-Pad Material

Features and Benefits

• Thermal impedance:

1.13°C-in2/W (@50 psi)

• Original Sil-Pad material

• Excellent mechanical and physical

characteristics

• Flame retardant

Sil-Pad 400 is a composite of silicone rubber

and fiberglass.The material is flame retardant

and is specially formulated for use as a

thermally conductive insulator.The primary

use for Sil-Pad 400 is to electrically isolate

power sources from heat sinks.

Sil-Pad 400 has excellent mechanical and

physical characteristics. Surfaces are pliable

and allow complete surface contact with

excellent heat dissipation. Sil-Pad 400 actually

improves its thermal resistance with age.

The reinforcing fiberglass provides excellent

cut-through resistance. In addition, Sil-Pad 400

is non-toxic and resists damage from

cleaning agents.

Typical Applications Include:

• Power supplies • Automotive electronics • Motor controls

• Power semiconductors • U.L. File Number E59150 • CAGE Number 55285

Configurations Available:

• Sheet form, die-cut parts and roll form; with or without pressure sensitive adhesive

Building a Part Number Standard Options

Sil-Pad®U.S. Patents 4,574,879; 4,602,125; 4,602,678; 4,685,987; 4,842,911 and others

SIL-PAD

Section A

Section B

Section C

Section D

Section E

NA = Selected standard option. If not selecting a standard

option, insert company name, drawing number, and

revision level.

SP400 = Sil-Pad 400 Material

SP400 0.007 AC 12/250 NA

Note: To build a part number, visit our website at www.bergquistcompany.com.

Standard thicknesses available: 0.007", 0.009"

AC = Adhesive, one side; AC2 = Adhesive, two sides; or

00 = no adhesive

_ _ _ = Standard configuration dash number,

1212 = 12" x 12" sheets, 12/250 = 12" x 250' rolls, or

00 = custom configuration

––––

TYPICAL PROPERTIES OF SIL-PAD 400

PROPERTY IMPERIAL VALUE METRIC VALUE TEST METHOD

Color Gray Gray Visual

Reinforcement Carrier Fiberglass Fiberglass —

Thickness (inch) / (mm) 0.007, 0.009 0.178, 0.229 ASTM D374

Hardness (Shore A) 85 85 ASTM D2240

Breaking Strength (lbs/inch) / (kN/m) 30 5 ASTM D1458

Elongation (%45° to Warp and Fill) 54 54 ASTM D412

Tensile Strength (psi) / (MPa) 3000 20 ASTM D412

Continuous Use Temp (°F) / (°C) -76 to 356 -60 to 180 —

ELECTRICAL

Dielectric Breakdown Voltage (Vac) 3500, 4500 3500, 4500 ASTM D149

Dielectric Constant (1000 Hz) 5.5 5.5 ASTM D150

Volume Resistivity (Ohm-meter) 1011 1011 ASTM D257

Flame Rating V-O V- O U.L. 94

THERMAL

Thermal Conductivity (W/m-K) 0.9 0.9 ASTM D5470

THERMAL PERFORMANCE vs PRESSURE

Pressure (psi) 10 25 50 100 200

TO-220 Thermal Performance (°C/W) 0.007" 6.62 5.93 5.14 4.38 3.61

TO-220 Thermal Performance (°C/W) 0.009" 8.51 7.62 6.61 5.63 4.64

Thermal Impedance (°C-in2/W) 0.007" (1) 1.82 1.42 1.13 0.82 0.54

Thermal Impedance (°C-in2/W) 0.009" (1) 2.34 1.83 1.45 1.05 0.69

1) The ASTM D5470 test fixture was used.The recorded value includes interfacial thermal resistance.These values are provided for

reference only. Actual application performance is directly related to the surface roughness, flatness and pressure applied.

SPDG_Chapter2_10.06.qxp 10/20/2006 11:26 AM Page 52

Sil-Pad

800

Features and Benefits

• Thermal impedance:

0.45°C-in2/W (@50 psi)

• High value material

• Smooth and highly compliant surface

• Electrically isolating

The Sil-Pad 800 family of thermally conductive

insulation materials is designed for applications

requiring high thermal performance and

electrical isolation.These applications also

typically have low mounting pressures for

component clamping.

Sil-Pad 800 material combines a smooth and

highly compliant surface characteristic with high

thermal conductivity.These features optimize the

thermal resistance properties at low pressure.

Applications requiring low component

clamping forces include discrete semiconduc-

tors (TO-220,TO-247 and TO-218) mounted

with spring clips. Spring clips assist with

quick assembly but apply a limited amount

of force to the semiconductor.The smooth

surface texture of Sil-Pad 800 minimizes

interfacial thermal resistance and maximizes

thermal performance.

High Performance Insulator for Low-Pressure Applications

Typical Applications Include:

• Power supplies

• Automotive electronics

• Motor controls

• Power semiconductors

Configurations Available:

• Sheet form, die-cut parts and roll form

• With or without pressure sensitive adhesive

Building a Part Number Standard Options

Sil-Pad®: U.S. Patents 4,574,879; 4,602,125; 4,602,678; 4,685,987; 4,842,911 and others

SIL-PAD

Section A

Section B

Section C

Section D

Section E

NA = Selected standard option. If not selecting a standard

option, insert company name, drawing number, and

revision level.

SP800 = Sil-Pad 800 Material

SP800 0.005 AC 1212 NA

Note: To build a part number, visit our website at www.bergquistcompany.com.

Standard thicknesses available: 0.005"

AC = Adhesive, one side

00 = No adhesive

_ _ _ = Standard configuration dash number,

1212 = 12" x 12" sheets, 12/250 = 12" x 250' rolls, or

00 = custom configuration

––––

TYPICAL PROPERTIES OF SIL-PAD 800

PROPERTY IMPERIAL VALUE METRIC VALUE TEST METHOD

Color Gold Gold Visual

Reinforcement Carrier Fiberglass Fiberglass —

Thickness (inch) / (mm) 0.005 0.127 ASTM D374

Hardness (Shore A) 91 91 ASTM D2240

Elongation (%45° to Warp and Fill) 20 20 ASTM D412

Tensile Strength (psi) / (MPa) 1700 12 ASTM D412

Continuous Use Temp (°F) / (°C) -76 to 356 -60 to 180 —

ELECTRICAL

Dielectric Breakdown Voltage (Vac) 1700 1700 ASTM D149

Type 3 Electrodes 3000 3000 ASTM D149

Dielectric Constant (1000 Hz) 6.0 6.0 ASTM D150

Volume Resistivity (Ohm-meter) 1010 1010 ASTM D257

Flame Rating V-O V- O U.L. 94

THERMAL

Thermal Conductivity (W/m-K) 1.6 1.6 ASTM D5470

THERMAL PERFORMANCE vs PRESSURE

Pressure (psi) 10 25 50 100 200

TO-220 Thermal Performance (°C/W) 3.56 3.01 2.45 2.05 1.74

Thermal Impedance (°C-in2/W) (1) 0.92 0.60 0.45 0.36 0.29

1) The ASTM D5470 test fixture was used.The recorded value includes interfacial thermal resistance.These values are provided for

reference only. Actual application performance is directly related to the surface roughness, flatness and pressure applied.

SPDG_Chapter2_10.06.qxp 10/20/2006 11:26 AM Page 53

Sil-Pad

900S

High Performance Insulator for Low-Pressure Applications

Features and Benefits

• Thermal impedance:

0.61°C-in2/W (@50 psi)

• Electrically isolating

• Low mounting pressures

• Smooth and highly compliant surface

• General-purpose thermal interface

material solution

The true workhorse of the Sil-Pad product

family, Sil-Pad 900S thermally conductive

insulation material, is designed for a wide

variety of applications requiring high thermal

performance and electrical isolation.These

applications also typically have low mounting

pressures for component clamping.

Sil-Pad 900S material combines a smooth

and highly compliant surface characteristic

with high thermal conductivity.These features

optimize the thermal resistance properties at

low pressures.

Applications requiring low component clamp-

ing forces include discrete semiconductors

(TO-220,TO-247 and TO-218) mounted with

spring clips. Spring clips assist with quick

assembly and apply a limited amount of force

to the semiconductor.The smooth surface

texture of Sil-Pad 900S minimizes interfacial

thermal resistance and maximizes thermal

performance.

Typical Applications Include:

• Power supplies

• Automotive electronics

• Motor controls

• Power semiconductors

Configurations Available:

• Sheet form, die-cut parts and roll form

• With or without pressure sensitive adhesive

Building a Part Number Standard Options

Sil-Pad®: U.S. Patents 4,574,879; 4,602,125; 4,602,678; 4,685,987; 4,842,911 and others

SIL-PAD

Section A

Section B

Section C

Section D

Section E

NA = Selected standard option. If not selecting a standard

option, insert company name, drawing number, and

revision level.

SP900S = Sil-Pad 900S Material

SP900S 0.009 AC 00 ACME 951753 Rev B

Note: To build a part number, visit our website at www.bergquistcompany.com.

Standard thicknesses available: 0.009"

AC = Adhesive, one side

00 = No adhesive

_ _ _ = Standard configuration dash number,

1212 = 12" x 12" sheets, 12/250 = 12" x 250' rolls, or

00 = custom configuration

––––

TYPICAL PROPERTIES OF SIL-PAD 900S

PROPERTY IMPERIAL VALUE METRIC VALUE TEST METHOD

Color Pink Pink Visual

Reinforcement Carrier Fiberglass Fiberglass —

Thickness (inch) / (mm) 0.009 0.229 ASTM D374

Hardness (Shore A) 92 92 ASTM D2240

Elongation (%45° to Warp and Fill) 20 20 ASTM D412

Tensile Strength (psi) / (MPa) 1300 9 ASTM D412

Continuous Use Temp (°F) / (°C) -76 to 356 -60 to 180 —

ELECTRICAL

Dielectric Breakdown Voltage (Vac) 5500 5500 ASTM D149

Type 3 Electrodes 8300 8300 ASTM D149

Dielectric Constant (1000 Hz) 6.0 6.0 ASTM D150

Volume Resistivity (Ohm-meter) 1010 1010 ASTM D257

Flame Rating V-O V- O U.L. 94

THERMAL

Thermal Conductivity (W/m-K) 1.6 1.6 ASTM D5470

THERMAL PERFORMANCE vs PRESSURE

Pressure (psi) 10 25 50 100 200

TO-220 Thermal Performance (°C/W) 3.96 3.41 2.90 2.53 2.32

Thermal Impedance (°C-in2/W) (1) 0.95 0.75 0.61 0.47 0.41

1) The ASTM D5470 test fixture was used.The recorded value includes interfacial thermal resistance.These values are provided for

reference only. Actual application performance is directly related to the surface roughness, flatness and pressure applied.

SPDG_Chapter2_10.06.qxp 10/20/2006 11:26 AM Page 54

Sil-Pad

980

Features and Benefits

• Thermal impedance:

1.07°C-in2/W (@50 psi)

• Excellent cut-through resistance

• Use in screw-mounted applications with

cut-through problems

In addition to excellent heat transfer and

dielectric properties, Sil-Pad 980 is specially

formulated for high resistance to crushing and

cut-through typically found in high-pressure

applications where surface imperfections such

as burrs and dents are inherently common

(e.g. heavily-machined metal surfaces

manufactured from extrusions or castings).

With a field-proven history of reliability,

Sil-Pad 980 is Bergquist's best material for

cut-through resistance in screw-mounted and

other applications with cut-through problems.

High Cut-Through Resistant, Electrically Insulating,Thermally Conductive Material

SIL-PAD

Typical Applications Include:

• Silicone-sensitive assemblies

• Telecommunications

• Automotive electronics

Configurations Available:

• Sheet form, die-cut parts and roll form

• With or without pressure sensitive adhesive

Building a Part Number Standard Options

Sil-Pad®: U.S. Patents 4,574,879; 4,602,125; 4,602,678; 4,685,987; 4,842,911 and others

Section A

Section B

Section C

Section D

Section E

NA = Selected standard option. If not selecting a standard

option, insert company name, drawing number, and

revision level.

SP980 = Sil-Pad 980 Material

SP980 0.009 AC 00 ACME 951753 Rev B

Note: To build a part number, visit our website at www.bergquistcompany.com.

Standard thicknesses available: 0.009"

AC = Adhesive, one side

00 = No adhesive

_ _ _ = Standard configuration dash number,

1212 = 12" x 12" sheets, 12/250 = 12" x 250' rolls, or

00 = custom configuration

––––

TYPICAL PROPERTIES OF SIL-PAD 980

PROPERTY IMPERIAL VALUE METRIC VALUE TEST METHOD

Color Mauve Mauve Visual

Reinforcement Carrier Fiberglass Fiberglass —

Thickness (inch) / (mm) 0.009 0.229 ASTM D374

Hardness (Shore A) 95 95 ASTM D2240

Breaking Strength (lbs/inch) / (kN/m) 140 26 ASTM D1458

Elongation (%45° to Warp and Fill) 10 10 ASTM D412

Cut-Through (lbs) / (kg) 750 340 ASTM D412

Continuous Use Temp (°F) / (°C) -40 to 302 -40 to 150 —

ELECTRICAL

Dielectric Breakdown Voltage (Vac) 4000 4000 ASTM D149

Dielectric Constant (1000 Hz) 6.0 6.0 ASTM D150

Volume Resistivity (Ohm-meter) 1010 1010 ASTM D257

THERMAL

Thermal Conductivity (W/m-K) 1.2 1.2 ASTM D5470

THERMAL PERFORMANCE vs PRESSURE

Pressure (psi) 10 25 50 100 200

TO-220 Thermal Performance (°C/W) 5.48 5.07 4.52 4.04 3.56

Thermal Impedance (°C-in2/W) (1) 1.51 1.22 1.07 0.89 0.53

1) The ASTM D5470 test fixture was used.The recorded value includes interfacial thermal resistance.These values are provided for

reference only. Actual application performance is directly related to the surface roughness, flatness and pressure applied.

SPDG_Chapter2_10.06.qxp 10/20/2006 11:26 AM Page 55

SIL-PAD

Sil-Pad

1100ST

Affordable, Electrically Insulating,Thermally Conductive, Soft Tack Elastomeric Material

Features and Benefits

• Inherent tack on both sides for exceptional

thermal performance and easy placement

• Re-positionable for higher utilization, ease of

use and assembly error reduction

• Lined on both sides for ease of handling

prior to placement in high volume

assemblies

• Exhibits exceptional thermal performance

even at a low mounting pressure

• Fiberglass reinforced

• Valve alternative to Sil-Pad 1500ST

Sil-Pad 1100ST (Soft Tack) is a fiberglass-

reinforced thermal interface material featuring

inherent tack on both sides.The material

exhibits excellent thermal performance at

low mounting pressures.The material is sup-

plied on two liners for exceptionally easy

handling prior to auto-placement in high-vol-

ume assemblies.The material is ideal for

placement between an electronic power

device and its heat sink.

Typical Applications Include:

• Automotive ECMs • Motor controls

• Power supplies • Between an electronic power device and its heat sink

Configurations Available:

• Sheet form, die-cut parts and roll form

• Top and bottom liners

Building a Part Number Standard Options

Sil-Pad®: U.S. Patents 4,574,879; 4,602,125; 4,602,678; 4,685,987; 4,842,911 and others

TYPICAL PROPERTIES OF SIL-PAD 1100ST

PROPERTY IMPERIAL VALUE METRIC VALUE TEST METHOD

Color Yellow Yellow Visual

Reinforcement Carrier Fiberglass Fiberglass —

Thickness (inch) / (mm) 0.012 0.305 ASTM D374

Inherent Surface Tack (1or 2 sided) 2 2 —

Hardness (Shore 00) (1) 85 85 ASTM D2240

Breaking Strength (lb/inch) / (kN/m) 2.6 0.5 ASTM D1458

Elongation (% - 45º to Warp and Fill) 16 16 ASTM D412

Tensile Strength (psi) / (MPa) 220 1.5 ASTM D412

Continuous Use Temp (°F) / (°C) -76 to 356 -60 to 180 —

ELECTRICAL

Dielectric Breakdown Voltage (Vac) 5000 5000 ASTM D149

Dielectric Constant (1000 Hz) 5.0 5.0 ASTM D150

Volume Resistivity (Ohm-meter) 1010 1010 ASTM D257

Flame Rating V-O V-O U.L. 94

THERMAL

Thermal Conductivity (W/m-K) 1.1 1.1 ASTM D5470

THERMAL PERFORMANCE VS. PRESSURE

Pressure (psi) 10 25 50 100 200

TO-220 Thermal Performance (ºC/W) 2.72 2.71 2.68 2.62 2.23

Thermal Impedance (ºC-in2/W) (2) 0.75 0.71 0.66 0.61 0.57

1) Thirty second delay value Shore 00 hardness scale.

2) The ASTM D5470 test fixture was used.The recorded value includes interfacial thermal resistance.These values are provided for

reference only. Actual application performance is directly related to the surface roughness, flatness and pressure applied.

SPDG_Chapter2_10.06.qxp 10/20/2006 11:26 AM Page 56

Sil-Pad

A1500

Electrically Insulating,Thermally Conductive Elastomeric Material

Features and Benefits

• Thermal impedance:

0.42°C-in2/W (@50 psi)

• Elastomeric compound coated on

both sides

Bergquist Sil-Pad A1500 is a silicone-based,

thermally conductive and electrically insulating

material. It consists of a cured silicone

elastomeric compound coated on both sides

of a fiberglass reinforcement layer.

Sil-Pad A1500 performs well under clamping

pressure up to 200 psi and is an excellent

choice for high performance applications

requiring electrical isolation and cut-through

resistance.

Typical Applications Include:

• Power supplies

• Automotive electronics

• Motor controls

• Power semiconductors

Configurations Available:

• Sheet form, die-cut parts, and roll form

• With or without pressure sensitive adhesive

Building a Part Number Standard Options

Sil-Pad®: U.S. Patents 4,574,879; 4,602,125; 4,602,678; 4,685,987; 4,842,911 and others

Section A

Section B

Section C

Section D

Section E

NA = Selected standard option. If not selecting a standard

option, insert company name, drawing number, and

revision level.

SPA1500 = Sil-Pad A1500 Material

SPA1500 0.010 AC 12/250 NA

Note: To build a part number, visit our website at www.bergquistcompany.com.

Standard thicknesses available: 0.010"

AC = Adhesive, one side

00 = No adhesive

_ _ _ = Standard configuration dash number,

1212 = 12" x 12" sheets, 12/250 = 12" x 250' rolls, or

00 = custom configuration

––––

TYPICAL PROPERTIES OF SIL-PAD A1500

PROPERTY IMPERIAL VALUE METRIC VALUE TEST METHOD

Color Green Green Visual

Reinforcement Carrier Fiberglass Fiberglass —

Thickness (inch) / (mm) 0.010 0.254 ASTM D374

Hardness (Shore A) 80 80 ASTM D2240

Breaking Strength (lbs/inch) / (kN/m) 65 12 ASTM D1458

Elongation (% - 45° to Warp and Fill) 40 40 ASTM D412

Continuous Use Temp (°F) / (°C) -76 to 356 -60 to 180 —

ELECTRICAL

Dielectric Breakdown Voltage (Vac) 6000 6000 ASTM D149

Dielectric Constant (1000 Hz) 7.0 7.0 ASTM D150

Volume Resistivity (Ohm-meter) 1011 1011 ASTM D257

Flame Rating V-O V- O U.L. 94

THERMAL

Thermal Conductivity (W/m-K) 2.0 2.0 ASTM D5470

THERMAL PERFORMANCE vs PRESSURE

Pressure (psi) 10 25 50 100 200

TO-220 Thermal Performance (°C/W) 3.03 2.62 2.21 1.92 1.78

Thermal Impedance (°C-in2/W) (1) 0.59 0.50 0.42 0.34 0.31

1) The ASTM D5470 test fixture was used.The recorded value includes interfacial thermal resistance.These

values are provided for reference only. Actual application performance is directly related to the surface roughness, flatness and

pressure applied.

SIL-PAD

SPDG_Chapter2_10.06.qxp 10/20/2006 11:26 AM Page 57

Sil-Pad

1500ST

Features and Benefits

• Thermal impedance:

0.23°C-in2/W (@50 psi)

• Naturally tacky on both sides

• Pad is repositionable

• Excellent thermal performance

• Auto-placement and dispensable

Bergquist Sil-Pad 1500ST (Soft Tack) is a fiber-

glass reinforced thermal interface material

that is naturally tacky on both sides.

Sil-Pad 1500ST exhibits superior thermal

performance when compared to the

competitors’ thermal interface materials.

Sil-Pad 1500ST is supplied in sheet or roll

form for exceptional auto-dispensing and

auto-placement in high volume assemblies.

Sil-Pad 1500ST is intended for placement

between an electronic power device and its

heat sink.

Electrically Insulating,Thermally Conductive, Soft Tack Elastomeric Material

Typical Applications Include:

• Power supplies

• Automotive electronics

• Motor controls

Configurations Available:

• Sheet form, die-cut parts and slit-to-width roll form

• Also available in 12 mil thickness

Building a Part Number Standard Options

Sil-Pad®: U.S. Patents 4,574,879; 4,602,125; 4,602,678; 4,685,987; 4,842,911 and others

Section A

Section B

Section C

Section D

Section E

NA = Selected standard option. If not selecting a standard

option, insert company name, drawing number, and

revision level.

SP1500ST = Sil-Pad 1500ST Material

SP1500ST 0.008 02 1012 NA

Note: To build a part number, visit our website at www.bergquistcompany.com.

Standard thicknesses available: 0.008", 0.012"

02 = Natural tack, both sides

_ _ _ = Standard configuration dash number,

1012 = 10" x 12" sheets, 10/250 = 10" x 250' rolls (8 mil

only), or 00 = custom configuration

––––

TYPICAL PROPERTIES OF SIL-PAD 1500ST

PROPERTY IMPERIAL VALUE METRIC VALUE TEST METHOD

Color Blue Blue Visual

Reinforcement Carrier Fiberglass Fiberglass —

Thickness (inch) / (mm) 0.008 0.203 ASTM D374

Hardness (Shore 00) 75 75 ASTM D2240

Breaking Strength (lbs/inch) / (kN/m) 1.9 0.34 ASTM D1458

Elongation (% - 45° to Warp and Fill) 22 22 ASTM D412

Tensile Strength (psi) / (MPa) 238 1.6 ASTM D412

Continuous Use Temp (°F) / (°C) -76 to 356 -60 to 180 —

ELECTRICAL

Dielectric Breakdown Voltage (Vac) 3000 3000 ASTM D149

Dielectric Constant (1000 Hz) 6.1 6.1 ASTM D150

Volume Resistivity (Ohm-meter) 1011 1011 ASTM D257

Flame Rating V-O V- O U.L. 94

THERMAL

Thermal Conductivity (W/m-K) 1. 8 1.8 ASTM D5470

THERMAL PERFORMANCE vs PRESSURE

Pressure (psi) 10 25 50 100 200

TO-220 Thermal Performance (°C/W) 1.54 1.52 1.51 1.49 1.46

Thermal Impedance (°C-in2/W) (1) 0.37 0.28 0.23 0.21 0.20

1) The ASTM D5470 test fixture was used.The recorded value includes interfacial thermal resistance.These values are provided for

reference only. Actual application performance is directly related to the surface roughness, flatness and pressure applied.

SIL-PAD

SPDG_Chapter2_10.06.qxp 10/20/2006 11:26 AM Page 58

SIL-PAD

Features and Benefits

• Thermal impedance:

0.53°C-in2/W (@50 psi)

• Excellent dielectric strength retention after

humidity exposure

• Elastomeric pad

The combination of high thermal conductivity

and excellent dielectric strength retention

after humidity exposure is formulated into

the Sil-Pad 1750 elastomeric pad.

Sil-Pad 1750 relies on processes that minimize

the effect of high humidity on the electrical

properties of finished material.Therefore,

exposure to humid environments during

assembly, or over long-term operating

conditions, will not severely affect the ability

of the material to perform.

Sil-Pad

1750

Typical Applications Include:

• High-voltage power supplies

• Motor controls

• High “hi-pot” requirements

Configurations Available:

• Sheet form and die-cut parts

• With or without pressure sensitive adhesive

Building a Part Number Standard Options

Sil-Pad®: U.S. Patents 4,574,879; 4,602,125; 4,602,678; 4,685,987; 4,842,911 and others

For High Humidity, High Dielectric (U.L. 94 1950, IEC 950) Requirements

TYPICAL PROPERTIES OF SIL-PAD 1750

PROPERTY IMPERIAL VALUE METRIC VALUE TEST METHOD

Color Green Green Visual

Reinforcement Carrier Fiberglass Fiberglass —

Thickness (inch) / (mm) 0.012 0.305 ASTM D374

Hardness (Shore A) 85 85 ASTM D2240

Breaking Strength (lbs/inch) / (kN/m) 65 12 ASTM D1458

Elongation (% - 45° to Warp and Fill) 23 23 ASTM D412

Tensile Strength (psi) / (MPa) 1500 10 ASTM D412

Continuous Use Temp (°F) / (°C) -76 to 356 -60 to 180 —

ELECTRICAL

Dielectric Breakdown Voltage (Vac) 6000 6000 ASTM D149

Dielectric Constant (1000 Hz) 4.0 4.0 ASTM D150

Volume Resistivity (Ohm-meter) 1012 1012 ASTM D257

Flame Rating V-O V- O U.L. 94

THERMAL

Thermal Conductivity (W/m-K) 2.2 2.2 ASTM D5470

THERMAL PERFORMANCE vs PRESSURE

Pressure (psi) 10 25 50 100 200

TO-220 Thermal Performance (°C/W) 3.11 2.87 2.42 2.08 1.90

Thermal Impedance (°C-in2/W) (1) 0.86 0.68 0.53 0.39 0.28

1) The ASTM D5470 test fixture was used.The recorded value includes interfacial thermal resistance.These values are provided for

reference only. Actual application performance is directly related to the surface roughness, flatness and pressure applied.

Section A

Section B

Section C

Section D

Section E

NA = Selected standard option. If not selecting a standard

option, insert company name, drawing number, and

revision level.

SP1750 = Sil-Pad 1750 Material

SP1750 0.012 AC 1212 NA

Note: To build a part number, visit our website at www.bergquistcompany.com.

Standard thicknesses available: 0.012"

AC = Adhesive, one side

00 = No adhesive

_ _ _ = Standard configuration dash number,

1212 = 12" x 12" sheets, or 00 = custom configuration

––––

SPDG_Chapter2_10.06.qxp 10/20/2006 11:26 AM Page 59

Sil-Pad

2000

Higher Performance, High Reliability Insulator

Features and Benefits

• Thermal impedance:

0.33°C-in2/W (@50 psi)

• Optimal heat transfer

• High thermal conductivity: 3.5 W/m-K

Sil-Pad 2000 is a high performance, thermally

conductive insulator designed for demanding

military /aerospace and commercial applica-

tions. In these applications, Sil-Pad 2000

complies with military standards.

Sil-Pad 2000 is a silicone elastomer formulated

to maximize the thermal and dielectric

performance of the filler/binder matrix.The

result is a grease-free, conformable material

capable of meeting or exceeding the thermal

and electrical requirements of high-reliability

electronic packaging applications.

Outgassing Data for

Spacecraft Materials

Post Cure

Conditions

% TML

(1.0% Max.

Acceptable)

%CVCM

(0.1% Max.

Acceptable)

24 hrs. @ 175°C

No Post Cure

0.07

0.26

0.03

0.10

TYPICAL PROPERTIES OF SIL-PAD 2000

PROPERTY IMPERIAL VALUE METRIC VALUE TEST METHOD

Color White White Visual

Reinforcement Carrier Fiberglass Fiberglass —

Thickness (inch) / (mm) 0.010 to 0.015 0.254 to 0.381 ASTM D374

Hardness (Shore A) 90 90 ASTM D2240

Continuous Use Temp (°F) / (°C) -76 to 392 -60 to 200 —

ELECTRICAL

Dielectric Breakdown Voltage (Vac) 4000 4000 ASTM D149

Dielectric Constant (1000 Hz) 4.0 4.0 ASTM D150

Volume Resistivity (Ohm-meter) 1011 1011 ASTM D257

Flame Rating V-O V- O U.L.94

THERMAL

Thermal Conductivity (W/m-K) 3.5 3.5 ASTM D5470

THERMAL PERFORMANCE vs PRESSURE

Pressure (psi) 10 25 50 100 200

TO-220 Thermal Performance (°C/W) 2.61 2.32 2.02 1.65 1.37

Thermal Impedance (°C-in2/W) (1) 0.57 0.43 0.33 0.25 0.20

1) The ASTM D5470 test fixture was used. The recorded value includes interfacial thermal resistance. These

values are provided for reference only. Actual application performance is directly related to the surface roughness, flatness and

pressure applied.

Typical Applications Include:

• Power supplies • Motor controls

• Power semiconductors • U.L. File Number E59150

• CAGE Number 55285 • Military Electronics

• Aerospace • Avionics

Configurations Available:

• Sheet form, die-cut parts and roll form

• With or without pressure sensitive adhesive

Building a Part Number Standard Options

Sil-Pad®: U.S. Patents 4,574,879; 4,602,125; 4,602,678; 4,685,987; 4,842,911 and others

Section A

Section B

Section C

Section D

Section E

NA = Selected standard option. If not selecting a standard

option, insert company name, drawing number, and

revision level.

SP2000 = Sil-Pad 2000 Material

SP2000 0.010 AC 00 NA

Note: To build a part number, visit our website at www.bergquistcompany.com.

Standard thicknesses available: 0.010", 0.015"

AC = Adhesive, one side

00 = No adhesive

_ _ _ = Standard configuration dash number,

1212 = 12" x 12" sheets, or 00 = custom configuration

––––

SIL-PAD

SPDG_Chapter3_10.06.qxp 10/20/2006 4:43 PM Page 59

Features and Benefits

• Thermal impedance:

0.32°C-in2/W (@50 psi)

• Optimal heat transfer

• High thermal conductivity: 3.0 W/m-K

Sil-Pad A2000 is a conformable elastomer

with very high thermal conductivity that acts

as a thermal interface between electrical

components and heat sinks. Sil-Pad A2000 is

for applications where optimal heat transfer is

a requirement.

This thermally conductive silicone elastomer is

formulated to maximize the thermal and

dielectric performance of the filler/binder

matrix.The result is a grease-free, conforma-

ble material capable of meeting or exceeding

the thermal and electrical requirements of high

reliability electronic packaging applications.

Sil-Pad

A2000

Higher Performance, High Reliability Insulator

Typical Applications Include:

• Motor drive controls

• Avionics

• High-voltage power supplies

• Power transistor / heat sink interface

Configurations Available:

• Sheet form, die-cut parts and roll form

• With or without pressure sensitive adhesive

Building a Part Number Standard Options

Sil-Pad®: U.S. Patents 4,574,879; 4,602,125; 4,602,678; 4,685,987; 4,842,911 and others

Section A

Section B

Section C

Section D

Section E

NA = Selected standard option. If not selecting a standard

option, insert company name, drawing number, and

revision level.

SPA2000 = Sil-Pad A2000 Material

SPA2000 0.015 00 1012 NA

Note: To build a part number, visit our website at www.bergquistcompany.com.

Standard thicknesses available: 0.015", 0.020"

AC = Adhesive, one side

00 = No adhesive

_ _ _ = Standard configuration dash number,

1012 = 10" x 12" sheets, 10/250 = 10" x 250' rolls, or

00 = custom configuration

––––

TYPICAL PROPERTIES OF SIL-PAD A2000

PROPERTY IMPERIAL VALUE METRIC VALUE TEST METHOD

Color White White Visual

Reinforcement Carrier Fiberglass Fiberglass —

Thickness (inch) / (mm) 0.015 to 0.020 0.381 to 0.508 ASTM D374

Hardness (Shore A) 90 90 ASTM D2240

Heat Capacity (J/g-K) 1.0 1.0 ASTM E1269

Continuous Use Temp (°F) / (°C) -76 to 392 -60 to 200 —

ELECTRICAL

Dielectric Breakdown Voltage (Vac) 4000 4000 ASTM D149

Dielectric Constant (1000 Hz) 7.0 7.0 ASTM D150

Volume Resistivity (Ohm-meter) 1011 1011 ASTM D257

Flame Rating V-O V- O U.L.94

THERMAL

Thermal Conductivity (W/m-K) 3.0 3.0 ASTM D5470

THERMAL PERFORMANCE vs PRESSURE

Pressure (psi) 10 25 50 100 200

TO-220 Thermal Performance (°C/W) 0.015" 2.05 1.94 1.86 1.79 1.72

Thermal Impedance (°C-in2/W) 0.015" (1) 0.53 0.40 0.32 0.28 0.26

1) The ASTM D5470 test fixture was used.The recorded value includes interfacial thermal resistance.These values are provided for

reference only. Actual application performance is directly related to the surface roughness, flatness and pressure applied.

SIL-PAD

SPDG_Chapter3_10.06.qxp 10/23/2006 10:26 AM Page 60

SIL-PAD

Sil-Pad

K-4

The Original Kapton

-Based Insulator

Features and Benefits

• Thermal impedance:

0.48°C-in2/W (@50 psi)

• Withstands high voltages

• High dielectric strength

• Very durable

Sil-Pad K-4 uses a specially developed film

which has high thermal conductivity, high

dielectric strength and is very durable. Sil-Pad

K-4 combines the thermal transfer properties

of well-known Sil-Pad rubber with the physical

properties of a film.

Sil-Pad K-4 is a durable insulator that with-

stands high voltages and requires no thermal

grease to transfer heat. Sil-Pad K-4 is available

in customized shapes and sizes.

Typical Applications Include:

• Power supplies • Motor controls

• Power semiconductors • CAGE Number 55285

Configurations Available:

• Sheet form, die-cut parts and roll form

• With or without pressure sensitive adhesive

Building a Part Number Standard Options

Sil-Pad®: U.S. Patents 4,574,879; 4,602,125; 4,602,678; 4,685,987; 4,842,911 and others.

Kapton®is a registered trademark of DuPont.

Section A

Section B

Section C

Section D

Section E

NA = Selected standard option. If not selecting a standard

option, insert company name, drawing number, and

revision level.

SPK4 = Sil-Pad K4 Material

SPK4 0.006 00 12/250 NA

Note: To build a part number, visit our website at www.bergquistcompany.com.

Standard thicknesses available: 0.006"

AC = Adhesive, one side

00 = No adhesive

_ _ _ = Standard configuration dash number,

1212 = 12" x 12" sheets, 12/250 = 12" x 250' rolls, or

00 = custom configuration

––––

TYPICAL PROPERTIES OF SIL-PAD K-4

PROPERTY IMPERIAL VALUE METRIC VALUE TEST METHOD

Color Gray Gray Visual

Reinforcement Carrier Kapton Kapton —

Thickness (inch) / (mm) 0.006 0.152 ASTM D374

Hardness (Shore A) 90 90 ASTM D2240

Breaking Strength (lbs/inch) / (kN/m) 30 5 ASTM D1458

Elongation (%) 40 40 ASTM D412

Tensile Strength (psi) / (MPa) 5000 34 ASTM D412

Continuous Use Temp (°F) / (°C) -76 to 356 -60 to 180 —

ELECTRICAL

Dielectric Breakdown Voltage (Vac) 6000 6000 ASTM D149

Dielectric Constant (1000 Hz) 5.0 5.0 ASTM D150

Volume Resistivity (Ohm-meter) 1012 1012 ASTM D257

Flame Rating VTM-O VTM-O U.L.94

THERMAL

Thermal Conductivity (W/m-K) 0.9 0.9 ASTM D5470

THERMAL PERFORMANCE vs PRESSURE

Pressure (psi) 10 25 50 100 200

TO-220 Thermal Performance (°C/W) 3.66 3.43 3.13 2.74 2.42

Thermal Impedance (°C-in2/W) (1) 1.07 0.68 0.48 0.42 0.38

1) The ASTM D5470 test fixture was used.The recorded value includes interfacial thermal resistance.These values are provided for

reference only. Actual application performance is directly related to the surface roughness, flatness and pressure applied.

SPDG_Chapter3_10.06.qxp 10/20/2006 1:38 PM Page 61

SIL-PAD

Features and Benefits

• Thermal impedance:

0.49°C-in2/W (@50 psi)

• Physically strong dielectric barrier against

cut-through

• Medium performance film

Sil-Pad K-6 is a medium performance, film-

based thermally conductive insulator.The film

is coated with a silicone elastomer to deliver

high performance and provide a continuous,

physically strong dielectric barrier against

“cut-through” and resultant assembly failures.

Sil-Pad

K-6

The Medium Performance Kapton

-Based Insulator

Typical Applications Include:

• Power supplies • Motor controls

• Power semiconductors • CAGE Number 55285

Configurations Available:

• Sheet form, die-cut parts and roll form

• With or without pressure sensitive adhesive

Building a Part Number Standard Options

Sil-Pad®: U.S. Patents 4,574,879; 4,602,125; 4,602,678; 4,685,987; 4,842,911 and others

Kapton®is a registered trademark of DuPont.

Section A

Section B

Section C

Section D

Section E

NA = Selected standard option. If not selecting a standard

option, insert company name, drawing number, and

revision level.

SPK6 = Sil-Pad K6 Material

SPK6 0.006 AC 12/250 NA

Note: To build a part number, visit our website at www.bergquistcompany.com.

Standard thicknesses available: 0.006"

AC = Adhesive, one side

00 = No adhesive

_ _ _ = Standard configuration dash number,

1212 = 12" x 12" sheets, 12/250 = 12" x 250' rolls, or

00 = custom configuration

––––

TYPICAL PROPERTIES OF SIL-PAD K-6

PROPERTY IMPERIAL VALUE METRIC VALUE TEST METHOD

Color Bluegreen Bluegreen Visual

Reinforcement Carrier Kapton Kapton —

Thickness (inch) / (mm) 0.006 0.152 ASTM D374

Hardness (Shore A) 90 90 ASTM D2240

Breaking Strength (lbs/inch) / (kN/m) 30 5 ASTM D1458

Elongation (%) 40 40 ASTM D412

Tensile Strength (psi) / (MPa) 5000 34 ASTM D412

Continuous Use Temp (°F) / (°C) -76 to 356 -60 to 180 —

ELECTRICAL

Dielectric Breakdown Voltage (Vac) 6000 6000 ASTM D149

Dielectric Constant (1000 Hz) 4.0 4.0 ASTM D150

Volume Resistivity (Ohm-meter) 1012 1012 ASTM D257

Flame Rating VTM-O VTM-O U.L.94

THERMAL

Thermal Conductivity (W/m-K) 1.1 1.1 ASTM D5470

THERMAL PERFORMANCE vs PRESSURE

Pressure (psi) 10 25 50 100 200

TO-220 Thermal Performance (°C/W) 3.24 3.03 2.76 2.45 2.24

Thermal Impedance (°C-in2/W) (1) 0.82 0.62 0.49 0.41 0.36

1) The ASTM D5470 test fixture was used.The recorded value includes interfacial thermal resistance.These values are provided for

reference only. Actual application performance is directly related to the surface roughness, flatness and pressure applied.

SPDG_Chapter3_10.06.qxp 10/20/2006 1:38 PM Page 62

SIL-PAD

Sil-Pad

K-10

The High Performance Kapton

-Based Insulator

Features and Benefits

• Thermal impedance:

0.41°C-in2/W (@50 psi)

• Tough dielectric barrier against cut-through

• High performance film

• Designed to replace ceramic insulators

Sil-Pad K-10 is a high performance insulator. It

combines special film with a filled silicone rubber.

The result is a product with good cut-through

properties and excellent thermal performance.

Sil-Pad K-10 is designed to replace ceramic

insulators such as Beryllium Oxide, Boron

Nitride and Alumina. Ceramic insulators are

expensive and they break easily. Sil-Pad K-10

eliminates breakage and costs much less

than ceramics.

Typical Applications Include:

• Power supplies • Motor controls

• Power semiconductors • CAGE Number 55285

Configurations Available:

• Sheet form, die-cut parts and roll form

• With or without pressure sensitive adhesive

Building a Part Number Standard Options

Sil-Pad®: U.S. Patents 4,574,879; 4,602,125; 4,602,678; 4,685,987; 4,842,911 and others.

Kapton®is a registered trademark of DuPont.

Section A

Section B

Section C

Section D

Section E

NA = Selected standard option. If not selecting a standard

option, insert company name, drawing number, and

revision level.

SPK10 = Sil-Pad K10 Material

SPK10 0.006 AC 1212 NA

Note: To build a part number, visit our website at www.bergquistcompany.com.

Standard thicknesses available: 0.006"

AC = Adhesive, one side

00 = No adhesive

_ _ _ = Standard configuration dash number,

1212 = 12" x 12" sheets, 12/250 = 12" x 250' rolls, or

00 = custom configuration

––––

TYPICAL PROPERTIES OF SIL-PAD K-10

PROPERTY IMPERIAL VALUE METRIC VALUE TEST METHOD

Color Beige Beige Visual

Reinforcement Carrier Kapton Kapton —

Thickness (inch) / (mm) 0.006 0.152 ASTM D374

Hardness (Shore A) 90 90 ASTM D2240

Breaking Strength (lbs/inch) / (kN/m) 30 5 ASTM D1458

Elongation (%) 40 40 ASTM D412

Tensile Strength (psi) / (MPa) 5000 34 ASTM D412

Continuous Use Temp (°F) / (°C) -76 to 356 -60 to 180 —

ELECTRICAL

Dielectric Breakdown Voltage (Vac) 6000 6000 ASTM D149

Dielectric Constant (1000 Hz) 3.7 3.7 ASTM D150

Volume Resistivity (Ohm-meter) 1012 1012 ASTM D257

Flame Rating VTM-O VTM-O U.L.94

THERMAL

Thermal Conductivity (W/m-K) 1.3 1.3 ASTM D5470

THERMAL PERFORMANCE vs PRESSURE

Pressure (psi) 10 25 50 100 200

TO-220 Thermal Performance (°C/W) 2.35 2.19 2.01 1.87 1.76

Thermal Impedance (°C-in2/W) (1) 0.86 0.56 0.41 0.29 0.24

1) The ASTM D5470 test fixture was used.The recorded value includes interfacial thermal resistance.These values are provided for

reference only. Actual application performance is directly related to the surface roughness, flatness and pressure applied.

SPDG_Chapter3_10.06.qxp 10/20/2006 1:38 PM Page 63

SIL-PAD

Features and Benefits

• Thermal impedance:

0.22°C-in2/W (@50 psi)

• Maximum heat transfer

• Aluminum foil coated both sides

• Designed to replace thermal grease

Q-Pad II is a composite of aluminum foil coated

on both sides with thermally / electrically

conductive Sil-Pad rubber.The material is

designed for those applications in which maxi-

mum heat transfer is needed and electrical

isolation is not required. Q-Pad II is the ideal

thermal interface material to replace messy

thermal grease compounds.

Q-Pad II eliminates problems associated with

grease such as contamination of reflow solder

or cleaning operations. Unlike grease, Q-Pad II

can be used prior to these operations. Q-Pad II

also eliminates dust collection which can cause

possible surface shorting or heat buildup.

Q-Pad

Foil-Format Grease Replacement for Maximum Heat Transfer

Typical Applications Include:

• Between a transistor and a heat sink

• Between two large surfaces such as an L-bracket and the chassis of an assembly

• Between a heat sink and a chassis

• Under electrically isolated power modules or devices such as resistors,

transformers and solid state relays

Configurations Available:

• Sheet form, die-cut parts and roll form

• With or without pressure sensitive adhesive

Building a Part Number Standard Options

Sil-Pad®: U.S. Patents 4,574,879; 4,602,125; 4,602,678; 4,685,987; 4,842,911 and others

TYPICAL PROPERTIES OF Q-PAD II

PROPERTY IMPERIAL VALUE METRIC VALUE TEST METHOD

Color Black Black Visual

Reinforcement Carrier Aluminum Aluminum —

Thickness (inch) / (mm) 0.006 0.152 ASTM D374

Hardness (Shore A) 93 93 ASTM D2240

Continuous Use Temp (°F) / (°C) -76 to 356 -60 to 180 —

ELECTRICAL

Dielectric Breakdown Voltage (Vac) Non-Insulating Non-Insulating ASTM D149

Dielectric Constant (1000 Hz) NA NA ASTM D150

Volume Resistivity (Ohm-meter) 102102ASTM D257

Flame Rating V-O V- O U.L.94

THERMAL

Thermal Conductivity (W/m-K) 2.5 2.5 ASTM D5470

THERMAL PERFORMANCE vs PRESSURE

Pressure (psi) 10 25 50 100 200

TO-220 Thermal Performance (°C/W) 2.44 1.73 1.23 1.05 0.92

Thermal Impedance (°C-in2/W) (1) 0.52 0.30 0.22 0.15 0.12

1) The ASTM D5470 test fixture was used.The recorded value includes interfacial thermal resistance.These values are provided for

reference only. Actual application performance is directly related to the surface roughness, flatness and pressure applied.

SPDG_Chapter3_10.06.qxp 10/20/2006 1:38 PM Page 64

SIL-PAD

Q-Pad

Glass-Reinforced Grease Replacement Thermal Interface

Features and Benefits

• Thermal impedance:

0.35°C-in2/W (@50 psi)

• Eliminates processing constraints typically

associated with grease

• Conforms to surface textures

• Easy handling

• May be installed prior to soldering and

cleaning without worry

Bergquist Q-Pad 3 eliminates problems

associated with thermal grease such as con-

tamination of electronic assemblies and reflow

solder baths. Q-Pad 3 may be installed prior

to soldering and cleaning without worry.When

clamped between two surfaces, the elastomer

conforms to surface textures thereby creating

an air-free interface between heat-generating

components and heat sinks.

Fiberglass reinforcement enables Q-Pad 3 to

withstand processing stresses without losing

physical integrity. It also provides ease of

handling during application.

Typical Applications Include:

• Between a transistor and a heat sink

• Between two large surfaces such as an L-bracket and the chassis of an assembly

• Between a heat sink and a chassis

• Under electrically isolated power modules or devices such as resistors,

transformers and solid state relays

Configurations Available:

• Sheet form, die-cut parts and roll form

• With or without pressure sensitive adhesive

Building a Part Number Standard Options

Sil-Pad®: U.S. Patents 4,574,879; 4,602,125; 4,602,678; 4,685,987; 4,842,911 and others

Section A

Section B

Section C

Section D

Section E

NA = Selected standard option. If not selecting a standard

option, insert company name, drawing number, and

revision level.

Q3 = Q-Pad 3 Material

Q3 0.005 AC 12/250 NA

Note: To build a part number, visit our website at www.bergquistcompany.com.

Standard thicknesses available: 0.005"

AC = Adhesive, one side

00 = No adhesive

_ _ _ = Standard configuration dash number,

1212 = 12" x 12" sheets, 12/250 = 12" x 250' rolls, or

00 = custom configuration

––––

TYPICAL PROPERTIES OF Q-PAD 3

PROPERTY IMPERIAL VALUE METRIC VALUE TEST METHOD

Color Black Black Visual

Reinforcement Carrier Fiberglass Fiberglass —

Thickness (inch) / (mm) 0.005 0.127 ASTM D374

Hardness (Shore A) 86 86 ASTM D2240

Continuous Use Temp (°F) / (°C) -76 to 356 -60 to 180 —

ELECTRICAL

Dielectric Breakdown Voltage (Vac) Non-Insulating Non-Insulating ASTM D149

Dielectric Constant (1000 Hz) NA NA ASTM D150

Volume Resistivity (Ohm-meter) 102102ASTM D257

Flame Rating V-O V- O U.L.94

THERMAL

Thermal Conductivity (W/m-K) 2.0 2.0 ASTM D5470

THERMAL PERFORMANCE vs PRESSURE

Pressure (psi) 10 25 50 100 200

TO-220 Thermal Performance (°C/W) 2.26 1.99 1.76 1.53 1.30

Thermal Impedance (°C-in2/W) (1) 0.65 0.48 0.35 0.24 0.16

1) The ASTM D5470 test fixture was used.The recorded value includes interfacial thermal resistance.These values are provided for

reference only. Actual application performance is directly related to the surface roughness, flatness and pressure applied.

SPDG_Chapter3_10.06.qxp 10/20/2006 1:38 PM Page 65

SIL-PAD

Poly-Pad

400

Polyester-Based,Thermally Conductive Insulation Material

Features and Benefits

• Thermal impedance:

1.13°C-in2/W (@50 psi)

• Polyester based

• For applications requiring conformal

coatings

• Designed for silicone-sensitive standard

applications

Poly-Pad 400 is a fiberglass-reinforced

insulator coated with a filled polyester resin.

Poly-Pad 400 is economical and designed for

most standard applications.

Polyester-based, thermally conductive insulators

from Bergquist provide a complete family of

materials for silicone-sensitive applications.

Poly-Pads are ideally suited for applications

requiring conformal coatings or applications

where silicone contamination is a concern

(telecomm and certain aerospace applications).

Poly-Pads are constructed with ceramic-filled

polyester resins coating either side of a fiber-

glass carrier or a film carrier.The Poly-Pad

family offers a complete range of performance

characteristics to match individual applications.

Typical Applications Include:

• Power supplies

• Automotive electronics

• Motor controls

• Power semiconductors

Configurations Available:

• Sheet form, die-cut parts and roll form

• With or without pressure sensitive adhesive

• We produce thousands of specials.Tooling charges vary depending on tolerances and the

complexity of the part.

Building a Part Number Standard Options

Sil-Pad®: U.S. Patents 4,574,879; 4,602,125; 4,602,678; 4,685,987; 4,842,911 and others

Section A

Section B

Section C

Section D

Section E

NA = Selected standard option. If not selecting a standard

option, insert company name, drawing number, and

revision level.

PP400 = Poly-Pad 400 Material

PP400 0.009 00 1212 NA

Note: To build a part number, visit our website at www.bergquistcompany.com.

Standard thicknesses available: 0.009"

AC = Adhesive, one side

00 = No adhesive

_ _ _ = Standard configuration dash number,

1212 = 12" x 12" sheets, 12/250 = 12" x 250' rolls, or

00 = custom configuration

––––

TYPICAL PROPERTIES OF POLY-PAD 400

PROPERTY IMPERIAL VALUE METRIC VALUE TEST METHOD

Color Ta n Ta n Visual

Reinforcement Carrier Fiberglass Fiberglass —

Thickness (inch) / (mm) 0.009 0.229 ASTM D374

Hardness (Shore A) 90 90 ASTM D2240

Breaking Strength (lbs/inch)/(kN/m) 100 18 ASTM D1458

Elongation(% - 45° to Warp and Fill) 10 10 ASTM D412

Tensile Strength (psi) / (MPa) 7000 48 ASTM D412

Continuous Use Temp (°F) / (°C) -4 to 302 -20 to 150 —

ELECTRICAL

Dielectric Breakdown Voltage (Vac) 2500 2500 ASTM D149

Dielectric Constant (1000 Hz) 5.5 5.5 ASTM D150

Volume Resistivity (Ohm-meter) 1011 1011 ASTM D257

THERMAL

Thermal Conductivity (W/m-K) 0.9 0.9 ASTM D5470

Flame Rating V- O V- O U. L. 94

THERMAL PERFORMANCE vs PRESSURE

Pressure (psi) 10 25 50 100 200

TO-220 Thermal Performance (°C/W) 5.85 5.61 5.13 4.59 4.12

Thermal Impedance (°C-in2/W) (1) 1.62 1.35 1.13 086 0.61

1) The ASTM D5470 test fixture was used.The recorded value includes interfacial thermal resistance.These values are provided for

reference only. Actual application performance is directly related to the surface roughness, flatness and pressure applied.

SPDG_Chapter3_10.06.qxp 10/20/2006 1:38 PM Page 66

SIL-PAD

Poly-Pad

1000

Polyester-Based,Thermally Conductive Insulation Material

Features and Benefits

• Thermal impedance:

0.82°C-in2/W (@50 psi)

• Polyester based

• For applications requiring non-silicone

conformal coatings

• Designed for silicone-sensitive applications

requiring high performance

Poly-Pad 1000 is a fiberglass-reinforced

insulator coated with a filled polyester resin.

The material offers superior thermal resistance

for high performance applications.

Polyester-based, thermally conductive insulators

from Bergquist provide a complete family of

materials for silicone-sensitive applications.

Poly-Pads are ideally suited for applications

requiring conformal coatings or applications

where silicone contamination is a concern

(telecomm and certain aerospace applications).

Poly-Pads are constructed with ceramic-filled

polyester resins coating either side of a fiber-

glass carrier or a film carrier.The Poly-Pad

family offers a complete range of performance

characteristics to match individual applications.

Typical Applications Include:

• Power supplies

• Automotive electronics

• Motor controls

• Power semiconductors

Configurations Available:

• Sheet form, die-cut parts and roll form

• With or without pressure sensitive adhesive

Building a Part Number Standard Options

Sil-Pad®: U.S. Patents 4,574,879; 4,602,125; 4,602,678; 4,685,987; 4,842,911 and others

Section A

Section B

Section C

Section D

Section E

NA = Selected standard option. If not selecting a standard

option, insert company name, drawing number, and

revision level.

PP1000 = Poly-Pad 1000 Material

PP1000 0.009 00 1212 NA

Note: To build a part number, visit our website at www.bergquistcompany.com.

Standard thicknesses available: 0.009"

AC = Adhesive, one side

00 = No adhesive

_ _ _ = Standard configuration dash number,

1212 = 12" x 12" sheets, 12/250 = 12" x 250' rolls, or

00 = custom configuration

––––

TYPICAL PROPERTIES OF POLY-PAD 1000

PROPERTY IMPERIAL VALUE METRIC VALUE TEST METHOD

Color Yellow Yellow Visual

Reinforcement Carrier Fiberglass Fiberglass —

Thickness (inch) / (mm) 0.009 0.229 ASTM D374

Hardness (Shore A) 90 90 ASTM D2240

Breaking Strength (lbs/inch) / (kN/m) 100 18 ASTM D1458

Elongation (%) 10 10 ASTM D412

Tensile Strength (psi) / (MPa) 7000 48 ASTM D412

Continuous Use Temp (°F) / (°C) -4 to 302 -20 to 150 —

ELECTRICAL

Dielectric Breakdown Voltage (Vac) 2500 2500 ASTM D149

Dielectric Constant (1000 Hz) 4.5 4.5 ASTM D150

Volume Resistivity (Ohm-meter) 1011 1011 ASTM D257

THERMAL

Thermal Conductivity (W/m-K) 1.2 1.2 ASTM D5470

THERMAL PERFORMANCE vs PRESSURE

Pressure (psi) 10 25 50 100 200

TO-220 Thermal Performance (°C/W) 4.70 4.25 3.74 3.27 2.89

Thermal Impedance (°C-in2/W) (1) 1.30 1.02 0.82 0.61 0.43

1) The ASTM D5470 test fixture was used.The recorded value includes interfacial thermal resistance.These values are provided for

reference only. Actual application performance is directly related to the surface roughness, flatness and pressure applied.

SPDG_Chapter3_10.06.qxp 10/20/2006 1:38 PM Page 67

SIL-PAD

Features and Benefits

• Thermal impedance:

0.95°C-in2/W (@50 psi)

• Polyester based

• For applications requiring non-silicone

conformal coatings

• Designed for silicone-sensitive applications

• Excellent dielectric and physical strength

Poly-Pad K-4 is a composite of film coated with

a polyester resin.The material is an economical

insulator and the film carrier provides excellent

dielectric and physical strength.

Polyester-based, thermally conductive insulators

from Bergquist provide a complete family of

materials for silicone-sensitive applications.

Poly-Pads are ideally suited for applications

requiring conformal coatings or applications

where silicone contamination is a concern

(telecomm and certain aerospace applications).

Poly-Pads are constructed with ceramic-filled

polyester resins coating either side of a fiber-

glass carrier or a film carrier.The Poly-Pad

family offers a complete range of performance

characteristics to match individual applications.

Poly-Pad

K-4

Polyester-Based,Thermally Conductive Insulation Material

Typical Applications Include:

• Power supplies

• Motor controls

• Power semiconductors

Configurations Available:

• Sheet form, die-cut parts and roll form

• With or without pressure sensitive adhesive

Building a Part Number Standard Options

Sil-Pad®: U.S. Patents 4,574,879; 4,602,125; 4,602,678; 4,685,987; 4,842,911 and others

Kapton®is a registered trademark of DuPont.

Section A

Section B

Section C

Section D

Section E

NA = Selected standard option. If not selecting a standard

option, insert company name, drawing number, and

revision level.

PPK4 = Poly-Pad K-4 Material

PPK4 0.006 00 12/250 NA

Note: To build a part number, visit our website at www.bergquistcompany.com.

Standard thicknesses available: 0.006"

AC = Adhesive, one side

00 = No adhesive

_ _ _ = Standard configuration dash number,

1212 = 12" x 12" sheets, 12/250 = 12" x 250' rolls, or

00 = custom configuration

––––

TYPICAL PROPERTIES OF POLY-PAD K-4

PROPERTY IMPERIAL VALUE METRIC VALUE TEST METHOD

Color Ta n Ta n Visual

Reinforcement Carrier Kapton Kapton —

Thickness (inch) / (mm) 0.006 0.152 ASTM D374

Hardness (Shore A) 90 90 ASTM D2240

Breaking Strength (lbs/inch) / (kN/m) 30 5 ASTM D1458

Elongation (%) 40 40 ASTM D412

Tensile Strength (psi) / (MPa) 5000 34 ASTM D412

Continuous Use Temp (°F) / (°C) -4 to 302 -20 to 150 —

ELECTRICAL

Dielectric Breakdown Voltage (Vac) 6000 6000 ASTM D149

Dielectric Constant (1000 Hz) 5.0 5.0 ASTM D150

Volume Resistivity (Ohm-meter) 1012 1012 ASTM D257

Flame Rating V-O V- O U.L.94

THERMAL

Thermal Conductivity (W/m-K) 0.9 0.9 ASTM D5470

THERMAL PERFORMANCE vs PRESSURE

Pressure (psi) 10 25 50 100 200

TO-220 Thermal Performance (°C/W) 5.64 5.04 4.34 3.69 3.12

Thermal Impedance (°C-in2/W) (1) 1.55 1.21 0.95 0.70 0.46

1) The ASTM D5470 test fixture was used.The recorded value includes interfacial thermal resistance.These values are provided for

reference only. Actual application performance is directly related to the surface roughness, flatness and pressure applied.

SPDG_Chapter3_10.06.qxp 10/20/2006 1:38 PM Page 68

SIL-PAD

Poly-Pad

K-10

Polyester-Based,Thermally Conductive Insulation Material

Features and Benefits

• Thermal impedance:

0.60°C-in2/W (@50 psi)

• Polyester based

• For applications requiring non-silicone

conformal coatings

• Designed for silicone-sensitive applications

• Excellent dielectric strength and

thermal performance

Poly-Pad K-10 is a composite of film coated

with a polyester resin.The material offers

superior thermal performance for your most

critical applications with a thermal resistance

of 0.2°C-in2/W as well as excellent dielectric

strength.

Polyester-based, thermally conductive insulators

from Bergquist provide a complete family of

materials for silicone-sensitive applications.

Poly-Pads are ideally suited for applications

requiring conformal coatings or applications

where silicone contamination is a concern

(telecomm and certain aerospace applications).

Poly-Pads are constructed with ceramic-filled

polyester resins coating either side of a fiber-

glass carrier or a film carrier.The Poly-Pad

family offers a complete range of performance

characteristics to match individual applications.

Typical Applications Include:

• Power supplies

• Motor controls

• Power semiconductors

Configurations Available:

• Sheet form, die-cut parts and roll form

• With or without pressure sensitive adhesive

Building a Part Number Standard Options

Sil-Pad®: U.S. Patents 4,574,879; 4,602,125; 4,602,678; 4,685,987; 4,842,911 and others

Kapton®is a registered trademark of DuPont.

Section A

Section B

Section C

Section D

Section E

NA = Selected standard option. If not selecting a standard

option, insert company name, drawing number, a nd

revision level.

PPK10 = Poly-Pad K-10 Material

PPK10 0.006 AC 1212 NA

Note: To build a part number, visit our website at www.bergquistcompany.com.

Standard thicknesses available: 0.006"

AC = Adhesive, one side

00 = No adhesive

_ _ _ = Standard configuration dash numbe r,

1212 = 12" x 12" sheets, 12/250 = 12" x 250' rolls, or

00 = custom configuration

––––

TYPICAL PROPERTIES OF POLY-PAD K-10

PROPERTY IMPERIAL VALUE METRIC VALUE TEST METHOD

Color Yellow Yellow Visual

Reinforcement Carrier Kapton Kapton —

Thickness (inch) / (mm) 0.006 0.152 ASTM D374

Hardness (Shore A) 90 90 ASTM D2240

Breaking Strength (lbs/inch) / (kN/m) 30 5 ASTM D1458

Elongation (%) 40 40 ASTM D412

Tensile Strength (psi) / (MPa) 5000 34 ASTM D412

Continuous Use Temp (°F) / (°C) -4 to 302 -20 to 150 —

ELECTRICAL

Dielectric Breakdown Voltage (Vac) 6000 6000 ASTM D149

Dielectric Constant (1000 Hz) 3.7 3.7 ASTM D150

Volume Resistivity (Ohm-meter) 1012 1012 ASTM D257

Flame Rating V-O V- O U.L.94

THERMAL

Thermal Conductivity (W/m-K) 1.3 1.3 ASTM D5470

THERMAL PERFORMANCE vs PRESSURE

Pressure (psi) 10 25 50 100 200

TO-220 Thermal Performance (°C/W) 3.76 3.35 2.75 2.30 2.03

Thermal Impedance (°C-in2/W) (1) 1.04 0.80 0.60 0.43 0.30

1) The ASTM D5470 test fixture was used.The recorded value includes interfacial thermal resistance.These

values are provided for reference only. Actual application performance is directly related to the surface roughness, flatness and

pressure applied.

SPDG_Chapter3_10.06.qxp 10/20/2006 1:39 PM Page 69

SIL-PAD

Sil-Pad

Tubes

Features and Benefits

• Thermal conductivity:

SPT 400 – 0.9 W/m-K

SPT 1000 – 1.2 W/m-K

• For clip-mounted plastic power packages

SPT 400 and SPT 1000 (Sil-Pad Tubes) provide

thermally conductive insulation for clip-

mounted plastic power packages. Sil-Pad

Tubes are made of silicone rubber with high

thermal conductivity.

Sil-Pad Tube 1000 is best suited for higher

thermal performance. Sil-Pad Tube 400 is ideal

for applications requiring average thermal

conductivity and economy.

Sil-Pad Tube 400 and Sil-Pad Tube 1000 are

designed to meet VDE, U.L. and TUV agency

requirements.

Typical Applications

Include:

• Clip-mounted power semiconductors

• TO-220,TO-218,TO-247 and TO-3P

Configurations Available:

• TO-220,TO-218,TO-247 and TO-3P

Special thickness and diameters can also be

ordered. Please contact Bergquist Sales.

Silicone-Based,Thermally Conductive Tubes

Standard Dimensions

A = Wall Thickness: .30 mm (.012") + .10 mm/ -0.0 mm (+.004" / -0.0")

B = Inner Diameter: 11 mm (.433") or 13.5 mm (.532") ± 1.0 mm (± .039")

C = Length: 25 mm (.985") or 30 mm (1.18") +3.18 mm / -0.0 mm (+ .125" / - 0.0")

Special lengths are available. For more information, contact a Bergquist Sales Representative.

Ordering Procedure:

Sample: SPT 400 ___ - ___ - ___

“A” – “B” – “C”

Sil-Pad®: U.S. Patents 4,574,879; 4,602,125;

4,602,678; 4,685,987; 4,842,911 and others.

TYPICAL PROPERTIES OF SIL-PAD TUBE 400

PROPERTY IMPERIAL VALUE METRIC VALUE TEST METHOD

Color Gray/Green Gray/Green Visual

Thickness / Wall (inch) / (mm) 0.012 0.30 ASTM D374

Hardness (Shore A) 80 80 ASTM D2240

Breaking Strength (lbs/inch) / (kN/m) 6 1 ASTM D1458

Continuous Use Temp (°F) / (°C) -76 to 356 -60 to 180 —

ELECTRICAL

Dielectric Breakdown Voltage (Vac) 5000 5000 ASTM D149

Dielectric Constant (1000 Hz) 5.5 5.5 ASTM D150

Volume Resistivity (Ohm-meter) 1011 1011 ASTM D257

Flame Rating V-O V-O U.L.94

THERMAL

Thermal Conductivity (W/m-K) 0.9 0.9 ASTM D5470

Thermal Impedance (°C-in2/W) (1) 0.6 0.6 ASTM D5470

TYPICAL PROPERTIES OF SIL-PAD TUBE 1000

PROPERTY IMPERIAL VALUE METRIC VALUE TEST METHOD

Color Brown Brown Visual

Thickness / Wall (inch) / (mm) 0.012 0.30 ASTM D374

Hardness (Shore A) 80 80 ASTM D2240

Breaking Strength (lbs/inch) / (kN/m) 6 1 ASTM D1458

Continuous Use Temp (°F) / (°C) -76 to 356 -60 to 180 —

ELECTRICAL

Dielectric Breakdown Voltage (Vac) 5000 5000 ASTM D149

Dielectric Constant (1000 Hz) 4.5 4.5 ASTM D150

Volume Resistivity (Ohm-meter) 1011 1011 ASTM D257

Flame Rating V-O V-O U.L.94

THERMAL

Thermal Conductivity (W/m-K) 1.2 1.2 ASTM D5470

Thermal Impedance (°C-in2/W) (1) 0.4 0.4 ASTM D5470

1) The ASTM D5470 test fixture was used.The recorded value includes interfacial thermal resistance.These

values are provided for reference only. Actual application performance is directly related to the surface roughness, flatness and

pressure applied.

SPDG_Chapter3_10.06.qxp 10/20/2006 1:39 PM Page 70

Sil-Pad

Shield

SIL-PAD

Bonded Laminate of Sil-Pad with a Copper Shield

Features and Benefits

• Bonded laminate

• Electrically isolating

• Copper shield between layers of Sil-Pad

• Pre-tinned 60/40 solder point for easy

grounding

PROBLEM:

Radio Frequency Interference (RFI) is pro-

duced by heat sink current.The capacitance

between a TO-3 encapsulated transistor and

its heat sink is typically 100pf when a mica or

other insulating washer is used. A power

supply constructed with a standard insulator

and a grounded heat sink can be expected to

produce about 10 times more interference

than is permitted.

SOLUTION:

1.The use of chokes, filters and LC networks

which have to be designed into the circuitry.

2. Constructing a shield between the transistor

and its heat sink by replacing the mica insu-

lator with a Sil-Pad Shield (see illustration).

Typical Applications Include:

• Switch mode power supplies • EMI / RFI shield between PCB’s

Configurations Available:

Sil-Pad Shield is available in many custom configurations to meet special requirements.Tooling

charges vary depending on tolerances and complexity of the part.

Sil-Pad Shield is a laminate of copper with Sil-Pad thermally conductive insulators. Sil-Pad Shield

provides:

• Shielding effectiveness of 50dB or higher

• Good thermal transfer

• Reduced labor costs due to the elimination of having to apply thermal grease

Sil-Pad®: U.S. Patents 4,574,879; 4,602,125; 4,602,678; 4,685,987; 4,842,911 and others

TYPICAL PROPERTIES OF SIL-PAD SHIELD

PROPERTY VALUE TEST METHOD

Thickness / Total (inches) 0.019 ***

Shield / Copper Thickness (inches) 0.0015 ***

Approx.Thermal Resistance (TO-3) (°C/W) 0.85 - 1.0 ***

Min. Breakdown Voltage Between Device and Copper (Volts) 4500 ASTM D149

Capacitance @ 1000 Hz and 5 Volts (pF) 50 ***

Dissipation Factor @ 1000 Hz and 5 Volts (Power Factor) 0.0155 ASTM D150

Dielectric Constant @ 1000 Hz and 5 Volts 5.5 ASTM D150

Continuous Use Temp. (°C) -60 to 180 ***

Recommended Torque (TO-3) (inch-pounds) 6-8 ***

SPDG_Chapter3_10.06.qxp 10/20/2006 1:39 PM Page 71

Bond-Ply

and Liqui-Bond

Adhesives

Bond-Ply Adhesive Tapes

Available in a pressure sensitive adhesive or laminating format, the

Bond-Ply family of materials are thermally conductive and electrically

isolating. Bond-Ply facilitates the decoupling of bonded materials with

mismatched thermal coefficients of expansion.

Typical Bond-Ply Applications

Features

• High performance, thermally conductive, pressure sensitive adhesive

• Material immediately bonds to the target surface

• Bond strength increases over time when repeatedly exposed to

high continuous-use temperatures

Benefits

• Provide an excellent dielectric barrier

• Excellent wet-out to most types of component surfaces

including plastic

• Bond-Ply 400 is unreinforced to increase conformance and

wet-out on low surface energy materials

• Eliminates need for screws, clip mounts or fasteners

Options

• Supplied in sheet, die-cut, roll and tabulated forms

• Available in thickness range of 3 to 11 mil

• Custom coated thickness

Applications

• Attach a heat sink to a graphics processing unit

• Attach a heat spreader to a motor control PCB

• Attach a heat sink to a power converter PCB

• Attach a heat sink to a drive processor

Liqui-Bond Liquid Adhesives

Bergquist Liqui-Bond liquid adhesives are high performance, thermally

conductive, liquid gap filling materials.These soft, form-in-place elas-

tomers are ideal for coupling “hot” electronic components mounted

on PC boards with an adjacent metal case or heat sink.

Typical Liqui-Bond Applications

Features

• Excellent low and high temperature mechanical and chemical stability

Benefits

Before cure, Liqui-Bond flows under pressure like a grease. After

cure, it bonds the components, eliminating the need for mechanical

fasteners. Additional benefits include:

• Low modulus provides stress-absorbing flexibility

• Supplied as a one-part material with an elevated temperature

curing system

• Offers infinite thickness with little or no stress during displacement

• Eliminates need for specific pad thickness and die-cut shapes

for individual applications

Options

The growing Liqui-Bond family offers a variety of choices to meet the

customer’s performance, handling and process needs.

Applications

Liqui-Bond products are intended for use in thermal interface

applications where a structural bond is a requirement.This material

is formulated for high cohesive and adhesive strength and cures to

a low modulus.Typical applications include:

• Automotive electronics

• Telecommunications

• Computer and peripherals

• Between any heat-generating semiconductor and a heat sink

BOND-PLY

SPDG_Chapter3_10.06.qxp 10/20/2006 1:39 PM Page 72

Frequently Asked Questions

BOND-PLY

Q: What is the primary difference between the

Bond-Ply 660B and Bond-Ply 100 products?

A: Bond-Ply 660B utilizes a dielectric film, replacing the fiberglass

inherent in our Bond-Ply 100 series products.The addition of

the film allows for high dielectric performance without additional

product thickness.

Q: How should I size my interface dimensions for Bond-Ply?

A: Bond-Ply product testing has been completed on various interface

materials.These tests have demonstrated that improper surface

wet-out is the single largest variable associated with maximizing

bond strength and heat transfer. Bergquist has found that reducing

the size of the interface pad to roughly 80% of the total interface

area actually improves the overall bonding performance while

offering significant improvements in total package cooling.

Bergquist offers three standard thicknesses for Bond-Ply 100

allowing each application to be optimized in three dimensions.

Q: What application pressure is required to optimize

bond strength with Bond-Ply?

A: The answer to this varies from application to application, depend-

ing upon surface roughness and flatness. In general, pressure, tempera-

ture, and time are the primary variables associated with increas-

ing surface contact or wet-out. Increasing the application time

and/or pressure will significantly increase surface contact. Natural

wet-out will continue to occur with Bond-Ply materials.This

inherent action often increases bond strength by more than 2x

within the first 24 hours.

Q: Will Bond-Ply adhere to plastic packages?

A: Adhesive performance on plastic packages is primarily a function

of surface contact or wet-out. If surface contaminants such as

plastic mold release oils are present, this will prevent contact

and/or bonding to the surface. Make sure all surfaces are clean

and dry prior to applying Bond-Ply materials.

Q: How are one-part Liqui-Bond adhesives cured?

A: Liqui-Bond SA 2000 and Liqui-Bond SA 1000 require heat to

cure and bond in theapplication. Altering the bond line tempera-

ture and time can control the cure schedule.The components

should not be moved during the curing process.

Bond-Ply

Comparison Data

SPDG_Chapter3_10.06.qxp 10/20/2006 1:39 PM Page 73

Bond-Ply

100

Thermally Conductive, Fiberglass Reinforced Pressure Sensitive Adhesive Tape

BOND-PLY

Features and Benefits

• Thermal impedance:

0.86°C-in2/W (@100 psi)

• High bond strength to a variety of surfaces

• Double-sided, pressure sensitive

adhesive tape

• High performance, thermally conductive

acrylic adhesive

• Can be used instead of heat-cure adhesive,

screw mounting or clip mounting

Typical Applications

Include:

• Mount heat sink onto BGA graphic

processor or drive processor

• Mount heat spreader onto power

converter PCB or onto motor control PCB

Configurations Available:

• Sheet form, roll form and die-cut parts

Shelf Life: The double-sided, pressure

sensitive adhesive used in Bond-Ply products

requires the use of dual liners to protect

the surfaces from contaminants. Bergquist

recommends a 6-month shelf life at a

maximum continuous storage temperature

of 35°C or 3-month shelf life at a maximum

continuous storage temperature of 45°C, for

maintenance of controlled adhesion to the

liner.The shelf life of the Bond-Ply material,

without consideration of liner adhesion

(which is often not critical for manual assembly

processing), is recommended at 12 months

from date of manufacture at a maximum

continuous storage temperature of 60°C.

Building a Part Number Standard Options

Bond-Ply®: U.S. Patent 5,090,484 and others.

Section A

Section B

Section C

Section D

Section E

NA = Selected standard option. If not selecting a standard

option, insert company name, drawing number, and

revision level.

BP100 = Bond-Ply 100 Material

BP100 0.008 00 1112 NA

Note: To build a part number, visit our website at www.bergquistcompany.com.

Standard thicknesses available: 0.005", 0.008", 0.011"

00 = No adhesive

1112 = 11" x 12" sheets,11250 = 11" x 250' rolls

or 00 = custom configuration

––––

TYPICAL PROPERTIES OF BOND-PLY 100

PROPERTY IMPERIAL VALUE METRIC VALUE TEST METHOD

Color White White Visual

Reinforcement Carrier Fiberglass Fiberglass —

Thickness (inch) / (mm) 0.005, 0.008, 0.011 0.127, 0.203, 0.279 ASTM D374

Temp. Resistance, 30 sec. (°F) / (°C) 392 200 —

Elongation (%45° to Warp & Fill) 70 70 ASTM D412

Tensile Strength (psi) / (MPa) 900 6 ASTM D412

CTE (ppm) 325 325 ASTM D3386

Glass Transition (°F) / (°C) -22 -30 ASTM 1356

Continuous Use Temp (°F) / (°C) -22 to 248 -30 to 120 —

ADHESION

Lap Shear @ RT (psi) / (MPa) 100 0.7 ASTM D1002

Lap Shear after 5 hr @ 100°C 200 1.4 ASTM D1002

Lap Shear after 2 min @ 200°C 200 1.4 ASTM D1002

Static Dead Weight Shear (°F) / (°C) 302 150 PSTC#7

ELECTRICAL VALUE TEST METHOD

Dielectric Breakdown Voltage - 0.005" (Vac) 3000 ASTM D149

Dielectric Breakdown Voltage - 0.008" (Vac) 6000 ASTM D149

Dielectric Breakdown Voltage - 0.011" (Vac) 8500 ASTM D149

Flame Rating V-O U.L.94

THERMAL

Thermal Conductivity (W/m-K) 0.8 ASTM D5470

THERMAL PERFORMANCE vs PRESSURE

Pressure (psi) 10 25 50 100 200

TO-220 Thermal Performance (°C/W) 0.005" 4.39 4.02 3.48 3.15 3.05

TO-220 Thermal Performance (°C/W) 0.008" 5.11 4.69 4.53 4.45 4.38

TO-220 Thermal Performance (°C/W) 0.011" 6.26 5.92 5.73 5.63 5.53

Thermal Impedance (°C-in2/W) 0.005" (1) 0.78 0.61 0.58 0.55 0.54

Thermal Impedance (°C-in2/W) 0.008" (1) 1.28 0.94 0.90 0.86 0.84

Thermal Impedance (°C-in2/W) 0.011" (1) 2.47 1.22 1.19 1.14 1.11

1) The ASTM D5470 test fixture was used.The recorded value includes interfacial thermal resistance.These

values are provided for reference only. Actual application performance is directly related to the surface roughness, flatness and

pressure applied.

SPDG_Chapt4_10.06.qxp 10/23/2006 12:47 PM Page 73

Bond-Ply

400

Features and Benefits

• Thermal impedance:

0.87°C-in2/W (@50 psi)

• Easy application

• Eliminates need for external hardware

(screws, clips, etc.)

• Available with easy release tabs

Bergquist Bond-Ply 400 is an un-reinforced,

thermally conductive, pressure sensitive

adhesive tape.The tape is supplied with

protective topside tabs and a carrier liner.

Bond-Ply 400 is designed to attain high bond

strength to a variety of “low energy” surfaces,

including many plastics, while maintaining high

bond strength with long term exposure to

heat and high humidity.

Typical Applications

Include:

Secure:

• Heat sink onto BGA graphic processor

• Heat sink to computer processor

• Heat sink onto drive processor

• Heat spreader onto power converter PCB

• Heat spreader onto motor control PCB

Configurations Available:

• Die-cut parts (supplied on rolls with easy

release, protective tabs)

Thermally Conductive, Unreinforced, Pressure Sensitive Adhesive Tape

Shelf Life: The double-sided pressure sensitive adhesive used in Bond-Ply products requires

the use of dual liners to protect the surfaces from contaminants. Bergquist recommends a

6-month shelf life at a maximum continuous storage temperature of 35°C, or 3-month shelf life at

a maximum continuous storage temperature of 45°C, for maintenance of controlled adhesion to

the liner. The shelf life of the Bond-Ply material, without consideration of liner adhesion (which is

often not critical for manual assembly processing), is recommended at 12 months from date of

manufacture at a maximum continuous storage temperature of 60°C.

Building a Part Number Standard Options

Bond-Ply®: U.S. Patent 5,090,484 and others.

Section A

Section B

Section C

Section D

Section E

NA = Selected standard option. If not selecting a standard

option, insert company name, drawing number, and

revision level.

BP400 = Bond-Ply 400 Material

BP400 0.005 00 11/250 NA

Note: To build a part number, visit our website at www.bergquistcompany.com.

Standard thicknesses available: 0.005"

00 = No adhesive

11/250 = 11" x 250' rolls or 00 = custom configuration

––––

TYPICAL PROPERTIES OF BOND-PLY 400

PROPERTY IMPERIAL VALUE METRIC VALUE TEST METHOD

Color White White Visual

Thickness (inch) / (mm) 0.005 0.127 ASTM D374

Glass Transition (°F) / (°C) -22 -30 ASTM E1356

Continuous Use Temp (°F) / (°C) -22 to 248 -30 to 120 —

ADHESION

Lap Shear @ RT (psi) / (MPa) 100 0.7 ASTM D1002

Lap Shear after 5 hr @ 100°C 200 1.4 ASTM D1002

Lap Shear after 2 min @ 200°C 200 1.4 ASTM D1002

ELECTRICAL VALUE TEST METHOD

Dielectric Breakdown Voltage (Vac) 3000 ASTM D149

Flame Rating V-O U.L.94

THERMAL

Thermal Conductivity (W/m-K) 0.4 ASTM D5470

THERMAL PERFORMANCE vs PRESSURE

Initial Assembly Pressure (psi for 5 seconds) 10 25 50 100 200

TO-220 Thermal Performance (°C/W) 0.005" 5.4 5.4 5.4 5.4 5.4

Thermal Impedance (°C-in2/W) (1) 0.87

1) The ASTM D5470 test fixture was used.The recorded value includes interfacial thermal resistance.These

values are provided for reference only. Actual application performance is directly related to the surface roughness, flatness and

pressure applied.

BOND-PLY

SPDG_Chapt4_10.06.qxp 10/23/2006 12:47 PM Page 74

BOND-PLY

Bond-Ply

660B

Thermally Conductive, Film Reinforced, Pressure Sensitive Adhesive Tape

Features and Benefits

• Designed to replace mechanical fasteners

or screws

• For applications that require

electrical isolation

• Double-sided pressure sensitive

adhesive tape

Bond-Ply 660B is a thermally conductive,

electrically insulating, double-sided pressure

sensitive adhesive tape.The tape consists of a

high performance, thermally conductive acrylic

adhesive coated on both sides of a PEN film.

Use Bond-Ply 660B in applications to replace

mechanical fasteners or screws.

Typical Applications

Include:

• Mount heat sink onto BGA graphic processor

• Mount heat sink onto drive processor

• Mount heat spreader onto power

converter PCB

• Mount heat spreader onto motor

control PCB

Configurations Available:

• Roll form and die-cut parts

The material as delivered will include a

continuous base liner with differential release

properties to allow simplicity in roll packaging

and application assembly.

Shelf Life: The double-sided pressure sensitive adhesive used in Bond-Ply products requires

the use of dual liners to protect the surfaces from contaminants. Bergquist recommends a

6-month shelf life at a maximum continuous storage temperature of 35°C, or 3-month shelf life

at a maximum continuous storage temperature of 45°C, for maintenance of controlled

adhesion to the liner.The shelf life of the Bond-Ply material, without consideration of liner

adhesion (which is often not critical for manual assembly processing), is recommended at

12 months from date of manufacture at a maximum continuous storage temperature

of 60°C.

Building a Part Number Standard OptionsBond-Ply®:

U.S. Patent 5,090,484 and others.

FR-4 or

Flex Circuit

Bond-Ply 660B

Metal Heat Spreader

Section A

Section B

Section C

Section D

Section E

NA = Selected standard option. If not selecting a standard

option, insert company name, drawing number, and

revision level.

BP660B = Bond-Ply 660B Material

BP660B 0.0055 00 1112 NA

Note: To build a part number, visit our website at www.bergquistcompany.com.

Standard thicknesses available: 0.0055"

00 = No adhesive

1112 = 11" x 12" sheets, 11/250 = 11" x 250' rolls, or

00 = custom configuration

––––

TYPICAL PROPERTIES OF BOND-PLY 660B

PROPERTY IMPERIAL VALUE METRIC VALUE TEST METHOD

Color White White Visual

Reinforcement Carrier PEN Film PEN Film —

Thickness (inch) / (mm) 0.0055 0.14 ASTM D374

Temp. Resistance, 30 sec. (°F) / (°C) 392 200 —

Elongation (%) 40 40 ASTM D412

Tensile Strength (psi) / (MPa) 30000 210 ASTM D412

CTE (ppm) 250 250 ASTM D3386

Glass Transition (°F) / (°C) -22 -30 ASTM E1356

Continuous Use Temp (°F) / (°C) -22 to 248 -30 to 120 —

ADHESION

Lap Shear @ RT (psi) / (MPa) 100 0.7 ASTM D1002

Lap Shear after 5 hr @ 100°C 200 1.4 ASTM D1002

Lap Shear after 2 min @ 200°C 200 1.4 ASTM D1002

Static Dead Weight Shear (°F) / (°C) 302 150 PSTC#7

ELECTRICAL

Dielectric Breakdown Voltage (Vac) 7000 7000 ASTM D149

Flame Rating V-O V-O U.L.94

THERMAL

Thermal Conductivity (W/m-K) 0.4 0.4 ASTM D5470

THERMAL PERFORMANCE vs PRESSURE

Pressure (psi) 10 25 50 100 200

TO-220 Thermal Performance (°C/W) 5.30 4.94 4.38 4.02 3.88

Thermal Impedance (°C-in2/W) (1) 1.15 0.79 0.74 0.72 0.70

1) The ASTM D5470 (Bergquist modified) test fixture was used.The recorded value includes interfacial thermal resistance.These values are

provided for reference only. Actual application performance is directly related to the surface roughness, flatness and pressure applied.

SPDG_Chapt4_10.06.qxp 10/23/2006 12:47 PM Page 75

BOND-PLY

Liqui-Bond

™

SA 1000 (One-Part)

Features and Benefits

• High thermal performance

• Eliminates need for mechanical fasteners

• Low viscosity for ease of screening or

stenciling

• Can achieve a very thin bond line

• Mechanical and chemical stability

• Maintains structural bond in

severe-environment applications

• Heat cure

Liqui-Bond SA 1000 is a thermally conductive,

one-part liquid silicone adhesive with a low

viscosity for easy screenability. Liqui-Bond SA

1000 features a high thermal performance

and maintains it’s structure even in severe-

environment applications.

Liqui-Bond SA 1000 features excellent

low and high-temperature mechanical and

chemical stability.The material’s mild elastic

properties assist in relieving CTE stresses

during thermal cycling. Liqui-Bond SA 1000

contains no cure by-products, cures at elevat-

ed temperatures and requires refrigeration

storage at 10°C.The material is available in

both tube and mid-sized container forms.

Typical Applications Include:

• PCBA to housing

• Discrete component to heat spreader

Configurations Available:

• With or without glass beads

Building a Part Number Standard Options

Section A

Section B

Section C

Section D

Section E

NA = Selected standard option. If not selecting a standard

option, insert company name, drawing number, and

revision level.

LBSA1000 = Liqui-Bond SA 1000 Liquid Adhesive Material

LBSA1000 00 00 30cc NA

Note: To build a part number, visit our website at www.bergquistcompany.com.

00 = No spacer beads

07 = 0.007" spacer beads

00 = No adhesive

Cartridges: 30cc = 30.0cc, 600cc = 600.0cc (ml)

Pail: 1G = 1-gallon, 5G = 5-gallon

––––

Thermally Conductive, One-Part, Liquid Silicone Adhesive

TYPICAL PROPERTIES OF LIQUI-BOND SA 1000

PROPERTY AS SUPPLIED IMPERIAL VALUE METRIC VALUE TEST METHOD

Color Black Black Visual

Viscosity (cps) (1) 125,000 125,000 ASTM B2196

Density (g/cc) 2.4 2.4 ASTM D792

Shelf Life @ 10°C (months) 6 6 —

PROPERTY AS CURED - PHYSICAL

Hardness (Shore A) 75 75 ASTM D2240

Continuous Use Temp (°F) / (°C) -76 to 392 -60 to 200 —

Shear Strength (psi) / (MPa) 200 1.4 ASTM D1002

PROPERTY AS CURED - ELECTRICAL

Dielectric Strength (V/mil) / (V/mm) 250 10,000 ASTM D149

Dielectric Constant (1000 Hz) 5.5 5.5 ASTM D150

Volume Resistivity (Ohm-meter) 1010 1010 ASTM D257

Flame Rating V-O V-O U.L.94

PROPERTY AS CURED - THERMAL

Thermal Conductivity (W/m-K) 1.0 1.0 ASTM D5470

CURE SCHEDULE

Pot Life @ 25°C (hours) (2) 10 10 —

Cure @ 125°C (minutes) (3) 20 20 —

Cure @ 150°C (minutes) (3) 10 10 —

1) Brookfield RV, Heli-path, Spindle TF @ 20 rpm, 25°C.

2) Based on 1/8" diameter bead.

3) Cure Schedule - time after cure temperature is achieved at the interface. Ramp time is application dependent.

SPDG_Chapt4_10.06.qxp 10/23/2006 12:47 PM Page 76

BOND-PLY

Liqui-Bond

™

SA 2000

Features and Benefits

• High thermal conductivity: 2.0 W/m-K

• Eliminates need for mechanical fasteners

• One-part formulation for easy dispensing

• Mechanical and chemical stability

• Maintains structural bond in

severe-environment applications

• Heat cure

Liqui-Bond SA 2000 is a high performance,

thermally conductive silicone adhesive that

cures to a solid bonding elastomer. Liqui-Bond

SA 2000 is supplied as a one-part liquid

component, in either tube or mid-sized

container form.

Liqui-Bond SA 2000 features excellent

low and high-temperature mechanical and

chemical stability.The material’s mild elastic

properties assist in relieving CTE stresses

during thermal cycling. Liqui-Bond SA 2000

cures at elevated temperatures and requires

refrigeration storage at 10°C.

Typical Applications Include:

• PCBA to housing

• Discrete component to heat spreader

Configurations Available:

• With or without glass beads

Building a Part Number Standard Options

Section A

Section B

Section C

Section D

Section E

NA = Selected standard option. If not selecting a standard

option, insert company name, drawing number, and

revision level.

LBSA2000 = Liqui-Bond SA 2000 Liquid Adhesive Material

LBSA2000 00 00 30cc NA

Note: To build a part number, visit our website at www.bergquistcompany.com.

00 = No spacer beads

07 = 0.007" spacer beads

00 = No adhesive

Cartridges: 30cc = 30.0cc, 600cc = 600.0cc (ml)

Pail: 1G = 1-gallon, 5G = 5-gallon

––––

Thermally Conductive, One-Part, Liquid Silicone Adhesive

TYPICAL PROPERTIES OF LIQUI-BOND SA 2000

PROPERTY AS SUPPLIED IMPERIAL VALUE METRIC VALUE TEST METHOD

Color Yellow Yellow Visual

Viscosity (cps) (1) 200,000 200,000 ASTM B2196

Density (g/cc) 2.4 2.4 ASTM D792

Shelf Life @ 10°C (months) 6 6 —

PROPERTY AS CURED - PHYSICAL

Hardness (Shore A) 80 80 ASTM D2240

Continuous Use Temp (°F) / (°C) -76 to 392 -60 to 200 —

Shear Strength (psi) / (MPa) 200 1.4 ASTM D1002

PROPERTY AS CURED - ELECTRICAL

Dielectric Strength (V/mil) / (V/mm) 250 10,000 ASTM D149

Dielectric Constant (1000 Hz) 6.0 6.0 ASTM D150

Volume Resistivity (Ohm-meter) 1011 1011 ASTM D257

Flame Rating V-O V-O U.L.94

PROPERTY AS CURED - THERMAL

Thermal Conductivity (W/m-K) 2.0 2.0 ASTM D5470

CURE SCHEDULE

Pot Life @ 25°C (hours) (2) 24 24 —

Cure @ 125°C (minutes) (3) 20 20 —

Cure @ 150°C (minutes) (3) 10 10 —

1) Brookfield RV, Heli-path, Spindle TF @ 20 rpm, 25°C.

2) Based on 1/8" diameter bead.

3) Cure Schedule - time after cure temperature is achieved at the interface. Ramp time is application dependent.

SPDG_Chapt4_10.06.qxp 10/23/2006 12:47 PM Page 77

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Real-Time Response to

Important Issues Facing

Design Engineers,

Engineering Managers

and Product Specifiers.

Need help selecting the right

Bergquist thermal management

product for your specific

application needs?

The Bergquist Company website

features a service for designers,

engineers and specifiers —

“TechChat,” an online technical

support service for anyone who

desires immediate support via the

web. “TechChat” can be found at:

www.bergquistcompany.com

“TechChat” provides real-time

answers to technical issues faced

when designing and specifying

thermal management materials,

touch screens, membrane switches

or electronic components.

TechChat is available Monday -

Friday, 8am-5pm, CST.

From the simplest of questions to the most complex, Bergquist’s seasoned professionals draw on the company’s extensive

experience with thermal management as well as membrane switch, touch screen and electronic component applications.

ORDERING

SPDG_Chapt4_10.06.qxp 10/23/2006 12:47 PM Page 78

ORDERING

Solutions for Surface Mount Applications

Sil-Pad

Sil-Pad is the benchmark in thermal interface materials.The Sil-Pad family of materials

are thermally conductive and electrically insulating. Available in custom shapes, sheets,

and rolls, Sil-Pad materials come in a variety of thicknesses and are frequently used in

SMT applications such as:

• Interface between thermal vias in a PCB, and a heat sink or casting

• Heat sink interface to many surface mount packages

Hi-Flow

The Hi-Flow family of phase change materials offers an easy-to-apply thermal interface

for many surface mount packages. At the phase change temperature, Hi-Flow materials

change from a solid and flow with minimal applied pressure.This characteristic optimizes

heat transfer by maximizing wet-out of the interface. Hi-Flow is commonly used to

replace messy thermal grease.

Bergquist phase change materials are specially compounded to prevent pump-out of

the interface area, which is often associated with thermal grease. Typical applications for

Hi-Flow materials include:

• Pentium®, Athlon®, Core 2 Duo and other high performance CPUs

• DC/DC converters

• Power modules

Hi-Flow materials are manufactured with or without film or foil carriers. Custom shapes

and sizes for non-standard applications are also available.

Mid Power Application with Bond-Ply or Sil-Pad

Power Device

Sil-Pad or

Bond-Ply FR-4

High Power Application

Hi-Flow without Thermal Clad

High Power Application

Hi-Flow with Thermal Clad

Power Device

Processor

Thermal Clad

Hi-Flow

Hi-Flow Heat

Spreader

Heat

Spreader

FR-4 Board

Heat

Spreader

Pentium®is a registered trademark of Intel Corporation.

Athlon®is a registered trademark of Advanced Micro Devices, Inc.

SPDG_Chapt4_10.06.qxp 10/23/2006 12:47 PM Page 79

ORDERING

Where Thermal Solutions Come Together

Bond-Ply and Liqui-Bond

The Bond-Ply family of materials are thermally conductive and electrically isolating.

Bond-Ply is available in a pressure sensitive adhesive or laminating format. Liqui-Bond is

a high thermal performance liquid silicone adhesive that cures to a solid bonding

elastomer. Bond-Ply provides for the mechanical decoupling of bonded materials with

mismatched thermal coefficients of expansion.Typical applications include:

• Bonding bus bars in a variety of electronic modules and sub assemblies

• Attaching a metal-based component to a heat sink

• Bonding a heat sink to a variety of ASIC, graphic chip, and CPU packages

• Bonding flexible circuits to a rigid heat spreader or thermal plane

• Assembly tapes for BGA heat spreader

• Attaching PCB assemblies to housings

Gap Pad and Gap Filler

The Gap Pad product family offers a line of thermally conductive materials which

are highly conformable.Varying degrees of thermal conductivity and compression

deflection characteristics are available.Typical applications include:

• On top of a semiconductor package such as a QFP or BGA. Often times, several

packages with varying heights can use a common heat sink when utilizing Gap Pad

• Between a PCB or substrate and a chassis, frame, or other heat spreader

• Areas where heat needs to be transferred to any type of heat spreader

• For interfacing pressure sensitive devices

• Filling various gaps between heat-generating devices and heat sinks or housings

Gap Pads are available in thickness of 0.010" to 0.250", and in custom shapes, with or

without adhesive. Gap Fillers are available in cartridge or kit form.

Top Efficiency In

Thermal Materials For

Today’s Changing Technology.

Contact Bergquist for additional information regarding

our Thermal Solutions.We are constantly innovating

to offer you the greatest selection of options and

flexibility to meet today’s changing technology.

Lower Power Application

with Gap Pad

Gap Pad

Power

Device

Heat

Spreader

FR-4 Board

SPDG_Chapt4_10.06.qxp 10/23/2006 12:47 PM Page 80

ORDERING

Rolls:

Sil-Pad materials are available in roll form, with or without adhesive,

with the exception of Sil-Pad 1750 and Sil-Pad 2000. Hi-Flow materials

are available in roll form. Certain Gap Pad materials are available in

roll form. Please contact Bergquist Sales for more information.

Adhesives:

Bergquist adhesives include:

SILICONE: (AC) - Unloaded

(ACA) - Unloaded, Low Tack

(TAC) - Loaded (Thermally Enhanced)

ACRYLIC: (AAC) - Unloaded

(TAAC) - Thermally Loaded

(EAAC) - Thermally Enhanced

THICKNESS: 0.0005" - 0.001", (12-25µm) (adhesive only)

Note:

For non-symmetrical parts, please indicate on print which side

the adhesive is on.

Peel Strength: See data below.

POL = Peel-Off Liner (force per unit width of the liner to

the adhesive).

QS = Quick Stick (simulated force per unit width of the adhesive to

the heat sink).

g/in = Grams per inch.

Note:

These values are typical after the material has aged for 2-3

weeks and are significantly different immediately after coating. Upon

completion of coating, QS is 250-500 g/in and POL is 3-20 g/in for all

silicone adhesives.

Shelf Life:

Silicone Adhesives: Six (6) months from date of manufacture when

stored in original packaging at 70°F (21°C) and 50% relative humidity.

Acrylic Adhesives: One (1) year from date of manufacture when stored

in original packaging at 70°F (21°C) and 50% relative humidity.

Peel adhesion data is available upon request. Please contact Bergquist

Sales for more information.

Ordering Procedure:

The last 2 or 3 digits define the part number selected.The “foot print”

and dimensions are shown on pages 87-95.

Special Shapes:

For applications requiring non-standard or custom Sil-Pad configurations,

contact your Bergquist Sales Representative. We produce thousands of

custom die shapes and designs.

Tolerances:

Typical converting tolerances are held on length (L), width (W), hole

diameter and hole location for most materials as noted below:

Sheets:

Standard sheet size for most materials is 12" x 12", with or without

adhesive as specified on the individual data sheet. When ordering

sheets, please specify material type, thickness and include all

dimensions. Contact Bergquist Sales if other sizes are required.

Note:

Sil-Pad A2000 maximum sheet size is 10" x 12". Gap Pad

standard sheet size is 8" x 16".

TYPICAL SIL-PAD / HI-FLOW TOLERANCES

Part Dimension Length and Width

Tolerance

Hole Location and

Diameter

<6" ± 0.010" ± 0.005"

6" - 12" ± 0.015" ± 0.010"

>12" ± 0.020" TBD

TYPICAL GAP PAD TOLERANCES

Material

Thickness

Length and Width

Tolerance

Hole Location and

Diameter

10 mil ± 0.015" ± 0.015"

15 mil ± 0.015" ± 0.015"

20 mil ± 0.020" ± 0.020"

40 mil ± 0.035" ± 0.035"

60 mil ± 0.050" ± 0.050"

80 mil ± 0.050" ± 0.050"

100 mil ± 0.060" ± 0.060"

125 mil ± 0.075" ± 0.075"

160 mil ± 0.100" ± 0.100"

200 mil ± 0.125" ± 0.125"

250 mil ± 0.160" ± 0.160"

Note: Dependent upon material and application requirements, tighter tolerances may be feasible

and available. Please contact Bergquist Sales for these requests and additional information regarding

tolerances.

TYPICAL ADHESIVE PROPERTIES

ADHESIVE POL QS

Silicone AC 50-150 g/in 50-150 g/in

Silicone ACA 5-70 g/in 5-150 g/in

Silicone TAC 50-150 g/in 50-150 g/in

Acrylic AAC 5-70 g/in 100-800 g/in

Acrylic TAAC 5-70 g/in 100-400 g/in

Acrylic EAAC 5-60 g/in 100-200 g/in

Ordering Information

SPDG_Chapt4_10.06.qxp 10/23/2006 12:47 PM Page 81

Ordering Information

ORDERING

Note:

These values are typical after the material has aged for 2-3

weeks and are significantly different immediately after coating. Upon

completion of coating, QS is 250-500 g/in and POL is 3-20 g/in for all

silicone adhesives.

Shelf Life:

Silicone Adhesives: Six (6) months from date of manufacture when

stored in original packaging at 70°F (21°C) and 50% relative humidity.

Acrylic Adhesives: One (1) year from date of manufacture when stored

in original packaging at 70°F (21°C) and 50% relative humidity.

Peel adhesion data is available upon request. Please contact Bergquist

Sales for more information.

PSA Characteristics:

Standard pressure sensitive adhesive (AC) coated on one side of a

Sil-Pad will increase the thermal resistance (per ASTM D5470) by

0.2°C-in2/W. Standard pressure sensitive adhesive on 2 sides increases

the thermal impedance by 0.4°C-in2/W.

Thermally conductive pressure sensitive adhesive (TAC) on one side

increases the thermal resistance by 0.05°C-in2/W and on two sides by

0.1°C-in2/W.

The effect of AC and TAC on the thermal impedance in an application

will vary. In low-pressure applications, the pressure sensitive adhesive

will wet-out the interface easier and eliminate the interfacial thermal

resistance.

Note:

Bergquist adhesives are designed for ease of application during

assembly. If an automated dispensing method is preferred, Bergquist

will recommend manufacturers of automated dispensing equipment

upon request. Please contact Bergquist Sales for more information on

this subject.

Note:

Bergquist cannot be responsible for dispensing equipment selection

and/or performance of specific materials on said equipment. It is the

customer’s responsibility to determine the suitability and compatibility of

the specific Bergquist material with the selected equipment.

Ordering Procedure:

The last 2 or 3 digits define the part number selected.The “foot print”

and dimensions are shown on pages 87-95.

Special Shapes:

For applications requiring non-standard or custom Sil-Pad configurations,

contact your Bergquist Sales Representative. We produce thousands of

custom die shapes and designs.

Tolerances:

Typical converting tolerances are held on length (L), width (W), hole

diameter and hole location for most materials as noted below:

Sheets:

Standard sheet size for most materials is 12" x 12", with or without

adhesive as specified on the individual data sheet. When ordering

sheets, please specify material type, thickness and include all

dimensions. Contact Bergquist Sales if other sizes are required.

Note:

Sil-Pad A2000 maximum sheet size is 10" x 12". Gap Pad

standard sheet size is 8" x 16".

Rolls:

Sil-Pad materials are available in roll form, with or without adhesive,

with the exception of Sil-Pad 1750 and Sil-Pad 2000. Hi-Flow materials

are available in roll form. Certain Gap Pad materials are available in

roll form. Please contact Bergquist Sales for more information.

Adhesives:

Bergquist adhesives include:

SILICONE: (AC) - Unloaded

(ACA) - Unloaded, Low Tack

(TAC) - Loaded (Thermally Enhanced)

ACRYLIC: (AAC) - Unloaded

(TAAC) - Thermally Loaded

(EAAC) - Thermally Enhanced

THICKNESS: 0.0005" - 0.001", (12-25µm) (adhesive only)

Note:

For non-symmetrical parts, please indicate on print which side

the adhesive is on.

Peel Strength: See data below.

POL = Peel-Off Liner (force per unit width of the liner to

the adhesive).

QS = Quick Stick (simulated force per unit width of the adhesive to

the heat sink).

g/in = Grams per inch.

SPDG_Chapt4_10.06.qxp 10/23/2006 12:47 PM Page 82

ORDERING

Sil-Pad

Configurations

4 Lead Part Number

TO-66 Suffix "A" "B" "C" "D" "E" "F" "G"

-84 1.312 .762 .140 .062 .960 .200 .100

Plastic Part Number Dimensions Part Number Dimensions

Power Suffix "A" "B" "C" "D" Suffix "A" "B" "C" "D"

Various -35 .710 .500 .160 .141 Various -104 1.000 .750 .300 .140

(Clip Mount) -43 .750 .500 Various -107 .810 .910 .170 .147

TO-126 -50 .437 .312 .140 093 Various -110 .984 .787

Various -51 .687 .562 .218 .125 Various -114 .827 .945 .197 .150

Various -52 .855 .630 .230 .093 Various -116 .855 .630 .228 .122

TO-220 -54 .750 .500 .187 .147 Various -117 .827 .709 .256 .126

TO-202 -55 .610 .560 .245 .125 Various -118 .748 .551 .217 .126

Various -56 .855 .562 .218 .125 Various -119 .437 .311 .142 .110

TO-220 -58 .750 .500 .187 .125 Various -120 .728 .472 .157 .098

TO-126 -60 .437 .312 .140 .122 TO-3P -122 1.140 .810 .355 .147

Various -61 .750 .410 .225 .156 Various -126 .945 .748 .256 .162

TO-220 -62 .750 .600 .240 .150 Various -128 .984 1.654 .315 .157

Various -63 .750 .600 .240 .115 Various -131 .709 .512 .177 .122

Various -64 .500 .385 .170 .120 Various -132 .472 .315 .157 .126

TO-218 -68 1.125 .625 .200 .145 Various -133 .866 .709 .256 .126

Various -70 1.410 .810 .355 .147 Various -134 .945 .709 .228 .126

Various -90 .860 .740 .200 .160 Various -136 1.250 1.000

Various -102 .866 .650 .217 .142 Various -137 1.250 1.000 .258 .127

Various -103 .750 .800 .150 .160 Various -138 1.250 1.000 .258 .148

Power Part Number Dimensions

Module Suffix "A" "B" "C" "D" "E" "F"

-67 1.500 .900 .150 1.200 .450 .075

-101 2.500 2.000 .344 1.812 1.000 .156

Plastic Part Number Dimensions

Power Suffix "A" "B" "C" "D" "E" "F" "G"

-57 .910 .500 .200 .125 .580 .046 .265

-89 .983 .750 .432 .156 .665 .101 .217

Plastic Part Number Dimensions

Power Suffix "A" "B" "C" "D" "E" "F" "G" "H"

-66 1.000 .500 .200 .141 .626 .046 .219 .032

Power Part Number Dimensions

Resistors Suffix "A" "B" "C" "D" "E" "F" "G" "H" "I"

RH-25 -94 1.187 1.205 .234 .469 .212 .156 .719 .781 .140

RH-50 -95 2.093 1.265 .265 .530 .210 .255 1.563 .845 .140

RH-5 -96 .725 .771 .140 .280 .140 .156 .445 .491 .093

RH-10 -97 .805 .890 .127 .250 .130 .190 .551 .630 .121

RH-25 -98 1.150 1.180 .231 .425 .190 .270 .688 .800 .147

RH-50 -99 1.965 1.236 .198 .404 .132 .263 1.569 .972 .130

TO-220 Part Number Dimensions # of

Multiples Suffix "A" "B" "C" "D" "E" "F" Holes

2 Parts -34 1.000 .750 .187 .125 .250 .500 2

3 Parts -36 1.500 .750 .187 .125 .250 .500 3

-37 2.000 .750 .187 .125 .250 .500 4

-38 2.500 .750 .187 .125 .250 .500 5

-39 3.000 .750 .187 .125 .250 .500 6

-40 3.500 .750 .187 .125 .250 .500 7

-41 4.000 .750 .187 .125 .250 .500 8

Power Part Number Dimensions

Module Suffix "A" "B" "C" "D" "E" "F"

-108 4.600 2.400 2.125 .500 1.800 .125

-140 4.598 2.402 2.098 0.500 1.799 0.150

-141 2.279 2.402 2.102 0.488 0.650 0.150

-142 2.280 1.450 1.270 0.490 0.650 0.130

TO-220

Imperial Measurements

SPDG_Chapt4_10.06.qxp 10/23/2006 12:47 PM Page 83

Part Number Dimensions

Multiwatt Suffix "A" "B" "C" "D" "E"

-124 .872 .790 .160 .148 .118 x 45°

-125 .866 .787 .157 .154 .079 x 45°

Multi-Lead Part Number

TO-66 Suffix "A" "B" "C" "D" "E" "F"

-93 1.350 .800 .140 .400 .960 .480

Diode Part Number Dimensions Part Number Dimensions

Washer Suffix "A" "B" Suffix "A" "B"

Various -19 .510 .140 Various -75 .360 .260

DO-4 -20 .510 .200 Various -76 .750 .125

DO-5 -21 .800 .260 Various -77 .800 .190

DO-4 (oversized) -22 .625 .200 DO-8 -78 .875 .313

DO-5 (oversized) -25 1.000 .260 Various -79 1.180 .515

Various -26 .812 .145 Various -80 1.250 .380

Various -27 .812 .115 Various -81 1.500 .200

Various -28 1.000 .140 Various -82 .512 .161

Various -32 1.500 .500 Various -111 .591 .217

Part Number Dimensions

TO-36 Suffix "A" "B" "C"

-08 1.063 .690 .190

Small

Power Part Number Dimensions

Devices Suffix "A" "B" "C"

TO-5, 3 Holes -09 .360 .200 .040

TO-18, 3 Holes -12 .250 .100 .036

TO-18, 4 Holes -13 .250 .100 .036

TO-5, 4 Holes -33 .360 .200 .040

TO-5, 3 Holes -44 .390 .200 .040

TO-5, 4 Holes -45 .390 .200 .040

Part Number Dimensions

Rectifier Suffix "A" "B" "C"

-46 1.250 1.250 .200

-47 1.125 1.125 .140

-48 1.000 1.000 .187

TIP Part Number Dimensions

Packages Suffix "A" "B" "C" "D" "E"

Clip Mount -42 .984 .787 .205

TIP-36

Plastic Tip -53 .865 .650 .650 .140 .205

TO-3P -65 1.260 .787 .984 .142 .205

Plastic Clip -73 .984 .787 .708 .142 .205

Power Part Number Dimensions

Module Suffix "A" "B" "C" "D" "E" "F" "G"

-100 2.510 1.260 .630 .305 1.900 .205 .205

-123 1.614 1.102 .551 .157 1.220 .118 .118

SIP Part Number Dimensions

Package Suffix "A" "B" "C" "D" "E" "F" "G"

-105 1.450 .838 .612 .245 .960 .170 .120

Part Number Dimensions

Quarz Suffix "A" "B" "C" "D"

-115 .472 .197 .193 .031

Power Part Number Dimensions

Module Suffix "A" "B" "C" "D" "E" "F" "G"

-109 1.350 .642 .321 .195 .960 .060 .125

Sil-Pad

Configurations

ORDERING

D-DIA EC

(2) G Dia

F RAD

(TYP)

Imperial Measurements

SPDG_Chapt4_10.06.qxp 10/23/2006 12:48 PM Page 84

ORDERING

Sil-Pad

Configurations

TO-3 & TO-66

Part Number Dimensions

Style Suffix "A" "B" "C" "D" "E" "F" "G"

-02 1.780 1.250 .140 .093 1.187 .430 .072

-03 1.563 1.050 .140 .080 1.187 .430 .072

-04 1.650 1.140 .122 .062 1.187 .430 .072

-05 1.650 1.140 .140 .093 1.187 .430 .072

-06 1.650 1.140 .165 .062 1.187 .430 .072

-07 1.780 1.250 .165 .094 1.187 .430 .072

-10 1.440 1.000 .140 .075 .960 .200 .100

-11 1.312 .762 .140 .062 .960 .200 .100

-15 1.780 1.250 .140 .046 1.187 .430 .072

-16 2.070 1.560 .122 .062 1.187 .430 .072

-17 1.650 1.140 .140 .046 1.187 .430 .072

-18 1.563 1.050 .140 .140 1.187 .430 .072

-23 1.593 1.100 .156 .062 1.187 .430 .072

-24 1.700 1.187 .156 .062 1.187 .430 .072

-29 1.650 1.065 .140 .046 1.187 .430 .072

-30 1.250 .700 .140 .062 .960 .200 .100

-31 1.375 .825 .140 .062 .960 .200 .100

-59 Leadless 1.650 1.140 .165 1.187

-112 1.780 1.248 .165 .063 1.185 .429 .073

-113 1.563 1.051 .165 .079 1.185 .429 .073

-127 1.307 .819 .165 .063 .909 .236 .061

-129 1.654 1.063 .138 .059 1.181 .433 .071

-135 1.650 1.142 .165 .142 1.187 .429 ..072

3 Lead Part Number Dimensions

TO-3 Suffix "A" "B" "C" "D" "E" "F" "G" "H" "I"

-92 1.650 1.140 .140 .093 1.187 .430 .400 .155 .718

4 Lead Part Number Dimensions

TO-3 Suffix "A" "B" "C" "D" "E" "F" "G"

-86 1.560 1.050 .156 .080 1.170 .470 72°

-87 1.563 1.050 .156 .063 1.187 .470 72°

8 Lead Part Number Dimensions

TO-3 Suffix "A" "B" "C" "D" "E" "F" "G"

-88 1.655 1.187 .156 .060 1.187 40° .500

10 Lead Part Number Dimensions

TO-3 Suffix "A" "B" "C" "D" "E" "F" "G" "H"

-91 1.650 1.140 .165 .040 1.187 .593 .500 32.7°

3 Lead Part Number Dimensions

TO-66 Suffix "A" "B" "C" "D" "E" "F" "G" "H"

-85 1.275 .750 .156 .100 .960 .200 .100 .200

9 Lead Part Number Dimensions

TO-66 Suffix "A" "B" "C" "D" "E" "F" "G" "H"

-83 1.440 1.000 .140 .055 .960 .480 .325 36°

Power Part Number Dimensions

Module Suffix "A" "B" "C" "D" "E"

-130 1.600 .480 .165 1.197 .240

F DIA.

C DIA.

(2)

D DIA.

(4)

18¡

G¡

C - DIA.

(2)

Imperial Measurements

SPDG_Chapt4_10.06.qxp 10/23/2006 12:48 PM Page 85

Hi-Flow

225 Configurations

MATERIAL

("B")

-.500+.030

LINER

PSA STRIP

.080+.000

.040

("B")

("C")

("A") ("A")

COLORED PSA TAPE

CLEAR PSA TAPE

PSA STRIP

MATERIAL

LINER

.750+.063

.500+.030

.250+.125

("B")

("C")

("A") ("A")

Part Number Dimensions (± .015)

Suffix “A” “B” “C” Min. Pcs/Roll

-150 1.650 1.650 2.650 3000

-151 1.500 1.500 2.500 5000

-152 1.375 1.375 2.375 5000

-153 1.250 1.250 2.250 5000

-154 1.000 1.000 2.000 7500

-155 .700 .700 1.700 10000

-156 .500 .500 1.500 15000

Part Number Dimensions (± .015)

Suffix “A” “B” “C” Min. Pcs/Roll

-143 1.500 1.500 2.500 5000

-144 1.378 1.378 2.378 5000

-145 1.250 1.250 2.250 5000

-146 1.000 1.000 2.000 7500

-147 .700 .700 1.700 10000

-148 .500 .500 1.500 15000

-149 .300 1.000 2.000 22500

Hi-Flow 225U Tab Configurations

Hi-Flow 225UT/225FT Tab Configurations

ORDERING

Imperial Measurements

SPDG_Chapt4_10.06.qxp 10/23/2006 12:48 PM Page 86

ORDERING

Sil-Pad

Configurations

4 Lead Part Number Dimensions

TO-66 Suffix "A" "B" "C" "D" "E" "F" "G"

-84 33.32 19.35 3.56 1.57 24.38 5.08 2.54

Plastic Part Number Dimensions Part Number Dimensions

Power Suffix "A" "B" "C" "D" Suffix "A" "B" "C" "D"

Various -35 18.03 12.70 4.06 3.58 Various -104 25.40 19.05 7.62 3.56

(Clip Mount) -43 19.05 12.70 Various -107 20.57 23.11 4.32 3.73

TO-126 -50 11.10 7.92 3.56 2.36 Various -110 24.99 19.99

Various -51 17.45 14.27 5.54 3.18 Various -114 21.01 24.00 5.00 3.81

Various -52 21.72 16.00 5.84 2.36 Various -116 21.72 16.00 5.79 3.10

TO-220 -54 19.05 12.70 4.75 3.73 Various -117 21.01 18.01 6.50 3.20

TO-202 -55 15.49 14.22 6.22 3.18 Various -118 19.00 14.00 5.51 3.20

Various -56 21.72 14.27 5.54 3.18 Various -119 11.10 7.90 3.61 2.79

TO-220 -58 19.05 12.70 4.75 3.18 Various -120 18.49 11.99 3.99 2.49

TO-126 -60 11.10 7.92 3.56 3.10 TO-3P -122 28.96 20.57 9.02 3.73

Various -61 19.05 10.41 5.72 3.96 Various -126 24.00 19.00 6.50 4.11

TO-220 -62 19.05 15.24 6.10 3.81 Various -128 24.99 42.01 8.00 3.99

Various -63 19.05 15.24 6.10 2.92 Various -131 18.01 13.00 4.50 3.10

Various -64 12.70 9.78 4.32 3.05 Various -132 11.99 8.00 3.99 3.20

TO-218 -68 28.58 15.88 5.08 3.68 Various -133 22.00 18.01 6.50 3.20

Various -70 35.81 20.57 9.02 3.73 Various -134 24.00 18.01 5.79 3.20

Various -90 21.84 18.80 5.08 4.06 Various -136 31.75 25.40

Various -102 22.00 16.51 5.51 3.61 Various -137 31.75 25.40 6.55 3.23

Various -103 19.05 20.32 3.81 4.06 Various -138 31.75 25.40 6.55 3.76

Power Number Dimensions

Module Suffix "A" "B" "C" "D" "E" "F"

-67 38.10 22.86 3.81 30.48 11.43 1.90

-101 63.50 50.80 8.74 46.02 25.40 3.96

Plastic Part Number Dimensions

Power Suffix "A" "B" "C" "D" "E" "F" "G"

-57 23.11 12.70 5.08 3.18 14.73 1.17 6.73

-89 24.97 19.05 10.97 3.96 16.89 2.57 5.51

Plastic Part Number Dimensions

Power Suffix "A" "B" "C" "D" "E" "F" "G" "H"

-66 25.40 12.70 5.08 3.58 15.90 1.17 5.56 0.81

Power Part Number Dimensions

Resistors Suffix "A" "B" "C" "D" "E" "F" "G" "H" "I"

RH-25 -94 30.15 30.61 5.94 11.91 5.38 3.96 18.26 19.84 3.56

RH-50 -95 53.16 32.13 6.73 13.46 5.33 6.48 39.70 21.46 3.56

RH-5 -96 18.42 19.58 3.56 7.11 3.56 3.96 11.30 12.47 2.36

RH-10 -97 20.45 22.61 3.23 6.35 3.30 4.83 14.00 16.00 3.07

RH-25 -98 29.21 29.97 5.87 10.80 4.83 6.86 17.48 20.32 3.73

RH-50 -99 49.91 31.39 5.03 10.26 3.35 6.68 39.85 24.69 3.30

TO-220 Part Number Dimensions # of

Multiples Suffix "A" "B" "C" "D" "E" "F" Holes

2 Parts -34 25.40 19.05 4.75 3.18 6.35 12.70 2

3 Parts -36 38.10 19.05 4.75 3.18 6.35 12.70 3

-37 50.80 19.05 4.75 3.18 6.35 12.70 4

-38 63.50 19.05 4.75 3.18 6.35 12.70 5

-39 76.20 19.05 4.75 3.18 6.35 12.70 6

-40 88.90 19.05 4.75 3.18 6.35 12.70 7

-41 101.60 19.05 4.75 3.18 6.35 12.70 8

Power Part Number Dimensions

Module Suffix "A" "B" "C" "D" "E" "F"

-108 116.84 60.96 53.97 12.70 45.72 3.18

-140 116.8 61.00 53.30 12.70 45.70 3.80

-141 57.90 61.00 53.40 12.40 16.50 3.80

-142 57.91 36.83 32.26 12.45 16.50 3.30

Metric Measurements

TO-220

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ORDERING

Sil-Pad

Configurations

Metric Measurements

Part Number Dimensions

Multiwatt Suffix "A" "B" "C" "D" " E"

-124 22.15 20.07 4.06 3.76 3.0 x 45°

-125 22.00 19.99 3.99 3.91 2.0 x 45°

Multi-

Lead Part Number Dimensions

TO-66 Suffix "A" "B" "C" "D" "E" "F"

-93 34.29 20.32 3.56 10.16 24.38 12.19

Diode Part Number Dimensions Part Number Dimensions

Washer Suffix "A" "B" Suffix "A" "B"

Various -19 12.95 3.56 Various -75 9.14 6.60

DO-4 -20 12.95 5.08 Various -76 19.05 3.18

DO-5 -21 20.32 6.60 Various -77 20.32 4.83

DO-4 (oversized) -22 15.88 5.08 DO-8 -78 22.23 7.95

DO-5 (oversized) -25 25.40 6.60 Various -79 29.97 13.08

Various -26 20.62 3.68 Various -80 31.75 9.65

Various -27 20.62 2.92 Various -81 38.10 5.08

Various -28 25.40 3.56 Various -82 13.00 4.09

Various -32 38.10 12.70 -111 15.01 5.51

Part Number Dimensions

TO-36 Suffix "A" "B" "C"

-08 27.00 17.53 4.83

Small

Power Part Number Dimensions

Devices Suffix "A" "B" "C"

TO-5, 3 Holes -09 9.14 5.08 1.02

TO-18, 3 Holes -12 6.35 2.54 0.91

TO-18, 4 Holes -13 6.35 2.54 0.91

TO-5, 4 Holes -33 9.14 5.08 1.02

TO-5, 3 Holes -44 9.91 5.08 1.02

TO-5, 4 Holes -45 9.91 5.08 1.02

Part Number Dimensions

Rectifier Suffix "A" "B" "C"

-46 31.75 31.75 5.08

-47 28.58 28.58 3.56

-48 25.40 25.40 4.75

TIP Part Number Dimensions

Packages Suffix "A" "B" "C" "D" "E"

Clip Mount -42 24.99 19.99 5.21

TIP-36 Plastic Tip -53 21.97 16.51 16.51 3.56 5.21

TO-3P -65 32.00 19.99 24.99 3.61 5.21

Plastic Clip -73 24.99 19.99 17.98 3.61 5.21

Power Part Number Dimensions

Module Suffix "A" "B" "C" "D" "E" "F" "G"

-100 63.75 32.00 16.00 7.75 48.26 5.21 5.21

-123 41.00 27.99 14.00 3.99 30.99 3.00 3.00

SIP Part Number Dimensions

Package Suffix "A" "B" "C" "D" "E" "F" "G"

-105 36.83 21.29 15.54 6.22 24.38 4.32 3.05

Power Part Number Dimensions

Module Suffix "A" "B" "C" "D"

-115 11.99 5.00 4.90 0.79

Power Part Number Dimensions

Module Suffix "A" "B" "C" "D" "E" "F" "G"

-109 34.29 16.31 8.15 4.95 24.38 1.52 3.18

D-DIA EC

(2) G Dia

F RAD

(TYP)

SPDG_Chapt4_10.06.qxp 10/23/2006 12:48 PM Page 88

ORDERING

TO-3 Part Number Dimensions

Style Suffix "A" "B" "C" "D" "E" "F" "G"

-02 45.21 31.75 3.56 2.36 30.15 10.92 1.83

-03 39.70 26.67 3.56 2.03 30.15 10.92 1.83

-04 41.91 28.96 3.10 1.57 30.15 10.92 1.83

-05 41.91 28.96 3.56 2.36 30.15 10.92 1.83

-06 41.91 28.96 4.19 1.57 30.15 10.92 1.83

-07 45.21 31.75 4.19 2.39 30.15 10.92 1.83

-10 36.58 25.40 3.56 1.90 24.38 5.08 2.54

-11 33.32 19.35 3.56 1.57 24.38 5.08 2.54

-15 45.21 31.75 3.56 1.17 30.15 10.92 1.83

-16 52.58 39.62 3.10 1.57 30.15 10.92 1.83

-17 41.91 28.96 3.56 1.17 30.15 10.92 1.83

-18 39.70 26.67 3.56 3.56 30.15 10.92 1.83

-23 40.46 27.94 3.96 1.57 30.15 10.92 1.83

-24 43.18 30.15 3.96 1.57 30.15 10.92 1.83

-29 41.91 27.05 3.56 1.17 30.15 10.92 1.83

-30 31.75 17.78 3.56 1.57 24.38 5.08 2.54

-31 34.92 20.96 3.56 1.57 24.38 5.08 2.54

-59 Leadless 41.91 28.96 4.19 30.15

-112 45.21 31.70 4.19 1.60 30.10 10.90 1.85

-113 39.70 26.70 4.19 2.01 30.10 10.90 1.85

-127 33.20 20.80 4.19 1.60 23.09 5.99 1.55

-129 42.01 27.00 3.51 1.50 30.00 11.00 1.80

-135 41.91 29.01 4.19 3.61 30.15 10.90 1.83

3 Lead Part Number Dimensions

TO-3 Suffix "A" "B" "C" "D" "E" "F" "G" "H" "I"

-92 41.91 28.96 3.56 2.36 30.15 10.92 10.16 3.94 18.24

4 Lead Part Number Dimensions

TO-3 Suffix "A" "B" "C" "D" "E" "F" "G"

-86 39.62 26.67 3.96 2.03 29.72 11.94 72°

-87 39.70 26.67 3.96 1.60 30.15 11.94 72°

8 Lead Part Number Dimensions

TO-3 Suffix "A" "B" "C" "D" "E" "F" "G"

-88 42.04 30.15 3.96 1.52 30.15 40° 12.70

10 Lead Part Number Dimensions

TO-3 Suffix "A" "B" "C" "D" "E" "F" "G" "H"

-91 41.91 28.96 4.19 1.02 30.15 15.06 12.70 32.7°

3 Lead Part Number Dimensions

TO-66 Suffix "A" "B" "C" "D" "E" "F" "G" "H"

-85 32.38 19.05 3.96 2.54 24.38 5.08 2.54 5.08

9 Lead Part Number Dimensions

TO-66 Suffix "A" "B" "C" "D" "E" "F" "G" "H"

-83 36.58 25.40 3.56 1.40 24.38 12.19 8.26 36°

Power Part Number Dimensions

Module Suffix "A" "B" "C" "D" "E"

-130 40.64 12.19 4.19 30.40 6.10

Sil-Pad

Configurations

Metric Measurements

F DIA.

C DIA.

(2)

D DIA.

(4)

18¡

G¡

C - DIA.

(2)

SPDG_Chapt4_10.06.qxp 10/23/2006 12:48 PM Page 89

Hi-Flow

225 Configurations

Metric Measurements

MATERIAL

("B")

-.500+.030

LINER

PSA STRIP

.080+.000

.040

("B")

("C")

("A") ("A")

COLORED PSA TAPE

CLEAR PSA TAPE

PSA STRIP

MATERIAL

LINER

.750+.063

.500+.030

.250+.125

("B")

("C")

("A") ("A")

Part Number Dimensions (± .015)

Suffix “A” “B” “C” Min. Pcs/Roll

-150 41.91 41.91 67.31 3000

-151 38.10 38.10 63.50 5000

-152 34.93 34.93 60.33 5000

-153 31.75 31.75 57.15 5000

-154 25.40 25.40 50.80 7500

-155 17.78 17.78 43.18 10000

-156 12.70 12.70 38.10 15000

Part Number Dimensions (± .015)

Suffix “A” “B” “C” Min. Pcs/Roll

-143 38.10 38.10 63.50 5000

-144 35.00 35.00 60.40 5000

-145 31.75 31.75 57.15 5000

-146 25.40 25.40 50.80 7500

-147 17.78 17.78 43.18 10000

-148 12.70 12.70 38.10 15000

-149 7.62 7.62 50.80 22500

Hi-Flow 225U Tab Configurations

Hi-Flow 225UT/225FT Tab Configurations

ORDERING

SPDG_Chapt4_10.06.qxp 10/23/2006 12:48 PM Page 90

ORDERING

Sil-Pad

Shield

Standard Configurations

P/N 09SPS01-002 (TO-220) P/N 09SPS01-001 (TO-3) P/N 09SPS01-009

P/N 09SPS01-011 (TO-5) P/N 09SPS01-016 (TO-3) P/N 09SPS01-017 (TO-66)

P/N 09SPS01-020 (DO-5) P/N 09SPS01-023 (TO-3) P/N 09SPS01-019 (DO-4)

Contact the factory for other configurations.

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SPDG_Chapt4_10.06.qxp 10/23/2006 12:48 PM Page 92