AXIAL LEADED CERAMIC CAPACITORS OPERATING TEMP. -2585 FEATURES 1pF10F 5mm26mm This widely used ceramic capacitor includes both monolithic and multilayer types to provide a wide capacitance range of 1pF through 10F in one standard size and shape. Automatic insertion related costs are lower than with radial type capacitors. Mounting pitch can be between 5mm to 26mm which could be used as a jumper. APPLICATIONS Class1BF The class 1 temperature compensating (NPO) products can be used in circuits to stabilize frequency and temperature characteristics. The B, and F dielectrics are optimum for bypass capacitors. ORDERING CODE 1 3 5 6 8 VDC Lxd mm pF L E T G U 10 16 25 35 50 4.2x3.2 3.5x1.9 075 050 025 3.2x2.2 2.3x2.0 015 3.0x2.5 010 1R2 103 R= D- J- K- M- Z- 1 1.2 10000 0.5pF 15% 10% 20% 80 20 % B C 2 4 7 9 mm P CK CH RH UJ SL B F -7501250ppm / -750160ppm / -220160ppm / -750120ppm / 350-1000ppm / 10 30 - 85 = A- B- KF KE NA 26mm 52mm 5.0 7.5 Z J = U P 0 5 0 C H 1 0 0 J _ A _ B 1 6 5 4 7 9 8 1 3 5 6 8 Rated voltage VDC Outside DimensionsLxd mm Nominal Capacitance pF Capacitance Tolerances Packaging L E T G U 10 16 25 35 50 4.2x3.2 multilayer type 3.5x1.9 monolithic type 050 3.2x2.2 multilayer type 025 2.3x2.0 multilayer type 015 3.0x2.5 multilayer type 075 example 010 1R2 103 D- J- K- M- Z- 1 1.2 10000 Rdecimal point 0.5pF 15% 10% 20% 80 20 % B C Ammo Bulk 2 4 7 9 Type Temperature haracteristics Lead Configuration Internal code P 120 3 2 Axial leaded capacitors CK CH RH UJ SL B F -7501250ppm / -750160ppm / -220160ppm / -750120ppm / 350-1000ppm / 10 30 - 85 Blank space A- B- KF KE NA 8 26mm lead space, ammo pack 52mm lead space, ammo pack 5.0mm pitch formed lead bulk 7.5mm pitch formed lead bulk Axial lead, bulk Z J Monolithic type Standard products Multilayer type Standard products Multilayer type (Low voltage products) Blank space EXTERNAL DIMENSIONS Dimensions TYPE D L d Taped product Bulk Product Straight Straight Formed 050 3.5max 1.9max 0.450.05 Monolithic Type 0.138max0.075max0.0180.002 0.550.05 4.2max 3.2max 075 Multilayer Type0.165max0.126max0.0220.002 050 3.2max 2.2max Multilayer Type0.126max0.087max 0.450.05 025 2.3max 2.0max Multilayer Type 0.09max 0.079max0.0180.002 015 3.0max 2.5max Multilayer Type0.118max0.098max Pitch:7.5mm 0.295 4 AVAILABLE CAPACITANCE RANGE (Monolithic type) Class 1 (Temperature compensating) WV 50VUP Temp.char. CH RH UJ Type cap. 025 050 050 050 pF pF3digits 010 1 1R2 1.2 1.5 1R5 1.8 1R8 2.2 2R2 2.7 2R7 3.3 3R3 3.9 3R9 4.7 4R7 5.6 5R6 6.8 6R8 8.2 8R2 10 100 11 110 12 120 13 130 15 150 16 160 18 180 20 200 22 220 24 240 27 270 30 300 33 330 36 360 39 390 43 430 47 470 51 510 56 560 62 620 68 680 100 101 150 151 220 221 330 331 470 471 680 681 1000 102 (Multilayer type) Class 2 (High dielectric constant) SL 025 050 CAPACITORS Unit : mminch WV 50VUP 35VGP 25VTP 16VEP 10VLP Temp.char. B F B F B F B F F Type cap. 025 050 075 015 025 050 075 075 015 075 025 050 015 025 050 015 050 050 pF pF3digits 75 750 82 820 91 910 100 101 120 121 150 151 180 181 220 221 270 271 330 331 390 391 470 471 560 561 680 681 820 821 1000 102 1200 122 1500 152 1800 182 2200 222 2700 272 3300 332 3900 392 4700 472 5600 562 6800 682 8200 822 10000 103 15000 153 22000 223 33000 333 47000 473 68000 683 100000 104 220000 224 470000 474 1000000 105 2200000 225 4700000 475 10000000 106 Since the production of monolithic layer products is scheduled to be discontinued, please contact your nearest sales office if you require any detailed information. Temperature char. Capacitance change CH 0160ppm/ RH UJ SL -220160ppm/ -750120ppm/ 350-1000ppm/ B Capacitance Tolerance Class Qtan Q or tan D0.5pF M20% K10% J5% 1 engRefer to the Part munber K10% 10% 2 F 30 85 % 20 Selection Guide P.10 etc Z % 80 20 Part Numbers P.122 Capacitance characteristics measured at 20 Electrical Characteristics P.128 Packaging Reliability Data P.129 8 P.130 Precautions P.142 121 PART NUMBERS Monolithic type Class 1 Since the production of monolithic layer products is scheduled to be discontinued, please contact your nearest sales office if you require any detailed information. RatedVoltage DC 50V Ordering code UP 0 5 0 0 1 0M- UP 0 5 0 1 R 2M- UP 0 5 0 1 R 5M- UP 0 5 0 1 R 8M- U P 0 5 0 2 R 2 K- U P 0 5 0 2 R 7 K- U P 0 5 0 3 R 3 K- U P 0 5 0 3 R 9 K- U P 0 5 0 4 R 7 K- U P 0 5 0 5 R 6 K- U P 0 5 0 6 R 8 K- U P 0 5 0 8 R 2 K- UP 0 5 0 1 0 0 J - UP 0 5 0 1 1 0 J - UP 0 5 0 1 2 0 J - UP 0 5 0 1 3 0 J - UP 0 5 0 1 5 0 J - UP 0 5 0 1 6 0 J - UP 0 5 0 1 8 0 J - UP 0 5 0 2 0 0 J - UP 0 5 0 2 2 0 J - UP 0 5 0 2 4 0 J - UP 0 5 0 2 7 0 J - UP 0 5 0 3 0 0 J - UP 0 5 0 S L 3 3 0 J - UP 0 5 0 S L 3 6 0 J - UP 0 5 0 S L 3 9 0 J - UP 0 5 0 S L 4 3 0 J - UP 0 5 0 S L 4 7 0 J - UP 0 5 0 S L 5 1 0 J - UP 0 5 0 S L 5 6 0 J - UP 0 5 0 S L 6 2 0 J - UP 0 5 0 S L 6 8 0 J - EHS (Environmental Hazardous Substances) RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS Temperature characteristics Capacitance Capacitance pF tolerance CH RH SL CH RH UJ SL CHUJSL UJ SL SL 1.0 1.2 1.5 1.8 2.2 2.7 3.3 3.9 4.7 5.6 6.8 8.2 10 11 12 13 15 16 18 20 22 24 27 30 33 36 39 43 47 51 56 62 68 Q or tan Insulation resistance 20 10 Q40020C (C: capacitance[pF]) RH 16pF Q500 but Q500 at 16pF or over of characteristic RH 5 Q500 Please specify the temperature characteristics code and lead configuration code. 122 8 10000Mmin PART NUMBERS 025 Multilayer 025 Type Class 1 RatedVoltage DC UP025010D- Z UP0251R2D- Z UP0251R5D- Z UP0251R8D- Z UP0252R2D- Z UP0252R7D- Z UP0253R3D- Z UP0253R9D- Z UP0254R7D- Z UP0255R6K- Z UP0256R8K- Z UP0258R2K- Z UP025100J- Z UP025120J- Z UP025150J- Z UP025180J- Z UP025220J- Z UP025270J- Z UP025330J- Z UP025390J- Z UP025470J- Z UP025560J- Z UP025680J- Z UP025820J- Z UP025CH101J- Z UP025CH151J- Z UP025CH221J- Z UP025CH331J- Z UP025CH471J- Z UP025CH681J- Z UP025CH102J- Z Hazardous Substances) RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS Temperature characteristics Capacitance Capacitance pF 1.0 1.2 1.5 1.8 2.2 2.7 3.3 3.9 4.7 5.6 6.8 8.2 10 12 15 18 22 27 33 39 47 56 68 82 100 150 220 330 470 680 1000 tolerance CH SL CH Q or tan Insulation resistance 4 CAPACITORS 50V Ordering code EHS (Environmental 0.5pF Q400+20C 10% 10000Mmin 5% Q1000 Please specify the temperature characteristics code and lead configuration code. 8 123 PART NUMBERS 015 Multilayer 015type Class 2 RatedVoltage Odering Code EHS Environmental Hazardous Substances DC 25V TP015 B103K- Z RoHS 16V EP015 B104K- Z RoHS 50V UP015 F103Z- Z RoHS 16V EP015 F104Z- Z RoHS Temperature characteristics Capacitance pF] Capacitance 10% 100000 80 % 20 10000 F 100000 Insulation resistance tolerance 10000 B Q or tan tan3.5% 5000Mmin tan5.0% 1000Mmin tan7.5% tan10.0% 1000Mmin Please specify the temperature characteristics code and lead configuration code. 025 Multilayer 025 Type Class 2 RatedVoltage DC 50V 50V 16V 25V Ordering code UP025 B101K - Z UP025 B121K - Z UP025 B151K - Z UP025 B181K - Z UP025 B221K - Z UP025 B271K - Z UP025 B331K - Z UP025 B391K - Z UP025 B471K - Z UP025 B561K - Z UP025 B681K - Z UP025 B821K - Z UP025 B102K - Z UP025 B122K - Z UP025 B152K - Z UP025 B222K - Z UP025 B332K - Z UP025 B472K - Z UP025 B682K - Z UP025 B103K - Z UP025 B153K - Z UP025 B223K - Z UP025 B333K - Z UP025 B473K - Z UP025 B683K - Z UP025 B104K - Z UP025 F103Z - Z UP025 F223Z - Z UP025 F473Z - Z UP025 F104Z - Z EP025 B122M - J EP025 B152M - J EP025 B182M - J EP025 B222M - J EP025 B272M - J EP025 B332M - J EP025 B392M - J EP025 B472M - J EP025 B562M - J EP025 B682M - J EP025 B822M - J EP025 B103M - J EP025 B123M - J EP025 B153M - J EP025 B183M - J EP025 B223M - J TP025 F103Z - J TP025 F223Z - J TP025 F473Z - J EHS (Environmental Hazardous Substances) RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS RoHS Temperature characteristics Capacitance Capacitance pF tolerance B F B F 100 120 150 180 220 270 330 390 470 560 680 820 1000 1200 1500 2200 3300 4700 6800 10000 15000 22000 33000 47000 68000 100000 10000 22000 47000 100000 1200 1500 1800 2200 2700 3300 3900 4700 5600 6800 8200 10000 12000 15000 18000 22000 10000 22000 47000 Please specify the temperature characteristics code and lead configuration code. 124 8 Q or tan Insulation resistance tan3.5% 5000Mmin tan5.0% 1000Mmin 80 20 tan7.5% 1000Mmin 20 tan3.5% 5000Mmin 80 20 tan7.5% 1000Mmin 10% PART NUMBERS Multilayer type Class 1 RatedVoltage DC Hazardous Substances) Temperature characteristics Capacitance Capacitance pF tolerance UP 0 5 0 CH2 2 0 J - Z RoHS 22 UP 0 5 0 CH2 4 0 J - Z RoHS 24 UP 0 5 0 CH2 7 0 J - Z RoHS 27 UP 0 5 0 CH3 0 0 J - Z RoHS 30 UP 0 5 0 CH3 3 0 J - Z RoHS 33 UP 0 5 0 CH3 6 0 J - Z RoHS 36 UP 0 5 0 CH3 9 0 J - Z RoHS 39 UP 0 5 0 CH4 3 0 J - Z RoHS 43 UP 0 5 0 CH4 7 0 J - Z RoHS 47 UP 0 5 0 CH5 1 0 J - Z RoHS 51 UP 0 5 0 CH5 6 0 J - Z RoHS 56 UP 0 5 0 CH6 2 0 J - Z RoHS 62 UP 0 5 0 CH6 8 0 J - Z RoHS 68 UP 0 5 0 CH7 5 0 J - Z RoHS 75 UP 0 5 0 CH8 2 0 J - Z RoHS 82 UP 0 5 0 CH9 1 0 J - Z RoHS 91 UP 0 5 0 CH1 0 1 J - Z RoHS 100 UP 0 5 0 CH1 1 1 J - Z RoHS 110 UP 0 5 0 CH1 2 1 J - Z RoHS 120 UP 0 5 0 CH1 3 1 J - Z RoHS 130 UP 0 5 0 CH1 5 1 J - Z RoHS UP 0 5 0 CH1 6 1 J - Z RoHS CH 150 Q or tan Insulation resistance 4 Q40020C 15% Q1000 10000Mmin 160 UP 0 5 0 CH1 8 1 J - Z RoHS 180 UP 0 5 0 CH2 0 1 J - Z RoHS 200 UP 0 5 0 CH2 2 1 J - Z RoHS 220 UP 0 5 0 CH2 4 1 J - Z RoHS 240 UP 0 5 0 CH2 7 1 J - Z RoHS 270 UP 0 5 0 CH3 0 1 J - Z RoHS 300 UP 0 5 0 CH3 3 1 J - Z RoHS 330 UP 0 5 0 CH3 6 1 J - Z RoHS 360 UP 0 5 0 CH3 9 1 J - Z RoHS 390 UP 0 5 0 CH4 3 1 J - Z RoHS 430 UP 0 5 0 CH4 7 1 J - Z RoHS 470 UP 0 5 0 CH5 1 1 J - Z RoHS 510 UP 0 5 0 CH5 6 1 J - Z RoHS 560 UP 0 5 0 CH6 2 1 J - Z RoHS 620 UP 0 5 0 CH6 8 1 J - Z RoHS 680 UP 0 5 0 CH7 5 1 J - Z RoHS 750 UP 0 5 0 CH8 2 1 J - Z RoHS 820 UP 0 5 0 CH9 1 1 J - Z RoHS 910 UP 0 5 0 CH1 0 2 J - Z RoHS 1000 CAPACITORS 50V Ordering code EHS (Environmental Please specify the temperature characteristics code and lead configuration code. : Option 8 125 PART NUMBERS Monolithic type Class 2 Since the production of monolithic layer products is scheduled to be discontinued, please contact your nearest sales office if you require any detailed information. RatedVoltage DC 50V 25V Ordering code EHS (Environmental Hazardous Substances) Temperature characteristics Capacitance Capacitance pF tolerance RoHS 75 U P 0 5 0 B 8 2 0 K- RoHS 82 U P 0 5 0 B 9 1 0 K- RoHS 91 U P 0 5 0 B 1 0 1 K- RoHS 100 U P 0 5 0 B 1 2 1 K- RoHS 120 U P 0 5 0 B 1 5 1 K- RoHS 150 U P 0 5 0 B 1 8 1 K- RoHS 180 U P 0 5 0 B 2 2 1 K- RoHS 220 U P 0 5 0 B 2 7 1 K- RoHS RoHS 330 U P 0 5 0 B 3 9 1 K- RoHS 390 U P 0 5 0 B 4 7 1 K- RoHS 470 U P 0 5 0 B 5 6 1 K- RoHS 560 U P 0 5 0 B 6 8 1 K- RoHS 680 U P 0 5 0 B 8 2 1 K- RoHS 820 U P 0 5 0 B 1 0 2 K- RoHS 1000 T P 0 5 0 F 1 0 3 Z- RoHS 10000 T P 0 5 0 F 2 2 3 Z- RoHS Insulation resistance 10000Mmin 10% tan2.5% 1000Mmin 80 20 % 22000 Please specify the capacitance tolerance code and lead configuration code. 126 Q or tan tan1.5% 270 U P 0 5 0 B 3 3 1 K- F U P 0 5 0 B 7 5 0 K- B 8 tan7.5% PART NUMBERS Multilayer type Class 2 RatedVoltage DC Ordering code UP 0 5 0 B 1 2 2 K- Z UP 0 5 0 B 1 5 2 K- Z 16V 50V 16V 10V 50V 35V 25V 35V Hazardous Substances) RoHS Temperature characteristics Capacitance Capacitance pF 1200 tolerance RoHS Q or tan Insulation resistance 4 1500 UP 0 5 0 B 1 8 2 K- Z RoHS 1800 UP 0 5 0 B 2 2 2 K- Z RoHS 2200 UP 0 5 0 B 2 7 2 K- Z RoHS 2700 UP 0 5 0 B 3 3 2 K- Z RoHS 3300 UP 0 5 0 B 3 9 2 K- Z RoHS 3900 UP 0 5 0 B 4 7 2 K- Z RoHS 4700 UP 0 5 0 B 5 6 2 K- Z RoHS 5600 UP 0 5 0 B 6 8 2 K- Z UP 0 5 0 B 8 2 2 K- Z RoHS 6800 RoHS 8200 UP 0 5 0 B 1 0 3 K- Z UP 0 5 0 B 1 2 3 K- Z RoHS 10000 RoHS 12000 UP 0 5 0 B 1 5 3 K- Z RoHS 15000 CAPACITORS 50V EHS (Environmental tan3.5% 5000Mmin UP 0 5 0 B 1 8 3 K- Z RoHS UP 0 5 0 B 2 2 3 K- Z UP 0 5 0 B 2 7 3 K- Z RoHS RoHS 27000 UP 0 5 0 B 3 3 3 K- Z RoHS 33000 UP 0 5 0 B 3 9 3 K- Z RoHS 39000 UP 0 5 0 B 4 7 3 K- Z RoHS 47000 UP 0 5 0 B 5 6 3 K- Z RoHS 56000 UP 0 5 0 B 6 8 3 K- Z UP 0 5 0 B 8 2 3 K- Z RoHS 68000 RoHS 82000 UP 0 5 0 B 1 0 4 K- Z RoHS 100000 UP 0 5 0 B 2 2 4 K- Z RoHS 220000 500Mmin UP 0 5 0 B 4 7 4 K- Z RoHS 470000 200Mmin 100Mmin B 18000 E P 0 5 0 B 1 0 5 K- Z RoHS 1000000 E P 0 5 0 B 2 2 5 K- Z RoHS 2200000 E P 0 5 0 B 4 7 5 K- Z RoHS 4700000 E P 0 5 0 B 1 0 6 K- Z RoHS 10000000 UP 0 5 0 F 1 0 3 Z- Z RoHS 10000 UP 0 5 0 F 2 2 3 Z- Z RoHS 22000 UP 0 5 0 F 4 7 3 Z- Z RoHS 47000 UP 0 5 0 F 1 0 4 Z- Z RoHS UP 0 5 0 F 2 2 4 Z- Z RoHS UP 0 5 0 F 4 7 4 Z- Z RoHS 220000 470000 RoHS 1000000 E P 0 5 0 F 2 2 5 Z- Z RoHS 2200000 L P 0 5 0 F 4 7 5 Z- Z RoHS 4700000 L P 0 5 0 F 1 0 6 Z- Z RoHS 10000000 UP 0 7 5 B 1 0 5 K- RoHS 1000000 GP 0 7 5 B 2 2 5 K- RoHS 2200000 GP 0 7 5 B 4 7 5K- RoHS T P 0 7 5 B 1 0 6 K- RoHS RoHS 1000Mmin tan5.0% tan7.5% tan12.5% 50Mmin 20Mmin tan7.5% 1000Mmin tan10.0% 500Mmin 100000 F UP 0 5 0 F 1 0 5 Z- Z GP 0 7 5 F 1 0 6 Z- 10% 22000 B 4700000 80 -20 % tan15% tan17.5% tan5.0% 10 10000000 F 10000000 tan7.5% tan12.5% 80 -20 tan17.5% 250Mmin 125Mmin 50Mmin 25Mmin 100Mmin 50Mmin 20Mmin 25Mmin Please specify the temperature characteristics code and lead configuration code. : Option 8 127 ELECTRICAL CHARACTERISTICS - Capacitance -vs- Temperature Characteristics Class Temp.char. F UP050 F104Z TP050 F223Z -20 10 Class2 Temp.char. B UP050B102K UP050B101K 5 0 -5 UP050B104K UP050B103K -10 128 -20 0 20 40 60 80 8 0 20 40 60 80 PACKAGING Minimum Quantity PCS Minimum Quantity Lead configuration code Type Bulk B-52mm2.047 inches wide Multilayer type 075, 050, 025,015 NA Taping 1000 NA A-26mm1.024 inch wide 4000 B-52mm2.047 inches wide 4000 NA 1000 KF 3000 4 2000 075type 3000 050type 5000 015,025type 2000 075type 3000 050type 5000 015,025type 3000, KE075type 4000 KF015,025,050type 015,025 type Monolithic type 050 A-a26mm a1.024 inch wide configuration CAPACITORS A-26mm1.024 inch wide Taping Dimensions Type Dimensions of Bulk Products D L a Dimensions b L1-L2 015 2.5max 3.0max Multilayer type 0.098max0.118max NA configuration Dimensionsmm Type D 015 Multilayer type 2.5max 0.098 3.0max 0.450.05 20.0min 0.118 0.0180.002 0.787 025 Multilayer type 2.0max 0.079 2.3max 0.09 050 Multilayer type 2.2max 0.087 3.2max 0.450.05 20.0min 0.126 0.0180.002 0.787 075 Multilayer type 3.2max 0.126 4.2max 0.550.05 20.0min 0.165 0.0220.002 0.787 050 Monolithic type 1.9max 0.075 3.5max 0.450.05 20.0min 0.138 0.0180.002 0.787 d L 0.450.05 20.0min 0.0180.002 0.787 d Minimum insertion pitch 0.450.05 0.0180.002 025 2.0max 2.3max Multilayer type 0.079max0.09max 260.5 -0 0.8 0.5max 050 2.2max 3.2max Multilayer type 0.087max0.126max1.0240.020 -0 0.031 or less 0.020max. 0.450.05 5.0 0.0180.0020.197 075 3.2max 4.2max Multilayer type 0.126max0.165max 0.550.05 7.5 0.0220.0020.295 050 1.9max 3.5max Monolithic type 0.075max0.138max 0.450.05 5.0 0.0180.0020.197 0.450.05 0.0180.002 Unitmm inch B-a52mm a2.047 inches wide configuration Unitmminch KF/KE Type 015 Multilayer type KF/KE configuration Lead configuration code KF 025 Multilayer type KF 050 Multilayer type KF 075 Multilayer type KE 050 Monolithic type KF D L 2.5max 3.0max Dimensions mm W d 5.00.5 0.450.05 6.50.5 0.098max0.118max0.1970.0200.0180.0020.2560.020 2.0max 2.3max 5.00.5 0.450.05 6.50.5 0.079max0.09max0.1970.0200.0180.0020.2560.020 2.2max 3.2max 5.00.5 0.450.05 6.50.5 0.087max0.126max0.1970.0200.0180.0020.2560.020 3.2max 4.2max 7.50.5 0.550.05 6.50.5 0.126max0.165max0.2950.0200.0220.0020.2560.020 1.9max 3.5max 5.00.5 0.450.05 6.50.5 0.075max0.138max0.1970.0200.0180.0020.2560.020 Type D L 015 2.5max 3.0max Multilayer type 0.098max0.118max a Dimensions b L1-L2 d Minimum insertion pitch 0.450.05 0.0180.002 0.450.05 5.0 025 2.0max 2.3max Multilayer type 0.079max0.09max 522 0.0180.0020.197 -1 1.2 1.0max 0.450.05 050 2.2max 3.2max +0.079 Multilayer type 0.087max0.126max2.047 -0.039 0.047 or less 0.039max. 0.0180.002 0.550.05 7.5 075 3.2max 4.2max Multilayer type 0.126max0.165max 0.0220.0020.295 050 1.9max 3.5max Monolithic type 0.075max0.138max Unitmm inch 0.450.05 5.0 0.0180.0020.197 Unitmm inch 075Type 8 129 1/6 RELIABILITY DATA AXIAL LEADED CERAMIC CAPACITORS Specified Value Temterature CompensatingClass1 Item 1. Operating Temperature Range 2. Storage Temperature Range 3. Rated Voltage 4. Withstanding Voltage Multilayer type -2585 High Permittivity Class2 Test Methods and Remarks Multilayer type Characteristics:B Multilayer type Characteristics:F -2585 50VDC Between No abnorminality terminals 16VDC25VDC35VDC50VDC 10VDC16VDC25VDC35VDC50VDC Between No abnorminality terminals and body 5. Insulation Resistance 10000min. Metal globule method Applied voltage: Rated Voltagex2.5 Duration: 1 to 5 sec. Charge/Discharge current : 50mA max. Rated Ivoltage:16VDC B: 100000pF :1000Mmin 1000000pF :100M min 2200000pF :50M min 4700000pF10000000pF :20M min 1200pF22000pFItem:J:5000Mmin Rated Ivoltage:10VDC F: 4700000pF :50M min 10000000pF :25M min 4 CAPACITORS Applied voltage: Rated Voltagex3 Class 1 Rated Voltagex2.5 Class 2 Duration: 1 to 5 sec. Charge/discharge current: 50mA max.Class 1,2 Applied voltage: Rated voltage Duration : 605 sec. Rated Ivoltage:16VDC F: 100000pF :1000Mmin 2200000pF :125M min Rated Ivoltage:25VDC B: 10000pF :5000Mmin Rated voltage:25VDC 10000000pF :20M min F: 10000pF47000pFItemJ:1000Mmin Rated Ivoltage:35VDC Rated voltage:35VDC B: 2200000pF :50M min F: :25M min 4700000pF :20M min 10000000pF Rated Ivoltage:50VDC B: 100pF39000pF 47000pF100000pF 220000pF 470000pF 1000000pF 6. Capacitance : 0.5pF 5% 10% Rated voltage:50VDC F: :5000M min 10000pF100000pF :1000M min 220000pF470000pF :500M min :1000M min :250M min :500M min 1000000pF :200M min :100M min Rated Ivoltage:16VDC B: 10%,20%ItemJ Rated Ivoltage:25VDC B: 10% Rated Ivoltage:35VDC B: 10% Rated Ivoltage:16VDC B: 1200pF22000pFItemJ:3.5%max 100000pF :5.0%max 1000000pF :5.0% max 2200000pF4700000pF :7.5% max 10000000pF :12.5% max Rated Ivoltage:25VDC B: 10000pF 10000000pF :3.5%max :12.5% max Rated Ivoltage:35VDC B: 2200000pF4700000pF :7.5% max Rated Ivoltage:10VDC F: 4700000pF10000000pF :17.5% max Rated Ivoltage:16VDC F: 100000pF 2200000pF Rated Ivoltage:35VDC F: 10000000pF Rated Ivoltage:50VDC F: 10000pF100000pF :3.5% max :5.0% max 220000pF470000pF 1000000pF Rated Ivoltage:16VDC Rated Ivoltage:10VDC F 30 B: 10% 85% Rated Ivoltage:25VDC B: 10% Rated Ivoltage:35VDC B: 10% Rated Ivoltage:50VDC B: 10% :10.0% max :15.0% max Rated Ivoltage:25VDC F: 10000pF47000pFItemJ :7.5% max Rated Ivoltage:50VDC B: 100pF39000pF 47000pF 1000000pF CH : 060 8. Capacitance : When SL : 3501000 Change due to voltage Temperature or is not [ppm/] Rate of Capaci- applied tance Change Measuring frequency 1MHz10% Class 1: C1000pF 1kHz10% Class 1: C1000pF 1kHz10% Class 2 Measuring voltage 1.00.5VrmsClass 1: C1000pF 1.00.2VrmsClass 1: C1000pF 1.00.2VrmsClass 2 Measuring temperature: 20 Bias application: None Rated Ivoltage:25VDC F 80 20% Rated Ivoltage:35VDC F 80 20% Rated Ivoltage:50VDC F 80 20% Rated Ivoltage:50VDC B: 10% 7. Q or Tangent of Loss Angle 30pF or under : Q40020C 33pF or over : Q1000 C:Nominal Capacitance :[pF] Rated Ivoltage:10VDC F 80 20% Rated Ivoltage:16VDC F 80 20% Rated Ivoltage:16VDC F 30 85% Rated Ivoltage:25VDC F 30 85% Rated Ivoltage:35VDC F 30 85% Rated Ivoltage:50VDC F 30 85% :17.5% max :7.5% max :10.0% max :15.0% max Measurement of capacitance at 20 and 85, -25 shall be made to calculate temperature characteristic by the following equation.Class 1 C85-C20 ppm/ x10 6 C20xT Change of maximum capacitance deviation in step 1 to 5Class 2 Temperature at step 1: 20 Temperature at step 4: 85 Temperature at step 2: 25 Temperature at step 5: 20 Temperature at step 3: 20Reference temperature Withstanding voltage is also referred to as "voltage proof" under IEC specifications. 8 131 2/6 RELIABILITY DATA AXIAL LEADED CERAMIC CAPACITORS Specified Value Item 9. Terminal Tensile Strength High Permittivity Class2 Test Methods and Remarks Multilayer type Multilayer type Characteristics:B Multilayer type Characteristics:F No abnomalities, such as cuts or looseness of terminals. Apply the stated tensile force progressively in the direction to draw terminal. No abnomalities, such as cuts or looseness of terminals. Nominal wire diameter Tensile force Duratio mm N s 0.45 19.6 5 Suspend a mass at the end the terminal, incline the body through angle of 90 and return it to initial position. This operation is done over a period of 5 sec. Then second bend in the opposite direction shall be made. 4 CAPACITORS Torsional Temterature CompensatingClass1 Number of bends : 2 times Nominal wire diameter Bending force 10Resistance to Vaibration Appearance : No significant abnomality Withstanding Voltage : No abnomality Capacitance : Within 5% 4.7pF or under :Within 0.5pF 5.6pF8.2pF :Within 10% 10pF or over :Within 5% Q: 30pF or under : Q400+20C 33pF or over : Q1000 Insulation resistance : 10000M min. C:Nominal Capacitance :[pF] Mass weight mm N kg 0.45 2.45 0.25 Appearance : No significant abnomality Appearance : No significant abnomality Withstanding Voltage : No abnomality Withstanding Voltage : No abnomality According to JIS C 5102 clause 8.2 Rated Voltage:16VDC B Capacitance 1200pF22000pFItemJ 100000pF10000000pF tan: 1200pF22000pFItemJ 100000pF 1000000pF 2200000pF4700000pF 10000000pF Insulation Resistance: 1200pF22000pFItemJ 100000pF 1000000pF 2200000pF 4700000pF10000000pF Directions: 2 hrs each in X, Y and Z directions Rated Voltage:25VDC B Capacitance tan: 10000pF 10000000pF Insulation Resistance: 10000pF 10000000pF Rated Voltage:35VDC B Capacitance tan: 2200000pF4700000pF Insulation Resistance: 2200000pF 4700000pF Rated Voltage:50VDC B Capacitance tan: 100pF39000pF 47000pF1000000pF Insulation Resistance: 100pF39000pF 47000pF100000pF 220000pF 470000pF 1000000pF Rated Voltage:10VDC F : Within 10% CapacitanceWithin80 -20 % :Within 20% :Within 10% tan: 4700000pF10000000pF : 17.5% max :3.5%max Insulation Resistance: :50M min :5.0%max 4700000pF :25M min :5.0% max 10000000pF :7.5% max :12.5% max Rated Voltage:16VDC F :5000Mmin CapacitanceWithin80 -20 % :1000Mmin :100Mmin tan: :10.0%max :50Mmin 100000pF :15.0% max :20Mmin 2200000pF Insulation Resistance: 100000pF :1000Mmin 2200000pF :125Mmin : Within 10% Rated Voltage:25VDC :3.5%max F :12.5%max CapacitanceWithin80 % -20 Vibration type: A Total: 6 hrs Frequency range: 10 to 55 to 10Hz1min Amplitude: 1.5 mm Mounting method: Soldering onto the PC board :5000Mmin tan: 10000pF47000pFItemJ :7.5%max :20Mmin Insulation Resistance: 10000pF47000pFItemJ :1000Mmin : Within 10% Rated Voltage:35VDC F :7.5%max CapacitanceWithin80 % -20 :50Mmin tan: :20Mmin 10000000pF Insulation Resistance: 10000000pF :17.5%max :25Mmin : Within 10% Rated Voltage:50VDC F :3.5% max CapacitanceWithin80 % -20 :5.0% max tan: :7.5%max :5000M min 10000pF100000pF :10.0%max :1000M min 220000pF470000pF 1000000pF :15.0%max :500M min :200M min Insulation Resistance: :1000Mmin :100M min 10000pF100000pF 220000pF470000pF :500Mmin :250Mmin 1000000pF Withstanding voltage is also referred to as "voltage proof" under IEC specifications. 8 133 3/6 RELIABILITY DATA AXIAL LEADED CERAMIC CAPACITORS Specified Value Item 11. Free Fall Temterature CompensatingClass1 Multilayer type Appearance : No significant abnomality Withstanding Voltage : No abnomality Capacitance : 4.7pF or under :Within 0.5pF :Within 10% 5.6pF8.2pF :Within 5% 10pF or over C:Nominal Capacitance :[pF] Rated Voltage:16VDC B Capacitance : 1200pF22000pFItemJ:Within20% 100000pF10000000pF :Within10% tan: 1200pF22000pFItemJ :3.5% max 100000pF :5.0%max :5.0% max 1000000pF :7.5% max 2200000pF4700000pF :12.5% max 10000000pF Insulation Resistance: 1200pF22000pFItemJ:5000M min :1000M min 100000pF 1000000pF :100M min 50M min 2200000pF 4700000pF10000000pF :20M min Rated Voltage:25VDC B Capacitance tan: 10000pF 10000000pF Insulation Resistance: 10000pF 10000000pF Rated Voltage:35VDC B Capacitance tan: 2200000pF4700000pF Insulation Resistance: 2200000pF 4700000pF Rated Voltage:50VDC B Capacitance tan: 100pF39000pF 47000pF1000000pF Insulation Resistance: 100pF39000pF 47000pF100000pF 220000pF 470000pF 1000000pF 12. Body Strength Test Methods and Remarks Rated Voltage:10VDC F CapacitanceWithin80 % -20 tan: 4700000pF10000000pF : Insulation Resistance: 4700000pF 10000000pF Height: 1 m Total number of drops: 5 times 17.5% max :50M min :25M min Rated Voltage:16VDC F CapacitanceWithin80 % -20 tan: 100000pF 2200000pF Insulation Resistance: 100000pF : Within 10% 2200000pF 4 CAPACITORS Q: 30pF or under : Q400+20C 33pF or over : Q1000 Insulation resistance : 10000M min. High Permittivity Class2 Multilayer type Characteristics:B Multilayer type Characteristics:F Appearance : No significant abnomality Appearance : No significant abnomality Drop Test: Free fall Withstanding Voltage : No abnomality Withstanding Voltage : No abnomality Impact material: Floor :10.0% max :15.0% max :1000M min :125M min :3.5%max Rated Voltage:25VDC :12.5%max F CapacitanceWithin80 % -20 :5000M min :20M min tan: 10000pF47000pFItemJ :7.5%max Insulation Resistance: 10000pF47000pFItemJ :1000M min : Within 10% Rated Voltage:35VDC F CapacitanceWithin80 % -20 :50M min tan: :20M min 10000000pF Insulation Resistance: 10000000pF :7.5%max : Within 10% :3.5%max :5.0%max :5000M min :1000M min :500M min :200M min :100M min :17.5% max :25M min Rated Voltage:50VDC F CapacitanceWithin80 % -20 tan: 10000pF100000pF 220000pF470000pF 1000000pF Insulation Resistance: 10000pF100000pF 220000pF470000pF 1000000pF No abnomality such as damage. :7.5% max :10.0% max :15.0% max :1000M min :500M min :250M min Applied force: 19.6N Duration: 5 sec. Speed: Shall attain to specified force in 2 sec. 1.5mm025type 13. Solderability At least 75% of lead surface is covered with new solder. Solder temperature: 2305 Duration: 20.5 sec. This test may be applicable after 6 months storage. Withstanding voltage is also referred to as "voltage proof" under IEC specifications. 8 135 4/6 RELIABILITY DATA AXIAL LEADED CERAMIC CAPACITORS Specified Value Item 14. Soldering Temterature CompensatingClass1 High Permittivity Class2 Test Methods and Remarks Multilayer type Multilayer type Characteristics:B Multilayer type Characteristics:F Appearance : No significant abnomality Appearance : No significant abnomality Appearance : No significant abnomality Solder temperature: 2705 Withstanding Voltage : No abnomality Withstanding Voltage : No abnomality Withstanding Voltage : No abnomality Duration: 50.5 sec. C:Nominal Capacitance :[pF] Rated Voltage:16VDC B Capacitance change : 1200pF22000pFItemJ : Within 7.5% : Within 10.0% 100000pF 1000000pF10000000pF : Within 10.0% tan: 1200pF22000pFItemJ :3.5% max :5.0%max 100000pF 1000000pF :5.0% max 2200000pF4700000pF :7.5% max 10000000pF :12.5% max Insulation Resistance: 1200pF22000pFItemJ :5000M min 100000pF :1000M min 1000000pF :100M min 2200000pF :50M min 4700000pF10000000pF :20M min Rated Voltage:25VDC B Capacitance change : 10000pF 10000000pF tan: 10000pF 10000000pF Insulation Resistance: 10000pF 10000000pF Rated Voltage:35VDC B Capacitance change tan: 2200000pF4700000pF Insulation Resistance: 2200000pF 4700000pF Rated Voltage:50VDC B Capacitance change : 100pF39000pF 47000pF1000000pF tan: 100pF39000pF 47000pF1000000pF Insulation Resistance: 100pF39000pF 47000pF100000pF 220000pF 470000pF 1000000pF Rated Voltage:10VDC F Capacitance change tan: 4700000pF10000000pF Insulation Resistance: 4700000pF 10000000pF Rated Voltage:16VDC F Capacitance change tan: 100000pF 2200000pF Insulation Resistance: 100000pF 2200000pF : Within 20.0% :17.5% max C:Nominal CapacitancepF Rated Voltage:16VDC B Capacitance change : 1200pF22000pFItemJ 100000pF 1000000pF10000000pF tan: 1200pF22000pFItemJ 100000pF 1000000pF 2200000pF4700000pF 10000000pF Insulation Resistance: 1200pF22000pFItemJ 100000pF 1000000pF 2200000pF 4700000pF10000000pF Rated Voltage:25VDC B Capacitance change : 10000pF 10000000pF tan: 10000pF 10000000pF Insulation Resistance: 10000pF 10000000pF Rated Voltage:35VDC B Capacitance change tan: 2200000pF4700000pF Insulation Resistance: 2200000pF 4700000pF Rated Voltage:50VDC B Capacitance change : 100pF39000pF 47000pF1000000pF tan: 100pF39000pF 47000pF1000000pF Insulation Resistance: 100pF39000pF 47000pF100000pF 220000pF 470000pF 1000000pF followed by 484 hrs of recovery under the standard condition. Recovery: Recovery for the following period under the : Within 20.0% standard condition after the test. 242 hrsClass 1 :10.0% max :15.0% max 484 hrsClass 2 :1000M min :125M min Rated Voltage:25VDC F Capacitance change : Within 20.0% : Within 7.5% tan: : Within 10.0% 10000pF47000pFItemJ :7.5% max Insulation Resistance: :3.5%max 10000pF47000pFItemJ :1000Mmin :12.5%max Rated Voltage:35VDC :5000M min F :20M min Capacitance change : Within 20.0% tan: 10000000pF :17.5% max Insulation Resistance: : Within 10.0% 10000000pF :25M min :7.5% max Rated Voltage:50VDC F :50M min Capacitance change : :20M min 10000pF1000000pF tan: 10000pF100000pF 220000pF470000pF 1000000pF :Within 7.5% Insulation Resistance: :Within 10.0% 10000pF100000pF 220000pF470000pF :3.5% max 1000000pF :5.0% max 4 :Within 20.0% :7.5% max :10.0% max :15.0% max :1000M min :500M min :250M min :5000M min :1000M min :500M min :200M min :100M min According to JIS C 5102 clause 8.7.4. Type of test: Method 1 Solvent temperature: 20 to 25 Duration: 305 sec. Solvent Type: A in Table 23, Isopropyl alcohol Appearance : No significant abnomality Appearance : No significant abnomality Appearance : No significant abnomality Withstanding Voltage : No abnomality Withstanding Voltage : No abnomality Withstanding Voltage : No abnomality Capacitance change : 8.2pF or under :Within 0.5pF :Within 5.0% 10pF or over Q: :8.2pF or under Q20010C :10pF30pF Q2752.5C 33pF or over: Q350 Insulation resistance: 1000M min. with t=1.6mm, hole=1.0mm diameter Preconditioning: 1 hr of preconditioning at 1500 -10 :50M min :25M min 15. Resistance to Solvent No significant abnormality in appearance and legible marking. 16.Thermal Shock Immersed conditions: Inserted into the PC board CAPACITORS Capacitance change : 8.2pF or under :Within 0.25pF :Within 2.5% 10pF or over Q: 30pF or under: Q400+20C 33pF or over: Q1000 Insulation resistance: 10000M min. : Within 12.5% : Within 15.0% : Within 15.0% Rated Voltage:10VDC F Capacitance change tan: 4700000pF10000000pF Insulation Resistance: 4700000pF 10000000pF min : 5.0% max : 7.5% max : 7.5% max : 10.0% max Rated Voltage:16VDC : 15.0% max F Capacitance change : 1000M min tan: :500Mmin 100000pF : 50M min 2200000pF : 25M min Insulation Resistance: : 5M min 100000pF 2200000pF Temperature Room temperature 0 -25 3 Durationmin Within 3 Within 3 4 Room temperature 3 85 0 5 Room temperature Within 3 Step 1 : Within 30.0% 2 :20.0% max 3 :10M min :5M 303 303 : Within 30.0% : 15.0% max : 17.5% max : 500M min : 25M min Rated Voltage:25VDC F : Within 30.0% : Within 12.5% Capacitance change : Within 15.0% tan: 10000pF47000pFItemJ : 12.5%max :5.0% max Insulation Resistance: :15.0% max 10000pF47000pFItemJ : 500Mmin :1000Mmin Rated Voltage:35VDC :5M min F Capacitance change tan: 10000000pF : Within 15.0% Insulation Resistance: 10000000pF :10.0% max Rated Voltage:50VDC :25M min F :5M min Capacitance change : 10000pF1000000pF tan: 10000pF100000pF 220000pF470000pF :Within 12.5% 1000000pF :Within 15.0% Insulation Resistance: 10000pF100000pF :5.0% max 220000pF470000pF :7.5% max 1000000pF Conditions for 1 cycle : Within 30.0% Number of cycles: 5 0 Preconditioning: 1 hr of preconditioning at 150 -10 followed by 484 hrs of recovery under the standard condition. Recovery: Recovery for the following period under the standard condition after the removal from test chamber. 242 hrsClass 1 484 hrsClass 2 :20.0% max :5M min :Within 30% :12.5% max :15.0% max :17.5% max :500M min :250M min :50M min :1000M min :500M min :250M min :100M min :50M min Withstanding voltage is also referred to as "voltage proof" under IEC specifications. Thermal Shock is also referred to as "rapid change of temperature" under IEC specifications. 8 137 5/6 RELIABILITY DATA AXIAL LEADED CERAMIC CAPACITORS Specified Value Item 17. Damp Heat steady state High Permittivity Class2 Test Methods and Remarks Multilayer type Characteristics:B Multilayer type Characteristics:F Appearance : No significant abnomality Appearance : No significant abnomality emperature: 402 Withstanding Voltage : No abnomality Withstanding Voltage : No abnomality Humidity: 90 to 95 % RH Rated Voltage:16VDC Rated Voltage:10VDC Capacitance change : 24 B Duration: 500 -0 hrs F 8.2pF or under :Within 0.5pF Capacitance change : Capacitance change: Within 30.0% 0 Preconditioning: 1 hr of preconditioning at 150-10 :Within 5.0% 1200pF22000pFItemJ : Within 12.5% tan: 10pF or over 100000pF : Within 15.0% 4700000pF10000000pF Q: :20.0% max followed by 484 hrs of recovery un1000000pF10000000pF : Within 15.0% Insulation Resistance: :8.2pF or under tan: der the standard condition. :10M min Q20010C 1200pF22000pFItemJ : 5.0% max 4700000pF :5M min 10000000pF 100000pF :7.5% max :10pF30pF Recovery: 242 hrs of recovery under the standard : 7.5% max 1000000pF Q2752.5C 2200000pF4700000pF : 10.0% max Rated Voltage:16VDC condition after the removal from test cham33pF or over: 10000000pF : 15.0% max F Q350 ber.Class 1 Capacitance change: Within 30.0% Insulation Resistance: 1200pF22000pFItemJ : 1000M min tan: Insulation resistance: : 1 hr of preconditioning at 150 10 100000pF :500M min 100000pF : max 15.0% -0 fol1000M min. 1000000pF : 50M min 2200000pF : 17.5% max lowed by 484 hrs of recovery under the : 25M min Insulation Resistance: 2200000pF C:Nominal CapacitancepF 4700000pF10000000pF : 5M min 100000pF : 500M min standard condition after the removal from 2200000pF : 25M min Rated Voltage:25VDC chamber.Class 2 B Rated Voltage:25VDC Capacitance change: 10000pF : Within 12.5% F 10000000pF : Within 15.0% Capacitance change: Within 30.0% tan: tan: : 12.5%max 10000pF :5.0% max 10000pF47000pFItemJ 10000000pF :15.0% max Insulation Resistance: Insulation Resistance: 10000pF47000pFItemJ : 500Mmin 10000pF :1000M min 10000000pF :5M min Rated Voltage:35VDC F Rated Voltage:35VDC Capacitance change: Within 30.0% B tan: Capacitance change : Within 15.0% 10000000pF :20.0% max tan: :10.0% max Insulation Resistance: 2200000pF4700000pF 10000000pF :5M min Insulation Resistance: 2200000pF :25M min Voltage:50VDC Rated 4700000pF :5M min F Capacitance change : Rated Voltage:50VDC B 10000pF1000000pF :Within 30% Capacitance change : tan: 100pF39000pF :Within 12.5% 10000pF100000pF :12.5% max 47000pF1000000pF :Within 15.0% 220000pF470000pF :15.0% max tan: :17.5% max 1000000pF 100pF39000pF :5.0% max Insulation Resistance: 47000pF1000000pF :7.5% max 10000pF100000pF :500M min Insulation Resistance: :250M min 100pF39000pF :1000M min 220000pF470000pF :50M min 47000pF100000pF :500M min 1000000pF :250M min 220000pF 470000pF :100M min 1000000pF :50M min Appearance : No significant abnomality Appearance : No significant abnomality Appearance : No significant abnomality Temperature: 402 Withstanding Voltage : No abnomality Withstanding Voltage : No abnomality Withstanding Voltage : No abnomality Humidity: 90 to 95 % RH Rated Voltage:16VDC Capacitance change : Rated Voltage:10VDC B Duration: 500 24 hrs -0 8.2pF or under :Within 0.75pF Capacitance change : F Applied voltage: Rated voltage 10pF or over :Within 7.5% 1200pF22000pFItemJ : Within 12.5% Capacitance change: Within 30.0% 100000pF : Within 15.0% Q: Preconditioning: 1 hr of preconditioning at 150 10 1000000pF2200000pF : Within 15.0% tan: -0 30pF or under: :20.0% max 4700000pF10000000pF : Within 22.5% 4700000pF10000000pF followed by 484 hrs of recovery Q100+10/3*C tan: Insulation Resistance: 1200pF22000pFItemJ : 5.0% max 4700000pF 33pF or over: under the standard condition. :5M min 100000pF : 7.5% max Q200 :2.5M min Recovery: 242 hrs of recovery under the standard 1000000pF : 7.5% max 10000000pF Insulation resistance: 2200000pF4700000pF : 10.0% max 500M min. condition after the removal from test cham10000000pF : 22.5% max Rated Voltage:16VDC Insulation Resistance: F ber.Class 1 1200pF22000pFItemJ : 500M min C:Nominal Capacitance [pF] : 250M min Capacitance change: Within 30.0% 100000pF : 1 hr of preconditioning at 150 10 1000000pF :12.5M min tan: -0 fol2200000pF :5M min 100000pF :15.0% max lowed by 484 hrs of recovery under the 4700000pF10000000pF :2.5M min 2200000pF :17.5% max standard condition after the removal from Insulation Resistance: Rated Voltage:25VDC B 100000pF :250M min chamber.Class 2 Capacitance change : 2200000pF :12.5M min 10000pF : Within 12.5% 10000000pF : Within 22.5.0% Rated Voltage:25VDC tan: 10000pF :5.0% max F 10000000pF :22.5% max Capacitance change: Within 30.0% Insulation Resistance: 10000pF :500Mmin tan: : 12.5% max 10000000pF :2.5Mmin 10000pF47000pFItemJ Insulation Resistance: Rated Voltage:35VDC 10000pF47000pFItemJ :250Mmin B Capacitance change : 2200000pF :Within 15.0% Rated Voltage:35VDC 4700000pF :Within 22.5% F tan: 2200000pF4700000pF :10.0% max Capacitance change: Within 30.0% tan: Insulation Resistance: 2200000pF :5M min 10000000pF :20.0% max 4700000pF :2.5M min Insulation Resistance: 10000000pF :25M min Rated Voltage:50VDC B Capacitance change : Rated Voltage:50VDC 100pF39000pF :Within 12.5% F 47000pF1000000pF :Within 15.0% Capacitance change : tan: :Within 30.0% 100pF39000pF : 5.0% max 10000pF1000000pF 47000pF1000000pF : 7.5% max tan: Insulation Resistance: 10000pF100000pF :12.5% max 100pF39000pF :500M min :15.0% max 47000pF100000pF :250M min 220000pF470000pF :17.5% max 220000pF :125M min 1000000pF 470000pF :25M min Insulation Resistance: 1000000pF :12.5M min 10000pF100000pF :250M min 220000pF470000pF :125M min 1000000pF :25M min Multilayer type Appearance : No significant abnomality Withstanding Voltage : No abnomality 4 CAPACITORS 18. Loading under Damp Heat Temterature CompensatingClass1 Withstanding voltage is also referred to as "voltage proof" under IEC specifications. 8 139 6/6 RELIABILITY DATA AXIAL LEADED CERAMIC CAPACITORS Specified Value Item 19. High Temperature Lading Test Temterature CompensatingClass1 High Permittivity Class2 Test Methods and Remarks Multilayer type Characteristics:B Multilayer type Characteristics:F Appearance : No significant abnomality Appearance : No significant abnomality Temperature: 85 30 Withstanding Voltage : No abnomality Withstanding Voltage : No abnomality Duration: 1000 48 0 hrs Rated Voltage:10VDC Capacitance change : Rated Voltage:16VDC Applied voltage: Rated voltagex2Class 1 F 8.2pF or under :Within 0.3pF B Capacitance change : Within 30.0% Class 2 10pF or over :Within 3.0% Capacitance change : tan: 1200pF22000pFItemJ : Within 12.5% 4700000pF10000000pF Q: :20.0% max Rated voltagex1.5 :8.2pF or under 100000pF : Within 15.0% Insulation Resistance: 1000000pF2200000pF : Within 15.0% 4700000pF Q200+10C :10M min Class 2: B 220000pF10000000pF 4700000pF10000000pF : Within 22.5% 10000000pF :10pF 30pF :5M min 0 Preconditioning: 1 hr of preconditioning at 150-10 tan: Q275+2.5C 1200pF22000pFItemJ : 5.0% max Rated Voltage:16VDC 33pF or over: followed by 484 hrs of recovery 100000pF : 7.5% max F Q350 under the standard condition. 1000000pF : 7.5% max Capacitance change :Within 30.0% Insulation resistance: tan: 2200000pF4700000pF : 10.0% max 1000M min. 100000pF :12.5% max Recovery: 242hrs of recovery under the standard 10000000pF : 22.5% max 2200000pF :17.5% max condition after the removal from test chamInsulation Resistance: C:Nominal Capacitance [pF] Insulation Resistance: 1200pF22000pFItemJ : 1000M min 100000pF : 500M min ber.Class1 100000pF :500M min 2200000pF :25M min : 1 hr of preconditioning at 150 10 1000000pF :50M min -0 fol2200000pF :25M min Rated Voltage:25VDC lowed by 484 hrs of recovery under the 4700000pF10000000pF :5M min F Capacitance change : Within 30.0% standard condition after the removal from tan: Rated Voltage:25VDC chamber.Class 2 10000pF47000pFItemJ : 10.0% max B Insulation Resistance: Capacitance change : 10000pF47000pFItemJ : 500Mmin 10000pF : Within 12.5% 10000000pF : Within 22.5% Rated Voltage:35VDC F tan: 10000pF :5.0% max Capacitance change : Within 30.0% 10000000pF :22.5% max tan: 10000000pF :20.0% max Insulation Resistance: Insulation Resistance: 10000pF :1000M min 10000000pF :5M min 10000000pF :5M min Rated Voltage:50VDC Rated Voltage:35VDC F Capacitance change : B 10000pF1000000pF :Within 30.0% Capacitance change : 2200000pF :Within 15.0% tan: 10000pF100000pF :10.0% max 4700000pF :Within 22.5% 220000pF470000pF :12.5% max tan: 1000000pF :17.5% max 2200000pF4700000pF :10.0% max Insulation Resistance: Insulation Resistance: 10000pF100000pF :500M min 2200000pF :25M min 220000pF470000pF :250M min :50M min 4700000pF :5M min 1000000pF Multilayer type Appearance : No significant abnomality Withstanding Voltage : No abnomality CAPACITORS Rated Voltage:50VDC B Capacitance change : 100pF39000pF 47000pF1000000pF tan: 100pF39000pF 47000pF1000000pF Insulation Resistance: 100pF39000pF 47000pF100000pF 220000pF 470000pF 1000000pF 4 :Within 12.5% :Within 15.0% :5.0% max :7.5% max :1000M min :500M min :250M min :100M min :50M min Note on standard condition: "standard condition" referred to herein is defined as follows: 5 to 35 of temperature, 45 to 85% relative humidity, and 86 to 106kPa of air pressure. When there are questions concerning measurement results: In order to provide correlation data, the test shall be conducted under condition of 202 of temperature, 60 to 70% relative humidity, and 86 to 106kPa of air pressure. Unless otherwise specified, all the tests are conducted under the "standard condition." Withstanding voltage is also referred to as "voltage proof" under IEC specifications. 8 141 1/2 PRECAUTIONS Precautions on the use of Axiel Leaded Ceramic Capacitors Stages 1. Circuit Design Precautions Technical considerations Verification of operating environment, electrical rating and performance 1. A malfunction in medical equipment, spacecraft, nuclear reactors, etc. may cause serious harm to human life or have 4 severe social ramifications. As such, any capacitors to be used in such equipment may require higher safety and/or CAPACITORS reliability considerations and should be clearly differentiated from components used in general purpose applications. Verification of Rated voltage (DC rated voltage) 1. The operating voltage for capacitors must always be lower than their rated values. If an AC voltage is loaded on a DC voltage, the sum of the two peak voltages should be lower than the rated value of the capacitor chosen. For a circuit where both an AC and a pulse voltage may be present, the sum of their peak voltages should also be lower than the capacitor's rated voltage. 2. Even if the applied voltage is lower than the rated value, the reliability of capacitors might be reduced if either a high frequency AC voltage or a pulse voltage having rapid rise time is present in the circuit. Self-generated heat (Verification of Temperature) 1-1. When an AC or a pulse voltage is applied to capacitors specified for DC use, even 1. If the capacitors specified only for DC use are used in AC or if the voltage is less than the rated voltage, the AC current or pulse current running pulse circuits, the AC or a pulse current can generate heat through the capacitor will cause the capacitor to self-generate heat because of the inside the capacitor so the self-generated temperature rise loss characteristics. should be limited to within 20 . The surface temperature The amount of heat generated depends on the dielectric materials used, capacitance, measured should include this self-temperature rise. There- applied voltage, frequency, voltage waveform, etc. The surface temperature changes fore, it is required to limit capacitor surface temperature due to emitted heat which differs by capacitor shape or mounting method. including self -generated heat should not exceed the maxi- Please contact Taiyo Yuden with any questions regarding emitted heat levels in your mum operating temperature of +85 . particular application. It is recommend the temperature rise be measured in the actual circuit to be used. 1-2. For capacitors, the voltage and frequency relationship is generally determined by peak voltage at low frequencies, and by self-generated heat at high frequencies. (Refer to the following curve.) Operating Environment precautions 1. Capacitors should not be used in the following environments: (1)Environmental conditions to avoid a. exposure to water or salt water. b. exposure to moisture or condensation. c. exposure to corrosive gases (such as hydrogen sulfide, sulfurous acid, chlorine, and ammonia) 2. PCB Design 1. When capacitors are mounted onto a PC board, hole dimensions on the board should match the lead pitch of the component, if not it will cause breakage of the terminals or cracking of terminal roots covered with resin as excess stress travels through the terminal legs. As a result, humidity resistance performance would be lost and may lead to a reduction in insulation resistance and cause a withstand voltage failure. 3. Considerations for automatic insertion Adjustment Automatic Insertion machines (leaded components) 1. When inserting capacitors in a PC board by auto-insertion machines the impact load imposed on the capacitors should be minimized to prevent the leads from chucking or clinching. 1. When installing products, care should be taken not to apply distortion stress as it may deform the products. 2. Our company recommends the method to place the lead with fewer loads that join the product. 8 143 2/2 PRECAUTIONS Precautions on the use of Axiel Leaded Ceramic Capacitors Stages 4. Soldering Precautions Selection of Flux 1. When soldering capacitors on the board, flux should be applied thinly and evenly. 2. Flux used should be with less than or equal to 0.1 wt% (equivalent to Chroline) of halogenated content. Flux having a strong acidity content should not be applied. to properly clean the boards. Wave Soldering 1.Temperature, time, amount of solder, etc. are specified in accordance with the following recommended conditions. 2. Do not immerse the entire capacitor in the flux during the soldering operation. Only solder the lead wires on the bottom of the board. 1. Flux is used to increase solderability in wave soldering, but if too much is applied, a large amount of flux gas may be emitted and may detrimentally affect solderability. To minimize the amount of flux applied, it is recommended to use a flux-bubbling system. 2. With too much halogenated substance (Chlorine, etc.) content is used to activate the flux, an excessive amount of residue after soldering may lead to corrosion of the terminal electrodes or degradation of insulation resistance on the surface of the capacitors. 3. Since the residue of water-soluble flux is easily dissolved by water content in the air, the residue on the surface of capacitors in high humidity conditions may cause a degradation of insulation resistance and therefore affect the reliability of the components. The cleaning methods and the capability of the machines used should also be considered carefully when selecting water-soluble flux. 1. If capacitors are used beyond the range of the recommended conditions, heat stresses may cause cracks inside the capacitors, and consequently degrade the reliability of the capacitors. 2. When the capacitors are dipped in solder, some soldered parts of the capacitor may melt due to solder heat and cause short-circuits or cracking of the ceramic material. Deterioration of the resin coating may lower insulation resistance and cause a reduction of withstand voltage. 4 CAPACITORS 3. When using water-soluble flux, special care should be taken Technical considerations Recommended conditions for using a soldering iron: Put the soldering iron on the land-pattern. Soldering iron's temperature - below 350 1. If products are used beyond the range of the recommended conditions,heat stress may deform the products,and consequently degrade the reliability of the products. Duration - 3 seconds or less Numbers of times - 1 times The soldering iron should not directly touch the capacitor. 5. Cleaning Board cleaning 1. When cleaning the mounted PC boards, make sure that cleaning conditions are consistent with prescribed usage conditions. 6. Post-cleaning-process Application of resin molding, etc. to the PCB and components. 1. Please contact your local Taiyo Yuden sales office before performing resin coating or molding on mounted capacitors. Please verify on the actual application that the coating process will not adversely affect the component quality. 7. Handling Mechanical considerations 1. Be careful not to subject the capacitors to excessive mechanical shocks. Withstanding voltage failure may result. 2. If ceramic capacitors are dropped onto the floor or a hard 1. The resin material used for the outer coating of capacitors is occasionally a wax substance for moisture resistance which can easily be dissolved by some solutions. So before cleaning, special care should be taken to test the component s vulnerability to the solutions used. When using water-soluble flux please clean the PCB with purified water sufficiently and dry thoroughly at the end of the process. Insufficient washing or drying could lower the reliability of the capacitors. 1-1. The thermal expansion and coefficient of contraction of the molded resin are not necessarily matched with those of the capacitor. The capacitors may be exposed to stresses due to thermal expansion and contraction during and after hardening. This may lower the specified characteristics and insulation resistance or cause reduced withstand voltage by cracking the ceramic or separating the coated resin from the ceramics. 1-2. With some types of mold resins, the resin's decomposition gas or reaction gas may remain inside the resin during the hardening period or while left under normal conditions, causing a deterioration of the capacitor's performance. 1-3. Some mold resins may have poor moisture proofing properties. Please verify the contents of the resins before they are applied. 1-4. Please contact Taiyo Yuden before using if the hardening process temperature of the mold resins is higher than the operating temperature of the capacitors. 1. Because the capacitor is made of ceramic, mechanical shocks applied to the board may damage or crack the capacitors. 2.Ceramic capacitors which are dropped onto the floor or a hard surface may develop defects and have a higher risk of failure over time. surface they should not be used. 8. Storage conditions Storage 1. To maintain the solderability of terminal electrodes and to keep the packaging material in good condition, care must be taken to 1. Under high temperature/high humidity conditions, the decrease in solderability due to the oxidation of terminal electrodes and deterioration of taping and packaging characteristics may be accelerated. control temperature and humidity in the storage area. Humidity should especially be kept as low as possible. Recommended conditions: Ambient temperature Below 40 Humidity Below 70% RH. Products should be used within 6 months after delivery. After the above period, the solderability should be checked before using the capacitors. 2. Capacitors should not be kept in an environment filled with decomposition gases such as (sulfurous hydrogen, sulfurous acid, chlorine, ammonia, etc.) 3. Capacitors should not be kept in a location where they may be exposed to moisture, condensation or direct sunlight. 8 145