NXH25VB2200M16*20_LO

RoHS MESSRS: APPROVAL NO 296-028 DATE 2014.01.13 ALUMINUM ELECTROLYTIC CAPACITOR APPROVAL SHEET CATALOG TYPE NXH SERIES USER PART NO. 适 用 机 种 特 记 事 项 Halogen-Free QINGDAO SAMYOUNG ELECTRONICS CO.,LTD. MANAGER OF DEVELOPMENT DEPARTMENT GONG JANG SUG 长孔 硕 USER APPROVAL: APPROVAL NO.： SamYoung(Korea) : 146-1,SANGDAEWON-DONG,JOONGWON-GU,SUNGNAM-CITY,KYUNGKI-DO,KOREA SamYoung(China) : No.5 CHANGJIANG ROAD,PINGDU-CITY,SHANDONG-PROVINCE,CHINA A4 （210×297） 样式：H-1001-011 SamYoung Electronics Co., Ltd. APPROVAL NO. ALUMINUM ELECTROLYTIC CAPACITOR 296-028 PAGE: 1 OF 6 DATE: 2014.01.13 Specifications of NXH Series Item Characteristics Rated Voltage Range 6.3 ~ 50 VDC Operating Temperature Range - 40 ~ + 105 ℃ Capacitance Tolerance ±20% (at 20℃ ,120Hz) Leakage Current After 2 minutes: 0.01CV ( μA ) or 3 μA,whichever is greater ( at 20 ℃ ) Where,C =Nominal capacitance（μF ） V =Rated Voltage（VDC） Dissipation Factor Rated voltage(VDC) 6.3 10 16 25 35 50 ( TANδ) TANδ(Max) 0.22 0.19 0.16 0.14 0.12 0.10 ( at 20℃，120Hz ) ※ When the Capacitance exceeds 1,000μF, 0.02 shall be added every 1,000μF increase. Temperature Characteristics Z(-25 ℃) / Z(20℃) 2 (Max.Impedance ratio) Z(-40 ℃) / Z(20℃) 3 (at 120Hz) The following specifications shall be satisfied when the capacitors are restored to 20℃ after the rated voltage is applied with the rated ripple current at 105℃ for the following test time. Load Life Capacitance change :≤± 30% the of initial Value (6.3 ~ 10VDC) Capacitance change :≤± 25% the of initial Value(16 ~ 50VDC) TANδ :≤200% of the initial specified value Leakage current :≤ The initial specified value Case Size (ΦD) Φ5, 6.3 Φ8 Φ10 ~ Life Time 6,000 hours 8,000 hours 10,000 hours The following specifications shall be satisfied when the capacitors are restored to 20℃ after exposing them for 1000 hours at 105℃ without voltage applied.The rated voltage shall be applied to the capacitor for a minimum of 30 minutes,at least 24 hours and not more than 48 hours before the measurements. Shelf Life Capacitance change :≤± 30% of the initial Value(6.3 ~ 10VDC) Capacitance change :≤± 25% of the initial Value(16 ~ 50VDC) Others TANδ :≤200% of the initial specified value Leakage current :≤The initial specified value Satisfies characteristic W of KS C 6421 A.DIAGRAM OF DIMENSION B.MARKING:WITH YELLOW SLEEVE, BLACK INK 4MIN F±0.5 15MIN ΦD - NXH + VINYL SLEEVE SAFETY VENT（≥6.3φ） Φd ≤10 105℃ 25V 1500μF ≥12.5 FRONT VIEW OF CAPACITOR LOT NO. ΦD' L' L BACK VIEW OF CAPACITOR When ΦD≤8,ΦD'≤ΦD+0.5,and L'≤L+1.5 When ΦD＞8,ΦD'≤ΦD+0.5,and L'≤L+2.0 ΦD Φd F 5 0.5 2.0 6.3 0.5 2.5 8 0.6 3.5 10 0.6 5.0 12.5 0.6 5.0 16 0.8 7.5 18 0.8 7.5 ← 李波 ← ← 立范 波 SamYoung Electronics Co., Ltd. 阿吕 勇 PAGE ALUMINUM ELECTROLYTIC CAPACITOR 2 OF 6 APPROVAL NO： 296-028 RATINGS OF NXH Series 6.3 VDC 10 16 CAP.(μF) IMP. RIPPLE CAP.(μF) IMP. RIPPLE CAP.(μF) IMP. RIPPLE 5×11 220 0.22 345 150 0.22 345 100 0.22 345 5×15 470 0.13 480 330 0.13 480 220 0.13 480 6.3×11 470 0.094 540 330 0.094 540 220 0.094 540 6.3×15 560 0.084 620 470 0.084 620 330 0.084 620 8×11.5 820 0.056 945 680 0.056 945 470 0.056 945 8×15 1200 0.045 1250 1000 0.045 1250 680 0.045 1250 ΦD×L 8×20 1500 0.029 1500 1500 0.029 1500 1000 0.029 1500 10×12.5 1200 0.039 1330 1000 0.039 1330 680 0.039 1330 10×16 1800 0.028 1760 1500 0.028 1760 1000 0.028 1760 10×20 2200 0.020 1960 1800 0.020 1960 1500 0.020 1960 10×25 2700 0.018 2250 2200 0.018 2250 1800 0.018 2250 10×33 3300 0.015 2550 2700 0.015 2550 2200 0.015 2550 12.5×20 3900 0.017 2480 3300 0.017 2480 2200 0.017 2480 12.5×25 4700 0.015 2900 3900 0.015 2900 2700 0.015 2900 12.5×30 5600 0.013 3450 4700 0.013 3450 3300 0.013 3450 12.5×35 6800 0.012 3570 5600 0.012 3570 3900 0.012 3570 16×20 6800 0.015 3250 4700 0.015 3250 3300 0.015 3250 16×25 8200 0.013 3630 6800 0.013 3630 4700 0.013 3630 18×25 10000 0.012 3650 8200 0.012 3650 5600 0.012 3650 CAP.(μF) IMP. RIPPLE CAP.(μF) IMP. RIPPLE CAP.(μF) IMP. RIPPLE 33 0.3 250 2.2 2.5 120 4.7 2.5 120 10 1.0 145 22 0.40 195 27 0.34 238 0.16 350 ΦD×L 5×11 35 25 VDC 68 0.22 345 47 0.22 50 345 5×15 150 0.13 480 100 0.13 480 56 33 0.20 320 6.3×11 100 0.094 540 100 0.094 540 47 0.14 450 150 0.094 540 56 0.14 450 6.3×15 220 0.084 620 150 0.084 620 100 0.12 586 68 0.10 646 330 0.056 945 220 0.056 945 100 0.074 724 390 0.045 1250 270 0.045 1250 120 0.061 950 470 0.045 1330 390 0.029 1500 560 0.029 1500 470 0.029 1600 180 0.046 1190 470 0.039 1330 330 0.039 1330 150 0.061 979 680 0.028 1760 470 0.028 1760 220 0.042 1370 330 0.042 1370 820 0.020 1960 560 0.020 1960 270 0.030 1580 8×11.5 8×15 8×20 10×12.5 10×16 10×20 1000 0.020 1960 680 0.025 1850 10×25 1000 0.018 2250 680 0.018 2250 330 0.028 1870 10×33 1200 0.015 2550 1000 0.015 2550 470 0.025 2110 1000 0.018 2500 1000 0.017 2480 470 0.027 2050 1500 0.017 2550 12.5×25 1800 0.015 2900 1200 0.015 2900 560 0.023 2410 12.5×30 2200 0.013 3450 1500 0.013 3450 680 0.021 2860 12.5×35 2700 0.012 3570 1800 0.012 3570 820 0.019 2960 2200 0.015 3250 1500 0.015 3250 820 0.023 2730 2700 0.015 3250 1000 0.023 2730 16×25 3300 0.013 3630 18×25 3900 0.012 3650 12.5×20 16×20 2200 0.013 3630 1000 0.021 3010 2700 0.012 3650 1500 0.019 3290 Permissible Ripple Current (mArms / 105℃,100KHz) Immpedance (Ω max. / 20℃, 100KHz) Nominal Capacitance (μF) SamYoung Electronics Co., Ltd. PAGE: 3 OF 6 APPROVAL NO. ALUMINUM ELECTROLYTIC CAPACITORS 296-028 STRUCTURE AND MATERIALS LEAD WIRE PACKING PAD LEAD WIRE AL LEAD AL FOIL ( - ) AL LEAD AL FOIL ( + ) SLEEVE AL CASE ADHESIVE TAPE ELEMENT SEPARATOR CE04 TYPE *MINIATURE SIZED TYPE CAPACITORS COMPONENT PART NAME LEAD WIRE AL LEAD MATERIALS TINNED COPPER - PLY WIRE(Pb-FREE) ALUMINUM 99.92 % OVER VENDER KISTRON JIANG SU HONG YANG (CHINA) NAN TONG HUI FENG (CHINA) JIANG SU HONG YANG (CHINA) SUNG NAM SYNTHETIC RUBBER OR BAKE PAD (CHINA) KANG WON AUTO FITTING KISTRON PACKING PAD (KOREA) ZHE JIANG TIAN TAI (KOREA) (KOREA/CHINA) (CHINA) ZHE JIANG TIAN HUA SLEEVE P.E.T(Poly Ethlylene Terephthalate Resin) MOO DEUNG YUN LIN PLASTIC ZHANG JIA GANG LIAN YI AL CASE ALUMINUM 99.0 % OVER LIN AN AO XING D.N TECH AL FOIL AL FOIL SEPARATOR FORMED ALUMINUM 99.9 % OVER ETCHED ALUMINUM 98.0 % OVER INSULATION PAPER ADHESIVE TAPE POLY PROPYLENE FILM (KOREA/CHINA) (CHINA) (CHINA) (CHINA) (KOREA/CHINA) K.D.K (JAPAN) SAM YOUNG (KOREA) HUAFENG / HISTAR / HAIYI (CHINA) K-JCC (KOREA) WU JIANG FEILO (CHINA) K.D.K (JAPAN) ELECON (CHINA) KAN (CHINA) N.K.K (JAPAN) DAI IL (KOREA) SamYoung Electronics Co., Ltd. PAGE : 4 OF 6 ALUMINNUM ELECTROLYTIC CAPACITOR APPROVAL NO. 296-028 Taping Dimensions：5.0mm T/P (8.0Φ*11.5L) P P2 Δh ΦD A H1 Adhesive Tape Base Tape F 1.0Max W0 W L W1 W2 H0 Φd H P1 t D0 P0 Items ΦD A Φd P P0 Dimensions 8 13.0 Max 0.6 12.7 12.7 Tolerance ±0.5 ±0.05 ±1.0 ±0.2 Cumulative pitch error : 1mm/20pitch P1 3.85 ±0.7 To be measured at bottom of clinch P2 6.35 ±1.0 F 5.0 +0.8 -0.2 △h W W0 0 18.0 ±2.0 ±0.5 10Min - W1 9.0 ±0.5 W2 H H0 H1 1.5 Max 18.5 16.0 ±0.75 ±0.5 H+A - D0 t L 4.0 0.7 11.0Max ±0.2 ±0.2 - Remarks Not to protrude over base tape check insertion machine specs SamYoung Electronics Co., Ltd. PAGE 5 OF 6 When using aluminum electrolytic capacitors,pay strict attention to the following: 1. Electrolytic capacitors for DC application require polarization. Confirm the polarity.If used in reversed polarity,the circuit life may be shortened or the capacitor may be damaged.For use on circuits whose polarity is occasionally reversed,or whose polarity is unknown,use bi-polarized capacitors (BPseries).Also,note that the electrolytic capacitor cannot be used for AC application. 2. Do not apply a voltage exceeding the capacitor`s voltage rating. If a voltage execeeding the capacitor`s voltage rating is applied,the capacitor may be damaged as leakage current increases. When using the capacitor with AC voltage superimposed on DC voltage,care must be exercised that the peak value of AC voltage does not exceed the rated voltage. 3. Do not allow excessive ripple current to pass. Use the electrolytic capacitor at current values within the permissible ripple range.If the ripple current exceeds the specified value,request capacitors for high ripple current applications. 4. Ascertain the operating temperature range. Use the electrolytic capacitors according to the specified operating temperature range.Usage at room temperature will ensure longer life. 5. The electrolytic capacitor is not suitable for circuits in which charge and discharge are frequently repeated. If used in circuits in which charge and discharge are frequently repeated,the capacitance value may drop,or the capacitor may be damaged.Please consult our engineering department for assistance in these applications. 6. Apply voltage treatment to the electrolytic capacitor which has been allowed to stand for a long time. If the electrolytic capacitor is allowed to stand for a long time,its withstand voltage is liable to drop,resulting in increased leakage current.If the rated voltage is applied to such a product,a large leakage current occurs and this generates internal heat,which damaged the capacitor.If the electrolytic capacitor is allowed to stand for a long time,therefore,use it after giving voltage treatment (Note 1).(However,no voltage treatment is required if the electrolytic capacitor is allowed to stand for less than 2 or 3 years at normal temperature.) 7. Be careful of temperature and time when soldering. When soldering a printed circuit board with various,components,care must be taken that the soldering temperature is not too high and that the dipping time is not too long.Otherwise,there will be adverse effects on the electrical characteristics and insulation sleeve of electrolytic capacitors in the case of small-sized electrolytic capacitors,nothing abnormal will occur if dipping is performed at less than 260℃ for less than 10 seconds. 8. Do not place a soldering iron on the body of the capacitor. The electrolytic capacitor is covered with a vinyl sleeve.If the soldering iron comes in contact with the electrolytic capacitor body during wiring,damage to the vinyl sleeve and/or case may result in defective insulation,or improper protection of the capacitor element. 9. Cleaning circuit boards after soldering. Some solvents have adverse effects on capacitors. Please refer to the next page. 10.Do not apply excessive force to the lead wires or terminals. If excessive force is applied to the lead wires and terminals,they may be broken or their connections with the internal elements may be affectde.(For strength of terminals,refer to KS C6035 KS C6421(JIS C5102,JIS C5141) 11.Care should be used in selecting a storage area. If electrolytic capacitors are exposed to high temperatures caused by such things as direct sunlight,the life of the capacitor may be adversely affected.Storage in a high humidity atmosphere may affect the solderability of lead wires and terminals. 12.Surge voltage. The surge voltage rating is the maximum DC over-voltage to which the capacitor may be subjected for short periods not exceeding approximately 30 seconds at infrequent intervals of not more than six minutes.According to KS C6421,the test shall be conducted 1000 cycles at room temperature for the capacitors of characteristic W of KS C6421 or at the maximum operating temperature for the capacitors of characteristics B and C of KS C6421 with voltage applied through a series resistance of 1000 ohms without discharge.The electrical characteristics of the capacitor after the test are specified in KS C6421.Unless otherwise specified,the rated surge voltage are as follows: Rated Voltage(V) 2 4 6.3 10 16 25 35 50 63 80 100 160 200 250 315 350 400 450 500 Rated Surge Voltage(V) 2.5 5 8 13 20 32 44 63 79 100 125 200 250 300 365 400 450 500 550 Note 1 Voltage treatment … Voltage treatment shall be performed by increasing voltage up to the capacitor`s voltage rating gradually while lowering the leakage current.In this case,the impressed voltage shall be in the range where the leakage current of the electrolytic capacitor is less than specified value.Meanwhile,the voltage treatment time may be effectively shortened if the ambient temperature is increased (within the operating temperature range). Note 2 For methods of testing, refer to KS C 6035, KS C 6421，（JIS C 5102，JIS C 5141） SamYoung Electronics Co., Ltd. PAGE 6 OF 6 CLEANING CONDITIONS Aluminum electrolytic capacitors that have been exposed to halogenated hydrocarbon cleaning and defluxing solvents are susceptible to attack by these solvents.This exposure can result in solvent penetration into the capacitors, leading to internal corrosion and potential failure. Therefore, for ordinary capacitors, the cleaning materials of alcohol system had to be used. However, the solvent proof type capacitors of Samyoung Elec. Can withstand cleaning by some halogenated solvents shown: (rated voltage≤100 VDC only) * FREON TE R OR TES R Cleaning method: One of immersion, ultrasonic or vap or cleaning. Maximum cleaning time: 5 minutes(where, KRE,SRM is 2 minutes) * 1,1,1-Trichlorethane Cleaning method: immersion cleaning at the normal temperature Maximum cleaning time: 5 minutes(where, KRE,SRM is not assured) — Caution — * When the lead space of the capacitor is different from the hole space of the PC board to be mounted , use the lead forming type capacitor to prevent stress on seal. * Consult for flux to be used and other cleaning conditions. (Freon TE and TES are registered trademarks of Dupont,Inc.) * lnfluence of cleaning solvent for aluminum electrolytic capacitor. Aluminum electrolytic capacitors are easily affeceted by halogen ions,particularly by chloride ions. Excessive amounts of halogen ions,if happened to enter the inside of the capacitors, will give corrosion accidents-rapid capacitance drop and vent open. The extent of corrosion accidents varies with kinds of electrolytes and seal-materials. Therefore, the prevention of halogen ion contamination is the most improtant check point for quality control in our procuction lines. At present, halogenated hydrocarboncontained organic solvents such as Trichloroethylene, 1,1,1-Trichloroethane, and Freon are used to remove flux from circuit boards. However, if general types of aluminum electroytic capacitors,whose seal constructions are not solvent-proof, are cleaned with such solvents, the solvents may gradually penetrate the seal portion and erode. The inside of the capacitors. The mechanism of corrosion of aluminum electrolytic capacitors by halogen ions can be explained as follows: Halides(RX) are absorbed and diffused into the seal portion. The halides then enter the inside of the capacitors and contact with the electrolyte of the capacitors. Where by halogen ions are made free by a hydrolysis with water in the electrolyte: + RX + H2O → ROH + H + X - The halogen ions (X ) react with the dielectric substance(Al 2O3) of aluminum electrolytic capacitors: AI2O3 + 6H+ + 6X- →2ALX3 + 3H2O AIX3 is dissociated with water: + ALX3 + 3H2O → AL（OH）3 + 3H + 3X SamYoung Electronics Co., Ltd.