GAP PAD VOTM Conformable, Thermally Conductive Material for Filling Air Gaps Property Value Value Test Method Mechanical Properties Thickness inches Color Specific Gravity Heat Capacity J/g-K Continuous Use Hardness, entire composite Gap Pad V0 is a thermally conductive material that acts as a thermal interface between a heat sink and an electronic device. The conformable nature of Gap Pad V0 allows the pad to fill in air gaps between PC boards and heat sinks or a metal chassis. Gap Pad V0 is a highly conformable, low modulus polymer on a fiberglass carrier. The material is available in thicknesses from .020" to .160" with a liner applied to the pink side of the material. The range in thicknesses and the materials flexibility allow Gap Pad V0 to be used in a variety of applications where surface textures vary and the space between surfaces is uneven. The material is available in die-cut parts and with or without adhesive. Applications * Between a semiconductor and heat sink * Replacement for messy grease U.L. File Number E59150 Die-Cut parts, and Sheets Gap Pad is available in die-cut parts and sheets. Standard sheet size is 8" x 16". Gap Pad is not available in rolls. (Type 00) 80 65 65 55 50 45 40 ASTM D2240 Rate 0.01 0.1 1.0 10.0 Modulus 200 300 400 800 ASTM D575 Young's Modulus (psi) vs. Rate of Strain (inches/minute)* Area = 0.5 in2 Low Modulus Portion Only ASTM D374 Visual ASTM D792 ASTM C351 Stress vs. strain and resultant deflection in mils for each Gap Pad V0 thickness. Example: Rate = 1 in/min. Modulus = stress/strain = 400 psi, Area = 0.5 in2, Low Modulus Portion Only; Stress Strain 20 mil 40 mil 60 mil 80 mil 100 mil 125 mil 160 mil 4 psi 1% 0.15 0.35 0.55 0.71 0.91 1.16 1.51 ASTM D575 8 psi 2% 0.30 0.70 1.10 1.42 1.82 2.32 3.02 20 psi 5% 0.75 1.75 2.75 3.55 4.55 5.80 7.55 40 psi 10% 1.50 3.50 5.50 7.10 9.10 11.6 15.1 80 psi 20% 3.00 7.00 11.0 14.2 18.2 23.2 30.2 200 psi 50% 7.50 17.5 27.5 35.5 45.5 58.0 75.5 Electrical Properties Dielectric Constant Dielectric Breakdown Voltage kV-AC Volume Resistivity, Ohm-meters 5.5 >6 1011 ASTM D150 ASTM D149 ASTM D257 Thermal Properties Thermal Conductivity @ 10 psi, W/m-K Thermal Resistance** vs. Entire composite * Areas where heat needs to be transferred to the frame or other type of heat spreader * Between a CPU and a heat spreader .020" to .160" Yellow/Pink 1.6 1 -60 to +200C vs. Thickness (in) 0.020 0.040 0.060 0.080 0.100 0.125 0.160 0.8 Thickness (in.) 0.020 0.040 0.060 0.080 0.100 0.125 0.160 ASTM D5470 (C-in /W) 2 1.0 2.0 3.0 4.0 5.0 6.2 8.0 ASTM D5470 MODULUS * The modulus of Gap Pad is shown as being rate dependent because Gap Pad is viscoelastic. At high rates of compression Gap Pad is elastic and at low rates it is viscous. Elastic strain is instantaneous, independent of time. The total deformation occurs at the instant the stress is applied and is completely recovered when the stress is released. Viscous strain is time dependent. The deformation is not instantaneous but occurs over time and is not completely recovered after the stress is removed. As an example, if the low modulus Gap Pad rubber is molded into a ball and dropped on the floor it will bounce. However, if a load is placed on the ball for a long period of time it will flatten out to a certain extent and will not recover completely to it's original shape after the load has been removed. THERMAL RESISTANCE ** With Gap Pad, the thermal resistance is dependent on the gap between the device and the heatsink. The engineer can minimize the thermal resistance by designing the gap as small as possible. A Gap Pad thickness is then chosen to be just thick enough to fill the largest gaps while minimizing the deflection needed in the smallest gaps to decrease the stress exerted on the devices. If the size of the gaps are known, the thermal resistance across each gap is determined from the table of thermal resistance vs. thickness. 12