HWS150A RELIABILITY DATA 信頼性データ

RELIABILITY DATA 信頼性データ TDK-Lambda A259-57-1C

I N D E X PAGE 1.MTBF 計算値 Calculated Values of MTBF R-1~2 2. 部品ディレーティング Components Derating R-3~7 3. 主要部品温度上昇値 Main Components Temperature Rise T List R-~9. 電解コンデンサ推定寿命計算値 Electrolytic Capacitor Lifetime R-1~13 カバー付きタイプ ( オプション ) R-1~17 With cover type (Option model) 5. アブノーマル試験 Abnormal Test R-1~19 6. 振動試験 Vibration Test R- 7. ノイズシミュレート試験 Noise Simulate Test R-21. 熱衝撃試験 Thermal Shock Test R-22 試験結果は 代表データでありますが 全ての製品はほぼ同等な特性を示します 従いまして 以下の結果は参考値とお考え願います Test results are typical data. Nevertheless the following results are considered to be reference data because all units have nearly the same characteristics. TDK-Lambda

1.MTBF 計算値 Calculated Values of MTBF (1) 部品ストレス解析法 MTBF Parts stress reliability projection MTBF MODEL : -2 算出方法 Calculating Method Telcordia の部品ストレス解析法 (*1) で算出されています 故障率 λ SS は それぞれの部品ごとに電気ストレスと動作温度によって決定されます Calculated based on parts stress reliability projection of Telcordia (*1). Individual failure rate λ SS is calculated by the electric stress and temperature rise of the each part. < 算出式 > λ equip *1: Telcordia document Reliability Prediction Procedure for Electronic Equipment (Document number SR-332,Issue3) MTBF 1 = λ equip = p l = l p p p ssi Gi Qi Si å ( N 1 ) 時間 (Hours) : 全機器故障率 (FITs) Total equipment failure rate (FITs = Failures in1 9 hours) m E i= 1 Ti 1 i l ssi 9 λ Gi π Qi π Si π Ti m N i π E :i 番目の部品に対する基礎故障率 Generic failure rate for the ith part :i 番目の部品に対する品質ファクタ Quality factor for the ith part :i 番目の部品に対するストレスファクタ Stress factor for the ith part :i 番目の部品に対する温度ファクタ Temperature factor for the ith part : 異なる部品の数 Number of different part types :i 番目の部品の個数 Quantity of ith part type : 機器の環境ファクタ Equipment environmental factor MTBF 値 MTBF Values 条件 Conditions 入力電圧 : 23VAC 出力電圧 電流 : 2VDC, 6.5A (1%) Input voltage Output voltage & current 環境ファクタ : GB (Ground, Benign) 取付方法 : 標準取付 A Environmental factor Mounting method : Standard mounting A SR-332,Issue3 MTBF(Ta=25 ) 2,676,1 時間 (Hours) MTBF(Ta= ) 1,262,313 時間 (Hours) TDK-Lambda R-1

(2) 部品点数法 MTBF Part count reliability projection MTBF MODEL : -5 算出方法 Calculating Method JEITA (RCR-912B) の部品点数法で算出されています それぞれの部品ごとに 部品故障率 λ G が与えられ 各々の点数によって決定されます Calculated based on part count reliability projection of JEITA (RCR-912B). Individual failure rates λ G is given to each part and MTBF is calculated by the count of each part. < 算出式 > 1 MTBF = λ equip 1 6 = n å i = 1 n i 1 ( l p ) G Q i 1 6 時間 (Hours) λequip : 全機器故障率 ( 故障数 /1 6 時間 ) Total equipment failure rate (Failure/1 6 Hours) λ G :i 番目の同属部品に対する故障率 ( 故障数 /1 6 時間 ) Generic failure rate for the ith generic part (Failure/1 6 Hours) n i n :i 番目の同属部品の個数 Quantity of ith generic part : 異なった同属部品のカテゴリーの数 Number of different generic part categories π Q :i 番目の同属部品に対する品質ファクタ (π Q =1) Generic quality factor for the ith generic part (π Q =1) MTBF 値 MTBF Values G F : 地上固定 (Ground, Fixed) RCR-912B MTBF 6,215 時間 (Hours) TDK-Lambda R-2

2. 部品ディレーティング Components Derating MODEL : -5 (1) 算出方法 Calculating Method (a) 測定方法 Measuring method 取付方法 : 標準取付 : A 周囲温度 :5 Mounting method Standard mounting : A Ambient temperature 入力電圧 :1, VAC 出力電圧 電流 :5V, 3A(1%) Input voltage Output voltage & current (b) 半導体 Semiconductors ケース温度 消費電力 熱抵抗より使用状態の接合点温度を求め最大定格 接合点温度との比較を求めました Compared with maximum junction temperature and actual one which is calculated based on case temperature, power dissipation and thermal impedance. (c) IC 抵抗 コンデンサ等 IC, Resistors, Capacitors, etc. 周囲温度 使用状態 消費電力など 個々の値は設計基準内に入っています Ambient temperature, operating condition, power dissipation and so on are within derating criteria. (d) 熱抵抗算出方法 Calculating method of thermal impedance Tj(max) - Tc Tj(max) - Tl q j- c = q j- l = Pch(max) Pch(max) Tc : ディレーティングの始まるケース温度一般に 25 Case Temperature at Start Point of Derating;25 in General Tl : ディレーティングの始まるリード温度一般に 25 Lead Temperature at Start Point of Derating;25 in General Pch(max) : 最大チャネル損失 Maximum Channel Dissipation Tj(max) : 最大接合点 ( チャネル ) 温度 (Tch(max)) Maximum Junction (channel) Temperature θj-c : 接合点 ( チャネル ) からケースまでの熱抵抗 (θch-c) Thermal Impedance between Junction (channel) and Case θj-l : 接合点 ( チャネル ) からリードまでの熱抵抗 (θch-l) Thermal Impedance between Junction (channel) and Lead TDK-Lambda R-3

(2) 部品ディレーティング表 Components Derating List 部品番号 Load = 1% Ta = 5 Location No. Q1 Tj (max) = 15 θj-c =.9 /W IPP6R199CP Pch = 3.31 W ΔTc = 6. Tc = 96. INFINEON Tch = Tc + ((θj-c) Pch ) = 99. D.F. = 66.3 % Q2 Tj (max) = 15 θj-c = 2.7 /W TKA5D Pch = 1.3 W ΔTc = 5.6 Tc = 1.6 TOSHIBA Tch = Tc + ((θj-c) Pch ) = 1.3 D.F. = 7.9 % Q3 Tj (max) = 15 θj-c = 2.7 /W TKA5D Pch = 1. W ΔTc = 5.9 Tc = 1.9 TOSHIBA Tch = Tc + ((θj-c) Pch ) = 1.9 D.F. = 72.6 % Q51 Tj (max) = 175 θj-c = 3. /W IPA57NN3 G Pch = 1.5 W ΔTc = 7.6 Tc =.6 INFINEON Tch = Tc + ((θj-c) Pch ) = 13.5 D.F. = 76.9 % Q52 Q53 Tj (max) = 175 θj-c = 3. /W IPA57NN3 G Pch =.96 W ΔTc = 67.2 Tc = 117.2 INFINEON Tch = Tc + ((θj-c) Pch ) = 1. D.F. = 69. % Q11 Tj (max) = 15 θj-c = 625. /W 2SC392A Pc =.1 mw ΔTc = 5.2 Tc = 1.2 ISAHAYA Tch = Tc + ((θj-c) Pc ) = 1.3 D.F. = 66.9 % Q1 Tj (max) = 15 θj-c = 25. /W 2SA27 Pc = 13.2 mw ΔTc = 5.2 Tc = 1.2 ISAHAYA Tch = Tc + ((θj-c) Pc ) = 17.5 D.F. = 71.7 % Q1 Tj (max) = 15 θj-c = 3.3 /W RQK63CGDQSTL Pc =.13 W ΔTc = 67.5 Tc = 117.5 RENESAS Tch = Tc + ((θj-c) Pc ) =.3 D.F. = 5.5 % D1 Tj (max) = 15 θj-c = 2. /W KBJ16G Pd = 3.5 W ΔTc = 66.3 Tc = 1.3 LITE-ON Tch = Tc + ((θj-c) Pd ) =. D.F. = 2.7 % D2 Tj (max) = 15 θj-c = 2. /W RFUSTF6S Pd =.79 W ΔTc = 62.6 Tc = 1.6 ROHM Tch = Tc + ((θj-c) Pd ) = 11.2 D.F. = 76.1 % D1 Tj (max) = 15 θj-l = 3. /W CRH1 Pd = 2. mw ΔTl = 51. Tl = 11. TOSHIBA Tch = Tl + ((θj-l) Pd ) = 11.1 D.F. = 67. % D15 Tj (max) = 15 θj-l = 3. /W CRH1 Pd = 2. mw ΔTl = 9. Tl = 99. TOSHIBA Tch = Tl + ((θj-l) Pd ) = 99.9 D.F. = 66.6 % TDK-Lambda R-

部品番号 Load = 1% Ta = 5 Location No. D16 Tj (max) = 15 θj-l =. /W CRS Pd = 19.2 mw ΔTl = 5.2 Tl = 1.2 TOSHIBA Tch = Tl + ((θj-l) Pd ) = 1.6 D.F. = 69.7 % D17 D19 Tj (max) = 15 θj-l = 23. /W LN1F6 Pd =.6 mw ΔTl = 57. Tl = 17. SHINDENGEN Tch = Tl + ((θj-l) Pd ) = 17.2 D.F. = 71.5 % D1 D113 Tj (max) = 15 θj-l = 3. /W CRH1 Pd = 2. mw ΔTl = 5. Tl = 1. TOSHIBA Tch = Tl + ((θj-l) Pd ) = 1.1 D.F. = 69. % D11 Tj (max) = 15 θj-l = 3. /W CRH1 Pd = 2.1 mw ΔTl = 5. Tl = 1. TOSHIBA Tch = Tl + ((θj-l) Pd ) = 1.1 D.F. = 69. % Z11 Tj (max) = 15 θj-c = 625. /W UDZV TE-17 B Pd =. mw ΔTc = 5.2 Tc = 1.2 ROHM Tch = Tc + ((θj-c) Pd ) = 1.7 D.F. = 67.1 % PC2 Tj (max) = 5 θj-c = 15. /W PS2561DL1 Pd = 1.2 mw ΔTc = 7. Tc = 97. (LED) Tch = Tc + ((θj-c) Pd ) = 97.2 RENESAS D.F. = 77. % PC2 Tj (max) = 5 θj-c = 15. /W PS2561DL1 Pc = 2.1 mw ΔTc = 7. Tc = 97. (TRANSISTOR) Tch = Tc + ((θj-c) Pc ) = 97.3 RENESAS D.F. = 77. % PD51 SEL21G If = 3. ma ΔTa = 23.3 Ta = 73.3 SANKEN Allowable If(max) =.3 ma (at Ta=73.3 ) D.F. = 36.1 % TDK-Lambda R-5

部品番号 Vin = VAC Load = 1% Ta = 5 Location No. Q1 Tj (max) = 15 θj-c =.9 /W IPP6R199CP Pch = 3.31 W ΔTc = 35.6 Tc = 5.6 INFINEON Tch = Tc + ((θj-c) Pch ) =.6 D.F. = 59.1 % Q2 Tj (max) = 15 θj-c = 2.7 /W TKA5D Pch = 1.3 W ΔTc = 53. Tc = 13. TOSHIBA Tch = Tc + ((θj-c) Pch ) = 17.5 D.F. = 71.7 % Q3 Tj (max) = 15 θj-c = 2.7 /W TKA5D Pch = 1. W ΔTc = 5.3 Tc = 1.3 TOSHIBA Tch = Tc + ((θj-c) Pch ) = 1.3 D.F. = 69.5 % Q51 Tj (max) = 175 θj-c = 3. /W IPA57NN3 G Pch = 1.5 W ΔTc = 73.5 Tc = 3.5 INFINEON Tch = Tc + ((θj-c) Pch ) = 9. D.F. = 73.9 % Q52 Q53 Tj (max) = 175 θj-c = 3. /W IPA57NN3 G Pch =.96 W ΔTc = 62. Tc = 1. INFINEON Tch = Tc + ((θj-c) Pch ) = 1. D.F. = 66.3 % Q11 Tj (max) = 15 θj-c = 625. /W 2SC392A Pc =.1 mw ΔTc = 3.6 Tc = 93.6 ISAHAYA Tch = Tc + ((θj-c) Pc ) = 93.7 D.F. = 62.5 % Q1 Tj (max) = 15 θj-c = 25. /W 2SA27 Pc = 13.2 mw ΔTc = 9. Tc = 99. ISAHAYA Tch = Tc + ((θj-c) Pc ) = 12.3 D.F. = 6.2 % Q1 Tj (max) = 15 θj-c = 3.3 /W RQK63CGDQSTL Pc =.13 W ΔTc = 62.7 Tc = 1.7 RENESAS Tch = Tc + ((θj-c) Pc ) = 3.5 D.F. = 2.3 % D1 Tj (max) = 15 θj-c = 2. /W KBJ16G Pd = 1.96 W ΔTc = 39.9 Tc = 9.9 LITE-ON Tch = Tc + ((θj-c) Pd ) = 93. D.F. = 62.5 % D2 Tj (max) = 15 θj-c = 2. /W RFUSTF6S Pd =.79 W ΔTc = 55. Tc = 15. ROHM Tch = Tc + ((θj-c) Pd ) = 17. D.F. = 71.3 % D1 Tj (max) = 15 θj-l = 3. /W CRH1 Pd = 2. mw ΔTl =.6 Tl = 9.6 TOSHIBA Tch = Tl + ((θj-l) Pd ) = 9.7 D.F. = 63.1 % D15 Tj (max) = 15 θj-l = 3. /W CRH1 Pd = 2. mw ΔTl = 3.1 Tl = 93.1 TOSHIBA Tch = Tl + ((θj-l) Pd ) = 93.2 D.F. = 62.1 % TDK-Lambda R-6

部品番号 Vin = VAC Load = 1% Ta = 5 Location No. D16 Tj (max) = 15 θj-l =. /W CRS Pd = 19.2 mw ΔTl = 9. Tl = 99. TOSHIBA Tch = Tl + ((θj-l) Pd ) = 99. D.F. = 66.3 % D17 D19 Tj (max) = 15 θj-l = 23. /W LN1F6 Pd =.6 mw ΔTl = 52. Tl = 12. SHINDENGEN Tch = Tl + ((θj-l) Pd ) = 12.2 D.F. = 6.1 % D1 D113 Tj (max) = 15 θj-l = 3. /W CRH1 Pd = 2. mw ΔTl =.9 Tl = 9.9 TOSHIBA Tch = Tl + ((θj-l) Pd ) = 99. D.F. = 66. % D11 Tj (max) = 15 θj-l = 3. /W CRH1 Pd = 2.1 mw ΔTl =.9 Tl = 9.9 TOSHIBA Tch = Tl + ((θj-l) Pd ) = 99. D.F. = 66. % Z11 Tj (max) = 15 θj-c = 625. /W UDZV TE-17 B Pd =.6 mw ΔTc = 3.6 Tc = 93.6 ROHM Tch = Tc + ((θj-c) Pd ) = 96.5 D.F. = 6.3 % PC2 Tj (max) = 5 θj-c = 15. /W PS2561DL1 Pd = 1.2 mw ΔTc =.7 Tc = 9.7 (LED) Tch = Tc + ((θj-c) Pd ) = 9.9 RENESAS D.F. = 72.7 % PC2 Tj (max) = 5 θj-c = 15. /W PS2561DL1 Pc = 2.1 mw ΔTc =.7 Tc = 9.7 (TRANSISTOR) Tch = Tc + ((θj-c) Pc ) = 91. RENESAS D.F. = 72. % PD51 SEL21G If = 3. ma ΔTa = 22.2 Ta = 72.2 SANKEN Allowable If(max) =. ma (at Ta=72.2 ) D.F. = 3.1 % TDK-Lambda R-7

3. 主要部品温度上昇値 Main Components Temperature Rise T List MODEL : -5 (1) 測定条件 Measuring Conditions 取付方法 Mounting Method Mounting A Mounting B Mounting C Mounting D ( 標準取付 : A) (Standard Mounting : A) 入力電圧 Vin Input Voltage 出力電圧 Vo Output Voltage 出力電流 Io Output Current (2) 測定結果 Measuring Results 1VAC 5VDC 3A(1%) ΔT Temperature Rise ( ) 出力ディレーティング Io=1 % Output Derating Ta=5 Ta= Ta=3 Ta=3 部品番号 部品名 取付方向 取付方向 取付方向 取付方向 Location No. Part name Mounting A Mounting B Mounting C Mounting D Q1 MOS FET 6. 5.2 9.1 55.6 Q2 MOS FET 5.6 56.6 56. 67.2 Q3 MOS FET 5.9 5. 5.6 62. Q51 MOS FET 7.6 75.6.1 7.2 Q52 MOS FET 67.2 6.2 69.7 65.5 Q53 MOS FET 63.1 6.1 66.1 6.7 D1 BRIDGE DIODE 66.3 7. 73. 66. D2 DIODE 62.6 72.2 65.9 75.2 A11 CHIP IC 51. 56.6 56.2 59.6 A12 CHIP IC 52.2 5.6 55. 5.9 A1 CHIP IC 1.6 37.5 9. 37.7 T1 DRIVE TRANS 3. 7.5 3.6 53.9 T2 TRANS 7.6 6.9 75. 75. L1 BALUN. 5. 55. 2. L2 BALUN 37. 9.9 7.7 9.3 L3 CHOKE COIL.2 62.6 56.9 6. L51 CHOKE COIL 61. 59.3 66.6 59.1 C6 E.CAP. 31.5 3.2.2 52.2 C7 E.CAP. 33. 32. 36.9 52. C51 E.CAP. 35.1 3.6 1. 33.3 C52 E.CAP. 32. 2. 1. 21. PC2 PHOTO COUPLER 7..6 51. 9. PD51 LED 23.3 19..7.9 TDK-Lambda R-

(1) 測定条件 Measuring Conditions 取付方法 Mounting Method Mounting A Mounting B Mounting C Mounting D ( 標準取付 : A) (Standard Mounting : A) 入力電圧 Vin Input Voltage 出力電圧 Vo Output Voltage 出力電流 Io Output Current (2) 測定結果 Measuring Results VAC 5VDC 3A(1%) ΔT Temperature Rise ( ) 出力ディレーティング Io=1 % Output Derating Ta=5 Ta= Ta=3 Ta=3 部品番号 部品名 取付方向 取付方向 取付方向 取付方向 Location No. Part name Mounting A Mounting B Mounting C Mounting D Q1 MOS FET 35.6 39.3 37. 3.3 Q2 MOS FET 53. 53.1 51.2 61. Q3 MOS FET 5.3 5.2 9.2 57. Q51 MOS FET 73.5 72.3 75. 73. Q52 MOS FET 62. 61. 65. 61.5 Q53 MOS FET 5.2 57. 61. 56.7 D1 BRIDGE DIODE 39.9 7. 6. 1. D2 DIODE 55. 63.9 5.6 65.7 A11 CHIP IC. 9.7.5 51.2 A12 CHIP IC 6.5 9. 9. 52.6 A1 CHIP IC 37.9 35. 5.9 35.1 T1 DRIVE TRANS 3.6 3.7 39. 9. T2 TRANS 66.5 6.1 71.9 72.2 L1 BALUN 25. 3.6 36. 27.7 L2 BALUN 2.5 3.6 33. 32. L3 CHOKE COIL 36. 9.1. 6.1 L51 CHOKE COIL 56.2 5. 62. 56.2 C6 E.CAP. 2.2 3.5 35.2 5.9 C7 E.CAP. 29.6 3.3 32. 7.5 C51 E.CAP. 31.1 2.2 39.1 31.5 C52 E.CAP. 31. 25. 36.6 3. PC2 PHOTO COUPLER.7.7 5. 3. PD51 LED 22.2 1. 39. 19. TDK-Lambda R-9

. 電解コンデンサ推定寿命計算値 Electrolytic Capacitor Lifetime MODEL : 空冷条件 : 自然空冷 Cooling condition : Convection cooling 取付方向 A Mounting A Conditions Ta : 5 : 6 : 5V Vin = VAC Load 5 6 Load 5 6 %. 19.1 9.5 %. 19.9 9.9 %. 15.7 7.9 %. 17..5 6%. 11.2 5.6 6%. 13.2 6.6 % 13. 6.7 - % 17.1.6-1% 7.3 3.6-1% 9.6. - 1 7 1 1 7 1 2V Vin = VAC Load 5 6 Load 5 6 %. 1. 9. %.. 1.1 %. 11.6 5. %. 1.1 7. 6%...2 6%. 11.1 5.6 %.7 6.3 - % 17.1.5-1% 9.2.6-1%.3 6.2-1 7 1 1 7 1 上記推定寿命は 弊社計算方法により算出した値であり 封口コ ムの劣化等の影響を含めておりません The lifetime is calculated based on our method and doesn't include the seal rubber degradation effect etc. TDK-Lambda R-1

MODEL : 空冷条件 : 自然空冷 Cooling condition : Convection cooling 取付方向 B Mounting B Conditions Ta : 5 : 6 : 5V Vin = VAC Load 5 6 Load 5 6 %. 19.1 9.5 %.. 1. %. 1.5 7.2 %. 15.2 7.6 6% 19.6 9..9 6%. 11.6 5. % 13.6 6. - % 17.2.6-1%. - - 1% 11.3 - - 1 7 1 1 7 1 2V Vin = VAC Load 5 6 Load 5 6 %. 17.1.5 %. 1.6 9.3 %. 1.9 5. %. 13.2 6.6 6% 15.3 7.6 3. 6%. 1.2 5.1 % 11.1 5.6 - % 1. 7. - 1% 7.9 - - 1% 11. - - 1 7 1 1 7 1 上記推定寿命は 弊社計算方法により算出した値であり 封口コ ムの劣化等の影響を含めておりません The lifetime is calculated based on our method and doesn't include the seal rubber degradation effect etc. TDK-Lambda R-11

MODEL : 空冷条件 : 自然空冷 Cooling condition : Convection cooling 取付方向 C Mounting C Conditions Ta 3 : : 5 : 5V Vin = VAC Load 3 5 Load 3 5 %... %.. 17.3 %.. 13.1 %.. 13. 6%. 1. 9.2 6%. 1.9 9. %. 1. - %. 11.2-1% 9. - - 1% 11. - - 1 7 1 1 7 1 2V Vin = VAC Load 3 5 Load 3 5 %.. 15.3 %...1 %... %.. 1. 6%. 17..9 6%.. 11. %..6 - %. 17. - 1% 17.9 - - 1%. - - 1 7 1 1 7 1 上記推定寿命は 弊社計算方法により算出した値であり 封口コ ムの劣化等の影響を含めておりません The lifetime is calculated based on our method and doesn't include the seal rubber degradation effect etc. TDK-Lambda R-

MODEL : 空冷条件 : 自然空冷 Cooling condition : Convection cooling 取付方向 D Mounting D Conditions Ta 3 : : 5 : 5V Vin = VAC Load 3 5 Load 3 5 %.. 1.2 %...3 %.. 1.5 %...6 6%..9 6.5 6%. 17.2.6 % 15.5 7.7 - % 19.9 9.9-1% 6. - - 1% 9.2 - - 1 7 1 1 7 1 2V Vin = VAC Load 3 5 Load 3 5 %.. 13.2 %.. 15. %.. 1.7 %...1 6%. 1. 7. 6%. 17.3.7 % 1.1 9. - %..7-1% 11.7 - - 1% 17.1 - - 1 7 1 1 7 1 上記推定寿命は 弊社計算方法により算出した値であり 封口コ ムの劣化等の影響を含めておりません The lifetime is calculated based on our method and doesn't include the seal rubber degradation effect etc. TDK-Lambda R-13

MODEL : /A カバー付きタイプ ( オプション ) With cover type (Option model) 空冷条件 : 自然空冷 Cooling condition : Convection cooling 取付方向 A Mounting A Conditions Ta : 5 : 6 : 5V Vin = VAC Load 5 6 Load 5 6 %. 15.9. %. 17.6. %.. 6.2 %. 1.3 7.1 6%.2.1.1 6%. 1. 5. %.9. - % 11.7 5.9-1% 5.3 2.6-1% 5.9 2.9-1 7 1 1 7 1 2V Vin = VAC Load 5 6 Load 5 6 %. 17.9 9. %. 19.2 9.6 %. 11. 5.5 %. 11.3 5.7 6% 1. 7.2 3.6 6% 17.2.6.3 % 9..9 - % 13.3 6.7-1% 6.3 3.1-1% 1.9 5. - 1 7 1 1 7 1 上記推定寿命は 弊社計算方法により算出した値であり 封口コ ムの劣化等の影響を含めておりません The lifetime is calculated based on our method and doesn't include the seal rubber degradation effect etc. TDK-Lambda R-1

MODEL : /A カバー付きタイプ ( オプション ) 空冷条件 : 自然空冷 With cover type (Option model) Cooling condition : Convection cooling 取付方向 B Mounting B Conditions Ta 3 : : 5 : 5V Vin = VAC Load 3 5 Load 3 5 %.. 17. %.. 1.1 %.. 1. %.. 11. 6%. 1. 7.2 6%. 17.7. % 1. 9. - %.. - 1% 1.3 - - 1% 1.5 - - 1 7 1 1 7 1 2V Vin = VAC Load 3 5 Load 3 5 %.. 1. %.. 15. %. 15.1 7.5 %. 19.3 9.7 6% 19.5 9.7.9 6%..9 6.5 % 13.7 6. - % 19.2 9.6-1%.3 - - 1%.3 - - 1 7 1 1 7 1 上記推定寿命は 弊社計算方法により算出した値であり 封口コ ムの劣化等の影響を含めておりません The lifetime is calculated based on our method and doesn't include the seal rubber degradation effect etc. TDK-Lambda R-15

MODEL : /A カバー付きタイプ ( オプション ) With cover type (Option model) 空冷条件 : 自然空冷 Cooling condition : Convection cooling 取付方向 C Mounting C Conditions Ta 3 : : 5 : 5V Vin = VAC Load 3 5 Load 3 5 %.. 1.1 %.. 1.2 %.. 1.3 %.. 1. 6%..2 6.1 6%. 13.9 7. %.6 6.3 - % 15.1 7.6-1% 5. - - 1% 6.7 - - 1 7 1 1 7 1 2V Vin = VAC Load 3 5 Load 3 5 %...7 %.. 13. %.. 1. %.. 11.2 6%. 13. 6.7 6%...2 % 1.5 9.2 - %. 11.7-1% 11. - - 1%.1 - - 1 7 1 1 7 1 上記推定寿命は 弊社計算方法により算出した値であり 封口コ ムの劣化等の影響を含めておりません The lifetime is calculated based on our method and doesn't include the seal rubber degradation effect etc. TDK-Lambda R-

MODEL : /A カバー付きタイプ ( オプション ) With cover type (Option model) 空冷条件 : 自然空冷 Cooling condition : Convection cooling 取付方向 D Mounting D Conditions Ta 3 : : 5 : 5V Vin = VAC Load 3 5 Load 3 5 %...7 %.. 1. %. 1.6 9.3 %.. 1. 6%. 1.7 5.3 6%. 13. 6.9 % 11.9 6. - % 15. 7.9-1%.7 - - 1% 7.2 - - 1 7 1 1 7 1 2V Vin = VAC Load 3 5 Load 3 5 %.. 11.9 %.. 13. %. 17.2.6 %.. 1. 6%. 1.9 5. 6%. 1.1 7. % 1. 7. - % 19.2 9.6-1%.1 - - 1%. - - 1 7 1 1 7 1 上記推定寿命は 弊社計算方法により算出した値であり 封口コ ムの劣化等の影響を含めておりません The lifetime is calculated based on our method and doesn't include the seal rubber degradation effect etc. TDK-Lambda R-17

5. アブノーマル試験 Abnormal Test MODEL : -5 (1) 試験条件 Test Conditions Input : 265VAC Output : 5V, 3A Ta : 25 (2) 試験結果 Test Results Test position No. 部品 No. 試験端子 Location No. Test point Test mode ショート Short オープン Open a b c d e f g h I j k l ヒュ変発発破異赤破ーO O 出そ化 V C 力の火煙裂臭熱損なズ P P 断他し断 Fire Smoke Burst Smell Red hot Damaged Fuse blown Test result No output No change Others ( Da : Damaged ) 1 Q1 D-S Da:D11 2 D-G Da:Q1,D11 3 G-S 力率低下 Power factor low D 力率低下 Power factor low 5 S 力率低下 Power factor low 6 G Da:Q1,D11 7 Q2 D-S D-G 9 G-S 1 D 11 S G 13 Q3 D-S 1 D-G 15 G-S D 17 S 1 G 19 Q51 D-S 間欠発振動作 Hiccup D-G 間欠発振動作 21 G-S 22 D 23 S 2 G 記事 Note Hiccup 入力電力増加 Input power increase 入力電力増加 Input power increase TDK-Lambda R-1

Test position No. 部品 No. 試験端子 Test mode ショート オープン Test result a b c d e f g h I j k l ヒュ変発発破異赤破ーO O 出そ化 V C 力の火煙裂臭熱損なズ P P 断他し断 ( Da : Damaged ) 記事 Location No. Test point Short Open Fire Smoke 25 Q52 D-S 26 D-G Burst 27 G-S 2 D 29 S 3 G 31 C6 32 33 C51 Smell Red hot Damaged Fuse blown No output No change Others Note Da:F1 入力電力増加 Input power increase 入力電力増加 Input power increase 入力電力増加 Input power increase 入力電力増加 Input power increase 力率低下 Power factor low 3 出力リップル大 Output ripple increase 35 D1 AC-AC 36 DC-DC 37 AC-DC 3 AC 39 DC D2 A-K Da:Q1 1 A/K Da:Q1 2 D17 A-K 3 A/K D19 A-K 5 A/K 6 T1 1-2 7 6-7 1/2 9 6/7 5 T2 1-2 51-6 52 9,1-11, 53 7-5 1/2 55 /6 56 9,1/11, 57 7/ 入力電力増加 Input power increase 入力電力増加 Input power increase 間欠発振動作 Hiccup 間欠発振動作 Hiccup 入力電力増加 Input power increase TDK-Lambda R-19

6. 振動試験 Vibration Test MODEL : -5 (1) 振動試験種類 Vibration Test Class 掃引振動数耐久試験 Frequency variable endurance test (2) 使用振動試験装置 Equipment Used IMV ( 株 ) 製 制御部 : RC-11 加振部 : VS-131- IMV CORP Controller Vibrator (3) 試験条件 Test Conditions 周波数範囲 : 1~55Hz 振動方向 : X, Y, Z Sweep frequency Direction 掃引時間 : 1. 分間 試験時間 : 各方向共 1 時間 Sweep time 1.min Sweep count 1 hour each 加速度 : 一定 19.6m/s 2 (2G) Acceleration Constant () 試験方法 Test Method 入出力端子 Input and output terminal Y X 供試品 D.U.T. Device Under Test 取付台 Fitting stage Z 振動方向 Direction 振動試験機 Vibrator (5) 判定条件 Acceptable Conditions 1. 破壊しない事 Not to be broken. 2. 試験後の出力に異常がない事 No abnormal output after test. (6) 試験結果 Test Results 合格 OK TDK-Lambda R-

7. ノイズシミュレート試験 Noise Simulate Test MODEL : -5 (1) 試験回路及び測定器 Test Circuit and Equipment シミュレータ :INS-3(A) ( ノイズ研究所 ) Simulator (Noise Laboratory Co.,LTD) (2) 試験条件 Test Conditions 入力電圧 : 1, 23VAC ノイズ電圧 : ~2kV Input voltage Noise level 出力電圧 : 定格 位相 : ~36 deg Output Voltage Rated Phase 出力電流 :, 1% 極性 : +,- Output current Polarity 周囲温度 : 25 印加モード : コモン ノーマル Ambient temperature Mode Common, Normal パルス幅 : 5~1ns トリガ選択 : Line Pulse width Trigger select (3) 判定条件 Acceptable Conditions 1. 試験中 5% を超える出力電圧の変動のない事 The regulation of output voltage must not exceed 5% of initial value during test. 2. 試験後の出力電圧は初期値から変動していない事 The output voltage must be within the regulation of specification after the test. 3. 発煙 発火のない事 Smoke and fire are not allowed. () 試験結果 Test Results 合格 OK TDK-Lambda R-21

. 熱衝撃試験 Thermal Shock Test MODEL : -5 (1) 使用計測器 Equipment Used TSV-ht : ESPEC (2) 試験条件 Test Conditions 1cycle 電源周囲温度 :- 5 Ambient Temperature 試験時間 : 図参照 Test Time Refer to Dwg. 試験サイクル :1 サイクル Test Cycle 1 Cycles 非動作 Not Operating +5-3min 3min (3) 試験方法 Test Method 初期測定の後 供試品を試験槽に入れ 上記サイクルで試験を行う 1 サイクル後に 供試品を常温常湿下に 1 時間放置し 出力に異常がない事を確認する Before testing, check if there is no abnormal output, then put the D.U.T. in testing chamber, and test it according to the above cycle. 1 cycles later, leave it for 1 hour at the room temperature, then check if there is no abnormal output. () 判定条件 Acceptable Conditions 試験後の出力に異常がない事 No abnormal output after test. (5) 試験結果 Test Results 合格 OK TDK-Lambda R-22