EUPEC A158 S Typenreihe/Type range 600 800 1000 1100 5eE D) 1200 1300* Elektrische Eigenschaften Hochsizulassige Werte Electrical properties Maximum permissible values VoRM 600...1300 V VaRM(C) tp = 1 us 50 Vv ItRMSM 400 A brava te = 85C 158 A te = 49C 254 A Tsu tp = 10 ms, ty = 45C 2,8 kA tp = 10 ms, ty = ty max 2,45 kA /i@dt tp = 10 ms, ty < 45C 39,2 kA?s tp = 10 ms, ty = ty max 30 kA2s (difdt),, nicht per./non rep. 1600 = A/us per/rep., itm = 600 A, Vp = 0,67 Voam. ty = ty max 400 Alus ig = 1,2 A, digit = 1,2 Afus (dv/dt)o; Vp = 67% Vprm, ty = ty max C: 400 Vius F: 1000 = Vius Charakteristische Werte Characteristic values VT ty = ty max Ip = 600 A 26 V Vo) ty = ty max 1,3 Vv tr ty = ty max 2 moQ Vet ty = 25C, vp = 12 V, Ra = 10 2 2,7 V let ty = 25C, vp = 12 V, Ra = 102 300 mA ty = ty max Vo = 12 V, Ra = 100 10 mA ta ty = 25C, vp = 12 V, Ra = 102 300 mA IL ty = 25C, Vp = 12 V, Rex = 10.2 1200 mA ig = 1,2 A, digidt = 1,2 Alus, ty = 20 us ip ty = ty max Vo = Vorm 30 mA in ty = ty max: VA = VRAM 150 mA tga ig = 1,2 A, digidt = 1,2 A/us 1,4 us ty Prifbedingungen siehe 3.4.3.2/ R: 8 us) test conditions see 3.4.3.2 B: 10 us) Cc: 12 ps) D: 15 us) Coun ty = 25C, f = 10 kHz 3,5 nF Thermische Eigenschaften Thermal properties Rie = 180el, sinus < 0,117C/W pc = 0,103C/W Riruc(a) 6 = 180el, sinus < 0,18 C/W pe < 0,166C/W Rincon) = 190el, sinus = 0,28 C/W Dc < 0,266C/W Rinck 0,03 C/W ty max 125C ty op 40C...+125C tetg 40C...+140C Mechanische Eigenschaften G M F Case DIN 41814151 A 4 * Far grBere Stickzahlen bitte Liefertermin erfragen/ Delivery for larger quantities on request 1) mit antiparalleler Diode/with inverse paralleled diode 160 Mechanical properties 3... 70g 4,5 kN 17mm Seite/page 198 340329? OOO0S4e 593 MMUPEC T-2Z5-/9 1 10 2 A158 59 Bild/Fig. 1 1 10 2 A158 $10 Bild/Fig. 2 2 aisesit Bild/Fig. 3 3.9456 8 107 394 56 8 107 2 36456 B80 Steuergenerator: ig =24A, tp = 148, RC-Glied: R [Q] = 0,02 voy [V] Cs 015 uF TMP 23456 610 2 3456 ard tp (us) 2 3456 810 2 3456 8107 tp bs) 2 3456 810 2 3456 80 ty [us] pulse generator: ig= 24 A, th = 148, RC network: R [a] = 0.02 Vom [v Cs 018 uF EUPEC Hz -2kHz 10 2 3 4 5 a (sas 12 6 7 8 8 10% 2 * dip/dt [A duis] Bild/Fig. 4 103 itm[Al 4 5OHZ-2kHz 10! 2 3 4 8S 6 7 89 102 2 A159S43 + diy/dt [A/S] Bild/Fig. 5 107 2 3 4 5 6 7 89 102 2 arsesis di p/dt [Atus]o Bild/Fig. 6 Steuergenerator: pulse generator: ig = 2.4 A, tp = 15, ig = 24A,t,= 148, RC-Glied: R [Q] = 0,02 voy [Vi RC network: R [Q] = 0.02 Voy [V] C < 0,22 uF C < 0.22 uF id TI +dipidt init \ LL Tr _, t 2 1 T= = } 0 SeE D MM 3403297 0000543 4eT MMUPEC T-25-19 4a tall 103 nN Ww fk OD ~ N Wau oo 101 2 3 456 8 102 2 3 456 6103 2 3456 8104 ats 8: ty [us] o Bild/Fig. 7 Ny war itm uw W hI Bh Ud & 101 2 3 456 B10 2 3456 8104 ty [us] 3.456 8107 2 aisesa Bild/Fig. 8 wy 10 8 6 5 4 3 to! 2 394 56 8 107 2 3.456 8 10 2 3.456 a 107 A tse s ty Gus] om Bild/Fig. 9 Steuergenerator: pulse generator: ig = 2.4 A, te = 18, ig =24A, f= 14S, RC-Glied: R [Q] > 0,02 voy [V) RC network: R [Q] = 0.02 voy [V} C < 0,22 uF Cs 0.22 uF uf Vay = SV '1 7 edipfat | ~diqldt ;t bee ty 161 EUPEC A158 S z z = w hb WwW db WO OO wb Aq og, 3.456 B 10% 10! 2 A156 59 Bild/Fig. 13 2 3456 6107 2 Mm 3403297 OO00O544 366 MMUPEC 5eE D tp [us] o- a00 ipfA] 600 400 200 7 a5 10 15 AISOS1S Bild/Fig. 14 (zu BildAto Fig. 13) Steuergenerator: ig = 24 A, tg = 148, RC-Glied: R [a] = 002 Vom [vi Cs 015 uF 20 2s 30 35 40 " vy wos pulse generator: ig = 2.4 A, tp = 148, RC network: R [Q] = 0.02 vow [V] Cs 0.15 uF Vay Ss 15 V 3456 8104 T=25-19 , 10.200 / 0.178} ++ thJic o1 oA 1 1 : 4 3456 810! t (5) w- wr? 2 3456801 2 3456 810 2 Aisa Ss Bild/Fig. 16 Transienter innerer Warmewiderstand Zinc Transient thermal impedance, junction to case, Zanuc beidseitige Kihlungiwo-sided cooling 1 6 810 34 680% 234 6810 2 34 234 6 610 t [5] _+ 107 2 aises & Bild/Fig. 17 Transienter innerer Warmewiderstand Zenuc Transient thermal impedance, junction to case, Zanuc beidseitige Kiihlung/two-sided cooling EUPEC 2 10 2. 34 9 1 2 6 810 2 34 6 810 2.34 6 810 t [5] 1_ 6810 2 34 A158 516 Bild/Fig. 18 Transienter innerer Warmewidersiand Zynic Transient thermal impedance, junction to case, Zanuc anodenseitige Kithlung/anode sided cooling 468072 4 681012 4 681 2 4 6810! 2 3 2 4158517 t [s]_-_ Bild/Fig. 19 Transienter innerer Warmewiderstand Zinc Transient thermal impedance, junction to case, Zinc anodenseitige KGhlung/anode sided cooling 94 R thyc (K) fer Rthac 93 Rth3c(a) 02 F Rthac or Qo 30 60 90 120 150 180 A158 S18 Fel] ~ Bild/Fig. 20 Innerer Warmewiderstand/Thermal resistance, junction to case Rinsc! + Deidseitige Kahlung/double-sided cooling Ainsciay anodenseitige Kihlung/anode-sided cooling Rinsca: Kathodenseitige Kihlung/cathade-sided cooling als Funktion des Stromflu6winkels/versus current conduction angle, f = 50 Hz. 4 63802 SeE D MM 3403297 OOOOS54S5 2eT2 MBUPEC 7-25-19 = nN Wh 1 4 3.456 8104 'g [nA] 10 2 3 456 8 10% 2 3456 610% 2 alse $7 Bild/Fig. 21 zundbereich und Spitzensteuerleistung bei vp = 6 V. Gate characteristic and peak gate power dissipation at vp = 6 V. Parameter: 1 2 3 Steuerimpulsdauer/Pulse duration ty lms[/ 10 7 0,5 Hchstzulassige Spitzensteuerleistung/ Maximum allowable peak gate power (Ww) 20 40 60 102, 3.456 9104 tg [2 A)_ 3.456 8 107 2 3456 8107 2 10! 2 Atsa Se Bild/Fig. 22 Zuindverzug tog Gate controlled delay time tgq i 1 2 3 4 5 6 7 Zme Rin [C/W] | 0,007545 | 0,018999} 0,046128 | 0,030328 aIs} 0,000788 | 0,008775 | 0,032627 | 0,241467 Zac Rim [C/W] | 0,07705 | 0,022843] 0,044024 | 0,040095 | 0,051333 a[s] 0,000805 | 0,009796 | 0,036779 | 0,373654 | 5,973800 Zrucaa Fin [C/W] | 0,007899 | 0,019758 | 0,038934 | 0,023269| 0,028398 | 0.079099 | 0,074643 a [s] 0,000827 | 0,008751 | 0,022657 | 0,118979| 0,577846 | 2,171151 | 9.760818 Tabelle/Table 1 GrBen des thermischen Ersatzschaltbilds fur Gleichstrom Quantities of the thermal equivalent circuit for direct current Znsc' beidseitige Kihlung/double-sided cooling Zniciay. aNodenseitige Kihlung/anode-sided cooling Znicyy Kathodenseitige Kiihlung/cathode-sided cooling 163