Supercapacitors FT Series Overview Applications FT Series Supercapacitors, also known as Electric DoubleLayer Capacitors (EDLCs), are intended for high energy storage applications. Supercapacitors have characteristics ranging from traditional capacitors and batteries. As a result, supercapacitors can be used like a secondary battery when applied in a DC circuit. These devices are best suited for use in low voltage DC hold-up applications such as embedded microprocessor systems with flash memory. Benefits * * * * * Wide range of temperature from -40C to +85C Maintenance free Maximum operating voltage: 5.5 VDC Highly reliable against liquid leakage Lead-free and RoHS Compliant Part Number System FT 0H 104 Z F Series Maximum Operating Voltage Capacitance Code (F) Capacitance Tolerance Environmental FT FTW 0H = 5.5 VDC First two digits represent significant figures. Third digit specifies number of zeros. Z = -20/+80% F = Lead-free One world. One KEMET (c) KEMET Electronics Corporation * P.O. Box 5928 * Greenville, SC 29606 * 864-963-6300 * www.kemet.com S6014_FT * 3/30/2017 1 Supercapacitors - FT Series 0.3 Minimum Sleeve H Maximum o D 0.5 Minimum Dimensions - Millimeters P 0.5 d1 0.1 d2 0.1 (Terminal) Part Number oD H P d1 d2 FT0H104ZF FT0H224ZF FT0H474ZF FT0H105ZF FT0H225ZF FT0H335ZF FT0H565ZF FTW0H104ZF 11.5 14.5 16.5 21.5 28.5 36.5 44.5 11.5 8.5 12.0 13.0 13.0 14.0 15.0 17.0 8.5 5.08 5.08 5.08 7.62 10.16 15.00 20.00 5.08 2.7 2.2 2.7 3.0 6.1 6.1 6.1 2.7 0.4 0.4 0.4 0.6 0.6 0.6 1.0 0.4 1.2 1.2 1.2 1.2 1.4 1.7 1.4 1.2 (c) KEMET Electronics Corporation * P.O. Box 5928 * Greenville, SC 29606 * 864-963-6300 * www.kemet.com S6014_FT * 3/30/2017 2 Supercapacitors - FT Series Performance Characteristics Supercapacitors should not be used for applications such as ripple absorption because of their high internal resistance (several hundred m to a hundred ) compared to aluminum electrolytic capacitors. Thus, its main use would be similar to that of secondary battery such as power back-up in DC circuit. The following list shows the characteristics of supercapacitors as compared to aluminum electrolytic capacitors for power back-up and secondary batteries. Secondary Battery Capacitor NiCd Lithium Ion Aluminum Electrolytic Supercapacitor Back-up ability - - - - Eco-hazard Cd - - - -20 to +60C -20 to +50C -55 to +105C -40 to +85C (FR, FT) few hours few hours few seconds few seconds approximately 500 times approximately 500 to 1,000 times limitless (*1) limitless (*1) yes yes none none Flow Soldering not applicable not applicable applicable applicable Automatic Mounting not applicable not applicable applicable applicable (FM and FC series) leakage, explosion leakage, combustion, explosion, ignition heat-up, explosion gas emission (*2) Operating Temperature Range Charge Time Charge/Discharge Life Time Restrictions on Charge/Discharge Safety Risks (*1) Aluminum electrolytic capacitors and supercapacitors have limited lifetime. However, when used under proper conditions, both can operate within a predetermined lifetime. (*2) There is no harm as it is a mere leak of water vapor which transitioned from water contained in the electrolyte (diluted sulfuric acid). However, application of abnormal voltage surge exceeding maximum operating voltage may result in leakage and explosion. Typical Applications Intended Use (Guideline) Power Supply (Guideline) Back-up for 1 hour or less 50 mA and below Application Examples of Equipment Embedded memory backup DVD player, television, game console, set-top box Motor driver DVD player, printer, projector, camera Series FT series Environmental Compliance All KEMET supercapacitors are RoHS Compliant. RoHS Compliant (c) KEMET Electronics Corporation * P.O. Box 5928 * Greenville, SC 29606 * 864-963-6300 * www.kemet.com S6014_FT * 3/30/2017 3 Supercapacitors - FT Series Table 1 - Ratings & Part Number Reference Part Number Maximum Operating Voltage (VDC) Nominal Capacitance Charge System (F) Discharge System (F) Maximum ESR at 1 kHz () Maximum Current at 30 Minutes (mA) Weight (g) 1.6 FT0H104ZF 5.5 0.10 0.14 16 0.15 FT0H224ZF 5.5 0.22 0.28 10 0.33 4.1 FT0H474ZF 5.5 0.47 0.60 6.5 0.71 5.3 FT0H105ZF 5.5 1.0 1.3 3.5 1.5 10.0 FT0H225ZF 5.5 2.2 2.8 1.8 3.3 18.0 FT0H335ZF 5.5 3.3 4.2 1.0 5.0 38.0 FT0H565ZF 5.5 5.6 7.2 0.6 8.4 72.0 FTW0H104ZF 5.5 0.10 0.14 16 0.15 2.0 Part numbers in bold type represent popularly purchased components. (c) KEMET Electronics Corporation * P.O. Box 5928 * Greenville, SC 29606 * 864-963-6300 * www.kemet.com S6014_FT * 3/30/2017 4 Supercapacitors - FT Series Specifications Item FT Type Test Conditions (conforming to JIS C 5160-1) Category Temperature Range -40C to +85C Maximum Operating Voltage 5.5 VDC Capacitance Refer to Table 1 Refer to "Measurement Conditions" Capacitance Allowance +80%, -20% Refer to "Measurement Conditions" ESR Refer to Table 1 Measured at 1 kHz, 10 mA; See also "Measurement Conditions" Current (30 minutes value) Refer to Table 1 Refer to "Measurement Conditions" Capacitance > 90% of initial ratings ESR 120% of initial ratings Current (30 minutes value) 120% of initial ratings Appearance No obvious abnormality Surge voltage: Charge: Discharge: Number of cycles: Series resistance: Surge Capacitance ESR Capacitance ESR Characteristics in Different Temperature Phase 2 Phase 3 Capacitance ESR 50% of initial value 400% of initial value 30% of initial value 700% of initial value 200% of initial value Phase 5 Satisfy initial ratings Current (30 minutes value) 1.5 CV (mA) Capacitance Within 20% of initial value ESR Phase 6 Current (30 minutes value) Lead Strength (tensile) Vibration Resistance Satisfy initial ratings Conforms to 4.9 Satisfy initial ratings Conforms to 4.13 Frequency: Testing Time: 10 to 55 Hz 6 hours Conforms to 4.11 Solder temp: Dipping time: +2455C 50.5 seconds No obvious abnormality Over 3/4 of the terminal should be covered by the new solder Solderability +252C -252C -402C +252C +702C +252C No terminal damage Current (30 minutes value) Appearance Conforms to 4.17 Phase 1: Phase 2: Phase 3: Phase 4: Phase 5: Phase 6: 0 852C Satisfy initial ratings Capacitance ESR Discharge resistance: Temperature: 6.3 V 30 seconds 9 minutes 30 seconds 1,000 0.10 F 150 0.22 F 56 0.47 F 30 1.0 F 15 2.2 F 10 3.3 F 10 5.6 F 10 1.6 mm from the bottom should be dipped. Capacitance Solder Heat Resistance ESR Satisfy initial ratings Conforms to 4.10 Solder temp: Dipping time: No obvious abnormality 1.6 mm from the bottom should be dipped. Satisfy initial ratings Conforms to 4.12 Temperature Condition: Current (30 minutes value) Appearance Capacitance Temperature Cycle ESR Current (30 minutes value) Appearance No obvious abnormality (c) KEMET Electronics Corporation * P.O. Box 5928 * Greenville, SC 29606 * 864-963-6300 * www.kemet.com Number of cycles: +26010C 101 seconds -40C Room temperature +85C Room temperature 5 cycles S6014_FT * 3/30/2017 5 Supercapacitors - FT Series Specifications cont'd Item High Temperature and High Humidity Resistance High Temperature Load FT Type Capacitance Within 20% of initial value ESR 120% of initial ratings Current (30 minutes value) 120% of initial ratings Appearance No obvious abnormality Capacitance Within 30% of initial value ESR < 200% of initial ratings Current (30 minutes value) < 200% of initial ratings Appearance No obvious abnormality Test Conditions (conforming to JIS C 5160-1) Conforms to 4.14 Temperature: Relative humidity: Testing time: Conforms to 4.15 Temperature: Voltage applied: Series protection resistance: Testing time: +402C 90 to 95% RH 2408 hours +852C Maximum operating voltage 0 1,000+48 (+48/-0) hours Marking Date code Serial number A1 001 A1 Super Capacitor FT 5.5 V 85C 0.22 F FT 5.5 V 85C 0.22 F Maximum operating voltage Nominal capacitance Negative polarity identification mark (c) KEMET Electronics Corporation * P.O. Box 5928 * Greenville, SC 29606 * 864-963-6300 * www.kemet.com S6014_FT * 3/30/2017 6 Supercapacitors - FT Series Packaging Quantities Part Number Bulk Quantity per Box FT0H104ZF FT0H224ZF FT0H474ZF FT0H105ZF FT0H225ZF FT0H335ZF FT0H565ZF FTW0H104ZF 1,000 pieces 400 pieces 400 pieces 90 pieces 50 pieces 30 pieces 20 pieces 1,000 pieces List of Plating & Sleeve Type By changing the solder plating from leaded solder to lead-free solder and the outer tube material of can-cased conventional supercapacitor from polyvinyl chloride to polyethylene terephthalate (PET), our supercapacitor is now even friendlier to the environment. a. Iron + copper base + lead-free solder plating (Sn-1Cu) b. SUS nickel base + copper base + reflow lead-free solder plating (100% Sn, reflow processed) Series Part Number Plating Sleeve FT All FT Types a PET (Blue) Recommended Pb-free solder : Sn/3.5Ag/0.75Cu Sn/3.0Ag/0.5Cu Sn/0.7Cu Sn/2.5Ag/1.0Bi/0.5Cu (c) KEMET Electronics Corporation * P.O. Box 5928 * Greenville, SC 29606 * 864-963-6300 * www.kemet.com S6014_FT * 3/30/2017 7 Supercapacitors - FT Series Measurement Conditions Capacitance (Charge System) Capacitance is calculated from expression (9) by measuring the charge time constant () of the capacitor (C). Prior to measurement, the capacitor is discharged by shorting both pins of the device for at least 30 minutes. In addition, use the polarity indicator on the device to determine correct orientation of capacitor for charging. Capacitance: C= Rc Eo: 3.0 (V) Product with maximum operating voltage of 3.5 V 5.0 (V) Product with maximum operating voltage of 5.5 V 6.0 (V) Product with maximum operating voltage of 6.5 V 10.0 (V) Product with maximum operating voltage of 11 V 12.0 (V) Product with maximum operating voltage of 12 V : Time from start of charging until Vc becomes 0.632 Eo (V) (seconds) Rc: See table below (). (F) (9) Switch Rc Eo C + - Charge Resistor Selection Guide Cap 0.010 F 0.022 F 0.033 F 0.047 F 0.10 F FA FE FS FYD Vc FY FYH FYL FR FM, FME FMR, FML - - - - - 5,000 - 1,000 - 1,000 2,000 2,000 2,000 2,000 - - - - - - - 1,000 1,000 1,000 2,000 1,000 2,000 1,000 510 510 510 1,000 510 - 1,000 0.22 F 200 200 200 510 510 - 0.33 F 0.47 F 1.0 F 1.4 F 1.5 F 2.2 F 2.7 F 3.3 F 4.7 F 5.0 F 5.6 F 10.0 F 22.0 F 50.0 F 100.0 F 200.0 F - 100 51 - - - - - - - - - - - - - - - 200 200 100 100 200 - - - 100 - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - 100 51 - 51 - - - - - - - - - - - - 100 100 - - - - - - 100 - - - - - - FMC 5,000 - 2,000 - Discharge - 2000 1,000 1000 1,000 0H: Discharge 510 - 0V: 1000 - - Discharge 200 - - 100 - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - FG FGR FGH FT FC, FCS HV 5,000 - - 2,000 - - - - - 2,000 - - 1,000 Discharge 510 - Discharge - - Discharge - - - - - 1,000 Discharge 200 Discharge - - - - 1,000 Discharge 100 510 Discharge 100 - - - 510 - - 200 - 51 - - - - - 51 100 - - - - - - - 20 - - - - - - - - - - - - - - - - Discharge Discharge - - - - - - - - - - - - - - - Discharge - - - Discharge - Discharge - - Discharge Discharge Discharge Discharge Discharge *Capacitance values according to the constant current discharge method. *HV Series capacitance is measured by discharge system (c) KEMET Electronics Corporation * P.O. Box 5928 * Greenville, SC 29606 * 864-963-6300 * www.kemet.com S6014_FT * 3/30/2017 8 1.5F 2.2F 3.3F 4.7F 5.0F 5.6F - - - - - - 51 - - - - - - - - - 100 - - 100 - - - - - - - - - - - - - - - - - - - - - - - - - - - - *Capacitance values according to the constant current discharge method. Supercapacitors - FT Series *HV series capacitance is measured by discharge system. Measurement Conditions cont'd 510 200 - 100 - - - - - - - - - - - - - - - 51 51 - - 20 - - - - - - Table 3 Capacitance measurement Capacitance (Discharge System) System) Capacitance (Discharge As shown in the diagram below, charging is performed a duration 30 minutes the voltage the capacitor In Capacitance the diagram below, charging is performed for afor duration of 30ofminutes, onceonce the voltage of theofcondensor terminal (Discharge System:3.5V) terminalreaches reaches 5.55.5 V. V. Then, use a constant current load device and measure the time for the terminal voltage to drop In the diagram below, charging is performed for a duration of 30 minutes, once the voltage of the capacitor terminal reaches 3.5V. from 3.0 to 2.5 V aupon discharge atload 0.22device mA perand 0.22 F, for example, andthe calculate statictocapacitance according to the Then, use constant current measure the time for terminalthe voltage drop from 3.0 to 2.5 V upon Then, use a constant current load device and measure the time for the terminal voltage to drop from 1.8 to 1.5V upon equation shown below. discharge at 0.22 mA for 0.22 F, for example, and calculate the static capacitance according to the equation shown below. discharge at 1 mA per 1F, and calculate the static capacitance according to the equation shown below. Note: TheNote: current value is 1 mA discharged per 1 F. The current value is 1 mA discharged per 1F. Ix(T2T1)Ix(T2T1) C (F) CapactanceC V1V2 V1V2 (F) 3.5V 5.5V V (V) SW 0.22mA(I) A A C R C V R 3.5V 5.5V V1 V1 V2 Voltage SW V2 V1 : 1.8V V1 : 3.0V V2 : 1.5V V1 : 2.5V 30 min. T2 T1 Duration (sec.) T1 Time T2 (sec.) 30 minutes Capacitance (Discharge System - 3.5 V) Super Capacitors (Discharge Vol.13 Capacitance As 36 shown in the diagram below, charging isSystem:HVseries) performed for a duration of 30 minutes once the voltage of the capacitor Capacitance (Discharge System:3.5V) Capacitance (Discharge System:3.5V) Capacitance (Discharge System:3.5V) Capacitance (Discharge System:3.5V) In the diagram below, is current performed fordevice a duration 30 minutes, oncefor thethe voltage of the capacitor terminal terminal reaches 3.5 V. Then, use acharging constant load and of measure the time terminal voltage to drop fromreaches In the diagram below, charging is performed for a duration of 30 minutes, once the of voltage of the capacitor terminal reaches In the diagram below, charging is performed for a duration of 30 minutes, once the voltage the capacitor terminal reaches 3.5V. Max. operating voltage. In the diagram below, charging is performed for a duration of 30 minutes, once the voltage of the capacitor terminal In thedischarge diagram below, is performed for a duration of 30 minutes, oncecapacitance the voltage ofaccording the capacitor terminal reaches reaches 3.5V. 1.8 to 1.5 V upon at 1.0charging mA per 1.0 F, for example, and calculate the static to the equation Then, use a constant current load device and measure the time for the terminal voltage to drop from 1.8 to 1.5V Then, use a constant current load device and measure the time for the terminal voltage to drop from 1.8 to 1.5V upon aaconstant load device andand measure themeasure time the terminal to drop voltage from 2.0to to drop 1.5V upon discharge Then, use a current constant current load device and the time forvoltage the terminal 1.8 to 1.5V Then, use use constant current load device measure the for time for the terminal voltage to drop from 1.8from to 1.5V upon shown below.Then, discharge at 1 mA per 1F, and calculate the static capacitance according to the equation shown below. discharge at 1 per calculate the capacitance according to the shown at 1 mA per andat calculate the1F, static according to the equation below. discharge 1 1F, mAand per andcapacitance calculate static capacitance according to the equation shown below. discharge at1F, 1 mA mA per 1F, and calculate the static staticthe capacitance according toshown the equation equation shown below. below. SW SW T1) Ix(T T Ix(T222T 1)) 2 Ix(T 1 2T1) 1 C Ix(T C (F) C (F) C V V222 V V111V V V11V22 (F)3.5V (F)3.5V 3.5V V 3.5V V SW SW A A (V) (V) (V) A A C R C R CV C V 3.5V 3.5V 3.5V V11 V V1 2 V R V V22 R (V) (V) 3.5V 3.5V V1 V1 V2 V2 V11 :: 2.0V 1.8V V V1 : 1.8V V 2 : 1.5V V V22 :: 1.5V 1.5V T22 T11 T T T2 T1 30 minutes 30 minutes 30 30 minutes minutes 30 minutes V1 : 1.8V V1 : 1.8V V2 : 1.5V V2 : 1.5V Time (sec.) 1 T2 TTime (sec.) (sec.) Time (sec.) 1 T2 TTime Time (sec.) Capacitance (Discharge System:HVseries) Capacitance (Discharge System:HVseries) Capacitance (Discharge System -resistance HV Series) Equivalent series (ESR) Capacitance (Discharge System:HVseries) Capacitance (Discharge System:HVseries) In thebelow, diagram below, is charging is performed for a duration of 30 minutes, once the of voltage of the capacitor terminal re As shown in the diagram charging performed for a duration of 30 minutes, minutes once the voltage ofthe the capacitor In the diagram below, charging is performed for of once voltage terminal reaches ESR from the below. In be thecalculated diagram below, charging is performed for a duration of 30 minutes, the of voltage of the capacitor In theshall diagram below, charging is equation performed for a a duration duration of 30 30 minutes, once the theonce voltage the capacitor capacitor terminalterminal reachesre Max. operating voltage. terminal reaches operating voltage. Then, use a constant current load device and measure the time for the Max. operating voltage. Max. operating Max.maximum operating voltage. voltage. Then, use2.0 a constant current loadand device the time forcalculate the terminal voltage to drop from 2.0 to 1.5V upon disc Then, use a constant current device measure the for the terminal voltage drop 2.0 to upon discharge terminal voltage to drop from to 1.5 upon discharge atand 1.0measure mA per 1.0 and theto static capacitance according Then, use a constant current load device and measure the time for the terminal voltage to drop 2.0 to 1.5V upon disc Then, use a constant currentVload load device and measure the time time for F, the terminal voltage to drop from from 2.0from to 1.5V 1.5V upon discharge 10mA V at 1 mA per 1F, and calculate the static capacitance according to the equation shown below. C at 1 mA per 1F, and calculate the static capacitance according to the equation shown below. to the equation shown below. at 1 mA per 1F, and calculate the static capacitance according to the equation shown below. at 1 mA per 1F, and static capacitance according to the equation shown below. ESR () calculate the f:1kHz 0.01 C VC SW SW Ix(T Ix(T2T 1) 2T1) Ix(T Ix(T 2T 1) 2T1) C (F) Current (at after 3.5V V C (F) 3.5V charging) CV C30 Vminutes (F) C (F)2 3.5V 1V V SW SW A A C (V) (V) A A 3.5V 3.5V V1 V1 2 R V V2 (V) (V) 3.5V 3.5V V1 V1 V2 V2 V1 : 2.0V V1 : 2.0V V2 : 1.5V V2 : 1.5V V1 : 2.0V V1 : 2.0V V2 : 1.5V V2 : 1.5V C R R 3.5V C R V V V22 V1V2 V11V Current shall be calculated from the equation below. Prior to measurement, both lead terminals must be short-circuited for a minimum of 30T1minutes. Time (sec.) 1 T2 TTime (sec.) T2 T Time (sec.) 1 T2 Time (sec.) T2 T1 30of minutes The lead terminal connected to the metal can case is connected to the negative side the power supply. 30 minutes 30 minutes 30 minutes Equivalent series resistance Equivalent series resistance (ESR) Equivalent series (ESR) Equivalent resistance (ESR)(ESR) Eo 2.5Vdcseries (HVseries 50F) resistance ESR shall be calculated from the equation below.VR ESR shall be calculated from equation below. except 50F) ESR shall be calculated from the equation ESR 2.7Vdc shall be(HVseries calculated from the the equation below. below. SW 3.0Vdc (3.5V type) RC 10mA 10mA 5.0Vdc (5.5V Vtype) 10mA 10mA V C EO VCC () V C ESR C VC Rc 1000 (0.010F, 0.022F, 0.047F)f:1kHz ESR () C VC ESR f:1kHz C C ESR () VC 0.01 () f:1kHz f:1kHz C VC 0.01 0.01 0.01 100 (0.10F, 0.22F, 0.47F) 10 (1.0F, 1.5F, 2.2F, 4.7F) 2.2 (HVseries) Current (at 30 minutes after Current (at minutes after V*RP.O. (c) KEMET Electronics Corporation Box 5928 * Greenville, SC 29606 charging) * 864-963-6300 * www.kemet.com S6014_FT * 3/30/2017 Current (at 30 minutes after charging) Current (at 30 30 minutes after charging) charging) Current (A) Current shall be calculated from the equation below. R Current shall calculated from equation below. C shall be calculated the equation Current Current shall be be calculated from the thefrom equation below. below. Prior to measurement, both lead terminals must be short-circuited for a minimum of 30 minutes. Prior to measurement, both lead terminals must short-circuited for of Prior to measurement, both lead terminals be short-circuited for a minimum of 30 minutes. Prior to measurement, both lead terminals must be bemust short-circuited for a a minimum minimum of 30 30 minutes. minutes. 9 at 1 mA per 1F, and calculate the static capacitance according to the equation shown below. SW SW (V) A 3.5V series resistance (ESR) T1) Ix(T2Equivalent V1 (F) Ix(T2T1) C 3.5V C R V V V V2 1 2 ESR shall be calculated from the equation below. SupercapacitorsC - FT Series (F) 3.5V C R V V1V2 Measurement Conditions cont'd ESR VC A () 10mA f:1kHz 0.01 Equivalent series resistance (ESR) Equivalent Series Resistance (ESR) Equivalent series resistance (ESR) (V) T1 C minutes 30 VV11: 2.0V V2 : 1.5V VV22: 1.5V T1 T2 VC T2 30 minutes V1 : 2.0V 3.5V Time (sec.) 30 minutes T1 T2 Time (sec.) ESR shall bebelow. calculated from the equation below. ESR shall be calculated from the equation ESR shall be calculated from the equation below. Current (at 30 minutes after charging) 10mA ESR VC Current shall be calculated C from the equation below. ESR () 10mA f:1kHz VC 0.01 () both lead terminals must be short-circuited for a minimum of 30 minute f:1kHzPrior to measurement, C VC 0.01 The lead terminal connected to the metal can case is connected to the negative side of the po VC Current (at 30 minutes after charging) Current (at 30 minutes charging) V Current (atafter 30 minutes after charging) 2.7Vdc (HVseries except 50F) SW Current shall be below. calculated from the equation below. Current shall be calculated from the equation Prior to measurement, both lead terminals must be short-circuited for 3.0Vdc (3.5V type) Current shall be calculated from the equation below. to measurement, bothto lead must beisshort-circuited for a negative minimumside of 30ofminutes. a minimum ofPrior 30 minutes. ThePrior leadboth terminal connected theterminals metal connectedofto30 the the power R 5.0Vdc (5.5V type) can case to measurement, lead terminals must short-circuited for a minutes. The lead terminal connected tobethe metal can case is minimum connected supply. E to the negative side of the power supply. Rc 1000 (0.010F, 0.022F, 0.047F) C The lead terminal connected to the metal can case is connected to the negative side of the power supply. Eo2.5Vdc (HVseries 50F) R C O 100 (0.10F, 0.22F, 0.47F) Eo2.5Vdc (HVseries 50F) Eo: 2.5 VDC (HV Series 50 F) 10 (1.0F, 1.5F, 2.2F, 4.7F) VR Eo2.5Vdc (HVseries 50F) SW 2.7 VDC (HV Series except 50 F) 2.7Vdc (HVseries except 50F) 2.2 (HVseries) VR 2.7Vdc (HVseries except 50F) SW 3.0Vdc (3.5V type) 3.0 VDC (3.5 V type) VR RC 5.0 VDC (5.53.0Vdc V type) (3.5V type)5.0Vdc (5.5V type) Current (A) EO 5.0Vdc (5.5V type) RC0.047F) RC Rc: 1,000 (0.010 F, 0.022 F, 0.047 RcF) 1000 (0.010F, 0.022F, C EO 100 (0.10 F, 0.22 F, 0.47 F) Rc1000 (0.010F, 0.022F, C 100 0.047F) (0.10F, 0.22F, 0.47F) 10 (1.0 F, 1.5 F, 2.2(0.10F, F, 4.7 F)0.22F, 0.47F) 100 Self-discharge characteristic (0H: 5.5V products) 10 (1.0F, 1.5F, 2.2F, 4.7F) 2.2 (HV Series) 10 (1.0F, 1.5F, 2.2F, 2.24.7F) (HVseries) The self-discharge characteristic is measured by charging a voltage of 5.0 Vdc (charge protec 2.2 (HVseries) VRto the capacitor polarity for 24 hours, then releasing between the pins for 24 hours and measu Self-Discharge Characteristic (0H - 5.5 V Products) (A) VR Current RCThe test should be carried out in an environment with an ambient temperature of 25 or belo Current (A) is measured The self-discharge characteristic by charging a voltage of 5.0 VDC (charge protection resistance: 0 ) RC RH or below. according to the capacitor polarity for 24 hours, then releasing between the pins for 24 hours and measuring the pin-toSelf-discharge characteristic (0H: 5.5V products) pin voltage. The test should becharacteristic carried out in an environment an ambient temperature of 25 C or below and relative Self-discharge (0H: 5.5V with products) Su The self-discharge characteristic is measured by charging a voltage of 5.0 Vdc (charge protection resistance RH or below. humidity of 70% The self-dischargetocharacteristic measured by hours, charging a voltage of between 5.0 Vdc (charge resistance: 0) according the capacitorispolarity for 24 then releasing the pinsprotection for 24 hours and measuring the pin-tothe soldering checked.polarity for 24 hours, then releasing between the pins for 24 hours and measuring the pin-to-pin voltage. to theiscapacitor The test should be carried out in an environment with an ambient temperature of 25 or below and relative The test should beRH carried out in an environment with an ambient temperature of 25 or below and relative humidity of 70% or below. 4. Dismantling RH or below. There is a small amount of electrolyte stored within the capacitor. Do not attempt to dismantle as direct skin contactSuper with Capacito Capacitors 37 the electrolyte will cause burning. This product should be treated as industrial waste and not is not Super to be disposed of byVol.13 fire. (c) KEMET Electronics Corporation * P.O. Box 5928 * Greenville, SC 29606 * 864-963-6300 * www.kemet.com S6014_FT * 3/30/2017 10 Supercapacitors - FT Series Notes on Using Supercapacitors or Electric Double-Layer Capacitors (EDLCs) 1. Circuitry Design 1.1 Useful life The FC Series Supercapacitor (EDLC) uses an electrolyte in a sealed container. Water in the electrolyte can evaporate while in use over long periods of time at high temperatures, thus reducing electrostatic capacity which in turn will create greater internal resistance. The characteristics of the supercapacitor can vary greatly depending on the environment in which it is used. Basic breakdown mode is an open mode due to increased internal resistance. 1.2 Fail rate in the field Based on field data, the fail rate is calculated at approximately 0.006 Fit. We estimate that unreported failures are ten times this amount. Therefore, we assume that the fail rate is below 0.06 Fit. 1.3 Exceeding maximum usable voltage Performance may be compromised and in some cases leakage or damage may occur if applied voltage exceeds maximum working voltage. 1.4 Use of capacitor as a smoothing capacitor (ripple absorption) As supercapacitors contain a high level of internal resistance, they are not recommended for use as smoothing capacitors in electrical circuits. Performance may be compromised and, in some cases, leakage or damage may occur if a supercapacitor is used in ripple absorption. 1.5 Series connections As applied voltage balance to each supercapacitor is lost when used in series connection, excess voltage may be applied to some supercapacitors, which will not only negatively affect its performance but may also cause leakage and/or damage. Allow ample margin for maximum voltage or attach a circuit for applying equal voltage to each supercapacitor (partial pressure resistor/voltage divider) when using supercapacitors in series connection. Also, arrange supercapacitors so that the temperature between each capacitor will not vary. 1.6 Case Polarity The supercapacitor is manufactured so that the terminal on the outer case is negative (-). Align the (-) symbol during use. Even though discharging has been carried out prior to shipping, any residual electrical charge may negatively affect other parts. 1.7 Use next to heat emitters Useful life of the supercapacitor will be significantly affected if used near heat emitting items (coils, power transistors and posistors, etc.) where the supercapacitor itself may become heated. 1.8 Usage environment This device cannot be used in any acidic, alkaline or similar type of environment. (c) KEMET Electronics Corporation * P.O. Box 5928 * Greenville, SC 29606 * 864-963-6300 * www.kemet.com S6014_FT * 3/30/2017 11 Supercapacitors - FT Series Notes on Using Supercapacitors or Electric Double-Layer Capacitors (EDLCs) cont'd 2. Mounting 2.1 Mounting onto a reflow furnace Except for the FC series, it is not possible to mount this capacitor onto an IR / VPS reflow furnace. Do not immerse the capacitor into a soldering dip tank. 2.2 Flow soldering conditions See Recommended Reflow Curves in Section - Precautions for Use 2.3 Installation using a soldering iron Care must be taken to prevent the soldering iron from touching other parts when soldering. Keep the tip of the soldering iron under 400C and soldering time to within 3 seconds. Always make sure that the temperature of the tip is controlled. Internal capacitor resistance is likely to increase if the terminals are overheated. 2.4 Lead terminal processing Do not attempt to bend or polish the capacitor terminals with sand paper, etc. Soldering may not be possible if the metallic plating is removed from the top of the terminals. 2.5 Cleaning, Coating, and Potting Except for the FM series, cleaning, coating and potting must not be carried out. Consult KEMET if this type of procedure is necessary. Terminals should be dried at less than the maximum operating temperature after cleaning. 3. Storage 3.1 Temperature and humidity Make sure that the supercapacitor is stored according to the following conditions: Temperature: 5 - 35C (Standard 25C), Humidity: 20 - 70% (Standard: 50%). Do not allow the build up of condensation through sudden temperature change. 3.2 Environment conditions Make sure there are no corrosive gasses such as sulfur dioxide, as penetration of the lead terminals is possible. Always store this item in an area with low dust and dirt levels. Make sure that the packaging will not be deformed through heavy loading, movement and/or knocks. Keep out of direct sunlight and away from radiation, static electricity and magnetic fields. 3.3 Maximum storage period This item may be stored up to one year from the date of delivery if stored at the conditions stated above. (c) KEMET Electronics Corporation * P.O. Box 5928 * Greenville, SC 29606 * 864-963-6300 * www.kemet.com S6014_FT * 3/30/2017 12 Supercapacitors - FT Series KEMET Electronic Corporation Sales Offices For a complete list of our global sales offices, please visit www.kemet.com/sales. Disclaimer All product specifications, statements, information and data (collectively, the "Information") in this datasheet are subject to change. The customer is responsible for checking and verifying the extent to which the Information contained in this publication is applicable to an order at the time the order is placed. All Information given herein is believed to be accurate and reliable, but it is presented without guarantee, warranty, or responsibility of any kind, expressed or implied. Statements of suitability for certain applications are based on KEMET Electronics Corporation's ("KEMET") knowledge of typical operating conditions for such applications, but are not intended to constitute - and KEMET specifically disclaims - any warranty concerning suitability for a specific customer application or use. The Information is intended for use only by customers who have the requisite experience and capability to determine the correct products for their application. Any technical advice inferred from this Information or otherwise provided by KEMET with reference to the use of KEMET's products is given gratis, and KEMET assumes no obligation or liability for the advice given or results obtained. Although KEMET designs and manufactures its products to the most stringent quality and safety standards, given the current state of the art, isolated component failures may still occur. Accordingly, customer applications which require a high degree of reliability or safety should employ suitable designs or other safeguards (such as installation of protective circuitry or redundancies) in order to ensure that the failure of an electrical component does not result in a risk of personal injury or property damage. Although all product-related warnings, cautions and notes must be observed, the customer should not assume that all safety measures are indicted or that other measures may not be required. KEMET is a registered trademark of KEMET Electronics Corporation. (c) KEMET Electronics Corporation * P.O. Box 5928 * Greenville, SC 29606 * 864-963-6300 * www.kemet.com S6014_FT * 3/30/2017 13 Mouser Electronics Authorized Distributor Click to View Pricing, Inventory, Delivery & Lifecycle Information: KEMET: FT0H474ZF FTW0H104ZF FT0H104ZF FT0H105ZF FT0H224ZF FT0H335ZF FT0H565ZF FT0H225ZF