Formosa MS Axial Leaded High Effciency Rectifiers HER301G THRU HER308G 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 Revised Date DS-222309 2008/02/10 2010/03/10 Revision C Page. 6 Formosa MS Axial Leaded High Effciency Rectifiers HER301G THRU HER308G 3.0A Axial Leaded High Effciency 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. • Glass passivated chip junction. • Lead-free parts meet RoHS requirments. • Suffix "-H" indicates Halogen free parts, ex. HER301G-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 3.0 A I FSM 150 A V RMS*2 (V) *3 VR (V) HER301G 50 35 50 HER302G 100 70 100 HER303G 200 140 200 HER304 G 300 210 300 HER305G 400 280 400 HER306G 600 420 600 HER307G 800 560 800 HER308G 1000 700 1000 *4 VF (V) 5.0 Operating temperature T J, ( OC) *5 t rr (ns) μA 100 CJ T STG *1 V RRM (V) SYMBOLS UNIT TYP. MIN. IR V R = V RRM T J = 125 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 +150 1.30 *4 Maximum forward voltage@I F=3.0A *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 Revised Date DS-222309 2008/02/10 2010/03/10 Revision C Page. 6 3.0 Peak Forward Surge Current , I FSM (A) Average Forward Current, I F(AV) (A) Rating and characteristic curves (HER301G THRU HER308G) Fig.1 - Forward Current Derating Curve 2.5 2.0 1.5 1.0 0.5 single phase half wave 60Hz resistive or inductive load 0 25 50 75 100 125 150 Fig. 3 - Typical Instantaneour Forward Characteristics 20 10 TJ = 25 OC HER306G~HER308G 1.0 HER304G~HER305G .1 HER301G~HER303G Pulse Width=300us 1% Duty Cycle .01 0 .5 1.0 1.5 2.0 2.5 3.0 8.3ms single half sine-wave (JEDEC Method) 150 100 50 0 1 3.5 Instantaneous Forward Voltage, V F (Volts) 2 5 10 20 50 100 Number of Cycles at 60 Hz Instantaneous Reverse Current, (μA) Instantaneous Forward Current, I F (A) Ambient Temperature, T A (°C) 200 Fig. 2 - Maximum Non-Repetitive Peak Forward Surge Current Fig. 4 - Typical Reverse Characteristics 1000 TJ = 125 100 C TJ = 75 OC 10 TJ = 25 OC 1.0 0.1 O 0 20 40 60 80 100 120 140 Percent of Rated Peak Reverse Voltage ( %) Fig. 6 - Test Circuit Diagram and Reverse Recovery Time Characteristic 50W NONINDUCTIVE Fig. 5 - Typical Junction Capacitance Junction Capacitance, C J (pF) 175 10W NONINDUCTIVE trr | | | | | | | | +0.5A 150 () 125 (+) 100 25Vdc (approx.) D.U.T. PULSE GENERATOR (NOTE 2) () 75 1W NONINDUCTIVE 50 0 -0.25A (+) OSCILLISCOPE (NOTE 1) -1.0A 25 1cm NOTES: 1. Rise Time= 7ns max., Input Impedance= 1 megohm.22pF. 0 .01 .05 .1 .5 1 5 10 50 100 SET TIME BASE FOR 50 / 10ns / cm 2. Rise Time= 10ns max., Source Impedance= 50 ohms. Reverse Voltage, V R (Volts) http://www.formosams.com/ TEL:886-2-22696661 FAX:886-2-22696141 Page 3 Document ID Issued Date Revised Date DS-222309 2008/02/10 2010/03/10 Revision C Page. 6 Formosa MS Axial Leaded High Effciency Rectifiers HER301G THRU HER308G Pinning information Pin Pin1 Pin2 Simplified outline cathode anode Symbol 1 2 1 2 Marking Type number HER301G HER302G HER303G HER304G HER305G HER306G HER307G HER308G Marking code HER301G HER302G HER303G HER304G HER305G HER306G HER307G HER308G 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 17.0 Document ID Issued Date Revised Date DS-222309 2008/02/10 2010/03/10 Revision C Page. 6 Formosa MS Axial Leaded High Effciency Rectifiers HER301G THRU HER308G 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 Revised Date DS-222309 2008/02/10 2010/03/10 Revision C Page. 6 Formosa MS Axial Leaded High Effciency Rectifiers HER301G THRU HER308G 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=150 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 Revised Date DS-222309 2008/02/10 2010/03/10 Revision C Page. 6