RHS7G2A151J0M2H01A

Reference Specification 200°C Operation Leaded MLCC for Automotive with AEC-Q200 RHS Series Product specifications in this catalog are as of Nov. 2020, 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 Positional Measurement DC Voltage Vo-p DC+AC Voltage Vo-p AC Voltage Vp-p Pulse Voltage(1) Vp-p Pulse Voltage(2) 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. In case of Class 2 capacitors (Temp.Char. : X7R,X7S,X8L, etc.), applied voltage should be the load such as self-generated heat is within 20 °C on the condition of atmosphere temperature 25 °C. Please contact us if self-generated heat is occurred with Class 1 capacitors (Temp.Char. : C0G,U2J,X8G, etc.). 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. Excessive heat may lead to deterioration of the capacitor’s characteristics and reliability. 3. Fail-safe Be sure to provide an appropriate fail-safe function on your product to prevent a second damage that may be caused by the abnormal function or the failure of our product. 4. 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 5 to 40 °C and 20 to 70%. Use capacitors within 6 months. 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. 7. BONDING AND RESIN MOLDING, RESIN COAT 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 a bonded or molded 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 or molding resin may cause a outer coating resin cracking and/or ceramic element cracking of a capacitor in a temperature cycling. 8. TREATMENT AFTER BONDING AND RESIN MOLDING, RESIN COAT When the outer coating is hot (over 100 °C) after soldering, it becomes soft and fragile. So please be careful not to give it mechanical stress. EGLEDMNO03 1 / 13 Reference only 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. 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. 2. Aerospace equipment 1. Aircraft 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. 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. Soldering and Mounting Insertion of the Lead Wire • When soldering, insert the lead wire into the PCB without mechanically stressing the lead wire. • Insert the lead wire into the PCB with a distance appropriate to the lead space. 3. CAPACITANCE CHANGE OF CAPACITORS • Class 2 capacitors (Temp.Char. : X7R,X7S,X8L, etc.) Class 2 capacitors 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. EGLEDMNO03 2 / 13 Reference only 1. Application This specification is applied to 200°C Operation Leaded MLCC RHS series in accordance with AEC-Q200 requirements used for Automotive Electronic equipment. 2. Rating • Applied maximum temperature up to 200°C Note : Maximum accumulative time to 200°C is within 2000 hours. • Part number configuration ex.) RHS 7G 2A Series Temperature Characteristic • Series Code RHS Rated voltage 101 J 0 A2 H01 B Capacitance Capacitance tolerance Dimension code Lead code Individual specification code Packing style code Content Epoxy coated, 200°C max. • Temperature characteristic Temp. Code Temp. Range Char. -55～25°C CCG 7G 25～125°C (Murata code) 125～200°C • Rated voltage Code 2A Temp. coeff.(ppm/°C) 0+30/-72 0±30 0+72/-30 Standard Temp. Operating Temp. Range 25°C -55～200°C Rated voltage DC100V When the product temperature exceeds 150°C, please use this product within the voltage and temperature derated conditions in the figure below. ETRH08D 3 / 13 Reference only • Capacitance The first two digits denote significant figures ; the last digit denotes the multiplier of 10 in pF. ex.) In case of 101. 10×101 = 100pF • Capacitance tolerance Code Capacitance tolerance J +/-5% • Dimension code Code Dimensions (LxW) mm max. 0 3.9 x 3.5 1 4.2 x 3.5 • Lead code Code A2 DG K1 M2 Lead style Straight type Straight taping type Inside crimp type Inside crimp taping type Lead spacing (mm) 2.5+/-0.8 2.5+0.4/-0.2 5.0+/-0.8 5.0+0.6/-0.2 Lead wire is solder coated CP wire. • Individual specification code Murata’s control code Please refer to [ Part number list ]. • Packing style code Code Packing style A Taping type of Ammo B Bulk type 3. Marking Temp. char. : Letter code : 4 (CCG char.) Capacitance : 3 digit numbers Capacitance tolerance : Code (Ex.) Rated voltage 100V Dimension code 0,1 4 101J ETRH08D 4 / 13 Reference only 4. Part number list Unit : mm Customer Part Number Murata Part Number DC Rated T.C. Volt. (V) Cap. Cap. tol. Dimension (mm) L W W1 F T Size Pack Lead qty. Code (pcs) RHS7G2A101J0A2H01B CCG 100 100pF ±5% 3.9 3.5 - 2.5 2.6 0A2 500 RHS7G2A121J0A2H01B CCG 100 120pF ±5% 3.9 3.5 - 2.5 2.6 0A2 500 RHS7G2A151J0A2H01B CCG 100 150pF ±5% 3.9 3.5 - 2.5 2.6 0A2 500 RHS7G2A181J0A2H01B CCG 100 180pF ±5% 3.9 3.5 - 2.5 2.6 0A2 500 RHS7G2A221J0A2H01B CCG 100 220pF ±5% 3.9 3.5 - 2.5 2.6 0A2 500 RHS7G2A271J0A2H01B CCG 100 270pF ±5% 3.9 3.5 - 2.5 2.6 0A2 500 RHS7G2A331J0A2H01B CCG 100 330pF ±5% 3.9 3.5 - 2.5 2.6 0A2 500 RHS7G2A391J0A2H01B CCG 100 390pF ±5% 3.9 3.5 - 2.5 2.6 0A2 500 RHS7G2A471J0A2H01B CCG 100 470pF ±5% 3.9 3.5 - 2.5 2.6 0A2 500 RHS7G2A561J0A2H01B CCG 100 560pF ±5% 3.9 3.5 - 2.5 2.6 0A2 500 RHS7G2A681J0A2H01B CCG 100 680pF ±5% 3.9 3.5 - 2.5 2.6 0A2 500 RHS7G2A821J0A2H01B CCG 100 820pF ±5% 3.9 3.5 - 2.5 2.6 0A2 500 RHS7G2A102J0A2H01B CCG 100 1000pF ±5% 3.9 3.5 - 2.5 2.6 0A2 500 RHS7G2A122J0A2H01B CCG 100 1200pF ±5% 3.9 3.5 - 2.5 2.6 0A2 500 RHS7G2A152J0A2H01B CCG 100 1500pF ±5% 3.9 3.5 - 2.5 2.6 0A2 500 RHS7G2A182J1A2H01B CCG 100 1800pF ±5% 4.2 3.5 - 2.5 2.8 1A2 500 RHS7G2A222J1A2H01B CCG 100 2200pF ±5% 4.2 3.5 - 2.5 2.8 1A2 500 RHS7G2A272J1A2H01B CCG 100 2700pF ±5% 4.2 3.5 - 2.5 2.8 1A2 500 RHS7G2A332J1A2H01B CCG 100 3300pF ±5% 4.2 3.5 - 2.5 2.8 1A2 500 RHS7G2A101J0K1H01B CCG 100 100pF ±5% 3.9 3.5 6.0 5.0 2.6 0K1 500 RHS7G2A121J0K1H01B CCG 100 120pF ±5% 3.9 3.5 6.0 5.0 2.6 0K1 500 RHS7G2A151J0K1H01B CCG 100 150pF ±5% 3.9 3.5 6.0 5.0 2.6 0K1 500 RHS7G2A181J0K1H01B CCG 100 180pF ±5% 3.9 3.5 6.0 5.0 2.6 0K1 500 RHS7G2A221J0K1H01B CCG 100 220pF ±5% 3.9 3.5 6.0 5.0 2.6 0K1 500 RHS7G2A271J0K1H01B CCG 100 270pF ±5% 3.9 3.5 6.0 5.0 2.6 0K1 500 RHS7G2A331J0K1H01B CCG 100 330pF ±5% 3.9 3.5 6.0 5.0 2.6 0K1 500 RHS7G2A391J0K1H01B CCG 100 390pF ±5% 3.9 3.5 6.0 5.0 2.6 0K1 500 RHS7G2A471J0K1H01B CCG 100 470pF ±5% 3.9 3.5 6.0 5.0 2.6 0K1 500 RHS7G2A561J0K1H01B CCG 100 560pF ±5% 3.9 3.5 6.0 5.0 2.6 0K1 500 RHS7G2A681J0K1H01B CCG 100 680pF ±5% 3.9 3.5 6.0 5.0 2.6 0K1 500 RHS7G2A821J0K1H01B CCG 100 820pF ±5% 3.9 3.5 6.0 5.0 2.6 0K1 500 RHS7G2A102J0K1H01B CCG 100 1000pF ±5% 3.9 3.5 6.0 5.0 2.6 0K1 500 RHS7G2A122J0K1H01B CCG 100 1200pF ±5% 3.9 3.5 6.0 5.0 2.6 0K1 500 RHS7G2A152J0K1H01B CCG 100 1500pF ±5% 3.9 3.5 6.0 5.0 2.6 0K1 500 RHS7G2A182J1K1H01B CCG 100 1800pF ±5% 4.2 3.5 5.0 5.0 2.8 1K1 500 RHS7G2A222J1K1H01B CCG 100 2200pF ±5% 4.2 3.5 5.0 5.0 2.8 1K1 500 RHS7G2A272J1K1H01B CCG 100 2700pF ±5% 4.2 3.5 5.0 5.0 2.8 1K1 500 RHS7G2A332J1K1H01B CCG 100 3300pF ±5% 4.2 3.5 5.0 5.0 2.8 1K1 500 5 / 13 Reference only Unit : mm Customer Part Number Murata Part Number DC Rated T.C. Cap. Cap. tol. volt. (V) Dimension (mm) L W W1 F T Size Pack Lead qty. H/H0 Code (pcs) RHS7G2A101J0DGH01A CCG 100 100pF ±5% 3.9 3.5 - 2.5 2.6 20.0 0DG 2000 RHS7G2A121J0DGH01A CCG 100 120pF ±5% 3.9 3.5 - 2.5 2.6 20.0 0DG 2000 RHS7G2A151J0DGH01A CCG 100 150pF ±5% 3.9 3.5 - 2.5 2.6 20.0 0DG 2000 RHS7G2A181J0DGH01A CCG 100 180pF ±5% 3.9 3.5 - 2.5 2.6 20.0 0DG 2000 RHS7G2A221J0DGH01A CCG 100 220pF ±5% 3.9 3.5 - 2.5 2.6 20.0 0DG 2000 RHS7G2A271J0DGH01A CCG 100 270pF ±5% 3.9 3.5 - 2.5 2.6 20.0 0DG 2000 RHS7G2A331J0DGH01A CCG 100 330pF ±5% 3.9 3.5 - 2.5 2.6 20.0 0DG 2000 RHS7G2A391J0DGH01A CCG 100 390pF ±5% 3.9 3.5 - 2.5 2.6 20.0 0DG 2000 RHS7G2A471J0DGH01A CCG 100 470pF ±5% 3.9 3.5 - 2.5 2.6 20.0 0DG 2000 RHS7G2A561J0DGH01A CCG 100 560pF ±5% 3.9 3.5 - 2.5 2.6 20.0 0DG 2000 RHS7G2A681J0DGH01A CCG 100 680pF ±5% 3.9 3.5 - 2.5 2.6 20.0 0DG 2000 RHS7G2A821J0DGH01A CCG 100 820pF ±5% 3.9 3.5 - 2.5 2.6 20.0 0DG 2000 RHS7G2A102J0DGH01A CCG 100 1000pF ±5% 3.9 3.5 - 2.5 2.6 20.0 0DG 2000 RHS7G2A122J0DGH01A CCG 100 1200pF ±5% 3.9 3.5 - 2.5 2.6 20.0 0DG 2000 RHS7G2A152J0DGH01A CCG 100 1500pF ±5% 3.9 3.5 - 2.5 2.6 20.0 0DG 2000 RHS7G2A182J1DGH01A CCG 100 1800pF ±5% 4.2 3.5 - 2.5 2.8 20.0 1DG 2000 RHS7G2A222J1DGH01A CCG 100 2200pF ±5% 4.2 3.5 - 2.5 2.8 20.0 1DG 2000 RHS7G2A272J1DGH01A CCG 100 2700pF ±5% 4.2 3.5 - 2.5 2.8 20.0 1DG 2000 RHS7G2A332J1DGH01A CCG 100 3300pF ±5% 4.2 3.5 - 2.5 2.8 20.0 1DG 2000 RHS7G2A101J0M2H01A CCG 100 100pF ±5% 3.9 3.5 6.0 5.0 2.6 20.0 0M2 2000 RHS7G2A121J0M2H01A CCG 100 120pF ±5% 3.9 3.5 6.0 5.0 2.6 20.0 0M2 2000 RHS7G2A151J0M2H01A CCG 100 150pF ±5% 3.9 3.5 6.0 5.0 2.6 20.0 0M2 2000 RHS7G2A181J0M2H01A CCG 100 180pF ±5% 3.9 3.5 6.0 5.0 2.6 20.0 0M2 2000 RHS7G2A221J0M2H01A CCG 100 220pF ±5% 3.9 3.5 6.0 5.0 2.6 20.0 0M2 2000 RHS7G2A271J0M2H01A CCG 100 270pF ±5% 3.9 3.5 6.0 5.0 2.6 20.0 0M2 2000 RHS7G2A331J0M2H01A CCG 100 330pF ±5% 3.9 3.5 6.0 5.0 2.6 20.0 0M2 2000 RHS7G2A391J0M2H01A CCG 100 390pF ±5% 3.9 3.5 6.0 5.0 2.6 20.0 0M2 2000 RHS7G2A471J0M2H01A CCG 100 470pF ±5% 3.9 3.5 6.0 5.0 2.6 20.0 0M2 2000 RHS7G2A561J0M2H01A CCG 100 560pF ±5% 3.9 3.5 6.0 5.0 2.6 20.0 0M2 2000 RHS7G2A681J0M2H01A CCG 100 680pF ±5% 3.9 3.5 6.0 5.0 2.6 20.0 0M2 2000 RHS7G2A821J0M2H01A CCG 100 820pF ±5% 3.9 3.5 6.0 5.0 2.6 20.0 0M2 2000 RHS7G2A102J0M2H01A CCG 100 1000pF ±5% 3.9 3.5 6.0 5.0 2.6 20.0 0M2 2000 RHS7G2A122J0M2H01A CCG 100 1200pF ±5% 3.9 3.5 6.0 5.0 2.6 20.0 0M2 2000 RHS7G2A152J0M2H01A CCG 100 1500pF ±5% 3.9 3.5 6.0 5.0 2.6 20.0 0M2 2000 RHS7G2A182J1M2H01A CCG 100 1800pF ±5% 4.2 3.5 5.0 5.0 2.8 20.0 1M2 2000 RHS7G2A222J1M2H01A CCG 100 2200pF ±5% 4.2 3.5 5.0 5.0 2.8 20.0 1M2 2000 RHS7G2A272J1M2H01A CCG 100 2700pF ±5% 4.2 3.5 5.0 5.0 2.8 20.0 1M2 2000 RHS7G2A332J1M2H01A CCG 100 3300pF ±5% 4.2 3.5 5.0 5.0 2.8 20.0 1M2 2000 6 / 13 Reference only 5. AEC-Q200 Murata Standard Specifications and Test Methods No. 1 2 AEC-Q200 Test Item Pre-and Post-Stress Electrical Test High Appearance Temperature Exposure Capacitance (Storage) Change Q I.R. 3 AEC-Q200 Test Method - No defects or abnormalities except color change of outer coating. Within ±3% or ±0.3pF (Whichever is larger) Q ≥ 350 1,000MΩ min. Temperature Appearance No defects or abnormalities except color Cycling change of outer coating Capacitance Within ±5% or ±0.5pF Change (Whichever is larger) Q Q ≥ 350 I.R. 1,000MΩ min. Moisture Resistance Appearance Capacitance Change Q I.R. Sit the capacitor for 1,000±12h at 200±5°C. Let sit for 24±2h at *room condition, then measure. Perform the 1,000 cycles according to the four heat treatments listed in the following table. Let sit for 24±2 h at *room condition, then measure. Step Temp. (°C) Time (min.) 1 -55+0/-3 15±3 2 Room Temp. 1 3 200+5/-0 15±3 4 Room Temp. 1 Apply the 24h heat (25 to 65°C) and humidity (80 to 98%) treatment shown below, 10 consecutive times. Let sit for 24±2 h at *room condition, then measure. No defects or abnormalities Within ±5% or ± 0.5pF (Whichever is larger) Q ≥ 200 500MΩ min. Humidity Temperature 80∼98% Humidity Humidity (°C) 90∼98% 90∼98% 70 65 60 55 50 45 40 35 30 25 +10 20 - 2 °C 15 10 Initial measurement 5 0 -5 -10 One cycle 24 hours Humidity 80∼98% Humidity 90∼98% Temperature 4 Specification 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 Biased Humidity 6 Operational Appearance No defects or abnormalities except color Life change of outer coating Capacitance Within ±3% or ±0.3pF Change (Whichever is larger) Q Q ≥ 350 I.R. 1,000MΩ min. 7 8 9 10 Appearance Capacitance Change Q I.R. Hours Apply the rated voltage and DC1.3+0.2/-0 V (add 100kΩ resistor) at 85±3°C and 80 to 85% humidity for 1,000±12h. Remove and let sit for 24±2 h at *room condition, then measure. The charge/discharge current is less than 50mA. 5 External Visual Physical Dimension Marking Resistance Appearance to Solvents Capacitance Q I.R. No defects or abnormalities Within ±5% or ± 0.5pF (Whichever is larger) Q ≥ 200 500MΩ min. No defects or abnormalities Within the specified dimensions To be easily legible. No defects or abnormalities Within the specified tolerance Q ≥ 1,000 10,000MΩ min. Apply voltage in Table for 1,000±12h at 200±5°C. Let sit for 24±2 h at *room condition, then measure. The charge/discharge current is less than 50mA. Capacitance Test Voltage 100pF-1000pF 50% of the rated voltage 1200pF-3300pF 25% of the rated voltage Visual inspection Using calipers and micrometers. Visual inspection Per MIL-STD-202 Method 215 Solvent 1 : 1 part (by volume) of isopropyl alcohol 3 parts (by volume) of mineral spirits Solvent 2 : Terpene defluxer Solvent 3 : 42 parts (by volume) of water 1part (by volume) of propylene glycol monomethyl ether 1 part (by volume) of monoethanolamine * “room condition” Temperature:15 to 35°C, Relative humidity:45 to 75%, Atmosphere pressure:86 to 106kPa ESRH05C 7 / 13 Reference only AEC-Q200 Test Item No. 11 12 13-1 13-2 13-3 14 15 16 Mechanical Shock Vibration Specification Appearance No defects or abnormalities Capacitance Within the specified tolerance Q Appearance Q ≥ 1,000 No defects or abnormalities Capacitance Within the specified tolerance Q Q ≥ 1,000 Resistance to Soldering Heat (Non-Preheat) Appearance No defects or abnormalities Capacitance Change Dielectric Strength (Between terminals) Within ±2.5% or ±0.25pF (Whichever is larger) No defects Resistance to Soldering Heat (On-Preheat) Appearance No defects or abnormalities Capacitance Change Dielectric Strength (Between terminals) Within ±2.5% or ±0.25pF (Whichever is larger) No defects Appearance No defects or abnormalities Capacitance Change Dielectric Strength (Between terminals) Within ±2.5% or ±0.25pF (Whichever is larger) No defects Resistance to Soldering Heat (soldering iron method) Thermal Shock ESD Solderability AEC-Q200 Test Method Three shocks in each direction should be applied along 3 mutually perpendicular axes of the test specimen (18 shocks). The specified test pulse should be Half-sine and should have a duration :0.5ms, peak value:1,500G and velocity change: 4.7m/s. The capacitor should be subjected to a simple harmonic motion having a total amplitude of 1.5mm, the frequency being varied uniformly between the approximate limits of 10 and 2,000Hz. The frequency range, from 10 to 2,000Hz and return to 10Hz, should be traversed in approximately 20 min. This motion should be applied for 12 items in each 3 mutually perpendicular directions (total of 36 times). The lead wires should be immersed in the melted solder 1.5 to 2.0mm from the root of terminal at 260±5°C for 10±1 seconds. • Post-treatment Capacitor should be stored for 24±2 hours at *room condition. First the capacitor should be stored at 120+0/-5°C for 60+0/-5 seconds. Then, the lead wires should be immersed in the melted solder 1.5 to 2.0mm from the root of terminal at 260±5°C for 7.5+0/-1 seconds. • Post-treatment Capacitor should be stored for 24±2 hours at *room condition. Test condition Termperature of iron-tip : 350±10°C Soldering time : 3.5±0.5 seconds Soldering position Straight Lead:1.5 to 2.0mm from the root of terminal. Crimp Lead:1.5 to 2.0mm from the end of lead bend. • Post-treatment Capacitor should be stored for 24±2 hours at *room condition. Appearance Capacitance Change No defects or abnormalities Within ±5% or ±0.5pF (Whichever is larger) Q I.R. Q ≥ 350 1,000MΩ min. Appearance No defects or abnormalities Capacitance Within the specified tolerance Q Q ≥ 1,000 I.R. 10,000MΩ min. Perform the 300 cycles according to the two heat treatments listed in the following table(Maximum transfer time is 20s.). Let sit for 24±2 h at *room condition, then measure. Step 1 2 Temp. -55+0/-3 200+5/-0 (°C) Time 15±3 15±3 (min.) Per AEC-Q200-002 Lead wire should be soldered with uniform The terminal of a capacitor is dipped into a solution of ethanol coating on the axial direction over 95% of the (JIS-K-8101) and rosin (JIS-K-5902) (25%rosin in weight propotion) and then into molten solder (JIS-Z-3282) for 2±0.5 sec. circumferential direction. In both cases the depth of dipping is up to about 1.5 to 2mm from the terminal body. Temp. of solder : 245±5°C Lead Free Solder(Sn-3.0Ag-0.5Cu) 235±5°C H60A or H63A Eutectic Solder * “room condition” Temperature:15 to 35°C, Relative humidity:45 to 75%, Atmosphere pressure:86 to 106kPa ESRH05C 8 / 13 Reference only No. 17 AEC-Q200 Test Item Electrical Characterization Apperance Specifications AEC-Q200 Test Method No defects or abnormalities Visual inspection. Capacitance Within the specified tolerance Q Q ≥ 1,000 The capacitance, Q should be measured at 25°C at the frequency and voltage shown in the table. Nominal Cap. C ≤ 1000pF C > 1000pF Insulation Resistance (I.R.) Between Terminals No defects or abnormalities Capacitance Test Voltage 100pF-1000pF 50% of the rated voltage 1200pF-3300pF 25% of the rated voltage The capacitor should not be damaged when voltage in Table is applied between the terminations for 1 to 5 seconds. (Charge/Discharge current ≤ 50mA.) Rated voltage DC100V Body Insulation No defects or abnormalities Terminal Strength Tensile Strength Termination not to be broken or loosened Test voltage 300% of the rated voltage The capacitor is placed in a container with metal balls of 1mm diameter so that each terminal, short-circuit, is kept approximately 2mm from the balls as shown in the figure, and voltage in table is impressed for 1 to 5 seconds between capacitor terminals and metal balls. (Charge/Discharge current ≤ 50mA.) Rated voltage DC100V 18 Voltage AC0.5 to 5V(r.m.s.) AC1±0.2V(r.m.s.) The insulation resistance should be measured at 25±3 °C with a DC voltage not exceeding the rated voltage at normal temperature and humidity and within 2 min. of charging. (Charge/Discharge current ≤ 50mA) The insulation resistance should be measured at 200±5 °C with a DC voltage not exceeding voltage in Table and within 2 min. of charging. (Charge/Discharge current ≤ 50mA) Room 10,000MΩ min. Temperature High 20MΩ min. Temperature Dielectric Strength Frequency 1±0.1MHz 1±0.1kHz Approx. 2mm Metal balls Test voltage 250% of the rated voltage As in the figure, fix the capacitor body, apply the force gradually to each lead in the radial direction of the capacitor until reaching 10N and then keep the force applied for 10±1 seconds. ↓ F Bending Strength 19 Capacitance Temperature Characteristics Termination not to be broken or loosened Within the specified Tolerance. 0+30/-72ppm/°C (-55～25°C) 0±30ppm/°C (25～125°C) 0+72/-30ppm/°C (125～200°C) Each lead wire should be subjected to a force of 2.5N and then be bent 90° at the point of egress in one direction. Each wire is then returned to the original position and bent 90° in the opposite direction at the rate of one bend per 2 to 3 seconds. The capacitance change should be measured after 5min. at each specified temperature step. Step 1 2 3 4 5 Temperature(°C) 25±2 -55±3 25±2 200±5 25±2 The temperature coefficient is determind using the capacitance measured in step 3 as a reference. When cycling the temperature sequentially from step 1 through 5 (-55°C to +150°C) the capacitance should be within the specified tolerance for the temperature coefficient and capacitance change as Table A. The capacitance drift is caluculated by dividing the differences betweeen the maximum and minimum measured values in the step 1, 3 and 5 by the capacitance value in step 3. * “room condition” Temperature:15 to 35°C, Relative humidity:45 to 75%, Atmosphere pressure:86 to 106kPa ESRH05C 9 / 13 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 Note) The outer package and the number of outer packing be changed by the order getting amount. 270 max. 125 max. 340 max. Unit : mm •Ammo pack taping type (Packing style code : A) ⋅ A crease is made every 25 pitches, and the tape with capacitors is packed zigzag into a case. ⋅ When body of the capacitor is piled on other body under it. The size of packing case and packing way 240 max. Position of label Unit : mm 340 max. Hold down tape Capacitor 51 max. Base tape Hold down tape upper EKBCRPE01 10 / 13 Reference only 7. Taping specification 7-1. Dimension of capacitors on tape Straight taping type < Lead code : DG > Pitch of component 12.7mm / Lead spacing 2.5mm Unit : mm Item Code Dimensions Pitch of component P 12.7+/-1.0 Pitch of sprocket hole P0 12.7+/-0.2 Lead spacing F 2.5+0.4/-0.2 Length from hole center to component center P2 6.35+/-1.3 Length from hole center to lead P1 5.1+/-0.7 Deviation along tape, left or right defect ∆S 0+/-2.0 Carrier tape width W 18.0+/-0.5 Position of sprocket hole Lead distance between reference and bottom plane W1 9.0+0/-0.5 H 20.0+/-0.5 Deviation of progress direction They include deviation by lead bend . Deviation of tape width direction 0.5 max. Protrusion length Diameter of sprocket hole D0 4.0+/-0.1 Lead diameter d 0.50+/-0.05 Total tape thickness t1 0.6+/-0.3 Total thickness of tape and lead wire t2 1.5 max. Deviation across tape Remarks ∆h1 ∆h2 1.0 max. Portion to cut in case of defect L 11.0+0/-1.0 Hold down tape width W0 9.5 min. Hold down tape position W2 1.5+/-1.5 Coating extension on lead e 2.0 max. 11 / 13 They include hold down tape thickness. Reference only Inside crimp taping type < Lead code : M2 > Pitch of component 12.7mm / Lead spacing 5.0mm 0 P P2 ∆h2 ∆h1 ∆S Marking t1 t2 W0 L φ D0 W φd W1 F H0 P1 W2 e P0 Unit : mm Item Code Dimensions Pitch of component P 12.7+/-1.0 Pitch of sprocket hole P0 12.7+/-0.2 Lead spacing F 5.0+0.6/-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 Deviation along tape, left or right defect ∆S 0+/-2.0 Carrier tape width W 18.0+/-0.5 Position of sprocket hole W1 9.0+0/-0.5 H0 20.0+/-0.5 Lead distance between reference and bottom plane Remarks Deviation of progress direction They include deviation by lead bend . Deviation of tape width direction 0.5 max. Protrusion length Diameter of sprocket hole D0 4.0+/-0.1 Lead diameter φd 0.50+/-0.05 Total tape thickness t1 0.6+/-0.3 Total thickness of tape and lead wire t2 1.5 max. ∆h1 2.0 max.（Dimension code：W） ∆h2 1.0 max.（except as above） Portion to cut in case of defect L 11.0+0/-1.0 Hold down tape width W0 9.5 min. Hold down tape position W2 1.5+/-1.5 Coating extension on lead e Up to the end of crimp Deviation across tape 12 / 13 They include hold down tape thickness. 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 shall be spliced by cellophane tape. (Total tape thickness shall 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 shall be spliced with overlapping. (Total tape thickness shall be less than 1.05mm.) ape are spliced •Base tape and adhesive tape shall be spliced with splicing tape. 20 to 30 Hold down tape Progress direction in production line Base tape Unit : mm c) When both tape are spliced •Base tape and hold down tape shall be spliced with splicing tape. ETP2R01 13 / 13