CBB 161G IG Series Polypropylene Film Capacitors for Snubber Applications Features 105°C - Very low dissipation factor - High peak pulse capability - Metal sprayed contacts for low ESL - Plates for direct IGBT connection - Self-healing Applications - High pulse and high frequency circuits - IGBT applications - Frequency converters - Photovoltaic and wind inverters Item Climatic Category Operating Temperature Storage Temperature DC Voltage Rating UR,DC Capacitance Range Capacitance Tolerance Voltage between Terminals UTT Voltage between Terminals and Case UTC Capacitor Dissipation Factor Dielectric Dissipation Factor Insulation Resistance Series Inductance Life Time Expectancy Reference Standard Characteristics 40/105/56 (IEC 61071) –40 ~ +105 °C (θhotspot ≤ 105 °C) –40 ~ +105 °C 850 ~ 1200 VDC 0,33 ~ 3,0 µF ±10 % (K), ±5 % (J) 1,5 * URDC (20 °C, 10 s) 3000 VAC (20 °C, 50 Hz, 10 s) tan δ ≤ 5 * 10-4 (20 °C, 1 kHz) tan δo ≤ 2 * 10-4 (20 °C, 1 kHz) ≥ 30.000 MΩ µF (20 °C, 100 VDC, 1 min) LS (typ.) ≤ 20 nH (20 °C) ≥ 100.000 h, Failure Rate ≤100 FIT (70 °C) IEC 61071:2007, REACH, RoHS Ratings for CBB 161G IG series UR CR Rs(2) Imax(3) 100 kHz 70 °C (A) W H T (A) 100 kHz 20 °C (mΩ) ±1.0 (mm) ±1.0 (mm) ±1.0 (mm) Ordering Code 306 455 520 650 780 975 683 819 910 1001 1138 1365 10 10 9 8 7 6 6 6 5 5 4 4 11.5 15.3 17.2 18.6 20.6 22 22 23 24 24 25 26 42.5 42.5 42.5 42.5 42.5 42.5 57.5 57.5 57.5 57.5 57.5 57.5 28 36 33 35.5 45 43 43.5 45 45 50 45 55 24 24 33 33.5 30 42 29.5 30 35 35 45 40 FCSK2IG474**FA****14*E3 FCSK2IG704**FD****14*E3 FCSK2IG804**FB****14*E3 FCSK2IG105**FC****14*E3 FCSK2IG125**FF****14*E3 FCSK2IG155**FE****14*E3 FCSK2IG155**HG****14*E3 FCSK2IG185**HH****14*E3 FCSK2IG205**HJ****14*E3 FCSK2IG225**HL****14*E3 FCSK2IG255**HK****14*E3 FCSK2IG305**HM****14*E3 dV/dt (V) Code (µF) 20 °C (V/μS) 850VDC (450VAC) K2 0.47 0.70 0.80 1.00 1.20 1.50 1.50 1.80 2.00 2.20 2.50 3.00 650 650 650 650 650 650 455 455 455 455 455 455 Î(1) (1) Maximum permissible peak current (2) Series resistance at 20°C ambient temperature (3) Maximum permissible r.m.s. ripple current “*” to be defined, see ordering code table Customized products are available on request 2016 v1.2 CBB 161G IG Series Ratings for CBB 161G IG series dV/dt UR CR (V) (µF) 20 °C (V/μS) 1200VDC (500VAC) 3B 0.33 0.50 0.60 0.70 0.80 1.00 1.00 1.20 1.40 1.60 1.70 2.00 800 800 800 800 800 800 560 560 560 560 560 560 Î(1) Imax(3) Rs(2) (A) 100 kHz 20 °C (mΩ) 100 kHz 70 °C (A) 264 400 480 560 640 800 560 672 784 896 952 1120 11 10 9 9 8 7 6 6 5 5 4 4 11.4 15 16.8 18.4 20.5 21 22 22 23 23 24 25 W H T ±1.0 (mm) ±1.0 (mm) ±1.0 (mm) Ordering Code 42.5 42.5 42.5 42.5 42.5 42.5 57.5 57.5 57.5 57.5 57.5 57.5 28 36 33 35.5 45 43 43.5 45 45 50 45 55 24 24 33 33.5 30 42 29.5 30 35 35 45 40 FCS3BIG334**FA****14*E3 FCS3BIG504**FD****14*E3 FCS3BIG604**FB****14*E3 FCS3BIG704**FC****14*E3 FCS3BIG804**FF****14*E3 FCS3BIG105**FE****14*E3 FCS3BIG105**HG****14*E3 FCS3BIG125**HH****14*E3 FCS3BIG145**HJ****14*E3 FCS3BIG165**HL****14*E3 FCS3BIG175**HK****14*E3 FCS3BIG205**HM****14*E3 (1) Maximum permissible peak current (2) Series resistance at 20°C ambient temperature (3) Maximum permissible r.m.s. ripple current “*” to be defined, see ordering code table Customized products are available on request Marking No. Item 1 Brand 2 Series designation 3 Capacitance, tolerance, and rated voltage 4 Date code Internal construction 3 No. Item Material 1 Dielectric Film Polypropylene 2 Single-sided Metallized Film PP + Al 3 Double sided Metallized Carrier Film PET + Al 4 Metal Sprayed Contact Zn + Sn/Zn No. 5 6 7 Item Terminals Potting Compound Case Material Sn-coated Cu Epoxy Flame retardant PBT 2016 v1.2 CBB 161G IG Series Dimensions 2016 v1.2 CBB 161G IG Series Life Time Expectancy Ordering code 2016 v1.2 Jianghai Film Capacitors Warranty: The information contained in this datasheet does neither form part of any quotation nor of a contract, it is believed to be accurate, reliable and up to date. Quality data are based on the statistical evaluations of a large quantity of parts and do not constitute a guarantee in a legal sense. However, agreement on these specifications does mean that the customer may claim for replacement of individual defective capacitors within the terms of delivery. We cannot assume any liability beyond the replacement of defective components. This applies in particular to any further consequences of component failure. Furthermore it must be taken into consideration that the figures stated for lifetime, failure rates and outlier percentages refer to the average production status and are therefore to be understood as mean values (statistical expectations) for a large number of delivery lots of identical capacitors. These figures are based on application experience and data obtained from preceding tests under normal conditions, or – for purpose of accelerated aging – more severe conditions. JIANGHAI reserves the right to change these specifications without prior notice. Any application information given is advisory and does not form part of any specification. The products are not primarily designed for use in life supporting applications, devices or systems where malfunction of these products can reasonably be expected to result in personal injury. JIANGHAI customers using or selling these products for use in such applications without prior written consent of JIANGHAI do so at their own risk and agree fully to indemnify JIANGHAI for any damage resulting from such improper use or sale. This version of the datasheet supersedes all previous versions. Voltage between terminals UTT: Voltage between terminals (at 20°C, 10s): 1.5×URDC Voltage between terminals and case UTC: Voltage between terminals and case (at 20°C, 10s): 2 × Ui + 1000 or 3000 (VAC), whichever value is larger. Buzzing noise: Any buzzing noise produced by a capacitor is caused by the vibration of the film due to the Coulomb force that is generated between the electrodes with opposite poles. If the wave-form with a high distortion rate or frequency is applied across the capacitor, the buzzing noise will become louder. But the buzzing noise is of no harm to the capacitor. Surface over temperature △ θ case: When current continuously flow through the capacitor, the temperature inside the capacitor will rise induced by dissipated heat. If the temperature exceeds the maximum allowed hot-spot temperature, it might cause a short circuit or fire. The limits described in the catalogue must not be exceeded and it's necessary to check the temperature on the capacitor’s surface in operation. Flame retardation: Although flame retarding PU resin or plastic case material is used in the coating or encapsulation of plastic film capacitors, continuous exposure to high temperature ambient or fire will break the coating layer or plastic case of the capacitor, and may lead to melting and ignition of the capacitor element. Rated Voltage UR: Rated Voltage is the maximum operating peak voltage of either polarity but of a non-reversing type waveform, for which the capacitor has been designed, for continuous operation. The Rated Voltage is marked on the capacitor and defined in the datasheets as UR. Humid ambient: If used for a long time in a humid ambient, the capacitor might absorb humidity and oxidize the electrodes causing damage to the capacitor. In case of AC application, high humidity would increase the corona effect. This phenomenon causes a drop in capacitance and an increase of capacitor losses. Operating voltage: The plastic film capacitor varies in the maximum applicable voltage depending on the applied voltage waveform, current waveform, frequency, ambient temperature (capacitor surface temperature), capacitance value, etc. Be sure to use capacitors within the specified values by checking the voltage waveform, current waveform, and frequency applied to them (In the application of high frequency, the permissible voltage varies with the type of the capacitor. Refer to the specification for details.). Storage conditions: 1) Capacitors must not be stored in corrosive atmospheres, particularly not when chlorides, sulfides, acids, lye, salts, organic solvents or similar substances are present. 2) It must not be stored in high temperature and/or high humidity environments. The following storage conditions must be kept (applicable only for storage in the original package): Temperature: ≤ 35 °C Humidity: ≤ 80% RH, no dew allowed on the capacitor. Storage time: ≤ 24 months (from the date marked on the capacitor's body or on the label sticking to the package) Non-recurrent surge voltage Us:Peak voltage induced by a switching or any other disturbance of the system which is allowed for a limited number of times and for durations shorter than the basic period. - Maximum duration: 50 ms / pulse - Maximum number of occurrences: 1000 (during load) Maximum rate of voltage rise dV/dt: Maximum permissible repetitive rate of voltage rise of the operational voltage. Charging and discharging: Because the charging and discharging current of capacitor is obtained by the product of voltage rise rate (dV/dt) and capacitance, low voltage charging and discharging may also cause deterioration of capacitor such as shorting and open due to sudden charging and discharging current. When charging and discharging, pass through a resistance of 20Ω/V to1000Ω/V or more to limit the current. When connecting multiple film capacitors in parallel in withstand voltage test or life test, connect a resistance of 20Ω/V to1000Ω/V or more in series to each capacitor (For detail see the specification). In addition, capacitors must be discharged via a resistor before handling. Because the capacitors do not have any discharge resistors built-in, there is a risk of residual voltages and electric energy contents that maybe dangerous. Mounting: Other devices, which are mounted near the capacitor, should not touch the capacitor. Additional heat coming from other components near the capacitor may reduce the lifetime of the capacitor. Do never attempt to bend or twist the capacitor after mounting and avoid any mechanical stress on the terminals. Never exceed the max. permissible torques when tightening the terminal screws or the mounting bolt’s cap nuts. Caution during use of Capacitors: Do not touch the terminals of capacitors. Keep the capacitor free from conductive solution, such as acids, alkali and so on. Ensure that the operating environment of the equipment into which the capacitor has been built is within the specified conditions mentioned in the catalogue or specification sheets. Definition of electrical parameters: Separate documents as application notes, equivalent circuit diagrams and so on are available on request. Packaging: Please refer to the data book for details. Further information is available on request. Operating Current:The pulse (or AC) current flowing through the capacitor is expressed as: I = C x dV/dt. Due to the fact that the dissipation factor of the capacitor is greater than zero, heat will be generated in any application where alternating currents or pulses occur. The resulting internal temperature rise may cause a severe deterioration of the capacitor’s withstanding voltage, or may lead to a breakdown (even smoke or fire may result).Therefore, the safe use of capacitor must be within the rated voltage (or category voltage) and the permissible current ranges. The rated current must be considered by dividing into pulse current (peak current) and continuous current (rms current) depending on the break down mode, and when using, should make sure the both currents are within the permissible range. Temperature range: Use film capacitors only within the specified operating temperature range. Expected lifetime:The expected lifetime of the capacitor depends on the applied voltage and the hot spot temperature during operation. For capacitors applied in different situations, the obtainable average service lives are different. The capacitors used in DC-Link circuits will have an expected lifetime of approximately 100000 hours at rated voltage and 70℃ hot spot temperature. Insulation voltage Ui: rms value of AC voltage designed for the insulation between terminals of the capacitor to case or earth. The insulation voltage is equal to the rated voltage of the capacitor, divided by 2 , unless otherwise specified. Jianghai Europe Electronic Components GmbH v2 0514