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| VDSM ITAVM ITRMS ITSM VT0 rT * * * * * = = = = = = 5200 V 3875 A 6090 A 55000 A 1.03 V 0.160 m Phase Control Thyristor 5STP 34Q5200 Doc. No. 5SYA1052-01 Sep. 01 Patented free-floating silicon technology Low on-state and switching losses Designed for traction, energy and industrial applications Optimum power handling capability Interdigitated amplifying gate Blocking Part Number VDSM VDRM VRSM1 IDSM IRSM dV/dtcrit VRSM VRRM 5STP 5200 V 4400 V 5700 V 5STP 34Q5000 5STP 34Q4600 Conditions 5000 V 4200 V 5500 V 500 mA 500 mA 2000 V/s 4600 V 4000 V 5100 V f = 5 Hz, tp = 10ms f = 50 Hz, tp = 10ms tp = 5ms, single pulse VDSM VRSM Tj = 125C Exp. to 0.67 x VDRM, Tj = 125C VDRM/ VRRM are equal to VDSM/ VRSM values up to Tj = 110C Mechanical data FM Mounting force nom. min. max. a Acceleration Device unclamped Device clamped m DS Da Weight Surface creepage distance Air strike distance 50 m/s2 100 m/s2 2.1 kg 36 mm 15 mm 90 kN 81 kN 108 kN ABB Semiconductors AG reserves the right to change specifications without notice. 5STP 34Q5200 On-state ITAVM ITRMS ITSM It 2 Max. average on-state current Max. RMS on-state current Max. peak non-repetitive surge current Limiting load integral 3875 A 6090 A 55000 A 60000 A 2 2 Half sine wave, TC = 70C tp = tp = 10 ms 8.3 ms 10 ms 8.3 ms 3000 A Tj = 125C Tj = 125C After surge: VD = VR = 0V 15125 kA s tp = 14940 kA s tp = VT VT0 rT IH IL On-state voltage Threshold voltage Slope resistance Holding current 1.54 V 1.03 V 0.160 m 50-125 mA 20-75 mA IT = IT = 2300 - 7000 A Tj = 25C Tj = 125C Tj = 25C Tj = 125C Latching current 100- mA 500 75-250 mA Switching di/dtcrit Critical rate of rise of on-state current 250 A/s 500 A/s Cont. f = 50 Hz VD 0.67VDRM , Tj = 125C 60 sec. f = 50Hz VD = 0.4VDRM ITRM = 3000 A IFG = 2 A, tr = 0.5 s IFG = 2 A, tr = 0.5 s td tq Qrr Delay time Turn-off time min max 3.0 s 700 s VD 0.67VDRM ITRM = 3000 A, Tj = 125C dvD/dt = 20V/s VR > 200 V, diT/dt = -5 A/s Recovery charge 7000 As 9000 As Triggering VGT IGT VGD IGD VFGM IFGM VRGM PG Gate trigger voltage Gate trigger current Gate non-trigger voltage Gate non-trigger current Peak forward gate voltage Peak forward gate current Peak reverse gate voltage Gate power loss 2.6 V 400 mA 0.3 V 10 mA 12 V 10 A 10 V 3W Tj = 25 Tj = 25 VD =0.4 x VDRM VD = 0.4 x VDRM ABB Semiconductors AG reserves the right to change specifications without notice. Doc. No. 5SYA1052-01 Sep. 01 page 2 of 6 5STP 34Q5200 Thermal Tjmax Tstg RthJC Max. operating junction temperature range Storage temperature range Thermal resistance junction to case 125 C -40...140 C 10 K/kW 10 K/kW 5 K/kW RthCH Thermal resistance case to heat sink Analytical function for transient thermal impedance: Anode side cooled Cathode side cooled Double side cooled Single side cooled Double side cooled 2 K/kW 1 K/kW ZthJC(t) = a Ri(1 - e -t/ i ) i =1 i Ri(K/kW) i(s) 1 3.27 0.5237 2 0.736 0.1082 3 0.661 0.02 4 0.312 0.0075 Fig. 1 Transient thermal impedance junction to case. On-state characteristic model: n VT = A + B iT + C ln(iT +1) + D IT Valid for iT = 500 - 14000 A A 1.0649 B 0.000105 C -0.038879 D 0.008155 Fig. 2 On-state characteristics. Tj=125C, 10ms half sine Fig. 3 On-state characteristics. ABB Semiconductors AG reserves the right to change specifications without notice. Doc. No. 5SYA1052-01 Sep. 01 page 3 of 6 5STP 34Q5200 Tcase (C) 130 Double-sided cooling 125 120 115 110 105 100 95 90 85 80 75 70 0 1000 2000 3000 4000 5000 DC 180 rectangular 180 sine 120 rectangular 6000 ITAV (A) Fig. 4 On-state power dissipation vs. mean onstate current. Turn - on losses excluded. Fig. 5 Max. permissible case temperature vs. mean on-state current. Fig. 6 Surge on-state current vs. pulse length. Half-sine wave. Fig. 7 Surge on-state current vs. number of pulses. Half-sine wave, 10 ms, 50Hz. ABB Semiconductors AG reserves the right to change specifications without notice. Doc. No. 5SYA1052-01 Sep. 01 page 4 of 6 5STP 34Q5200 5STP 34Q5200 Fig. 8 Gate trigger characteristics. Fig. 9 Max. peak gate power loss. Fig. 10 Recovery charge vs. decay rate of onstate current. Fig. 11 Peak reverse recovery current vs. decay rate of on-state current. Turn - off time, typical parameter relationship. Fig. 12 tq/tq1 = f1(Tj) Fig. 13 tq/tq1 = f2(-diT/dt) Fig. 14 tq/tq1 = f3(dv/dt) tq = tq1 * f1(Tj) * f2(-diT/dt) * f3(dv/dt) tq1 :at normalized values (see page 2) tq : at varying conditions ABB Semiconductors AG reserves the right to change specifications without notice. Doc. No. 5SYA1052-01 Sep. 01 page 5 of 6 5STP 34Q5200 Turn-on and Turn-off losses Fig. 15 Won = f(IT, tP), Tj = 125C. Half sinusoidal waves. Fig. 16 Won = f(IT, di/dt), Tj = 125C. Rectangular waves. Fig. 17 Woff = f(V0,IT), Tj = 125C. Half sinusoidal waves. tP = 10 ms. Fig. 18 Woff = f(V0,di/dt), Tj = 125C. Rectangular waves. ABB Semiconductors AG reserves the right to change specifications without notice. ABB Semiconductors AG Fabrikstrasse 3 CH-5600 Lenzburg, Switzerland Telephone Fax Email Internet +41 (0)62 888 6419 +41 (0)62 888 6306 abbsem@ch.abb.com www.abbsem.com Doc. No. 5SYA1052-01 Sep. 01 |
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