5SDD 14F6000 5SDD 14F6000 Old part no. DV 808-1360-60 High Voltage Diode Properties Key Parameters V RRM = 6 000 I FAVm = 1 363 I FSM = 17 500 V TO = 1.015 rT = 0.407 Low forward voltage drop Low recovery charge High operating temperature Low leakage current Applications V A A V m Rectifier bridges Types VRRM 5SDD 14F6000 6 000 V Conditions: Tj = -40 / 150 C, half sine waveform, f = 50 Hz Mechanical Data Fm Mounting force 22 2 kN m Weight 0.46 kg DS Surface creepage distance 30 mm Da Air strike distance 20.5 mm Fig. 1 Case ABB s.r.o. Novodvorska 1768/138a, 142 21 Praha 4, Czech Republic tel.: +420 261 306 250, http://www.abb.com/semiconductors TS - DV/051/01a Aug-11 1 of 5 5SDD 14F6000 Maximum Ratings VRRM Maximum Limits Unit 6 000 V 1 363 A 2 142 A 75 mA Repetitive peak reverse voltage Tj = -40 / 150 C IFAVm Average forward current Tc = 85 C IFRMS RMS forward current IRRM Repetitive reverse current, VR = VRRM IFSM 2 It Non repetitive peak surge current tp = 8.3 ms 20 300 A VR = 0 V, half sine pulse, Tj = 25 C tp = 10 ms 19 000 A Non repetitive peak surge current tp = 8.3 ms 18 700 A VR = 0 V, half sine pulse tp = 10 ms 17 500 A Limiting load integral tp = 8.3 ms 1 710 000 A2s VR = 0 V, half sine pulse, Tj = 25 C tp = 10 ms 1 805 000 A2s Limiting load integral tp = 8.3 ms 1 450 000 A2s VR = 0 V, half sine pulse tp = 10 ms 1 531 250 A2s Tjmin -Tjmax Operating temperature range -40 / 150 C TSTG Storage temperature range -40 / 150 C Value Unit Unless otherwise specified Tj = 150 C Characteristics min VT0 typ Threshold voltage max 1.015 V IF1 = 2 142 A, IF2 = 6 425 A rT Forward slope resistance 0.407 m VFM Maximum forward voltage 2.68 V IFM = 4 000 A Qrr Recovered charge 3 000 4 000 C VR = 100 V, IFM = 1 000 A, diF/dt = -10 A/ s Unless otherwise specified Tj = 150 C ABB s.r.o., Novodvorska 1768/138a, 142 21 Praha 4, Czech Republic ABB s.r.o. reserves the right to change the data contained herein at any time without notice TS - DV/051/01a Aug-11 2 of 5 5SDD 14F6000 Thermal Parameters Rthjc Rthch Thermal resistance junction to case Thermal resistance case to heatsink Value Unit double side cooling 20 K/kW anode side cooling 34 cathode side cooling 48 double side cooling 5 single side cooling 10 K/kW Transient Thermal Impedance Analytical function for transient thermal impedance i 1 2 3 4 Ri( K/kW ) 11.83 4.26 1.63 2.28 0.432 0.071 0.01 0.0054 i( s) 4 R i (1 exp( t / i 1 Conditions: Fm = 22 2 kN, Double side cooled i )) 22 Transient thermal impedance junction to case Zthjc ( K/kW ) Z thjc 20 18 16 14 12 10 8 6 4 2 0 0,001 0,01 0,1 1 Square wave pulse duration t d ( s ) Fig. 2 Dependence transient thermal impedance junction to case on square pulse ABB s.r.o., Novodvorska 1768/138a, 142 21 Praha 4, Czech Republic ABB s.r.o. reserves the right to change the data contained herein at any time without notice TS - DV/051/01a Aug-11 3 of 5 10 5SDD 14F6000 IF ( A ) 7000 25 C 150 C 6000 5000 4000 3000 2000 1000 0 0 1 2 3 VF (V) 4 i2dt 2,2 I FSM 34 2 20 IFSM ( kA ) 38 i 2dt (106 A2s) IFSM ( kA ) Fig. 3 Maximum forward voltage drop characteristics 15 30 1,8 26 1,6 VR = 0 V 10 22 1,4 18 1,2 14 5 VR 0.5 V RRM 1 10 1 10 t ( ms ) 0,8 100 Fig. 4 Surge forward current vs. pulse length, half sine wave, single pulse, VR = 0 V, Tj = Tjmax 0 1 10 100 Number n of cycles at 50 Hz Fig. 5 Surge forward current vs. number of pulses, half sine wave, Tj = Tjmax ABB s.r.o., Novodvorska 1768/138a, 142 21 Praha 4, Czech Republic ABB s.r.o. reserves the right to change the data contained herein at any time without notice TS - DV/051/01a Aug-11 4 of 5 3500 PT ( W ) PT ( W ) 5SDD 14F6000 = 60 120 180 3000 3500 = 30 60 90 120 180 3000 270 DC DC 2500 2500 2000 2000 1500 1500 1000 1000 500 500 0 0 0 200 400 600 800 1000 1200 1400 1600 0 200 400 600 800 1000 1200 1400 1600 I FAV ( A ) I FAV ( A ) Fig. 6 Forward power loss vs. average forward current, sine waveform, f = 50 Hz, T = 1/f Fig. 7 Forward power loss vs. average forward current, square waveform, f = 50 Hz, T = 1/f 160 TC ( C ) TC ( C ) 160 150 150 140 140 130 130 120 120 110 110 100 DC 90 90 270 80 80 70 70 100 DC = 60 120 180 60 0 200 400 600 800 1000 1200 1400 1600 = 30 60 60 0 200 400 600 180 800 1000 1200 1400 1600 I FAV ( A ) I FAV ( A ) Fig. 8 Max. case temperature vs. aver. forward current, sine waveform, f = 50 Hz, T = 1/f 90 120 Fig. 9 Max.case temperature vs. aver. forward current, square waveform, f = 50 Hz, T = 1/f Notes: ABB s.r.o., Novodvorska 1768/138a, 142 21 Praha 4, Czech Republic ABB s.r.o. reserves the right to change the data contained herein at any time without notice TS - DV/051/01a Aug-11 5 of 5