Formosa MS Axial Leaded High Effciency Rectifiers HER501 THRU HER508 List List................................................................................................. 1 Package outline............................................................................... 2 Features.......................................................................................... 2 Mechanical data............................................................................... 2 Maximum ratings .............................................................................. 2 Rating and characteristic curves........................................................ 3 Pinning information........................................................................... 4 Marking........................................................................................... 4 Taping & bulk specifications for AXIAL devices.................................... 4 Suggested thermal profiles for soldering processes............................. 5 High reliability test capabilities........................................................... 6 http://www.formosams.com/ TEL:886-2-22696661 FAX:886-2-22696141 Page 1 Document ID Issued Date DS-222318 2009/02/10 Revised Date 2010/03/10 Revision C Page. 6 Formosa MS Axial Leaded High Effciency Rectifiers HER501 THRU HER508 5.0A Axial Leaded High Efficiency Rectifiers-50-1000V Package outline Features DO-201AD • Axial lead type devices for through hole design. • High current capability. • Ultrafast recovery time for high efficiency. • High surge capability. • Silicon rubber coating chip junction. • Lead-free parts meet RoHS requirments. • Suffix "-H" indicates Halogen free parts, ex. HER501-H. 1.0(25.4) MIN. .220(5.6) .197(5.0) DIA. .375(9.5) .285(7.2) Mechanical data • Epoxy : UL94-V0 rated flame retardant • Case : Molded plastic, DO-201AD • Lead : Axial leads, solderable per MIL-STD-202, 1.0(25.4) MIN. .052(1.3) .048(1.2) DIA. Method 208 guranteed • Polarity: Color band denotes cathode end • Mounting Position : Any • Weight : Approximated 1.10 gram Dimensions in inches and (millimeters) Maximum ratings and Electrical Characteristics (AT PARAMETER T A=25 oC unless otherwise noted) CONDITIONS O Forward rectified current Ambient temperature = 50 C Forward surge current 8.3ms single half sine-wave (JEDEC methode) V R = V RRM T J = 25 OC Reverse current f=1MHz and applied 4V DC reverse voltage Storage temperature IO 5.0 A I FSM 200 A V RMS*2 (V) *3 VR (V) HER501 50 35 50 HER502 100 70 100 HER503 200 140 200 HER504 300 210 300 HER505 400 280 400 HER506 600 420 600 HER507 800 560 800 HER508 1000 700 1000 *4 VF (V) TYP. 5.0 Operating temperature T J, ( OC) *5 t rr (ns) µA 100 CJ T STG *1 V RRM (V) SYMBOLS UNIT MIN. IR V R = V RRM T J = 100 OC Diode junction capacitance MAX. Symbol pF 75 +175 -65 O C *1 Repetitive peak reverse voltage *2 RMS voltage 1.00 50 *3 Continuous reverse voltage -55 to +125 1.30 *4 Maximum forward voltage@I F=5.0A *5 Maximum Reverse recovery time, note 1 1.85 75 Note 1. Reverse recovery time test condition, I F =0.5A, I R =1.0A, I RR =0.25A http://www.formosams.com/ TEL:886-2-22696661 FAX:886-2-22696141 Page 2 Document ID Issued Date DS-222318 2009/02/10 Revised Date 2010/03/10 Revision C Page. 6 6.0 Peak Forward Surge Current , I FSM (A) Average Forward Current, I F(AV) (A) Rating and characteristic curves (HER501 THRU HER508) Fig.1 - Forward Current Derating Curve 5.0 4.0 3.0 2.0 1.0 single phase half wave 60Hz resistive or inductive load 0 25 50 75 100 125 150 Ambient Temperature, T A ( OC) 200 8.3ms single half sine-wave (JEDEC Method) 150 100 50 0 1 Instantaneous Reverse Current, (μA) 05 3 H6E 0R0 5/80 060~ /H10E 0R05 V08 HE R5 R50 04~ ~HE 501 R5 HE HER Instantaneous Forward Current, I F (A) TJ = 25 .1 Pulse Width = 300us 1% Duty Cycle .01 0 .2 .4 .6 .8 1.0 5 10 20 50 100 Fig. 4 - Typical Reverse Characteristics 100 1.0 2 Number of Cycles at 60 Hz Fig. 3 - Typical Instantaneour Forward Characteristics 10 Fig. 2 - Maximum Non-Repetitive Peak Forward Surge Current 1000 100 TJ = 100 10 TJ = 25 1.0 0.1 .01 1.2 1.4 1.6 1.8 0 20 40 60 80 100 120 140 Percent of Rated Peak Reverse Voltage ( %) Instantaneous Forward Voltage, V F (Volts) Fig. 6 - Test Circuit Diagram and Reverse Recovery Time Characteristic Fig. 5 - Typical Junction Capacitance Junction Capacitance, C J (pF) 175 50W NONINDUCTIVE 150 10W NONINDUCTIVE trr 125 | | | | | | | | +0.5A 100 ( ) (+) 25Vdc (approx.) 75 D.U.T. PULSE GENERATOR (NOTE 2) ( ) 50 1W NONINDUCTIVE 25 (+) 0 -0.25A OSCILLISCOPE (NOTE 1) -1.0A 0 .01 .05 .1 .5 1 5 Reverse Voltage, V R (Volts) http://www.formosams.com/ TEL:886-2-22696661 FAX:886-2-22696141 10 50 100 NOTES: 1. Rise Time= 7ns max., Input Impedance= 1 megohm.22pF. 1cm SET TIME BASE FOR 2. Rise Time= 10ns max., Source Impedance= 50 ohms. 50 / 10ns / cm Page 3 Document ID Issued Date DS-222318 2009/02/10 Revised Date 2010/03/10 Revision C Page. 6 Formosa MS Axial Leaded High Effciency Rectifiers HER501 THRU HER508 Pinning information Pin Pin1 Pin2 Simplified outline cathode anode Symbol 1 2 1 2 Marking Type number HER501 HER502 HER503 HER504 HER505 HER506 HER507 HER508 Marking code HER501 HER502 HER503 HER504 HER505 HER506 HER507 HER508 Taping & bulk specifications for AXIAL devices 52.4mm 17mm DIA. 55mm Max. A 17mm DIA. 72mm DIA. 71mm Max. 355mm OFF Center both sids 1.0mm Max OFF Alignment 1.2mm 6.3mm REEL PACKING DEVICE Q'TY 1 COMPONENT CARTON Q'TY 2 APPROX. CASE (PCS / REEL) SPACING SIZE (PCS / CARTON) CROSS "A" in FIG. A (m/m) 10 mm 380 * 340 * 370 TYPE DO-201AD 1,200 WEIGHT(kg) 4,800 9.1 AMMO PACKING DEVICE Q'TY 1 INNER CARTON Q'TY 2 APPROX. CASE (PCS / BOX) BOX SIZE SIZE (PCS / CARTON) CROSS (m/m) (m/m) TYPE DO-201AD 1,200 http://www.formosams.com/ TEL:886-2-22696661 FAX:886-2-22696141 260 * 83 * 160 440 * 270 * 340 Page 4 WEIGHT(kg) 12,000 Document ID Issued Date DS-222318 2009/02/10 17.0 Revised Date 2010/03/10 Revision C Page. 6 Formosa MS Axial Leaded High Effciency Rectifiers HER501 THRU HER508 BULK PACKING DEVICE Q'TY 1 INNER CARTON Q'TY 2 APPROX. CASE (PCS / BOX) BOX SIZE SIZE (PCS / CARTON) CROSS TYPE (m/m) DO-201AD 500 WEIGHT(kg) (m/m) 305 * 73 * 40 347 * 320 * 271 12,000 16.4 Suggested thermal profiles for soldering processes 1.Lead free temperature profile wave-soldering 280 Peak soldering temperature not to exceed 260ºC 260 240 220 Temperature(°C) 200 180 160 140 120 Peak Max well time 5 Max 100 80 Cool Down Max gradient-4ºC/s Suggested gradient - 2ºC/s or less 60 40 20 Preheat Max gradient 2ºC/s 0 0 20 40 60 80 100 120 140 160 180 200 220 240 Time(Sec) http://www.formosams.com/ TEL:886-2-22696661 FAX:886-2-22696141 Page 5 Document ID Issued Date DS-222318 2009/02/10 Revised Date 2010/03/10 Revision C Page. 6 Formosa MS Axial Leaded High Effciency Rectifiers HER501 THRU HER508 High reliability test capabilities Item Test Conditions Reference o 1. Solder Resistance at 260±5 C for 10±2sec. immerse body into solder 1/16"±1/32" MIL-STD-750D METHOD-2031 2. Solderability at 245±5 oC for 5 sec. MIL-STD-202F METHOD-208 3. Pull Test 2.0kg in axial lead direction for 10 sec. I F=I O 4. Bend Lead 5. High Temperature Reverse Bias 6. Forward Operation Life 7. Intermittent Operation Life 8. Pressure Cooker MIL-STD-202F METHOD-211A 2.0kg weight applied to each lead bending arc 90 o±5 o for 3 times MIL-STD-202F METHOD-211A V R=80% rate at T J=125 oC for 168 hrs. MIL-STD-750D METHOD-1038 Rated average rectifier current at T A=25 oC for 500hrs. MIL-STD-750D METHOD-1027 T A = 25 OC, I F = I O On state: power on for 5 min. off state: power off for 5 min, on and off for 500 cycles. MIL-STD-750D METHOD-1036 JESD22-A102 15P SIG at T A=121 oC for 4 hrs. MIL-STD-750D METHOD-1051 9. Temperature Cycling -55 oC to +125 oC dwelled for 30 min. and transferred for 5min. total 10 cycles. 10. Forward Surge 8.3ms single half sine-wave one surge. MIL-STD-750D METHOD-4066-2 11. Humidity at T A=85 oC, RH=85% for 1000hrs. MIL-STD-750D METHOD-1021 12. High Temperature Storage Life at 175 oC for 1000 hrs. MIL-STD-750D METHOD-1031 http://www.formosams.com/ TEL:886-2-22696661 FAX:886-2-22696141 Page 6 Document ID Issued Date DS-222318 2009/02/10 Revised Date 2010/03/10 Revision C Page. 6