DEA1X3D100JC1B

Reference Specification DEA Series High Temperature Lead Type Disc Ceramic Capacitors of Class 1 for General Purpose Product specifications in this catalog are as of Dec. 2017, and are subject to change or obsolescence without notice. Please consult the approval sheet before ordering.Please read rating and Cautions first. Reference only CAUTION 1. OPERATING VOLTAGE When DC-rated capacitors are to be used in AC or ripple current circuits, be sure to maintain the Vp-p value of the applied voltage or the Vo-p which contains DC bias within the rated voltage range. When the voltage is started to apply to the circuit or it is stopped applying, the irregular voltage may be generated for a transit period because of resonance or switching. Be sure to use a capacitor within rated voltage containing these irregular voltage. When DC-rated capacitors are to be used in input circuits from commercial power source (AC filter), be sure to use Safety Recognized Capacitors because various regulations on withstand voltage or impulse withstand established for each equipment should be taken into considerations. Voltage DC Voltage DC+AC Voltage AC Voltage Pulse Voltage(1) Pulse Voltage(2) Positional Vo-p Measurement Vo-p Vp-p Vp-p Vp-p 2. OPERATING TEMPERATURE AND SELF-GENERATED HEAT Keep the surface temperature of a capacitor below the upper limit of its rated operating temperature range. Be sure to take into account the heat generated by the capacitor itself. When the capacitor is used in a high-frequency current, pulse current or the like, it may have the selfgenerated heat due to dielectric-loss. The allowable frequency should be in less than 300kHz in sine wave. Applied voltage should be the load such as self-generated heat is within 5 °C on the condition of atmosphere temperature 25 °C. When measuring, use a thermocouple of small thermal capacity-K of φ0.1mm and be in the condition where capacitor is not affected by radiant heat of other components and wind of surroundings. (Never attempt to perform measurement with the cooling fan running. Otherwise, accurate measurement cannot be ensured.) 3. FAIL-SAFE When capacitor would be broken, failure may result in a short circuit. Be sure to provide an appropriate fail-safe function like a fuse on your product if failure would follow an electric shock, fire or fume. 4. LOAD REDUCTION AND SELF-GENERATED HEAT DURING APPLICATION OF HIGH-FREQUENCY AND HIGH-VOLTAGE Since the heat generated by the low-dissipation capacitor itself is low, its allowable power is much higher than the general B characteristic. However, in case such an applied load that the self-heating temperature is 20 °C at the rated voltage, the allowable power may be exceeded. Therefore, when using the low-dissipation capacitors in a high-frequency and high-voltage circuit with a frequency of 1kHz or higher, make sure that the Vp-p values including the DC bias, do not exceed the applied voltage value specified in Table 1. Also make sure that the self-heating temperature (the difference between the capacitor’s surface temperature and the capacitor’s ambient temperature) at an ambient temperature of 25 °C does not exceed the value specified in Table 1. As shown in Fig. 1, the self-heating temperature depends on the ambient temperature. Therefore, if you are not able to set the ambient temperature to approximately 25 °C, please contact our sales representatives or product engineers. Allowable Conditions at High-frequency SL Allowable Conditions at High-frequency *2 Self-heating Temp. (25 °C Ambient Temp.) Capacitor’s Ambient Temp. *1 1kV Applied Voltage (max.) 1000Vp-p 2kV 2000Vp-p 5 °C max. -25 to +85 °C Temp. DC Rated Char. Voltage 3.15kV 3150Vp-p *1 When the ambient temperature is 85 to 125 °C, the applied voltage needs to be further reduced. If the low-dissipation capacitors needs to be used at an ambient temperature of 85 to 125 °C, please contact our sales representatives or product engineers. *2 Fig. 2 shows reference data on the allowable voltage-frequency characteristic for a sine wave voltage. EGD20E 1 / 21 Reference only Dependence of Self-heating Temperature on Ambient Temperature Allowable Voltage (Sine Wave Voltage) – Frequency Characteristic [At Ambient Temperature of 85 °C or less] Because of the influence of harmonics, when the applied voltage is a rectangular wave or pulse wave voltage (instead of a sine wave voltage), the heat generated by the capacitor is higher than the value obtained by application of the sine wave with the same fundamental frequency. Roughly calculated for reference, the allowable voltage for a rectangular wave or pulse wave corresponds approximately to the allowable voltage for a sine wave whose fundamental frequency is twice as large as that of the rectangular wave or pulse wave. This allowable voltage, however, varies depending on the voltage and current waveforms. Therefore, you are requested to make sure that the self-heating temperature is not higher than the value specified in Table 1. 5. VIBRATION AND IMPACT Do not expose a capacitor or its leads to excessive shock or vibration during use. 6. SOLDERING When soldering this product to a PCB/PWB, do not exceed the solder heat resistance specification of the capacitor. Subjecting this product to excessive heating could melt the internal junction solder and may result in thermal shocks that can crack the ceramic element. When soldering capacitor with a soldering iron, it should be performed in following conditions. Temperature of iron tip : 400 °C max. Soldering iron wattage : 50W max. Soldering time : 3.5 s max. EGD20E 2 / 21 Reference only 7. BONDING, RESIN MOLDING AND COATING In case of bonding, molding or coating this product, verify that these processes do not affect the quality of capacitor by testing the performance of the bonded, molded or coated product in the intended equipment. In case of the amount of applications, dryness / hardening conditions of adhesives and molding resins containing organic solvents (ethyl acetate, methyl ethyl ketone, toluene, etc.) are unsuitable, the outer coating resin of a capacitor is damaged by the organic solvents and it may result, worst case, in a short circuit. The variation in thickness of adhesive, molding resin or coating may cause a outer coating resin cracking and/or ceramic element cracking of a capacitor in a temperature cycling. 8. TREATMENT AFTER BONDING, RESIN MOLDING AND COATING When the outer coating is hot (over 100 ℃) after soldering, it becomes soft and fragile. So please be careful not to give it mechanical stress. Failure to follow the above cautions may result, worst case, in a short circuit and cause fuming or partial dispersion when the product is used. 9. OPERATING AND STORAGE ENVIRONMENT The insulating coating of capacitors does not form a perfect seal; therefore, do not use or store capacitors in a corrosive atmosphere, especially where chloride gas, sulfide gas, acid, alkali, salt or the like are present. And avoid exposure to moisture. Before cleaning, bonding, or molding this product, verify that these processes do not affect product quality by testing the performance of a cleaned, bonded or molded product in the intended equipment. Store the capacitors where the temperature and relative humidity do not exceed -10 to 40 °C and 15 to 85%. Use capacitors within 6 months after delivered. Check the solderability after 6 months or more. 10. LIMITATION OF APPLICATIONS Please contact us before using our products for the applications listed below which require especially high reliability for the prevention of defects which might directly cause damage to the third party’s life, body or property. 1. Aircraft equipment 2. Aerospace equipment 3. Undersea equipment 4. Power plant control equipment 5. Medical equipment 6. Transportation equipment (vehicles, trains, ships, etc.) 7. Traffic signal equipment 8. Disaster prevention / crime prevention equipment 9. Data-processing equipment exerting influence on public 10. Application of similar complexity and/or reliability requirements to the applications listed in the above. EGD20E 3 / 21 Reference only NOTICE 1. CLEANING (ULTRASONIC CLEANING) To perform ultrasonic cleaning, observe the following conditions. Rinse bath capacity : Output of 20 watts per liter or less. Rinsing time : 5 min maximum. Do not vibrate the PCB/PWB directly. Excessive ultrasonic cleaning may lead to fatigue destruction of the lead wires. 2. CAPACITANCE CHANGE OF CAPACITORS - Class 1 capacitors Capacitance might change a little depending on a surrounding temperature or an applied voltage. Please contact us if you use for the strict time constant circuit. - Class 2 and 3 capacitors Class 2 and 3 capacitors like temperature characteristic B, E and F have an aging characteristic, whereby the capacitor continually decreases its capacitance slightly if the capacitor leaves for a long time. Moreover, capacitance might change greatly depending on a surrounding temperature or an applied voltage. So, it is not likely to be able to use for the time constant circuit. Please contact us if you need a detail information. NOTE 1.Please make sure that your product has been evaluated in view of your specifications with our product being mounted to your product. 2.You are requested not to use our product deviating from this specification. EGD20E 4 / 21 Reference only 1. Application This specification is applied to High Temperature Lead Type Disc Ceramic Capacitors of DC2kV ～3.15kV ratings and Class 1 of DEA series used for General Electric equipment. Do not use these products in any automotive power train or safety equipment including battery chargers for electric vehicles and plug-in hybrids. 2. Rating 2-1. Operating temperature range -25  +125C 2-2. Part number configuration ex.) DEA Series 1X 3D 561 J B3 B Temperature Rated Capacitance Capacitance Lead Packing Individual characteristic voltage tolerance code style code specification . Temperature characteristic Code Temperature characteristic 1X SL Please confirm detailed specification on  Specification and test methods .  Rated voltage Code 3D 3F Rated voltage DC2kV DC3.15kV  Capacitance The first two digits denote significant figures ; the last digit denotes the multiplier of 10 in pF. ex.) In case of 561. 56101 = 560pF  Capacitance tolerance Please refer to  Part number list .  Lead code Code Lead style Vertical crimp long type A Straight long type C Vertical crimp short type B Straight short type D Vertical crimp taping type N Straight taping type P  Please refer to  Part number list . Solder coated copper wire is applied for termination.  Packing style code Code B A Packing type Bulk type Ammo pack taping type  Individual specification In case part number cannot be identified without ‘individual specification’ , it is added at the end of part number. 5 / 21 Reference only 3. Marking Nominal capacitance Capacitance tolerance Rated voltage Company name code Manufacturing year Manufacturing month : Actual value(under 100pF) 3 digit system(100pF and over) : Code (Omitted for maximum body diameter  6mm and under) : Letter code(In case of DC3.15kV, marked with 3KV) : Abbreviation (Omitted for maximum body diameter  9mm and under) : Letter code(The last digit of A.D. year.) (Omitted for maximum body diameter  5mm and under) : Code (Omitted for maximum body diameter  5mm and under) Feb./Mar.  2 Aug./Sep.  8 Apr./May  4 Oct./Nov.  O Jun./Jul.  6 Dec./Jan.  D (Example) 561J 2KV 6 / 21 Reference only 4. Part number list Unit : mm T.C. Cap. (pF) Cap. tol. Customer Part Number Murata Part Number Dimension (mm) DC Rated Volt. (V) D T F d Lead Code Pack qty. (pcs) SL 10 ±5% DEA1X3D100JC1B 2000 4.5 5.0 5.0 0.5 C1 500 SL 12 ±5% DEA1X3D120JC1B 2000 4.5 5.0 5.0 0.5 C1 500 SL 15 ±5% DEA1X3D150JC1B 2000 4.5 5.0 5.0 0.5 C1 500 SL 18 ±5% DEA1X3D180JC1B 2000 4.5 5.0 5.0 0.5 C1 500 SL 22 ±5% DEA1X3D220JC1B 2000 4.5 5.0 5.0 0.5 C1 500 SL 27 ±5% DEA1X3D270JC1B 2000 4.5 5.0 5.0 0.5 C1 500 SL 33 ±5% DEA1X3D330JC1B 2000 4.5 5.0 5.0 0.5 C1 500 SL 39 ±5% DEA1X3D390JC1B 2000 5.0 5.0 5.0 0.5 C1 500 SL 47 ±5% DEA1X3D470JA2B 2000 6.0 5.0 5.0 0.6 A2 500 SL 56 ±5% DEA1X3D560JA2B 2000 6.0 5.0 5.0 0.6 A2 500 SL 68 ±5% DEA1X3D680JA2B 2000 6.0 5.0 5.0 0.6 A2 500 SL 82 ±5% DEA1X3D820JA2B 2000 7.0 5.0 5.0 0.6 A2 500 SL 100 ±5% DEA1X3D101JA2B 2000 7.0 5.0 5.0 0.6 A2 500 SL 120 ±5% DEA1X3D121JA2B 2000 8.0 5.0 5.0 0.6 A2 250 SL 150 ±5% DEA1X3D151JA2B 2000 8.0 5.0 5.0 0.6 A2 250 SL 180 ±5% DEA1X3D181JA2B 2000 9.0 5.0 5.0 0.6 A2 250 SL 220 ±5% DEA1X3D221JA2B 2000 10.0 5.0 5.0 0.6 A2 250 SL 270 ±5% DEA1X3D271JA2B 2000 11.0 5.0 5.0 0.6 A2 250 SL 330 ±5% DEA1X3D331JA3B 2000 12.0 5.0 7.5 0.6 A3 200 SL 390 ±5% DEA1X3D391JA3B 2000 13.0 5.0 7.5 0.6 A3 200 SL 470 ±5% DEA1X3D471JA3B 2000 14.0 5.0 7.5 0.6 A3 200 SL 560 ±5% DEA1X3D561JA3B 2000 15.0 5.0 7.5 0.6 A3 100 SL 10 ±5% DEA1X3F100JCDB 3150 5.0 6.0 7.5 0.5 CD 500 SL 12 ±5% DEA1X3F120JCDB 3150 5.0 6.0 7.5 0.5 CD 500 SL 15 ±5% DEA1X3F150JCDB 3150 5.0 6.0 7.5 0.5 CD 500 SL 18 ±5% DEA1X3F180JCDB 3150 5.0 6.0 7.5 0.5 CD 500 SL 22 ±5% DEA1X3F220JCDB 3150 5.0 6.0 7.5 0.5 CD 500 7 / 21 Reference only Unit : mm T.C. Cap. (pF) Cap. tol. Customer Part Number Murata Part Number Dimension (mm) DC Rated Volt. (V) D T F d Lead Code Pack qty. (pcs) SL 27 ±5% DEA1X3F270JC3B 3150 6.0 6.0 7.5 0.6 C3 500 SL 33 ±5% DEA1X3F330JC3B 3150 6.0 6.0 7.5 0.6 C3 500 SL 39 ±5% DEA1X3F390JC3B 3150 6.0 6.0 7.5 0.6 C3 500 SL 47 ±5% DEA1X3F470JC3B 3150 7.0 6.0 7.5 0.6 C3 250 SL 56 ±5% DEA1X3F560JC3B 3150 7.0 6.0 7.5 0.6 C3 250 SL 68 ±5% DEA1X3F680JA3B 3150 8.0 6.0 7.5 0.6 A3 250 SL 82 ±5% DEA1X3F820JA3B 3150 8.0 6.0 7.5 0.6 A3 250 SL 100 ±5% DEA1X3F101JA3B 3150 9.0 6.0 7.5 0.6 A3 250 SL 120 ±5% DEA1X3F121JA3B 3150 10.0 6.0 7.5 0.6 A3 250 SL 150 ±5% DEA1X3F151JA3B 3150 11.0 6.0 7.5 0.6 A3 250 SL 180 ±5% DEA1X3F181JA3B 3150 11.0 6.0 7.5 0.6 A3 250 SL 220 ±5% DEA1X3F221JA3B 3150 12.0 6.0 7.5 0.6 A3 200 SL 270 ±5% DEA1X3F271JA3B 3150 14.0 6.0 7.5 0.6 A3 200 SL 330 ±5% DEA1X3F331JA3B 3150 15.0 6.0 7.5 0.6 A3 100 SL 390 ±5% DEA1X3F391JA3B 3150 16.0 6.0 7.5 0.6 A3 100 8 / 21 Reference only Unit : mm T.C. Cap. (pF) Cap. tol. Customer Part Number Murata Part Number Dimension (mm) DC Rated Volt. (V) D T F d Lead Code Pack qty. (pcs) SL 10 ±5% DEA1X3D100JD1B 2000 4.5 5.0 5.0 0.5 D1 500 SL 12 ±5% DEA1X3D120JD1B 2000 4.5 5.0 5.0 0.5 D1 500 SL 15 ±5% DEA1X3D150JD1B 2000 4.5 5.0 5.0 0.5 D1 500 SL 18 ±5% DEA1X3D180JD1B 2000 4.5 5.0 5.0 0.5 D1 500 SL 22 ±5% DEA1X3D220JD1B 2000 4.5 5.0 5.0 0.5 D1 500 SL 27 ±5% DEA1X3D270JD1B 2000 4.5 5.0 5.0 0.5 D1 500 SL 33 ±5% DEA1X3D330JD1B 2000 4.5 5.0 5.0 0.5 D1 500 SL 39 ±5% DEA1X3D390JD1B 2000 5.0 5.0 5.0 0.5 D1 500 SL 47 ±5% DEA1X3D470JB2B 2000 6.0 5.0 5.0 0.6 B2 500 SL 56 ±5% DEA1X3D560JB2B 2000 6.0 5.0 5.0 0.6 B2 500 SL 68 ±5% DEA1X3D680JB2B 2000 6.0 5.0 5.0 0.6 B2 500 SL 82 ±5% DEA1X3D820JB2B 2000 7.0 5.0 5.0 0.6 B2 500 SL 100 ±5% DEA1X3D101JB2B 2000 7.0 5.0 5.0 0.6 B2 500 SL 120 ±5% DEA1X3D121JB2B 2000 8.0 5.0 5.0 0.6 B2 500 SL 150 ±5% DEA1X3D151JB2B 2000 8.0 5.0 5.0 0.6 B2 500 SL 180 ±5% DEA1X3D181JB2B 2000 9.0 5.0 5.0 0.6 B2 500 SL 220 ±5% DEA1X3D221JB2B 2000 10.0 5.0 5.0 0.6 B2 500 SL 270 ±5% DEA1X3D271JB2B 2000 11.0 5.0 5.0 0.6 B2 500 SL 330 ±5% DEA1X3D331JB3B 2000 12.0 5.0 7.5 0.6 B3 250 SL 390 ±5% DEA1X3D391JB3B 2000 13.0 5.0 7.5 0.6 B3 250 SL 470 ±5% DEA1X3D471JB3B 2000 14.0 5.0 7.5 0.6 B3 250 SL 560 ±5% DEA1X3D561JB3B 2000 15.0 5.0 7.5 0.6 B3 200 SL 10 ±5% DEA1X3F100JDDB 3150 5.0 6.0 7.5 0.5 DD 500 SL 12 ±5% DEA1X3F120JDDB 3150 5.0 6.0 7.5 0.5 DD 500 SL 15 ±5% DEA1X3F150JDDB 3150 5.0 6.0 7.5 0.5 DD 500 SL 18 ±5% DEA1X3F180JDDB 3150 5.0 6.0 7.5 0.5 DD 500 SL 22 ±5% DEA1X3F220JDDB 3150 5.0 6.0 7.5 0.5 DD 500 9 / 21 Reference only Unit : mm T.C. Cap. (pF) Cap. tol. Customer Part Number Murata Part Number Dimension (mm) DC Rated Volt. (V) D T F d Lead Code Pack qty. (pcs) SL 27 ±5% DEA1X3F270JD3B 3150 6.0 6.0 7.5 0.6 D3 500 SL 33 ±5% DEA1X3F330JD3B 3150 6.0 6.0 7.5 0.6 D3 500 SL 39 ±5% DEA1X3F390JD3B 3150 6.0 6.0 7.5 0.6 D3 500 SL 47 ±5% DEA1X3F470JD3B 3150 7.0 6.0 7.5 0.6 D3 500 SL 56 ±5% DEA1X3F560JD3B 3150 7.0 6.0 7.5 0.6 D3 500 SL 68 ±5% DEA1X3F680JB3B 3150 8.0 6.0 7.5 0.6 B3 500 SL 82 ±5% DEA1X3F820JB3B 3150 8.0 6.0 7.5 0.6 B3 500 SL 100 ±5% DEA1X3F101JB3B 3150 9.0 6.0 7.5 0.6 B3 500 SL 120 ±5% DEA1X3F121JB3B 3150 10.0 6.0 7.5 0.6 B3 500 SL 150 ±5% DEA1X3F151JB3B 3150 11.0 6.0 7.5 0.6 B3 500 SL 180 ±5% DEA1X3F181JB3B 3150 11.0 6.0 7.5 0.6 B3 500 SL 220 ±5% DEA1X3F221JB3B 3150 12.0 6.0 7.5 0.6 B3 250 SL 270 ±5% DEA1X3F271JB3B 3150 14.0 6.0 7.5 0.6 B3 250 SL 330 ±5% DEA1X3F331JB3B 3150 15.0 6.0 7.5 0.6 B3 200 SL 390 ±5% DEA1X3F391JB3B 3150 16.0 6.0 7.5 0.6 B3 200 10 / 21 Reference only Unit : mm T.C. Cap. (pF) Cap. tol. Customer Part Number Murata Part Number Dimension (mm) DC Rated volt. (V) D T F d P Lead code Pack qty. (pcs) SL 10 ±5% DEA1X3D100JP2A 2000 4.5 5.0 5.0 0.6 12.7 P2 1500 SL 12 ±5% DEA1X3D120JP2A 2000 4.5 5.0 5.0 0.6 12.7 P2 1500 SL 15 ±5% DEA1X3D150JP2A 2000 4.5 5.0 5.0 0.6 12.7 P2 1500 SL 18 ±5% DEA1X3D180JP2A 2000 4.5 5.0 5.0 0.6 12.7 P2 1500 SL 22 ±5% DEA1X3D220JP2A 2000 4.5 5.0 5.0 0.6 12.7 P2 1500 SL 27 ±5% DEA1X3D270JP2A 2000 4.5 5.0 5.0 0.6 12.7 P2 1500 SL 33 ±5% DEA1X3D330JP2A 2000 4.5 5.0 5.0 0.6 12.7 P2 1500 SL 39 ±5% DEA1X3D390JP2A 2000 5.0 5.0 5.0 0.6 12.7 P2 1500 SL 47 ±5% DEA1X3D470JN2A 2000 6.0 5.0 5.0 0.6 12.7 N2 1500 SL 56 ±5% DEA1X3D560JN2A 2000 6.0 5.0 5.0 0.6 12.7 N2 1500 SL 68 ±5% DEA1X3D680JN2A 2000 6.0 5.0 5.0 0.6 12.7 N2 1500 SL 82 ±5% DEA1X3D820JN2A 2000 7.0 5.0 5.0 0.6 12.7 N2 1500 SL 100 ±5% DEA1X3D101JN2A 2000 7.0 5.0 5.0 0.6 12.7 N2 1500 SL 120 ±5% DEA1X3D121JN2A 2000 8.0 5.0 5.0 0.6 12.7 N2 1500 SL 150 ±5% DEA1X3D151JN2A 2000 8.0 5.0 5.0 0.6 12.7 N2 1500 SL 180 ±5% DEA1X3D181JN2A 2000 9.0 5.0 5.0 0.6 12.7 N2 1500 SL 220 ±5% DEA1X3D221JN2A 2000 10.0 5.0 5.0 0.6 12.7 N2 1500 SL 270 ±5% DEA1X3D271JN2A 2000 11.0 5.0 5.0 0.6 12.7 N2 1500 SL 330 ±5% DEA1X3D331JN3A 2000 12.0 5.0 7.5 0.6 15.0 N3 900 SL 390 ±5% DEA1X3D391JN3A 2000 13.0 5.0 7.5 0.6 15.0 N3 900 SL 470 ±5% DEA1X3D471JN7A 2000 14.0 5.0 7.5 0.6 30.0 N7 500 SL 560 ±5% DEA1X3D561JN7A 2000 15.0 5.0 7.5 0.6 30.0 N7 500 SL 10 ±5% DEA1X3F100JP3A 3150 5.0 6.0 7.5 0.6 15.0 P3 900 SL 12 ±5% DEA1X3F120JP3A 3150 5.0 6.0 7.5 0.6 15.0 P3 900 SL 15 ±5% DEA1X3F150JP3A 3150 5.0 6.0 7.5 0.6 15.0 P3 900 SL 18 ±5% DEA1X3F180JP3A 3150 5.0 6.0 7.5 0.6 15.0 P3 900 SL 22 ±5% DEA1X3F220JP3A 3150 5.0 6.0 7.5 0.6 15.0 P3 900 11 / 21 Reference only Unit : mm T.C. Cap. (pF) Cap. tol. Customer Part Number Murata Part Number Dimension (mm) DC Rated volt. (V) D T F d P Lead code Pack qty. (pcs) SL 27 ±5% DEA1X3F270JP3A 3150 6.0 6.0 7.5 0.6 15.0 P3 900 SL 33 ±5% DEA1X3F330JP3A 3150 6.0 6.0 7.5 0.6 15.0 P3 900 SL 39 ±5% DEA1X3F390JP3A 3150 6.0 6.0 7.5 0.6 15.0 P3 900 SL 47 ±5% DEA1X3F470JP3A 3150 7.0 6.0 7.5 0.6 15.0 P3 900 SL 56 ±5% DEA1X3F560JP3A 3150 7.0 6.0 7.5 0.6 15.0 P3 900 SL 68 ±5% DEA1X3F680JN3A 3150 8.0 6.0 7.5 0.6 15.0 N3 900 SL 82 ±5% DEA1X3F820JN3A 3150 8.0 6.0 7.5 0.6 15.0 N3 900 SL 100 ±5% DEA1X3F101JN3A 3150 9.0 6.0 7.5 0.6 15.0 N3 900 SL 120 ±5% DEA1X3F121JN3A 3150 10.0 6.0 7.5 0.6 15.0 N3 900 SL 150 ±5% DEA1X3F151JN3A 3150 11.0 6.0 7.5 0.6 15.0 N3 900 SL 180 ±5% DEA1X3F181JN3A 3150 11.0 6.0 7.5 0.6 15.0 N3 900 SL 220 ±5% DEA1X3F221JN3A 3150 12.0 6.0 7.5 0.6 15.0 N3 900 SL 270 ±5% DEA1X3F271JN7A 3150 14.0 6.0 7.5 0.6 30.0 N7 500 SL 330 ±5% DEA1X3F331JN7A 3150 15.0 6.0 7.5 0.6 30.0 N7 500 SL 390 ±5% DEA1X3F391JN7A 3150 16.0 6.0 7.5 0.6 30.0 N7 500 12 / 21 Reference only 5. Specification and test methods No. Item 1 Appearance and dimensions 2 3 4 Marking Dielectric strength Between lead wires Body insulation No failure. Between lead wires 10 000MΩ min. 5 Insulation Resistance (I.R.) Capacitance 6 Q 7 Temperature characteristic 8 Strength of lead Specification No marked defect on appearance form and dimensions. Please refer to [Part number list]. To be easily legible. No failure. Within specified tolerance. Pull 400+20C*²min. (30pF under) 1 000 min. (30pF min.) +350 to -1 000ppm/°C (Temp. range: +20 to +85°C) Step 1 2 3 4 5 Temp.(°C) 20±2 -25±3 20±2 85±2 20±2 Lead wire should not cut off. Capacitor should not be broken. Bending 9 Vibration resistance Appearance Capacitance Q 10 Solderability of leads Test method The capacitor should be inspected by naked eyes for visible evidence of defect. Dimensions should be measured with slide calipers. The capacitor should be inspected by naked eyes. The capacitor should not be damaged when DC voltage of 200% of the rated voltage are applied between the lead wires for 1 to 5 s. (Charge/Discharge current≤50mA.) The capacitor is placed in the container with metal balls of diameter 1mm so that each lead wire, shortcircuited, is kept about 2mm off the balls as shown in the figure, and AC1 250V (r.m.s.) is applied for 1 to 5 s About 2mm between capacitor lead Metal balls wires and small metals. (Charge/Discharge current≤50mA.) The insulation resistance should be measured with DC500±50V within 60±5 s of charging. The capacitance should be measured at 20°C with 1±0.2MHz and AC5V(r.m.s.) max.. The Q should be measured at 20°C with 1±0.2MHz and AC5V(r.m.s.) max.. The capacitance measurement should be made at each step specified in Table. No marked defect. Within specified tolerance. 400+20C*²min. (30pF under) 1 000 min. (30pF min.) Lead wire should be soldered with uniformly coated on the axial direction over 3/4 of the circumferential direction. *² "C " expresses nominal capacitance value (pF) ESDEA01A 13 / 21 As shown in the figure at right, fix the body of the capacitor and apply a tensile weight gradually to each lead wire in the radial direction of the capacitor up to 10N ( 5N for lead diameter 0.5mm ), and keep it for 10±1 s. Each lead wire should be subjected to 5N ( 2.5N for lead diameter 0.5mm ) of weight and bent 90° at the point of egress, in one direction, then returned to its original position, and bent 90° in the opposite direction at the rate of one bend in 2 to 3 s. The capacitor should be firmly soldered to the supporting lead wire and vibrated at a frequency range of 10 to 55Hz, 1.5mm in total amplitude, with about a 1min rate of vibration change from 10Hz to 55Hz and back to 10Hz. Apply for a total of 6 h; 2 h each in 3 mutually perpendicular directions. The lead wire of a capacitor should be dipped into a ethanol solution of 25wt% rosin and then into molten solder for 2±0.5 s. In both cases the depth of dipping is up to about 1.5 to 2mm from the root of lead wires. Temp. of solder : 245±5°C Lead Free Solder (Sn-3Ag-0.5Cu) 235±5°C H63 Eutectic Solder Reference only No. 11 12 13 14 15 Item Soldering effect Appearance (Non-preheat) Capacitance change Dielectric strength (Between lead wires) Specification No marked defect. Within ± 2.5% Soldering effect (On-preheat) No marked defect. Within ± 2.5% Humidity (Under steady state) Humidity loading Life Appearance Capacitance change Dielectric strength (Between lead wires) Temperature cycle Per item 3. Appearance Capacitance change Q No marked defect. Within ± 5% I.R. Appearance Capacitance change Q 1 000MΩ min. No marked defect. Within ± 5% I.R. Appearance Capacitance change Q I.R. 16 Per item 3. Appearance Capacitance change Q I.R. Dielectric strength (Between lead wires) 275+5/2C*²min. (30pF under) 350 min. (30pF min.) 275+5/2C*²min. (30pF under) 350 min. (30pF min.) 1 000MΩ min. No marked defect. Within ± 3% 275+5/2C*²min. (30pF under) 350 min. (30pF min.) 2 000MΩ min. No marked defect. Within ± 5% 275+5/2C*²min. (30pF under) 350 min. (30pF min.) 1 000MΩ min. Per item 3. Test method The lead wire should be immersed into the melted solder of 350±10°C ( Body of φ5 and under: 270±5°C ) up to about 1.5 to 2.0mm from the main body for 3.5±0.5 s. ( Body of φ5 and under: 5±0.5 s. ) Post-treatment : Capacitor should be stored for 1 to 2 h at *¹room condition. First the capacitor should be stored at 120+0/-5°C for 60+0/-5 s. Then, as in figure, the lead wires should be immersed solder of 260+0/-5°C up to 1.5 to 2.0mm from the root of terminal for 7.5+0/-1 s. Post-treatment : Capacitor should be stored for 1 to 2 h at *¹room condition. Set the capacitor for 500 +24/-0 h at 40±2°C in 90 to 95% relative humidity. Post-treatment : Capacitor should be stored for 1 to 2 h at *¹room condition. Apply the rated voltage for 500 +24/-0 h at 40±2°C in 90 to 95% relative humidity. (Charge/Discharge current≤50mA.) Post-treatment : Capacitor should be stored for 1 to 2 h at *¹room condition. Apply a DC voltage of 150% of the rated voltage for 1 000 +48/-0 h at 125±2°C, and relative humidity of 50% max.. (Charge/Discharge current≤50mA.) Post-treatment : Capacitor should be stored for 1 to 2 h at *¹room condition. The capacitor should be subjected to 5 temperature cycles. Step Temperature(°C) Time 1 30 min -25±3 2 Room Temp. 3 min 3 30 min +125±3 4 Room Temp. 3 min Cycle time : 5 cycle Post-treatment : Capacitor should be stored for 1 to 2 h at *¹room condition. *¹ "room condition" Temperature: 15 to 35°C, Relative humidity: 45 to 75%, Atmospheric pressure: 86 to 106kPa *² "C" expresses nominal capacitance value (pF) ESDEA01A 14 / 21 Reference only 6.Packing specification •Bulk type (Packing style code : B) ∗1 ∗2 The number of packing = Packing quantity × n The size of packing case and packing way ∗1 : Please refer to [Part number list]. ∗2 : Standard n = 20 (bag) Polyethylene bag Partition 270 max. 125 max. 340 max. Note) The outer package and the number of outer packing be changed by the order getting amount. Unit : mm •Ammo pack taping type (Packing style code : A) ⋅ The tape with capacitors is packed zigzag into a case. ⋅ When body of the capacitor is piled on other body under it. ⋅ There should be 3 pitches and over without capacitors in leader and trailer. The size of packing case and packing way 240 max. Position of label 340 max. 60 max. Capacitor Hold down tape Base tape Hold down tape upper EKBCDE01 15 / 21 Unit : mm Reference only 7. Taping specification 7-1. Dimension of capacitors on tape Vertical crimp taping type < Lead code : N2 > Pitch of component 12.7mm / Lead spacing 5.0mm ∗ Unit : mm Item Code Dimensions Remarks Pitch of component P 12.7±1.0 Pitch of sprocket hole P0 12.7±0.3 Lead spacing F 5.0± 0.2 Length from hole center to component center P2 6.35±1.3 Length from hole center to lead P1 3.85±0.7 Body diameter D Please refer to [Part number list ]. Deviation along tape, left or right ∆S 0±1.0 Carrier tape width W 18.0±0.5 Position of sprocket hole W1 9.0±0.5 H0 18.0± 2.0 0 Lead distance between reference and bottom planes 0.8 Deviation of progress direction They include deviation by lead bend . Deviation of tape width direction +0.5∼−1.0 Protrusion length Diameter of sprocket hole φD0 4.0±0.1 Lead diameter φd 0.60±0.05 Total tape thickness t1 0.6±0.3 Total thickness, tape and lead wire t2 1.5 max. Deviation across tape, front ∆h1 Deviation across tape, rear ∆h2 Portion to cut in case of defect L 11.0± 1.0 Hold down tape width W0 11.5 min. Hold down tape position W2 1.5±1.5 Coating extension on lead e Up to the end of crimp Body thickness T Please refer to [Part number list ]. They include hold down tape thickness. 1.0 max. 0 ETP1N201A 16 / 21 Reference only Vertical crimp taping type < Lead code : N3 > Pitch of component 15.0mm / Lead spacing 7.5mm ∗ Unit : mm Item Code Dimensions Remarks Pitch of component P 15.0±2.0 Pitch of sprocket hole P0 15.0±0.3 Lead spacing F 7.5±1.0 Length from hole center to component center P2 7.5±1.5 Length from hole center to lead P1 3.75±1.0 Body diameter D Please refer to [ Part number list ]. Deviation along tape, left or right ∆S 0±2.0 Carrier tape width W 18.0±0.5 Position of sprocket hole W1 9.0±0.5 H0 18.0± 2.0 0 Lead distance between reference and bottom planes Deviation of progress direction They include deviation by lead bend . Deviation of tape width direction +0.5∼−1.0 Protrusion length Diameter of sprocket hole φD0 4.0±0.1 Lead diameter φd 0.60±0.05 Total tape thickness t1 0.6±0.3 Total thickness, tape and lead wire t2 1.5 max. Deviation across tape, front ∆h1 Deviation across tape, rear ∆h2 Portion to cut in case of defect L 11.0± 1.0 Hold down tape width W0 11.5 min. Hold down tape position W2 1.5±1.5 Coating extension on lead e Up to the end of crimp Body thickness T Please refer to [ Part number list ]. They include hold down tape thickness. 2.0 max. 0 ETP1N30101A 17 / 21 Reference only Vertical crimp taping type < Lead code : N7 > Pitch of component 30.0mm /Lead spacing 7.5mm Unit : mm Item Code Dimensions Remarks Pitch of component P 30.0±2.0 Pitch of sprocket hole P0 15.0±0.3 Lead spacing F 7.5±1.0 Length from hole center to component center P2 7.5±1.5 Length from hole center to lead P1 3.75±1.0 Body diameter D Please refer to [ Part number list ]. Deviation along tape, left or right ∆S 0±2.0 Carrier tape width W 18.0±0.5 Position of sprocket hole W1 9.0±0.5 H0 18.0± 2.0 0 Lead distance between reference and bottom planes Deviation of progress direction They include deviation by lead bend. Deviation of tape width direction +0.5∼−1.0 Protrusion length Diameter of sprocket hole φD0 4.0±0.1 Lead diameter φd 0.60±0.05 Total tape thickness t1 0.6±0.3 Total thickness, tape and lead wire t2 1.5 max. Deviation across tape, front ∆h1 Deviation across tape, rear ∆h2 Portion to cut in case of defect L 11.0± 1.0 Hold down tape width W0 11.5 min. Hold down tape position W2 1.5±1.5 Coating extension on lead e Up to the end of crimp Body thickness T Please refer to [ Part number list ]. They include hold down tape thickness. 2.0 max. 0 ETP1N70101A 18 / 21 Reference only Straight taping type < Lead code: P2 > Pitch of component 12.7mm / Lead spacing 5.0mm Unit : mm Item Code Dimensions Remarks Pitch of component P 12.7±1.0 Pitch of sprocket hole P0 12.7±0.3 Lead spacing F 5.0±0.2 Length from hole center to component center P2 6.35±1.3 Length from hole center to lead P1 3.85±0.7 Body diameter D Please refer to [ Part number list ]. Deviation along tape, left or right ∆S 0±1.0 Carrier tape width W 18.0±0.5 Position of sprocket hole W1 9.0±0.5 H 20.0±1.5 1.0 Lead distance between reference and bottom planes 0.8 Deviation of progress direction They include deviation by lead bend . Deviation of tape width direction +0.5∼−1.0 Protrusion length Diameter of sprocket hole φD0 4.0±0.1 Lead diameter φd 0.60±0.05 Total tape thickness t1 0.6±0.3 Total thickness, tape and lead wire t2 1.5 max. Deviation across tape, front ∆h1 Deviation across tape, rear ∆h2 Portion to cut in case of defect L 11.0± 1.0 Hold down tape width W0 11.5 min. Hold down tape position W2 1.5±1.5 Coating extension on lead e 3.0 max. Body thickness T Please refer to [ Part number list ]. They include hold down tape thickness. 1.0 max. 0 ETP1P20101A 19 / 21 Reference only Straight taping type < Lead code : P3 > Pitch of component 15.0mm / Lead spacing 7.5mm Unit : mm Item Code Dimensions Remarks Pitch of component P 15.0±2.0 Pitch of sprocket hole P0 15.0±0.3 Lead spacing F 7.5±1.0 Length from hole center to component center P2 7.5±1.5 Length from hole center to lead P1 3.75±1.0 Body diameter D Please refer to [ Part number list ]. Deviation along tape, left or right ∆S 0±2.0 Carrier tape width W 18.0±0.5 Position of sprocket hole W1 9.0±0.5 H 20.0± 1.5 1.0 Lead distance between reference and bottom planes Deviation of progress direction They include deviation by lead bend . Deviation of tape width direction +0.5∼−1.0 Protrusion length Diameter of sprocket hole φD0 4.0±0.1 Lead diameter φd 0.60±0.05 Total tape thickness t1 0.6±0.3 Total thickness, tape and lead wire t2 1.5 max. Deviation across tape, front ∆h1 Deviation across tape, rear ∆h2 Portion to cut in case of defect L 11.0± 1.0 Hold down tape width W0 11.5 min. Hold down tape position W2 1.5±1.5 Coating extension on lead e 3.0 max. Body thickness T Please refer to [ Part number list ]. They include hold down tape thickness. 2.0 max. 0 ETP1P30101A 20 / 21 Reference only 7-2. Splicing way of tape 1) Adhesive force of tape is over 3N at test condition as below. W Hold down tape Base tape 2) Splicing of tape a) When base tape is spliced •Base tape should be spliced by cellophane tape. (Total tape thickness should be less than 1.05mm.) Progress direction in production line Hold down tape Base tape About 30 to 50 Cellophane tape No lifting for the direction of progressing Unit : mm b) When hold down tape is spliced •Hold down tape should be spliced with overlapping. (Total tape thickness should be less than 1.05mm.) ape are spliced •Base tape and adhesive tape should be spliced with splicing tape. 20 to 60 Hold down tape Progress direction in production line Base tape Unit : mm c) When both tape are spliced •Base tape and hold down tape should be spliced with splicing tape. 3 ) Missing components •There should be no consecutive missing of more than three components. •The number of missing components should be not more than 0.5% of total components that should be present in a Ammo pack. ETP2D03 21 / 21 Appendix EU RoHS This products of the following crresponds to EU RoHS. RoHS 　maximum concentration values tolerated by weight in homogeneous materials 　・1000 ppm maximum Lead 　・1000 ppm maximum Mercury 　・100 ppm maximum Cadmium 　・1000 ppm maximum Hexavalent chromium 　・1000 ppm maximum Polybrominated biphenyls (PBB) 　・1000 ppm maximum Polybrominated diphenyl ethers (PBDE)