Film Capacitors Metallized Polyester Film Capacitors (MKT) Series/Type: B32572, B32573 Date: May 2009 © EPCOS AG 2009. Reproduction, publication and dissemination of this publication, enclosures hereto and the information contained therein without EPCOS' prior express consent is prohibited. Metallized polyester film capacitors (MKT) B32572, B32573 Ignition (stacked) SilverCapTM Typical applications Ignition for gas, engines, generators Energy storage Dimensional drawing Climatic Max. operating temperature: 125 °C Climatic category (IEC 60068-1): 55/125/56 Features Special dimensions available on request High pulse strength Construction Dielectric: polyethylene terephthalate (polyester, PET) Stacked-film technology Uncoated Dimensions in mm Lead spacing ±0.4 15.0 22.5 Lead diameter Type d1 0.8 B32572 0.8 B32573 Terminals Parallel wire leads, lead-free tinned Marking Rated capacitance (coded), rated DC voltage Delivery mode Bulk (untaped) Notes on mounting When mounting these capacitors, take into account creepage distances and clearances to adjacent live parts. The insulating strength of the cut surfaces to other live parts of the circuit is 1.5 times the capacitors rated DC voltage, but is always at least 300 V DC. Please read Cautions and warnings and Important notes at the end of this document. Page 2 of 19 B32572, B32573 Ignition (stacked) SilverCapTM Overview of available types Lead spacing 15.0 mm 22.5 mm Type B32572 B32573 Page 4 5 VR (V DC) 250 250 VRMS (V AC) 160 160 CR (µF) 0.68 1.0 1.5 2.2 Please read Cautions and warnings and Important notes at the end of this document. Page 3 of 19 B32572 Ignition (stacked) SilverCapTM Ordering codes and packing units (lead spacing 15 mm) VR VRMS CR f ≤60 Hz V DC V AC µF 250 160 0.68 1.0 1.5 2.2 Max. dimensions w×h×l mm 7.0 × 11.0 × 16.5 9.1 × 11.7 × 16.5 11.5 × 13.5 × 16.5 11.5 × 19.8 × 16.5 Ordering code (composition see below) B32572A3684+000 B32572A3105+000 B32572A3155+000 B32572A3225+000 Untaped pcs./MOQ 1800 1200 800 600 MOQ = Minimum Order Quantity, consisting of 4 packing units. Further E series and intermediate capacitance values on request. Special dimensions available on request. For corresponding design rules, refer to chapter "General technical information", page . Composition of ordering code + = Capacitance tolerance code: M = ±20% K = ±10% J = ±5% Please read Cautions and warnings and Important notes at the end of this document. Page 4 of 19 B32573 Ignition (stacked) SilverCapTM Ordering codes and packing units (lead spacing 22.5 mm) VR VRMS CR f ≤60 Hz V DC V AC µF 250 160 0.68 1.0 1.5 2.2 Max. dimensions w×h×l mm 5.6 × 9.2 × 24.0 6.4 × 11.8 × 24.0 7.6 × 14.3 × 24.0 8.9 × 17.4 × 24.0 Ordering code (composition see below) B32573A3684+000 B32573A3105+000 B32573A3155+000 B32573A3225+000 Untaped pcs./MOQ 4720 4200 3720 2240 MOQ = Minimum Order Quantity, consisting of 4 packing units. Further E series and intermediate capacitance values on request. Special dimensions available on request. For corresponding design rules, refer to chapter "General technical information", page . Composition of ordering code + = Capacitance tolerance code: M = ±20% K = ±10% J = ±5% Please read Cautions and warnings and Important notes at the end of this document. Page 5 of 19 B32572, B32573 Ignition (stacked) SilverCapTM Technical data Operating temperature range Max. operating temperature Top,max Upper category temperature Tmax Lower category temperature Tmin Rated temperature TR Dissipation factor tan δ (in 10-3) at CR ≤ 1 µF at 20 °C 1 kHz 8 (upper limit values) 10 kHz 15 Time constant τ = CR Rins 2500 s at 20 °C, rel. humidity ≤ 65% (minimum as-delivered values) DC test voltage 1.6 VR, 2 s TA (°C) DC voltage derating Category voltage VC (continuous operation with VDC TA ≤ 85 VC = VR or VAC at f ≤ 60 Hz) 85<TA≤125 VC = VR (165TA)/80 Max. charging voltage Cch 1.2 VR for ≤ 1 s Damp heat test Limit values after damp heat test Reliability: Failure rate λ Service life tSL Failure criteria: Total failure Failure due to variation of parameters CR > 1 µF 10 AC voltage derating VC,RMS = VRMS VC,RMS=VRMS (165TA)/80 56 days1)/40 °C/93% relative humidity Capacitance change ∆C/C ≤ 5% Dissipation factor change ∆ tan δ ≤ 3 10-3 (at 1 kHz) ≤ 5 10-3 (at 10 kHz) Time constant τ = CR Rins ≥ 50% of minimum as-delivered values 1 fit (≤ 2 10-9/h) at 0.5 VR, 40 °C 200 000 h at 1.0 VR, 85 °C For conversion to other operating conditions and temperatures, refer to chapter "Quality, 2 Reliability". Short circuit or open circuit Capacitance change ∆C/C Dissipation factor tan δ Time constant τ = CR Rins 1) Test criteria must be met after exposure to damp heat for 21 days Please read Cautions and warnings and Important notes at the end of this document. +125 °C +125 °C 55 °C +85 °C Page 6 of 19 > 10% > 2 upper limit value < 50 s B32572, B32573 Ignition (stacked) SilverCapTM Pulse handling capability The capacitors are especially manufactured and tested to suit their intended applications. Typical permissible load: Lead spacing Max. rate of voltage rise Vpp/τ Pulse characteristic k0 Max. charging voltage Vch Max. voltage change Vpp (at Vpp = 500 V) (at Vpp ≤ 500 V) (≤1 s) ( at f = 100 kHz) Unlimited number of pulses permitted. Impedance Z versus frequency f (typical values) Please read Cautions and warnings and Important notes at the end of this document. Page 7 of 19 15 and 22.5 mm 200 V/µs 200 000 V2/µs 300 V DC 500 V B32572, B32573 Ignition (stacked) SilverCapTM Permissible AC voltage VRMS versus frequency f (for sinusoidal waveforms, TA ≤55 °C) For TA >55 °C, please refer to "General technical information", section 3.2.3. Lead spacing 15 mm 250 V DV/160 V AC Lead spacing 22.5 mm 250 V DC/160 V AC Please read Cautions and warnings and Important notes at the end of this document. Page 8 of 19 B32572, B32573 Ignition (stacked) SilverCapTM Mounting guidelines 1 Soldering 1.1 Solderability of leads The solderability of terminal leads is tested to IEC 60068-2-20, test Ta, method 1. Before a solderability test is carried out, terminals are subjected to accelerated ageing (to IEC 60068-2-2, test Ba: 4 h exposure to dry heat at 155 °C). Since the ageing temperature is far higher than the upper category temperature of the capacitors, the terminal wires should be cut off from the capacitor before the ageing procedure to prevent the solderability being impaired by the products of any capacitor decomposition that might occur. Solder bath temperature 235 ±5 °C Soldering time 2.0 ±0.5 s Immersion depth 2.0 +0/0.5 mm from capacitor body or seating plane Evaluation criteria: Visual inspection Wetting of wire surface by new solder ≥90%, free-flowing solder 1.2 Resistance to soldering heat Resistance to soldering heat is tested to IEC 60068-2-20, test Tb, method 1A. Conditions: Series Solder bath temperature Soldering time MKT boxed (except 2.5 × 6.5 × 7.2 mm) 260 ±5 °C coated uncoated (lead spacing > 10 mm) MFP MKP (lead spacing > 7.5 mm) MKT boxed (case 2.5 × 6.5 × 7.2 mm) MKP (lead spacing ≤ 7.5 mm) MKT uncoated (lead spacing ≤ 10 mm) insulated (B32559) Please read Cautions and warnings and Important notes at the end of this document. Page 9 of 19 10 ±1 s 5 ±1 s <4s recommended soldering profile for MKT uncoated (lead spacing ≤ 10 mm) and insulated (B32559) B32572, B32573 Ignition (stacked) SilverCapTM Immersion depth 2.0 +0/0.5 mm from capacitor body or seating plane Shield Heat-absorbing board, (1.5 ±0.5) mm thick, between capacitor body and liquid solder Evaluation criteria: Visual inspection ∆C/C0 tan δ Please read Cautions and warnings and Important notes at the end of this document. No visible damage 2% for MKT/MKP/MFP 5% for EMI suppression capacitors As specified in sectional specification Page 10 of 19 B32572, B32573 Ignition (stacked) SilverCapTM 1.3 General notes on soldering Permissible heat exposure loads on film capacitors are primarily characterized by the upper category temperature Tmax. Long exposure to temperatures above this type-related temperature limit can lead to changes in the plastic dielectric and thus change irreversibly a capacitor's electrical characteristics. For short exposures (as in practical soldering processes) the heat load (and thus the possible effects on a capacitor) will also depend on other factors like: Pre-heating temperature and time Forced cooling immediately after soldering Terminal characteristics: diameter, length, thermal resistance, special configurations (e.g. crimping) Height of capacitor above solder bath Shadowing by neighboring components Additional heating due to heat dissipation by neighboring components Use of solder-resist coatings The overheating associated with some of these factors can usually be reduced by suitable countermeasures. For example, if a pre-heating step cannot be avoided, an additional or reinforced cooling process may possibly have to be included. EPCOS recommends the following conditions: Pre-heating with a maximum temperature of 110 °C Temperature inside the capacitor should not exceed the following limits: MKP/MFP 110 °C MKT 160 °C When SMD components are used together with leaded ones, the leaded film capacitors should not pass into the SMD adhesive curing oven. The leaded components should be assembled after the SMD curing step. Leaded film capacitors are not suitable for reflow soldering. Uncoated capacitors For uncoated MKT capacitors with lead spacings ≤10 mm (B32560/B32561) the following measures are recommended: pre-heating to not more than 110 °C in the preheater phase rapid cooling after soldering Please read Cautions and warnings and Important notes at the end of this document. Page 11 of 19 B32572, B32573 Ignition (stacked) SilverCapTM 2 Cleaning To determine whether the following solvents, often used to remove flux residues and other substances, are suitable for the capacitors described, refer to the table below: Type Ethanol, isopropanol, n-propanol MKT (uncoated) MKT, MKP, MFP (coated/boxed) Suitable n-propanol-water mixtures, water with surface tension-reducing tensides (neutral) Unsuitable Solvent from table A (see next page) Suitable Suitable Solvent from table B (see next page) In part suitable Unsuitable Even when suitable solvents are used, a reversible change of the electrical characteristics may occur in uncoated capacitors immediately after they are washed. Thus it is always recommended to dry the components (e.g. 4 h at 70 °C) before they are subjected to subsequent electrical testing. Table A Manufacturers' designations for trifluoro-trichloro-ethane-based cleaning solvents (selection) Trifluoro-trichloroethane Freon TF Frigen 113 TR Arklone P Kaltron 113 MDR Flugene 113 Mixtures of trifluoro-trichloro-ethane with ethanol and isopropanol Freon TE 35; Freon TP 35; Freon TES Frigen 113 TR-E; Frigen 113 TR-P; Frigen TR-E 35 Arklone A; Arklone L; Arklone K Kaltron 113 MDA; Kaltron 113 MDI; Kaltron 113 MDI 35 Flugene 113 E; Flugene 113 IPA Manufacturer Du Pont Hoechst ICI Kali-Chemie Rhone-Progil Table B (worldwide banned substances) Manufacturers' designations for unsuitable cleaning solvents (selection) Mixtures of chlorinated hydrocarbons and ketones with fluorated hydrocarbons Freon TMC; Freon TA; Freon TC Arklone E Kaltron 113 MDD; Kaltron 113 MDK Flugene 113 CM Please read Cautions and warnings and Important notes at the end of this document. Page 12 of 19 Manufacturer Du Pont ICI Kali-Chemie Rhone-Progil B32572, B32573 Ignition (stacked) SilverCapTM 3 Embedding of capacitors in finished assemblies In many applications, finished circuit assemblies are embedded in plastic resins. In this case, both chemical and thermal influences of the embedding ("potting") and curing processes must be taken into account. Our experience has shown that the following potting materials can be recommended: non-flexible epoxy resins with acid-anhydride hardeners; chemically inert, non-conducting fillers; maximum curing temperature of 100 °C. Caution: Consult us first if you wish to embed uncoated types! Please read Cautions and warnings and Important notes at the end of this document. Page 13 of 19 B32572, B32573 Ignition (stacked) SilverCapTM Cautions and warnings Do not exceed the upper category temperature (UCT). Do not apply any mechanical stress to the capacitor terminals. Avoid any compressive, tensile or flexural stress. Do not move the capacitor after it has been soldered to the PC board. Do not pick up the PC board by the soldered capacitor. Do not place the capacitor on a PC board whose PTH hole spacing differs from the specified lead spacing. Do not exceed the specified time or temperature limits during soldering. Avoid external energy inputs, such as fire or electricity. Avoid overload of the capacitors. The table below summarizes the safety instructions that must always be observed. A detailed description can be found in the relevant sections of the chapters "General technical information" and "Mounting guidelines". Topic Storage conditions Flammability Resistance to vibration Safety information Reference chapter "General technical information" Make sure that capacitors are stored within the 4.5 specified range of time, temperature and humidity "Storage conditions" conditions. Avoid external energy, such as fire or electricity 5.3 (passive flammability), avoid overload of the "Flammability" capacitors (active flammability) and consider the flammability of materials. Do not exceed the tested ability to withstand 5.2 vibration. The capacitors are tested to "Resistance to vibration" IEC 60068-2-6. EPCOS offers film capacitors specially designed for operation under more severe vibration regimes such as those found in automotive applications. Consult our catalog "Film Capacitors for Automotive Electronics". Please read Cautions and warnings and Important notes at the end of this document. Page 14 of 19 B32572, B32573 Ignition (stacked) SilverCapTM Topic Safety information Soldering Do not exceed the specified time or temperature limits during soldering. Cleaning Use only suitable solvents for cleaning capacitors. Embedding of When embedding finished circuit assemblies in capacitors in plastic resins, chemical and thermal influences finished assemblies must be taken into account. Caution: Consult us first, if you also wish to embed other uncoated component types! Please read Cautions and warnings and Important notes at the end of this document. Page 15 of 19 Reference chapter "Mounting guidelines" 1 "Soldering" 2 "Cleaning" 3 "Embedding of capacitors in finished assemblies" B32572, B32573 Ignition (stacked) SilverCapTM Symbols and terms Symbol α αC A βC C CR ∆C ∆C/C ∆C/CR dt ∆t ∆T ∆tan δ ∆V dV/dt ∆V/∆t E ESL ESR f f1 f2 fr FD FT i IC English Heat transfer coefficient Temperature coefficient of capacitance Capacitor surface area Humidity coefficient of capacitance Capacitance Rated capacitance Absolute capacitance change Relative capacitance change (relative deviation of actual value) Capacitance tolerance (relative deviation from rated capacitance) Time differential Time interval Absolute temperature change (self-heating) Absolute change of dissipation factor Absolute voltage change Time differential of voltage function (rate of voltage rise) Voltage change per time interval Activation energy for diffusion Self-inductance Equivalent series resistance Frequency Frequency limit for reducing permissible AC voltage due to thermal limits German Wärmeübergangszahl Temperaturkoeffizient der Kapazität Kondensatoroberfläche Feuchtekoeffizient der Kapazität Kapazität Nennkapazität Absolute Kapazitätsänderung Relative Kapazitätsänderung (relative Abweichung vom Ist-Wert) Kapazitätstoleranz (relative Abweichung vom Nennwert) Differentielle Zeit Zeitintervall Absolute Temperaturänderung (Selbsterwärmung) Absolute Änderung des Verlustfaktors Absolute Spannungsänderung Differentielle Spannungsänderung (Spannungsflankensteilheit) Spannungsänderung pro Zeitintervall Aktivierungsenergie zur Diffusion Eigeninduktivität Ersatz-Serienwiderstand Frequenz Grenzfrequenz für thermisch bedingte Reduzierung der zulässigen Wechselspannung Frequency limit for reducing permissible Grenzfrequenz für strombedingte AC voltage due to current limit Reduzierung der zulässigen Wechselspannung Resonant frequency Resonanzfrequenz Thermal acceleration factor for diffusion Therm. Beschleunigungsfaktor zur Diffusion Derating factor Deratingfaktor Current (peak) Stromspitze Category current (max. continuous Kategoriestrom (max. Dauerstrom) current) Please read Cautions and warnings and Important notes at the end of this document. Page 16 of 19 B32572, B32573 Ignition (stacked) SilverCapTM Symbol IRMS iz k0 LS λ λ0 λtest Pdiss Pgen Q ρ R R Ri Rins RP RS S t T τ tan δ tan δD tan δP tan δS TA Tmax Tmin tOL Top TR Tref tSL VAC English (Sinusoidal) alternating current, root-mean-square value Capacitance drift Pulse characteristic Series inductance Failure rate Constant failure rate during useful service life Failure rate, determined by tests Dissipated power Generated power Heat energy Density of water vapor in air Universal molar constant for gases Ohmic resistance of discharge circuit Internal resistance Insulation resistance Parallel resistance Series resistance severity (humidity test) Time Temperature Time constant Dissipation factor Dielectric component of dissipation factor Parallel component of dissipation factor Series component of dissipation factor Ambient temperature Upper category temperature Lower category temperature Operating life at operating temperature and voltage Operating temperature Rated temperature Reference temperature Reference service life AC voltage Please read Cautions and warnings and Important notes at the end of this document. German (Sinusförmiger) Wechselstrom Inkonstanz der Kapazität Impulskennwert Serieninduktivität Ausfallrate Konstante Ausfallrate in der Nutzungsphase Experimentell ermittelte Ausfallrate Abgegebene Verlustleistung Erzeugte Verlustleistung Wärmeenergie Dichte von Wasserdampf in Luft Allg. Molarkonstante für Gas Ohmscher Widerstand des Entladekreises Innenwiderstand Isolationswiderstand Parallelwiderstand Serienwiderstand Schärfegrad (Feuchtetest) Zeit Temperatur Zeitkonstante Verlustfaktor Dielektrischer Anteil des Verlustfaktors Parallelanteil des Verlfustfaktors Serienanteil des Verlustfaktors Umgebungstemperatur Obere Kategorietemperatur Untere Kategorietemperatur Betriebszeit bei Betriebstemperatur und -spannung Beriebstemperatur Nenntemperatur Referenztemperatur Referenz-Lebensdauer Wechselspannung Page 17 of 19 B32572, B32573 Ignition (stacked) SilverCapTM Symbol VC VC,RMS English Category voltage Category AC voltage VCD Vch VDC VFB Vi Vo Vop Vp Vpp VR Corona-discharge onset voltage Charging voltage DC voltage Fly-back capacitor voltage Input voltage Output voltage Operating voltage Peak pulse voltage Peak-to-peak voltage Impedance Rated voltage Amplitude of rated AC voltage R VRMS German Kategoriespannung (Sinusförmige) Kategorie-Wechselspannung Teilentlade-Einsatzspannung Ladespannung Gleichspannung Spannung (Flyback) Eingangsspannung Ausgangssspannung Betriebsspannung Impuls-Spitzenspannung Spannungshub Nennspannung Amplitude der Nenn-Wechselspannung VSC Vsn (Sinusoidal) alternating voltage, root-mean-square value S-correction voltage Snubber capacitor voltage Z Impedance Spannung bei Anwendung "S-correction" Spannung bei Anwendung "Beschaltung" Scheinwiderstand Lead spacing Rastermaß Please read Cautions and warnings and Important notes at the end of this document. (Sinusförmige) Wechselspannung Page 18 of 19 Important notes The following applies to all products named in this publication: 1. Some parts of this publication contain statements about the suitability of our products for certain areas of application. These statements are based on our knowledge of typical requirements that are often placed on our products in the areas of application concerned. We nevertheless expressly point out that such statements cannot be regarded as binding statements about the suitability of our products for a particular customer application. As a rule, EPCOS is either unfamiliar with individual customer applications or less familiar with them than the customers themselves. For these reasons, it is always ultimately incumbent on the customer to check and decide whether an EPCOS product with the properties described in the product specification is suitable for use in a particular customer application. 2. We also point out that in individual cases, a malfunction of electronic components or failure before the end of their usual service life cannot be completely ruled out in the current state of the art, even if they are operated as specified. In customer applications requiring a very high level of operational safety and especially in customer applications in which the malfunction or failure of an electronic component could endanger human life or health (e.g. in accident prevention or lifesaving systems), it must therefore be ensured by means of suitable design of the customer application or other action taken by the customer (e.g. installation of protective circuitry or redundancy) that no injury or damage is sustained by third parties in the event of malfunction or failure of an electronic component. 3. The warnings, cautions and product-specific notes must be observed. 4. In order to satisfy certain technical requirements, some of the products described in this publication may contain substances subject to restrictions in certain jurisdictions (e.g. because they are classed as hazardous). Useful information on this will be found in our Material Data Sheets on the Internet (www.epcos.com/material). Should you have any more detailed questions, please contact our sales offices. 5. We constantly strive to improve our products. Consequently, the products described in this publication may change from time to time. The same is true of the corresponding product specifications. Please check therefore to what extent product descriptions and specifications contained in this publication are still applicable before or when you place an order. We also reserve the right to discontinue production and delivery of products. Consequently, we cannot guarantee that all products named in this publication will always be available. The aforementioned does not apply in the case of individual agreements deviating from the foregoing for customer-specific products. 6. Unless otherwise agreed in individual contracts, all orders are subject to the current version of the "General Terms of Delivery for Products and Services in the Electrical Industry" published by the German Electrical and Electronics Industry Association (ZVEI). 7. The trade names EPCOS, BAOKE, Alu-X, CeraDiode, CSMP, CSSP, CTVS, DSSP, MiniBlue, MKK, MLSC, MotorCap, PCC, PhaseCap, PhaseCube, PhaseMod, SIFERRIT, SIFI, SIKOREL, SilverCap, SIMDAD, SIMID, SineFormer, SIOV, SIP5D, SIP5K, ThermoFuse, WindCap are trademarks registered or pending in Europe and in other countries. Further information will be found on the Internet at www.epcos.com/trademarks. Page 19 of 19