5STF 28H26 5STF 28H26 Fas Thyrisor Properies Key Parameers Amplifying gae VDRM, VRRM = 2 V High operaional capabiliy ITAV = 2 667 A Opimized urn-off parameers ITSM = 46.5 ka VTO = 1.198 V Applicaions rt =.13 m Power swiching applicaions q = 6 µs Types V RRM, V DRM 5STF 28H26 2 V Condiions: T j = -4 125 C, half sine waveform, f = 5 Hz, noe 1 Mechanical Daa F m Mouning force 5 ± 5 kn m Weigh.93 kg D S D a Surface creepage disance Air srike disance 36 mm 15 mm Fig. 1 Case ABB s.r.o. Novodvorska 1768/138a, 142 21 Praha 4, Czech Republic el.: +42 261 36 25, hp://www.abb.com/semiconducors TS - TR/311/12e May-16 1 of 1
5STF 28H26 Maximum Raings Maximum Limis Uni V RRM V DRM Repeiive peak reverse and off-sae volage 2 V T j = -4 125 C, noe 1 I TRMS I TAVm I TSM I 2 (di T/d) cr (dv D/d) cr RMS on-sae curren T c = 7 C, half sine waveform, f = 5 Hz Average on-sae curren T c = 7 C, half sine waveform, f = 5 Hz Peak non-repeiive surge half sine pulse, V R = V Limiing load inegral half sine pulse, V R = V Criical rae of rise of on-sae curren I T = I TAVm, half sine waveform, f = 5 Hz, V D = 2/3 V DRM, r =.3 µs, I GT = 2 A Criical rae of rise of off-sae volage V D = 2/3 V DRM p = 1 ms p = 8.3 ms p = 1 ms p = 8.3 ms 4 189 A 2 667 A 46 5 49 7 1 81 1 25 A A 2 s 8 A/µs 1 V/µs P GAVm Maximum average gae power losses 3 W I FGM Peak gae curren 1 A V FGM Peak gae volage 12 V V RGM Reverse peak gae volage 1 V T jmin - T jmax Operaing emperaure range -4 125 C T sgmin - T sgmax Sorage emperaure range -4 125 C Unless oherwise specified T j = 125 C Noe 1: De-raing facor of.13% V RRM or V DRM per C is applicable for T j below 25 C TS - TR/311/12e May-16 2 of 1
5STF 28H26 Characerisics Value Uni min. yp. max. V TM Maximum peak on-sae volage I TM = 2 A I TM = 4 A 1.35 1.61 V V T Threshold volage 1.198 V r T I DM I RM gd q1 q2 Q rr I rrm Slope resisance I T1 = 4 188 A, I T2 = 12 563 A Peak off-sae curren V D = V DRM Peak reverse curren V R = V RRM Delay ime T j = 25 C, V D =.4 V DRM, I TM = I TAVm, r =.3 µs, I GT = 2 A Turn-off ime I T = 1 A, di T/d = -5 A/µs, V R = 1 V, V D = 2/3 V DRM, dv D/d = 5 V/µs Turn-off ime I T = 1 A, di T/d = -25 A/µs, V R = 1 V, V D = 2/3 V DRM, dv D/d = 4 V/µs Recovery charge he same condiions as a q1 Reverse recovery curren he same condiions as a q1.13 m 15 ma 15 ma 2. µs 6. µs 8. µs 24 µc 315 A I H Holding curren T j = 25 C T j = 125 C I L Laching curren T j = 25 C T j = 125 C 25 15 5 3 ma ma V GT Gae rigger volage V D = 12V, I T = 4 A T j = - 4 C T j = 25 C T j = 125 C.25 4 3 2 V I GT Gae rigger curren V D = 12V, I T = 4 A T j = - 4 C T j = 25 C T j = 125 C 1 1 5 3 ma Unless oherwise specified T j = 125 C TS - TR/311/12e May-16 3 of 1
Transien hermal impedance juncion o case Z hjc ( K/kW ) 5STF 28H26 Thermal Parameers Value Uni R hjc R hch Thermal resisance juncion o case double side cooling anode side cooling 16. cahode side cooling 26.5 Thermal resisance case o heasink double side cooling single side cooling 6. 1. K/kW 3. K/kW Transien Thermal Impedance Analyical funcion for ransien hermal impedance Z hjc 5 i 1 R (1 exp( / )) Condiions: F m = 5 ± 5 kn, Double side cooled i Correcion for periodic waveforms 18 sine: add 1. K/kW 18 recangular: add 1. K/kW 12 recangular: add 1.5 K/kW 6 recangular: add 3. K/kW i i 1 2 3 4 5 i ( s ).4871.1468.677.79.21 Ri( K/kW ) 6.73 1.44.65.84.32 12 1 8 6 4 2.1.1.1 1 1 Square wave pulse duraion d ( s ) Fig. 2 Dependence ransien hermal impedance juncion o case on square pulse TS - TR/311/12e May-16 4 of 1
I T ( A ) 5STF 28H26 On-Sae Characerisics 14 12 T j = 125 C Analyical funcion for on-sae characerisics: V T A B I T C I T D ln( I 1) T 1 8 6 4 Tj ( C ) 125 A.57536 B.8 C.194 D.6964 2 1 2 3 V T ( V ) Fig. 3 Maximum on-sae characerisics Gae Trigger Characerisics VG ( V ) 6 5 VG ( V ) 14 12 V GTmax 4-4 C 1 5 µs 3 +25 C 8 1 ms 6 I GTmax 2 +125 C 4 1 ms VGTmin 1.2.4.6.8 1 I G ( A ) I GTmin 2 2 4 6 8 1 12 I G ( A ) Fig. 4 Gae rigger characerisics Fig. 5 Maximum peak gae power loss TS - TR/311/12e May-16 5 of 1
I TSM ( ka ) i 2 d (1 6 A 2 s) I TSM ( ka ) 5STF 28H26 Surge Characerisics 85 15.5 5 45 75 13.5 4 65 I TSM 11.5 35 3 55 9.5 25 V R = V 45 i 2 d 7.5 2 35 5.5 15 1 V R.5 V DRM 25 3.5 5 15 1.5 1 1 1 ( ms ) 1 1 1 Number n of cycles a 5 Hz Fig. 6 Surge on-sae curren vs. pulse lengh, half sine wave, single pulse, Fig. 7 Surge on-sae curren vs. number of pulses, half sine wave, T j = T jmax V R = V, T j = T jmax TS - TR/311/12e May-16 6 of 1
T C ( C ) T C ( C ) P T ( W ) P T ( W ) 5STF 28H26 Power Loss and Maximum Case Temperaure Characerisics 6 5 y = 3 6 9 12 18 6 5 y = 3 6 9 12 18 27 4 4 3 3 2 2 1 1 5 1 15 2 25 3 I TAV ( A ) 5 1 15 2 25 3 I TAV ( A ) Fig. 8 On-sae power loss vs. average on-sae curren, sine waveform, f = 5 Hz, T = 1/f 13 Fig. 9 On-sae power loss vs. average on-sae curren, square waveform, f = 5 Hz, T = 1/f 13 12 12 11 11 1 1 9 9 8 8 7 7 27 18 6 y = 3 6 9 12 18 5 1 15 2 25 3 I TAV ( A ) 6 y = 3 6 9 12 5 1 15 2 25 3 I TAV ( A ) Fig. 1 Max. case emperaure vs. aver. on-sae curren, sine waveform, f = 5 Hz, T = 1/f Fig. 11 Max. case emperaure vs. aver. on-sae curren, square waveform, f = 5 Hz, T = 1/f Noe 2: Figures number 8 11 have been calculaed wihou considering any urn-on and urn-off losses. They are valid for f = 5 or 6 Hz operaion. TS - TR/311/12e May-16 7 of 1
q / q1 ( - ) q / q1 ( - ) q / q1 ( - ) 5STF 28H26 Turn-off Time, Parameer Relaionship Maximum values of urn-off ime a applicaion specific condiions are given by using his formula: 1. q q1 q q1 q q ( T j ) ( dv D / d ) ( dit / d ) q1 q1.9.8 where: q1 is urn-off ime a sandard condiions, see secion "Characerisics".7.6 q ( T j ) q1 q ( dv D / d ) q1 q ( dit / d ) q1 1.8 is facor o be aken from fig. 12 is facor o be aken from fig. 13 is facor o be aken from fig. 14.5.4.3 25 5 75 1 125 T j ( C ) Fig. 12 Normalised maximum urn-off ime vs. juncion emperaure 1.4 1.6 1.3 1.4 1.2 1.2 1.1 1. 1..9.8 2 4 6 8 1 dv D /d ( V/µs ).8 1 2 3 4 5 6 - di T /d ( A/µs ) Fig. 13 Normalised maximum urn-off ime vs. rae of rise of off-sae volage Fig. 14 Normalised maximum urn-off ime vs. rae of fall of on-sae curren TS - TR/311/12e May-16 8 of 1
5STF 28H26 I rrm ( A ) W off ( J ) Q rr ( µc ) Turn-off Characerisics vt (), it () v T () V D 1 I TM = 2 A 1 A 5 A I TM i T () - di T /d dv D /d 1 q I rrm 1 Q rr V R -6-6 1 1 1 1 - di T /d ( A/µs ) Fig. 17 Typical waveforms and definiion of symbols a urn-off of a hyrisor, inducive swiching wihou RC snubber 1 Fig. 18 Max. recovered charge vs. rae of fall on-sae curren, rapezoid pulse, V R = 1 V, T j = T jmax 6. V R = 2/3 V DRM 1 I TM = 2 A 1 A 5 A 5. 4. 1 V 3. 1 2. 5 V 1 1 1 1 - di T /d ( A/µs ) 1.. 2 V 1 V 1 2 3 4 5 6 - di T /d ( A/µs ) Fig. 19 Max. reverse recovery curren vs. rae of fall on-sae curren, rapezoid pulse, V R = 1 V, T j = T jmax Fig. 2 Maximum urn-off energy per pulse vs. rae of fall on-sae curren, rapezoid pulse, inducive swiching wihou RC snubber, I TM = 2 A, T j = T jmax TS - TR/311/12e May-16 9 of 1
5STF 28H26 Noes: TS - TR/311/12e May-16 1 of 1