MULTILAYER CERAMIC CAPACITORS/AXIAL & RADIAL LEADED Multilayer ceramic capacitors are available in a variety of physical sizes and configurations, including leaded devices and surface mounted chips. Leaded styles include molded and conformally coated parts with axial and radial leads. However, the basic capacitor element is similar for all styles. It is called a chip and consists of formulated dielectric materials which have been cast into thin layers, interspersed with metal electrodes alternately exposed on opposite edges of the laminated structure. The entire structure is fired at high temperature to produce a monolithic block which provides high capacitance values in a small physical volume. After firing, conductive terminations are applied to opposite ends of the chip to make contact with the exposed electrodes. Termination materials and methods vary depending on the intended use. TEMPERATURE CHARACTERISTICS Ceramic dielectric materials can be formulated with Class III: General purpose capacitors, suitable a wide range of characteristics. The EIA standard for for by-pass coupling or other applications in which ceramic dielectric capacitors (RS-198) divides ceramic dielectric losses, high insulation resistance and dielectrics into the following classes: stability of capacitance characteristics are of little or no importance. Class III capacitors are similar to Class Class I: Temperature compensating capacitors, II capacitors except for temperature characteristics, suitable for resonant circuit application or other appliwhich are greater than ± 15%. Class III capacitors cations where high Q and stability of capacitance charhave the highest volumetric efficiency and poorest acteristics are required. Class I capacitors have stability of any type. predictable temperature coefficients and are not affected by voltage, frequency or time. They are made KEMET leaded ceramic capacitors are offered in from materials which are not ferro-electric, yielding the three most popular temperature characteristics: superior stability but low volumetric efficiency. Class I C0G: Class I, with a temperature coefficient of 0 ± capacitors are the most stable type available, but have 30 ppm per degree C over an operating the lowest volumetric efficiency. temperature range of - 55°C to + 125°C (Also known as “NP0”). Class II: Stable capacitors, suitable for bypass X7R: Class II, with a maximum capacitance or coupling applications or frequency discriminating change of ± 15% over an operating temperature circuits where Q and stability of capacitance charrange of - 55°C to + 125°C. acteristics are not of major importance. Class II Z5U: Class III, with a maximum capacitance capacitors have temperature characteristics of ± 15% change of + 22% - 56% over an operating temor less. They are made from materials which are perature range of + 10°C to + 85°C. ferro-electric, yielding higher volumetric efficiency but less stability. Class II capacitors are affected by Specified electrical limits for these three temperature temperature, voltage, frequency and time. characteristics are shown in Table 1. SPECIFIED ELECTRICAL LIMITS Temperature Characteristics Parameter Dissipation Factor: Measured at following conditions. C0G – 1 kHz and 1 vrms if capacitance >1000pF 1 MHz and 1 vrms if capacitance 1000 pF X7R – 1 kHz and 1 vrms* or if extended cap range 0.5 vrms Z5U – 1 kHz and 0.5 vrms C0G X7R Z5U 0.10% 2.5% (3.5% @ 25V) 4.0% Dielectric Stength: 2.5 times rated DC voltage. Pass Subsequent IR Test Insulation Resistance (IR): At rated DC voltage, whichever of the two is smaller 1,000 M F or 100 G 1,000 M F or 100 G Temperature Characteristics: Range, °C Capacitance Change without DC voltage -55 to +125 0 ± 30 ppm/°C -55 to +125 ± 15% * MHz and 1 vrms if capacitance 1,000 M or 10 G 100 pF on military product. Table I 4 © KEMET Electronics Corporation, P.O. Box 5928, Greenville, S.C. 29606, (864) 963-6300 F + 10 to +85 +22%,-56% APPLICATION NOTES FOR MULTILAYER CERAMIC CAPACITORS Polarity: Multilayer ceramic capacitors are not polar, and may be used with DC voltage applied in either direction. Rated Voltage: This term refers to the maximum continuous DC working voltage permissible across the entire operating temperature range. Multilayer ceramic capacitors are not extremely sensitive to voltage, and brief applications of voltage above rated will not result in immediate failure. However, reliability will be reduced by exposure to sustained voltages above rated. Capacitance: The standard unit of capacitance is the farad. For practical capacitors, it is usually expressed in microfarads (10-6 farad), nanofarads (10-9 farad), or picofarads (10-12 farad). Standard measurement conditions are as follows: Class I (up to 1,000 pF): 1MHz and 1.2 VRMS maximum. Class I (over 1,000 pF): 1kHz and 1.2 VRMS maximum. Class II: 1 kHz and 1.0 ± 0.2 VRMS. Class III: 1 kHz and 0.5 ± 0.1 VRMS. Like all other practical capacitors, multilayer ceramic capacitors also have resistance and inductance. A simplified schematic for the equivalent circuit is shown in Figure 1. Other significant electrical characteristics resulting from these additional properties are as follows: R P Figure 1 R S L C C = Capacitance L = Inductance R = Equivalent Series Resistance (ESR) S R = Insulation Resistance (IR) P Impedance: Since the parallel resistance (Rp) is normally very high, the total impedance of the capacitor is: Z= Where 2 RS + (XC - XL) 2 Z = Total Impedance RS = Equivalent Series Resistance XC = Capacitive Reactance = 1 2π πfC XL = Inductive Reactance = 2π πfL The variation of a capacitor’s impedance with frequency determines its effectiveness in many applications. Application Notes ELECTRICAL CHARACTERISTICS The fundamental electrical properties of multilayer ceramic capacitors are as follows: Dissipation Factor: Dissipation Factor (DF) is a measure of the losses in a capacitor under AC application. It is the ratio of the equivalent series resistance to the capacitive reactance, and is usually expressed in percent. It is usually measured simultaneously with capacitance, and under the same conditions. The vector diagram in Figure 2 illustrates the relationship between DF, ESR, and impedance. The reciprocal of the dissipation factor is called the “Q”, or quality factor. For convenience, the “Q” factor is often used for very low values of dissipation factor. DF is sometimes called the “loss tangent” or “tangent d”, as derived from this diagram. ESR Figure 2 O DF = ESR Xc δ X c Ζ 1 Xc = 2πfC Insulation Resistance: Insulation Resistance (IR) is the DC resistance measured across the terminals of a capacitor, represented by the parallel resistance (Rp) shown in Figure 1. For a given dielectric type, electrode area increases with capacitance, resulting in a decrease in the insulation resistance. Consequently, insulation resistance is usually specified as the “RC” (IR x C) product, in terms of ohm-farads or megohm-microfarads. The insulation resistance for a specific capacitance value is determined by dividing this product by the capacitance. However, as the nominal capacitance values become small, the insulation resistance calculated from the RC product reaches values which are impractical. Consequently, IR specifications usually include both a minimum RC product and a maximum limit on the IR calculated from that value. For example, a typical IR specification might read “1,000 megohm-microfarads or 100 gigohms, whichever is less.” Insulation Resistance is the measure of a capacitor to resist the flow of DC leakage current. It is sometimes referred to as “leakage resistance.” The DC leakage current may be calculated by dividing the applied voltage by the insulation resistance (Ohm’s Law). Dielectric Withstanding Voltage: Dielectric withstanding voltage (DWV) is the peak voltage which a capacitor is designed to withstand for short periods of time without damage. All KEMET multilayer ceramic capacitors will withstand a test voltage of 2.5 x the rated voltage for 60 seconds. KEMET specification limits for these characteristics at standard measurement conditions are shown in Table 1 on page 4. Variations in these properties caused by changing conditions of temperature, voltage, frequency, and time are covered in the following sections. © KEMET Electronics Corporation, P.O. Box 5928, Greenville, S.C. 29606, (864) 963-6300 5 APPLICATION NOTES FOR MULTILAYER CERAMIC CAPACITORS TABLE 1 EIA TEMPERATURE CHARACTERISTIC CODES FOR CLASS I DIELECTRICS Significant Figure of Temperature Coefficient Multiplier Applied to Temperature Coefficient Tolerance of Temperature Coefficient * PPM per Degree C Letter Symbol Multiplier Number Symbol PPM per Degree C Letter Symbol 0.0 0.3 0.9 1.0 1.5 2.2 3.3 4.7 7.5 C B A M P R S T U -1 -10 -100 -1000 -100000 +1 +10 +100 +1000 +10000 0 1 2 3 4 5 6 7 8 9 ±30 ±60 ±120 ±250 ±500 ±1000 ±2500 G H J K L M N * These symetrical tolerances apply to a two-point measurement of temperature coefficient: one at 25°C and one at 85°C. Some deviation is permitted at lower temperatures. For example, the PPM tolerance for C0G at -55°C is +30 / -72 PPM. TABLE 2 EIA TEMPERATURE CHARACTERISTIC CODES FOR CLASS II & III DIELECTRICS 6 Low Temperature Rating High Temperature Maximum Capacitance Rating Shift Degree Celcius Letter Symbol Degree Celcius Number Symbol +10C -30C -55C Z Y X +45C +65C +85C +105C +125C +150C +200C 2 4 5 6 7 8 9 Percent ±1.0% ±1.5% ±2.2% ±3.3% ±4.7% ±7.5% ±10.0% ±15.0% ±22.0% +22 / -33% +22 / -56% +22 / -82% Letter Symbol A B C D E F P R S T U V +10 +20 +30 +40 +50 +60 +70 © KEMET Electronics Corporation, P.O. Box 5928, Greenville, S.C. 29606, (864) 963-6300 +80 APPLICATION NOTES FOR MULTILAYER CERAMIC CAPACITORS Application Notes At higher AC voltages, both capacitance and dissipation factor begin to decrease. Typical curves showing the effect of applied AC and DC voltage are shown in Figure 6 for KEMET X7R capacitors and Figure 7 for KEMET Z5U capacitors. Effect of Frequency: Frequency affects both capacitance and dissipation factor. Typical curves for KEMET multilayer ceramic capacitors are shown in Figures 8 and 9. The variation of impedance with frequency is an important consideration in the application of multilayer ceramic capacitors. Total impedance of the capacitor is the vector of the capacitive reactance, the inductive reactance, and the ESR, as illustrated in Figure 2. As frequency increases, the capacitive reactance decreases. However, the series inductance (L) shown in Figure 1 produces inductive reactance, which increases with frequency. At some frequency, the impedance ceases to be capacitive and becomes inductive. This point, at the bottom of the V-shaped impedance versus frequency curves, is the self-resonant frequency. At the self-resonant frequency, the reactance is zero, and the impedance consists of the ESR only. Typical impedance versus frequency curves for KEMET multilayer ceramic capacitors are shown in Figures 10, 11, and 12. These curves apply to KEMET capacitors in chip form, without leads. Lead configuration and lead length have a significant impact on the series inductance. The lead inductance is approximately 10nH/inch, which is large compared to the inductance of the chip. The effect of this additional inductance is a decrease in the self-resonant frequency, and an increase in impedance in the inductive region above the self-resonant frequency. Effect of Time: The capacitance of Class II and III dielectrics change with time as well as with temperature, voltage and frequency. This change with time is known as “aging.” It is caused by gradual realignment of the crystalline structure of the ceramic dielectric material as it is cooled below its Curie temperature, which produces a loss of capacitance with time. The aging process is predictable and follows a logarithmic decay. Typical aging rates for C0G, X7R, and Z5U dielectrics are as follows: C0G X7R Z5U Effect of Temperature: Both capacitance and dissipation factor are affected by variations in temperature. The maximum capacitance change with temperature is defined by the temperature characteristic. However, this only defines a “box” bounded by the upper and lower operating temperatures and the minimum and maximum capacitance values. Within this “box”, the variation with temperature depends upon the specific dielectric formulation. Typical curves for KEMET capacitors are shown in Figures 3, 4, and 5. These figures also include the typical change in dissipation factor for KEMET capacitors. Insulation resistance decreases with temperature. Typically, the insulation resistance at maximum rated temperature is 10% of the 25°C value. Effect of Voltage: Class I ceramic capacitors are not affected by variations in applied AC or DC voltages. For Class II and III ceramic capacitors, variations in voltage affect only the capacitance and dissipation factor. The application of DC voltage higher than 5 vdc reduces both the capacitance and dissipation factor. The application of AC voltages up to 10-20 Vac tends to increase both capacitance and dissipation factor. None 2.0% per decade of time 5.0% per decade of time Typical aging curves for X7R and Z5U dielectrics are shown in Figure 13. The aging process is reversible. If the capacitor is heated to a temperature above its Curie point for some period of time, de-aging will occur and the capacitor will regain the capacitance lost during the aging process. The amount of deaging depends on both the elevated temperature and the length of time at that temperature. Exposure to 150°C for onehalf hour or 125°C for two hours is usually sufficient to return the capacitor to its initial value. Because the capacitance changes rapidly immediately after de-aging, capacitance measurements are usually delayed for at least 10 hours after the de-aging process, which is often referred to as the “last heat.” In addition, manufacturers utilize the aging rates to set factory test limits which will bring the capacitance within the specified tolerance at some future time, to allow for customer receipt and use. Typically, the test limits are adjusted so that the capacitance will be within the specified tolerance after either 1,000 hours or 100 days, depending on the manufacturer and the product type. © KEMET Electronics Corporation, P.O. Box 5928, Greenville, S.C. 29606, (864) 963-6300 7 APPLICATION NOTES FOR MULTILAYER CERAMIC CAPACITORS POWER DISSIPATION Power dissipation has been empirically determined for two representative KEMET series: C052 and C062. Power dissipation capability for various mounting configurations is shown in Table 3. This table was extracted from Engineering Bulletin F-2013, which provides a more detailed treatment of this subject. Note that no significant difference was detected between the two sizes in spite of a 2 to 1 surface area ratio. Due to the materials used in the construction of multilayer ceramic capacitors, the power dissipation capability does not depend greatly on the surface area of the capacitor body, but rather on how well heat is conducted out of the capacitor lead wires. Consequently, this power dissipation capability is applicable to other leaded multilayer styles and sizes. TABLE 3 POWER DISSIPATION CAPABILITY (Rise in Celsius degrees per Watt) Mounting Configuration Power Dissipation of C052 & C062 1.00" leadwires attached to binding post of GR-1615 bridge (excellent heat sink) 90 Celsius degrees rise per Watt ±10% 0.25" leadwires attached to binding post of GR-1615 bridge 55 Celsius degrees rise per Watt ±10% Capacitor mounted flush to 0.062" glassepoxy circuit board with small copper traces 77 Celsius degrees rise per Watt ±10% Capacitor mounted flush to 0.062" glassepoxy circuit board with four square inches of copper land area as a heat sink 53 Celsius degrees rise per Watt ±10% As shown in Table 3, the power dissipation capability of the capacitor is very sensitive to the details of its use environment. The temperature rise due to power dissipation should not exceed 20°C. Using that constraint, the maximum permissible power dissipation may be calculated from the data provided in Table 3. It is often convenient to translate power dissipation capability into a permissible AC voltage rating. Assuming a sinusoidal wave form, the RMS “ripple voltage” may be calculated from the following formula: E=Zx Where PMAX R RELIABILITY A well constructed multilayer ceramic capacitor is extremely reliable and, for all practical purposes, has an infinite life span when used within the maximum voltage and temperature ratings. Capacitor failure may be induced by sustained operation at voltages that exceed the rated DC voltage, voltage spikes or transients that exceed the dielectric withstanding voltage, sustained operation at temperatures above the maximum rated temperature, or the excessive temperature rise due to power dissipation. Failure rate is usually expressed in terms of percent per 1,000 hours or in FITS (failure per billion hours). Some KEMET series are qualified under U.S. military established reliability specifications MIL-PRF-20, MIL-PRF-123, MILPRF-39014, and MIL-PRF-55681. Failure rates as low as 0.001% per 1,000 hours are available for all capacitance / voltage ratings covered by these specifications. These specifications and accompanying Qualified Products List should be consulted for details. For series not covered by these military specifications, an internal testing program is maintained by KEMET Quality Assurance. Samples from each week’s production are subjected to a 2,000 hour accelerated life test at 2 x rated voltage and maximum rated temperature. Based on the results of these tests, the average failure rate for all non-military series covered by this test program is currently 0.06% per 1,000 hours at maximum rated conditions. The failure rate would be much lower at typical use conditions. For example, using MILHDBK-217D this failure rate translates to 0.9 FITS at 50% rated voltage and 50°C. Current failure rate details for specific KEMET multilayer ceramic capacitor series are available on request. MISAPPLICATION Ceramic capacitors, like any other capacitors, may fail if they are misapplied. Typical misapplications include exposure to excessive voltage, current or temperature. If the dielectric layer of the capacitor is damaged by misapplication the electrical energy of the circuit can be released as heat, which may damage the circuit board and other components as well. If potential for misapplication exists, it is recommended that precautions be taken to protect personnel and equipment during initial application of voltage. Commonly used precautions include shielding of personnel and sensing for excessive power drain during board testing. E = RMS Ripple Voltage (volts) P = Power Dissipation (watts) Z = Impedance R = ESR The data necessary to make this calculation is included in Engineering Bulletin F-2013. However, the following criteria must be observed: 1. The temperature rise due to power dissipation should be limited to 20°C. 2. The peak AC voltage plus the DC voltage must not exceed the maximum working voltage of the capacitor. Provided that these criteria are met, multilayer ceramic 8 capacitors may be operated with AC voltage applied without need for DC bias. STORAGE AND HANDLING Ceramic chip capacitors should be stored in normal working environments. While the chips themselves are quite robust in other environments, solderability will be degraded by exposure to high temperatures, high humidity, corrosive atmospheres, and long term storage. In addition, packaging materials will be degraded by high temperature – reels may soften or warp, and tape peel force may increase. KEMET recommends that maximum storage temperature not exceed 40˚ C, and maximum storage humidity not exceed 70% relative humidity. In addition, temperature fluctuations should be minimized to avoid condensation on the parts, and atmospheres should be free of chlorine and sulfur bearing compounds. For optimized solderability, chip stock should be used promptly, preferably within 1.5 years of receipt. © KEMET Electronics Corporation, P.O. Box 5928, Greenville, S.C. 29606, (864) 963-6300 APPLICATION NOTES FOR MULTILAYER CERAMIC CAPACITORS IMPEDANCE VS FREQUENCY 0.20 100 Impedance vs. Frequency Ceramic C0G Leaded .001μF %ΔC 0.10 %DF .01μF 100 %DF -0.2 100 Figure 8. 1K 10K 100K 1M 0.0 10M Frequency - Hertz Capacitance & DF vs Frequency - C0G Impedance (Ohms) 10 10. Figure 10. Figure -0.1 Impedance (Ohms) %ΔC +0.1 0 Application Notes EFFECT OF FREQUENCY +0.2 vs Frequency ImpedanceImpedance vs Frequency for C0G Dielectric for C0G Dielectric 10 1 0.001µF 1 0.1 10. Figure 10. Figure 0.1 vs Frequency vs 0.01µF Frequency ImpedanceImpedance for C0G Dielectric for C0G Dielectric 0.01 0.01 0.1 1 1 0 100 1000 Frequency - MHz 5.0 -10 2.5 -15 0.0 10M 100 1K 10K 100K 1M Figure 9. Frequency - Hertz Capacitance & DF vs Frequency - X7R & Z5U Figure 10. Frequency - MHz Impedance Impedance vs Frequency for C0G Dielectric vs. Frequency Leaded X7R 100 100 Impedance (Ohms) %ΔC %ΔC -5 1,000 7.5 Impedance (Ohms) %DF 0 Impedance vs Frequency Figure 10. Figure 10. Impedance vs Frequency 10.0 0.001 for C0G Dielectric for 0.1 1 C0G Dielectric 10 100 %DF +5 0.1μF 10 10 0.01µF .01μF 0.1µF 1.0 μF 1 1.0µF Impedance 11. Impedance vs Frequency Figure 11. Figure vs Frequency 1 0.1 for X7R Dielectric for X7R Dielectric EFFECT OF TIME (hours) 0.1 1 10 100 1000 Frequency - MHz vs Frequency Figure 11. Figure 11. ImpedanceImpedance vs Frequency 0.01 for X7R Dielectric for X7R Dielectric X7R X7R Capacitance Capacitance 0.001 0.1 1 Impedance vs. 10 Frequency 100 1,000 Z5U Z5U Impedance (Ohms) Leaded Z5U Figure Impedance vs Frequency Figure 11.Figure vs Frequency 11.11.ImpedanceFrequency - MHz for X7Rfor Dielectric for X7R Dielectric 100 Impedance vs Frequency X7R Dielectric 10 100 10 10 100 100 1000 1000 10K 10K Figure 13. Typical Aging Rates for X7R & Z5U 100K 100K Impedance (Ohms) 100% 100% 98% 98% 96% 96% 94% 94% 92% 92% 90% 90% 88% 88% 86% 86% 84% 84% 82% 82% 80% 80% 78% 78% 76% 76% 74% 74% 11 0.01 0.1 0.1µF 1 0.1μF 1.0µF 10 0.1 1.0 μF 0.01 1 0.1 1 1 0 100 1000 Frequency - MHz vs Frequency Figure 12. Figure 12. ImpedanceImpedance vs Frequency for Z5U Dielectric for Z5U Dielectric 0.1 0.01 vs Frequency Figure 12. Figure 12. ImpedanceImpedance vs Frequency for Z5U Dielectric for Z5U Dielectric 0.001 0.1 1 10 100 1,000 Figure 12. Frequency - MHz Impedance vs Frequency for Z5U Dielectric Impedance vs Frequency Figure 12. Figure 12.Impedance vs Frequency for Z5U Dielectric for Z5U Dielectric © KEMET Electronics Corporation, P.O. Box 5928, Greenville, S.C. 29606, (864) 963-6300 9 MIL-STD-202, Method 208, Sn62 solder, 245 C for 5 ±1/2 seconds. CERAMIC MOLDED AXIAL & RADIAL Terminal Strength: PERFORMANCE CHARACTERISTICS EIA-198 Method 303, Condition A (2.2 kg) GENERAL SPECIFICATIONS Working Voltage: C0G – 50, 100, 200 X7R – 50, 100, 200 Temperature Characteristics: C0G 0 ±30 PPM / °C from -55°C to +125°C X7R ± 15% from -55°C to +125°C Capacitance Tolerance: C0G ±0.5pF, ±1%, ±2%, ±5%, ±10%, ±20% (±0.5pF is tightest tolerance available) X7R ±10%, ±20%, -0 +100%, +80% / -20% Construction: Monolithic block of ceramic dielectric with Interdigitated internal electrodes, encapsulated in a molded case, and having axial or radial leads. Meets flame test requirements of UL Standard 94V-0. ELECTRICAL Capacitance: Within specified tolerance and when measured with 1 volt rms at 1kHz (1000 pF or less at 1 MHz for C0G). Dissipation Factor @25°C: 25°C at 1kHz (1000 pF or less at 1 MHz for C0G). C0G – 0.15% maximum X7R – 2.5% maximum Insulation Resistance: After 2 minutes electrification at 25°C and rated voltage C0G – 100K M or 1000 M – F, whichever is less. X7R – 100K M or 1000 M – F, whichever is less. Dielectric Withstanding Voltage: 250% of rated voltage for 5 seconds with current limited to 50 mA at 25°C. Lead Material: Axial: Solder coated copper clad steel Radial: Solder-coated copper standard (100% tin plated optional) Solderability: MIL-STD-202, Method 208, Sn62 solder, 245°C for 5 ±1/2 seconds. Terminal Strength: EIA-198 Method 303, Condition A (2.2 kg) ELECTRICAL Capacitance: Within specified tolerance and when measured with 1 volt rms at 1kHz (1000 pF or less at 1 MHz for C0G). Dissipation Factor @25°C: 25°C at 1kHz (1000 pF or less at 1 MHz for C0G). C0G – 0.15% maximum X7R – 2.5% maximum Ceramic Molded Axial/Radial - Standard Insulation Resistance: After 2 minutes electrification at 25°C and rated voltage C0G – 100K M or 1000 M – F, whichever is less. X7R – 100K M or 1000 M – F, whichever is less. Dielectric Withstanding Voltage: 250% of rated voltage for 5 seconds with current limited to 50 mA at 25°C. © KEMET Electronics Corporation, P.O. Box 5928, Greenville, S.C. 29606, (864) 963-6300 27 CERAMIC MOLDED/AXIAL & RADIAL - STANDARD CAPACITOR (AXIALLEADS) LEADS) CAPACITOR OUTLINE DRAWINGS — - (AXIAL L 1.50 Min. (38.10) D 1.50 Min. (38.10) C DIMENSIONS — INCHES (MILLIMETERS) Case Size Military Equivalent Styles L Length D Body diameter C Lead Diameter C114 CC75, CCR75 CK12, CKR11 .160 ± .010 (4.06 ± .25) .090 ± .010 (2.29 ± .25) .020, +.000, -.003 (.51, +.00, -.08) C124 CC76, CCR76 CK13, CKR12 .250 ± .010 (6.35 ± .25) .090 ± .010 (2.29 ± .25) .020, +.000, -.003 (.51, +.00, -.08) C192 CC77, CCR77 CK14, CKR14 .390 ± .010 (9.91 ± .25) .140 ± .010 (3.56 ± .25) .025, +.004, -.001 (.64, +.10, -.025) C202 CC78, CCR78 CK15, CKR15 .500 ± .020 (12.70 ± .51) .250 ± .015 (6.35 ± .38) .025, +.004, -.001 (.64, +.10, -.025) C222 CC79, CCR79 CK16, CKR16 .690 ± .030 (17.53 ± .76) .350 ± .020 (8.89 ± .51) .025, +.004, -.001 (.64, +.10, -.025) CAPACITOR OUTLINE DRAWINGS — (RADIAL LEADS) CAPACITOR OUTLINE DRAWINGS - (RADIAL LEADS) C052 L W H 1.25 Min. Lead Dia. .025 (+.004 -.002) C062, C512, C522 .045 Max. L H 1.25 Min. Center Line of leads within .030" of Center Line of case. S W Lead Dia. .025 (+.004 -.002) S DIMENSIONS — INCHES (MILLIMETERS) Case Size C052 Military Equivalent Styles CC05, CCR05 CK05, CKR05 C062 CC06, CCR06 CK06, CKR06 C522 CC08, CCR08 C512 CC07, CCR07 S Lead Spacing H Height L Length W Width .190 ± .010 (4.83 ± .25) .190 ± .010 (4.83 ± .25) .090 ± .010 (2.29 ± .25) .200 ± .015 (5.08 ± .38) .290 ± .010 (7.37 ± .25) .290 ± .010 (7.37 ± .25) .090 ± .010 (2.29 ± .25) .200 ± .015 (5.08 ± .38) .480 ± .020 (12.19 ± .51) .240 ± .010 (6.10 ± .25) .480 ± .020 (12.19 ± .51) .480 ± .020 (12.19 ± .51) .480 ± .020 (12.19 ± .51) .140 ± .010 (3.56 ± .25) .400 ± .020 (10.16 ± .51) .400 ± .020 (10.16 ± .51) For packaging information, see pages 46, 47 and 48. 28 © KEMET Electronics Corporation, P.O. Box 5928, Greenville, S.C. 29606, (864) 963-6300 CERAMIC MOLDED/AXIAL & RADIAL - STANDARD C 052 C CERAMIC CASE SIZE See Table Below ORDERING INFORMATION 102 K 2 R 5 SPECIFICATION C – Standard CAPACITANCE PICOFARAD CODE Expressed in picofarads (pF). First two digits represent significant figures. Third digit specifies number of zeros following except 9 indicates division by 10). Examples: 0.1 µF = 100,000 pF = 104 and 9.1 pF = 919. See tables for standard values. CAPACITANCE Standard M – ±20% K – ±10% J – ±5% Axial C114 C124 C192 C202 C222 FAILURE RATE A – Not Applicable LEAD MATERIAL C – 60/40 Tin/Lead (SnPb) T – 100% Tin (Sn)(C052, C062 only) INTERNAL CONSTRUCTION 5 – Multilayer KEMET EIA Designator Equivalent TOLERANCE Others H – ±3% G – ±2% F – ±1% D – ±.5pF Case Sizes A TEMPERATURE CHARACTERISTIC G (Ultra Stable) R (Stable) Standard tolerances for each Series are shown in the repetitive parts lists. Radial C052 C062 C512 C522 T C0G (NP0) X7R Cap. Change with Temp. Measured Temp without DC Range, °C Bias Voltage -55 to ±30 +125° ppm/°C -55° to +125 ±15% WORKING VOLTAGE (DC) 2 – 200V; 1 – 100V; 5 – 50V Part Number Example: C052C102K2R5TA (14 digits – no spaces) AXIAL CAPACITOR MARKING STANDARD C114C, C124C, C192C, C202C & C222C KC0G 101J 200V 0812 KEMET, Temperature Characteristic Capacitance, Capacitance Tolerance Voltage Date Code RADIAL CAPACITOR MARKING C052C & C062C STANDARD MARKING C062 X7R 104K BACK 100V K 0811 Voltage KEMET Date Code Ceramic Molded Axial/Radial - Standard FRONT Style Temperature Characteristic Capacitance, Capacitance Tolerance C512 & C522 STANDARD MARKING KEMET C512X7R 105K 50V 0832 KEMET SIZE and Temperature Characteristic Capacitance, Capacitance Tolerance, Voltage Date Code © KEMET Electronics Corporation, P.O. Box 5928, Greenville, S.C. 29606, (864) 963-6300 29 CERAMIC MOLDED/RADIAL – STANDARD ULTRA-STABLE TEMPERATURE CHARACTERISTIC—C0G (NP0) RATINGS & PART NUMBER REFERENCE CAPACITANCE pF KEMET PART NUMBER CAPACITANCE pF 200 VOLT – C114 STANDARD C0G 1.0 C114C109(1)2G5CA 1.5 C114C159(1)2G5CA 2.2 C114C229(1)2G5CA 2.7 C114C279(1)2G5CA 3.3 C114C339(1)2G5CA 3.9 C114C399(1)2G5CA 4.7 C114C479(1)2G5CA 5.6 C114C569(1)2G5CA 6.8 C114C689(1)2G5CA 8.2 C114C829(1)2G5CA 10.0 C114C100(2)2G5CA 12.0 C114C120(2)2G5CA 15.0 C114C150(2)2G5CA 18.0 C114C180(2)2G5CA 22.0 C114C220(2)2G5CA 27.0 C114C270(3)2G5CA 33.0 C114C330(3)2G5CA 39.0 C114C390(3)2G5CA 47.0 C114C470(3)2G5CA 56.0 C114C560(4)2G5CA 68.0 C114C680(4)2G5CA 82.0 C114C820(4)2G5CA 100.0 C114C101(4)2G5CA 120.0 C114C121(4)2G5CA 150.0 C114C151(4)2G5CA 180.0 C114C181(4)2G5CA 220.0 C114C221(4)2G5CA 270.0 C114C271(4)2G5CA 330.0 C114C331(4)2G5CA 100 VOLT – C114 STANDARD C0G 82.0 C114C820(4)1G5CA 100.0 C114C101(4)1G5CA 120.0 C114C121(4)1G5CA 150.0 C114C151(4)1G5CA 180.0 C114C181(4)1G5CA 220.0 C114C221(4)1G5CA 270.0 C114C271(4)1G5CA 330.0 C114C331(4)1G5CA 390.0 C114C391(4)1G5CA 470.0 C114C471(4)1G5CA 560.0 C114C561(4)1G5CA 680.0 C114C681(4)1G5CA KEMET PART NUMBER CAPACITANCE pF 200 VOLT – C124 STANDARD C0G 390.0 C124C391(4)2G5CA 470.0 C124C471(4)2G5CA 560.0 C124C561(4)2G5CA 200 VOLT – C202 STANDARD C0G 5,600.0 C202C562(4)2G5CA 6,800.0 C202C682(4)2G5CA 8,200.0 C202C822(4)2G5CA 10,000.0 C202C103(4)2G5CA 12,000.0 C202C123(4)2G5CA 15,000.0 C202C153(4)2G5CA 18,000.0 C202C183(4)2G5CA 22000.0 C202C223(4)2G5CA 100 VOLT – C124 STANDARD C0G 820.0 C124C821(4)1G5CA 1,000.0 C124C102(4)1G5CA 200 VOLT – C192 STANDARD C0G 680.0 C192C681(4)2G5CA 820.0 C192C821(4)2G5CA 1,000.0 C192C102(4)2G5CA 1,200.0 C192C122(4)2G5CA 1,500.0 C192C152(4)2G5CA 1,800.0 C192C182(4)2G5CA 2,200.0 C192C222(4)2G5CA 2,700.0 C192C272(4)2G5CA 3,300.0 C114C332(4)2G5CA 3,900.0 C114C392(4)2G5CA 4,700.0 C114C472(4)2G5CA 100 VOLT – C192 STANDARD C0G 1,200.0 C114C122(4)1G5CA 1,500.0 C114C152(4)1G5CA 1,800.0 C114C182(4)1G5CA 2,200.0 C114C222(4)1G5CA 2,700.0 C114C272(4)1G5CA 3,300.0 C114C332(4)1G5CA 3,900.0 C114C392(4)1G5CA 4,700.0 C114C472(4)1G5CA 5,600.0 C114C562(4)1G5CA 6,800.0 C114C682(4)1G5CA 8,200.0 C114C822(4)1G5CA 100 VOLT – C202 STANDARD C0G 10,000.0 C202C103(4)1G5CA 12,000.0 C202C123(4)1G5CA 15,000.0 C202C153(4)1G5CA 18,000.0 C202C183(4)1G5CA 22,000.0 C202C223(4)1G5CA 27,000.0 C202C273(4)1G5CA 33,000.0 C202C333(4)1G5CA 200 VOLT – C222 STANDARD C0G 27,000.0 C222C273(4)2G5CA 33,000.0 C222C333(4)2G5CA 39,000.0 C222C393(4)2G5CA 47,000.0 C222C473(4)2G5CA 100 VOLT – C222 STANDARD C0G 39,000.0 C222C393(4)1G5CA 47,000.0 C222C473(4)1G5CA 56,000.0 C222C563(4)1G5CA 68,000.0 C222C683(4)1G5CA 82,000.0 C222C823(4)1G5CA 100,000.0 C222C104(4)1G5CA NOTE 1: Insert proper symbol for capacitance tolerance as follows: NOTE 1: Insert proper symbol for capacitance tolerance as follows: (1) (2) (3) (4) KEMET PART NUMBER 1.0 pF to 8.2 pF: D— ±.5 pF 10.0 pF to 22 pF: J— ±5%, K— ±10% 27.0 pF to 47 pF: G— ±2%, J— ±5%, K— ±10% 56.0 pF and up: F— ±1%,G— ±2%, J— ±5%, K— ±10% (1) 1.0 pF to 8.2 pF: D— ±.5 pF (2) 10.0 pF to 22 pF: J— ±5%, K— ±10% (3) 27.0 pF to 47 pF: G— ±2%, J— ±5%, K— ±10% (4) 56.0 pF and up: F— ±1%,G— ±2%, J— ±5%, K— ±10% NOTE 1: Insert proper symbol for capacitance tolerance as follows: (1) (2) (3) (4) 30 1.0 pF to 8.2 pF: D— ±.5 pF 10.0 pF to 22 pF: J— ±5%, K— ±10% 27.0 pF to 47 pF: G— ±2%, J— ±5%, K— ±10% 56.0 pF and up: F— ±1%,G— ±2%, J— ±5%, K— ±10% © KEMET Electronics Corporation, P.O. Box 5928, Greenville, S.C. 29606, (864) 963-6300 CERAMIC MOLDED/RADIAL – STANDARD ULTRA-STABLE TEMPERATURE CHARACTERISTIC—C0G (NP0) RATINGS & PART NUMBER REFERENCE KEMET PART NUMBER CAPACITANCE pF 200 VOLT – C062 SIZE C0G 3,300.0 C062C332(4)2G5CA 3,900.0 C062C392(4)2G5CA 4,700.0 C062C472(4)2G5CA 5,600.0 C062C562(4)2G5CA 6,800.0 C062C682(4)2G5CA 8,200.0 C062C822(4)2G5CA 10,000.0 C062C103(4)2G5CA 200 VOLT – C052 SIZE C0G 1.0 C052C109(1)2G5CA 1.5 C052C159(1)2G5CA 2.2 C052C229(1)2G5CA 2.7 C052C279(1)2G5CA 3.3 C052C339(1)2G5CA 3.9 C052C399(1)2G5CA 4.7 C052C479(1)2G5CA 5.6 C052C569(1)2G5CA 6.8 C052C689(1)2G5CA 8.2 C052C829(1)2G5CA 10.0 C052C100(2)2G5CA 12.0 C052C120(2)2G5CA 15.0 C052C150(2)2G5CA 18.0 C052C180(2)2G5CA 22.0 C052C220(2)2G5CA 27.0 C052C270(3)2G5CA 33.0 C052C330(3)2G5CA 39.0 C052C390(3)2G5CA 47.0 C052C470(3)2G5CA 56.0 C052C560(4)2G5CA 68.0 C052C680(4)2G5CA 82.0 C052C820(4)2G5CA 100.0 C052C101(4)2G5CA 120.0 C052C121(4)2G5CA 150.0 C052C151(4)2G5CA 180.0 C052C181(4)2G5CA 220.0 C052C221(4)2G5CA 270.0 C052C271(4)2G5CA 330.0 C052C331(4)2G5CA 390.0 C052C391(4)2G5CA 470.0 C052C471(4)2G5CA 560.0 C052C561(4)2G5CA 680.0 C052C681(4)2G5CA 820.0 C052C821(4)2G5CA 1,000.0 C052C102(4)2G5CA 1,200.0 C052C122(4)2G5CA 1,500.0 C052C152(4)2G5CA 1,800.0 C052C182(4)2G5CA 2,200.0 C052C222(4)2G5CA 2,700.0 C052C272(4)2G5CA 100 VOLT – C052 SIZE C0G 390.0 C052C391(4)1G5CA 470.0 C052C471(4)1G5CA 560.0 C052C561(4)1G5CA 680.0 C052C681(4)1G5CA 820.0 C052C821(4)1G5CA 1,000.0 C052C102(4)1G5CA 1,200.0 C052C122(4)1G5CA 1,500.0 C052C152(4)1G5CA 1,800.0 C052C182(4)1G5CA 2,200.0 C052C222(4)1G5CA 2,700.0 C052C272(4)1G5CA 3,300.0 C052C332(4)1G5CA 3,900.0 C052C392(4)1G5CA 4,700.0 C052C472(4)1G5CA KEMET PART NUMBER 100 VOLT – C062 SIZE C0G 5,600.0 C062C562(4)1G5CA 6,800.0 C062C682(4)1G5CA 8,200.0 C062C822(4)1G5CA 10,000.0 C062C103(4)1G5CA 12,000.0 C062C123(4)1G5CA 15,000.0 C062C153(4)1G5CA 18,000.0 C062C183(4)1G5CA 22,000.0 C062C223(4)1G5CA 200 VOLT – C512 SIZE C0G 12,000.0 C512C123(4)2G5CA 15,000.0 C512C153(4)2G5CA 18,000.0 C512C183(4)2G5CA 22,000.0 C512C223(4)2G5CA 27,000.0 C512C273(4)2G5CA 33,000.0 C512C333(4)2G5CA 39,000.0 C512C393(4)2G5CA 47,000.0 C512C473(4)2G5CA 56,000.0 C512C563(4)2G5CA 68,000.0 C512C683(4)2G5CA 100 VOLT – C512 SIZE C0G 27,000.0 C512C273(4)1G5CA 33,000.0 C512C333(4)1G5CA 39,000.0 C512C393(4)1G5CA 47,000.0 C512C473(4)1G5CA 56,000.0 C512C563(4)1G5CA 68,000.0 C512C683(4)1G5CA 82,000.0 C512C823(4)1G5CA 100,000.0 C512C104(4)1G5CA 200 VOLT – C522 SIZE C0G 82,000.0 C522C823(4)2G5CA 100,000.0 C522C104(4)2G5CA 100 VOLT – C522 SIZE C0G 120,000.0 C522C124(4)1G5CA 150,000.0 C522C154(4)1G5CA 180,000.0 C522C184(4)1G5CA NOTE 1: Insert proper symbol for capacitance tolerance as follows: (1) (2) (3) (4) 1.0 pF to 8.2 pF: D— ±.5 pF 10.0 pF to 22 pF: J— ±5%, K— ±10% 27.0 pF to 47 pF: G— ±2%, J— ±5%, K— ±10% 56.0 pF and up: F— ±1%,G— ±2%, J— ±5%, K— ±10% Ceramic Molded Axial/Radial - Standard CAPACITANCE pF NOTE 1: Insert proper symbol for capacitance tolerance as follows: (1) (2) (3) (4) 1.0 pF to 8.2 pF: D— ±.5 pF 10.0 pF to 22 pF: J— ±5%, K— ±10% 27.0 pF to 47 pF: G— ±2%, J— ±5%, K— ±10% 56.0 pF and up: F— ±1%,G— ±2%, J— ±5%, K— ±10% © KEMET Electronics Corporation, P.O. Box 5928, Greenville, S.C. 29606, (864) 963-6300 31 CERAMIC LEADED PACKAGING INFORMATION CERAMIC PACKAGING KEMET Series C114C-K-G C124C-K-G C192C-K-G C202C-K C222C-K C052C-K-G C062C-K-G C114G C124G C192G C202G C222G C052/56G C062/66G C512G C522G C114T C124T C192T C202T C222T C052/56T C062/66T C31X C32X C33X C340 C350 C410 C412 C420 C430 C440 C512 C522 C617 C622/C623 C627/C628 C630/C631 C637/C638 C640/C641 C642/C643 C647/C648 C657/C658 C667/C668 Military Style CK12, CC75 CK13, CC76 CK14, CC77 CK15 CK16 CK05, CC05 CK06, CC06 CCR75 CCR76 CCR77 CC78-CCR78 CC79-CCR79 CCR05 CCR06 CC07-CCR07 CC08-CCR08 CKR11 CKR12 CKR14 CKR15 CKR16 CKR05 CKR06 N/A N/A Military Specification MIL-C-11015/ MIL-PRF-20 MIL-PRF-20 MIL-PRF-39014 N/A N/A Standard (1) Bulk Quantity 200/Box 200/Box 100/Box 25/Box 10/Tray 100/Bag 100/Bag 200/Box 200/Box 100/Box 25/Box 10/Tray 100/Bag 100/Bag Footnote (2) Footnote (2) 200/Box 200/Box 100/Box 25/Box 10/Tray 100/Bag 100/Bag 500/Bag 500/Bag 250/Bag 100/Bag 50/Bag 300/Box 200/Box 300/Box 200/Box 200/Box Footnote (2) Footnote (2) 250/Bag 100/Bag 100/Bag 100/Bag 50/Bag 50/Bag 50/Bag 50/Bag 50/Bag 50/Bag Ammo Pack Quantity Maximum 2000 1500 2500 2500 1500 1000 N/A 4000 4000 4000 2000 2000 Maximum Reel Quantity 5000 5000 3000 500 300 2000 1500 5000 5000 3000 500 300 1700 1500 N/A N/A 5000 5000 3000 500 300 1700 1500 2500 2500 1500 1000 500 5000 5000 5000 2500 2500 N/A N/A 1000 500 500 500 500 500 500 500 500 500 NOTE: (1) Standard packaging refers to number of pieces per bag, tray or vial. (2) Quantity varies. For further details, please consult the factory. 48 © KEMET Electronics Corporation, P.O. Box 5928, Greenville, S.C. 29606, (864) 963-6300 Reel Size 12" 12" 12" 12" 12" 12" 12" 12" 12" 12" 12" 12" 12" 12" N/A N/A 12" 12" 12" 12" 12" 12" 12" 12" 12" 12" 12" 12" 12" 12" 12" 12" 12" N/A N/A 12" 12" 12" 12" 12" 12" 12" 12" 12" 12" Tape & Reel Packaging Information KEMET offers standard reeling of Molded and Conformally Coated Radial Leaded Capacitors in accordance with EIA standard 468. Parts are taped to a tagboard carrier strip, and wound on a reel as shown in Figure 1. Kraft paper interleaving is inserted between the layers of capacitors on the reel. Ammopack is also available, with the same lead tape configuration and package quantities. t Ceramic Radial Tape and Reel Dimensions Metric will govern Constant Dimensions — Millimeters (Inches) D0 ±0.2 (0.008) P0 ±0.3 (0.012) ΔH ±0.2 (0.008) L1 Maximum t ±0.2 (0.008) T Maximum W + 1.0/- 0.5 (+0.039/-0.020) W0 Minimum W2 Maximum 4.00 (0.157) 12.7 (0.500) 4.0 (0.157) 1.0 (0.039) 0.7 (0.051) 1.5 (0.059) 18.0 (0.709) 5.0 (0.197) 3.0 (0.118) Ceramic Radial Tape and Reel Dimensions cont'd Metric will govern Variable Dimensions — Millimeters (Inches) F ±0.030 (0.78) Note 1 P1 ±0.030 (0.012) Note 1 P ±0.3 (0.012) P2 ±1.3 (0.51) 2.54 (0.100) 5.08 (0.200) 12.7 (0.500) 6.35 (0.250) 4.32 (0.170) 3.89 (0.153) 12.7 (0.500) 6.35 (0.250) 5.08 (0.200) 3.81 (0.150) 12.7 (0.500) 6.35 (0.250) 5.59 (0.220) 3.25 (0.128) 12.7 (0.500) 6.35 (0.250) 6.98 (0.275) 2.54 (0.100) 12.7 (0.500) 6.35 (0.250) 7.62 (0.300) 2.24 (0.088) 12.7 (0.500) 6.35 (0.250) 9.52 (0.375) 7.62 (0.300) 12.7 (0.500) 6.35 (0.250) 10.16 (0.400) 7.34 (0.290) 25.4 (1.000) N/A 12.06 (0.475) 6.35 (0.250) 25.4 (1.000) N/A 14.60 (0.575) 5.08 (0.200) 25.4 (1.000) N/A 17.14 (0.675) 3.81 (0.15) 25.4 (1.000) N/A 1.Measuredattheegressfromthecarriertape,onthecomponentside. 2.StraightLeadconfigurationparttypesonly. 3.Formed(bent)leadconfigurationparttypesonly. Symbol Reference Table D0 P0 P F P1 P2 H H0 H1 ΔH L1 t W W0 W2 Sprocket Hole Diameter Sprocket Hole Pitch Component Pitch Lead Spacing Sprocket Hole Center to Lead Center Sprocket Hole Center To Component Center Height to Seating Plane (Straight Leads Only) Height to Seating Plane (Formed Leads Only) Component Height Above Tape Center Component Alignment Lead Protrusion Composite Tape Thickness Carrier Tape Width Hold-Down Tape Width Hold-Down Tape Location H Minimum Note 2 H0 ±0.5 (0.630) Note 3 18.0 (0.709) 16.0 (0.024) Tape & Reel Packaging Information KEMET offers standard reeling of molded and conformally coated axial leaded ceramic capacitors for automatic insertion or lead forming machines in accordance with EIA standard 296. KEMET’sinternalspecificationfour-digitsuffix,7200,isplacedat the end of the part number to designate tape and reel packaging, e.g.,C410C104Z5U5CA7200. Paper (50 lb.) test minimum is inserted between the layers ofcapacitorswoundonreelsforcomponentpitch≤0.400". Capacitor lead length may extend only a maximum of .0625" (1.59 mm) beyond the tapes’ edges. Capacitors are centered in a row between the two tapes and will deviate only ± 0.031" (0.79 mm) from the row center. A minimum of 36" (91.5 cm) leader tapeisprovidedateachfinishedlengthoftapedcomponents. Universalsplicingclipsareusedtoconnectthetape. Table 3 – Ceramic Axial Tape and Reel Dimensions Metric will govern Dimensions — Millimeters (Inches) Axial Capacitor Body Diameter 0.0 to 5.0 (0.0 to 0.197) A ±0.5 (0.020) B ±1.5 (0.059)* 5.0 (0.197) 52.4 (2.062) Symbol Reference Table A B * Inside tape spacing dimension (B) is determined by the body diameter of the capacitor. © KEMET Electronics Corporation • P.O. Box 5928 • Greenville, SC 29606 (864) 963-6300 • www.kemet.com Component Pitch Inside Tape Spacing KEMET Corporation World Headquarters Europe Asia Southern Europe Sasso Marconi, Italy Tel:39-051-939111 Northeast Asia Hong Kong Tel:852-2305-1168 MailingAddress: P.O. Box 5928 Greenville, SC 29606 Skopje, Macedonia Tel:389-2-55-14-623 Shenzhen, China Tel:86-755-2518-1306 www.kemet.com Tel:864-963-6300 Fax:864-963-6521 Central Europe Landsberg, Germany Tel:49-8191-3350800 Corporate Offices Fort Lauderdale, FL Tel:954-766-2800 Kamen, Germany Tel:49-2307-438110 North America Northern Europe Wyboston,UnitedKingdom Tel:44-1480-273082 Taipei, Taiwan Tel:886-2-27528585 Espoo, Finland Tel:358-9-5406-5000 Southeast Asia Singapore Tel:65-6701-8033 2835 KEMET Way Simpsonville, SC 29681 Southeast Lake Mary, FL Tel:407-855-8886 Northeast Wilmington, MA Tel:978-658-1663 Central Novi, MI Tel:248-994-1030 Beijing, China Tel:86-10-5877-1075 Shanghai, China Tel:86-21-6447-0707 Seoul, South Korea Tel:82-2-6294-0550 Penang, Malaysia Tel:60-4-6430200 Bangalore, India Tel:91-806-53-76817 West Milpitas, CA Tel:408-433-9950 Mexico Guadalajara, Jalisco Tel:52-33-3123-2141 Note: KEMET reserves the right to modify minor details of internal and external construction at any time in the interest of product improvement. KEMET does not assume any responsibility for infringement that might result from the use of KEMET Capacitors in potential circuit designs. KEMET is a registered trademark of KEMET Electronics Corporation. © KEMET Electronics Corporation • P.O. Box 5928 • Greenville, SC 29606 (864) 963-6300 • www.kemet.com Disclaimer Allproductspecifications,statements,informationanddata(collectively,the“Information”)inthisdatasheetaresubjecttochange.Thecustomerisresponsibleforcheckingand 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 notintendedtoconstitute–andKEMETspecificallydisclaims–anywarrantyconcerningsuitabilityforaspecificcustomerapplicationoruse.TheInformationisintendedforuseonly 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. Althoughallproduct–relatedwarnings,cautionsandnotesmustbeobserved,thecustomershouldnotassumethatallsafetymeasuresareindictedorthatothermeasuresmaynot be required. © KEMET Electronics Corporation • P.O. Box 5928 • Greenville, SC 29606 (864) 963-6300 • www.kemet.com