5sdd 49h3000 ts - dv/150/04 jul-10 1 of 5 5sdd 49h3000 old part no. dv 889-4860-30 rectifier diode properties key parameters industry standard housing v rrm = 3 000 v suitable for parallel operation i favm = 4 865 a high operating temperature i fsm = 64 000 a low forward voltage drop v to = 0.947 v r t = 0.064 m w types v rrm 5sdd 49h3000 3 000 v 5sdd 49h2800 2 800 v conditions: t j = -40 160 c, half sine waveform, f = 50 hz mechanical data f m mounting force 50 5 kn m weight 0.9 kg d s surface creepage distance 40 mm d a air strike distance 20 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
5sdd 49h3000 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/150/04 jul-10 2 of 5 maximum ratings maximum limits unit v rrm repetitive peak reverse voltage t j = -40 160 c 5sdd 49h3000 5sdd 49h2800 3 000 2 800 v i favm average forward current t c = 85 c 4 865 a i frms rms forward current t c = 85 c 7 642 a i rrm repetitive reverse current v r = v rrm 100 ma t p = 8.3 ms 68 300 a i fsm non repetitive peak surge current v r = 0 v, half sine pulse t p = 10 ms 64 000 a t p = 8.3 ms 19 398 000 a 2 s i 2 t limiting load integral v r = 0 v, half sine pulse t p = 10 ms 20 480 000 a 2 s t jmin -t jmax operating temperature range -40 160 c t stg storage temperature range -40 160 c unless otherwise specified t j = 160 c value characteristics min typ max unit v t0 threshold voltage 0.947 v r t forward slope resistance i f1 = 7 634 a, i f2 = 22 902 a 0.064 m w v fm maximum forward voltage i fm = 4 000 a 1.150 v q rr recovered charge v r = 100 v, i fm = 2000 a, di f /dt = -30 a/s 3 500 c unless otherwise specified t j = 160 c
5sdd 49h3000 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/150/04 jul-10 3 of 5 thermal parameters value unit double side cooling 8.0 k/kw anode side cooling 14.5 r thjc thermal resistance junction to case cathode side cooling 18.0 double side cooling 2.5 k/kw r thch thermal resistance case to heatsink single side cooling 5.0 transient thermal impedance i 1 2 3 4 t i ( s ) 0.4406 0.1045 0.0092 0.0022 r i ( k/kw ) 4.533 2.255 0.868 0.345 0 1 2 3 4 5 6 7 8 9 0,001 0,01 0,1 1 10 square wave pulse duration t d ( s ) t r a n s i e n t t h e r m a l i m p e d a n c e j u n c t i o n t o c a s e z t h j c ( k / k w ) analytical function for transient thermal impedance ? = t - - = 4 1 )) / exp( 1 ( i i i thjc t r z conditions: f m = 50 5 kn, double side cooled correction for periodic waveforms 180 sine: 1.0 k/kw 120 sine: 1.5 k/kw 60 sine: 2.5 k/kw 180 rectangular: 0.9 k/kw 120 rectangular: 1.5 k/kw 60 rectangular: 2.5 k/kw fig. 2 dependence transient thermal impedance junction to case on square pulse
5sdd 49h3000 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/150/04 jul-10 4 of 5 0 5000 10000 15000 20000 25000 30000 0 1 2 3 v f ( v ) i f ( a ) 160c t j = 25c fig. 3 maximum forward voltage drop characteristics 20 40 60 80 100 120 140 1 10 100 t ( ms ) i f s m ( k a ) 0 5 10 15 20 25 30 i 2 d t ( 1 0 6 a 2 s ) i fsm i 2 dt 0 10 20 30 40 50 60 70 1 10 100 number n of cycles at 50 hz i f s m ( k a ) v r = 0 v v r 0.5 v rrm fig. 4 surge forward current vs. pulse length, half sine wave, single pulse, v r = 0 v, t j = t jmax fig. 5 surge forward current vs. number of pulses, half sine wave, t j = t jmax
5sdd 49h3000 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/150/04 jul-10 5 of 5 0 1000 2000 3000 4000 5000 6000 7000 8000 9000 10000 0 2000 4000 6000 i fav ( a ) p t ( w ) 120 180 dc y = 60 0 1000 2000 3000 4000 5000 6000 7000 8000 9000 10000 0 2000 4000 6000 i fav ( a ) p t ( w ) y = 30 60 90 120 180 270 dc 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 60 80 100 120 140 160 0 2000 4000 6000 i fav ( a ) t c ( c ) 180 120 dc y = 60 60 80 100 120 140 160 0 2000 4000 6000 i fav ( a ) t c ( c ) 180 dc 270 120 90 60 y = 30 fig. 8 max. case temperature vs. aver. forward current, sine waveform, f = 50 hz, t = 1/f fig. 9 max.case temperature vs. aver. forward current, square waveform, f = 50 hz, t = 1/f notes:
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