1.5KE6.8A thru 1.5KE540A, 1N6267A thru 1N6303A www.vishay.com Vishay General Semiconductor TRANSZORB(R) Transient Voltage Suppressors FEATURES * Glass passivated chip junction * Available in uni-directional and bi-directional * 1500 W peak pulse power capability with a 10/1000 s waveform, repetitive rate (duty cycle): 0.01 % * Excellent clamping capability * Very fast response time * Low incremental surge resistance Case Style 1.5KE * AEC-Q101 qualified * Solder dip 275 C max. 10 s, per JESD 22-B106 * Material categorization: For definitions of compliance please see www.vishay.com/doc?99912 TYPICAL APPLICATIONS PRIMARY CHARACTERISTICS VBR uni-directional Use in sensitive electronics protection against voltage transients induced by inductive load switching and lighting on ICs, MOSFET, signal lines of sensor units for consumer, computer, industrial, automotive, and telecommunication. 6.8 V to 540 V VBR bi-directional 6.8 V to 440 V VWM uni-directional 5.8 V to 459 V VWM bi-directional 5.8 V to 376 V PPPM 1500 W PD 6.5 W IFSM (uni-directional only) 200 A TJ max. 175 C Polarity Uni-directional, bi-directional Package 1.5KE MECHANICAL DATA Case: Molded epoxy body over passivated junction Molding compound meets UL 94 V-0 flammability rating Base P/N-E3 - RoHS compliant, commercial grade Base P/NHE3 - RoHS compliant, AEC-Q101 qualified Terminals: Matte tin plated leads, solderable per J-STD-002 and JESD 22-B102 E3 suffix meets JESD 201 class 1A whisker test, HE3 suffix meets JESD 201 class 2 whisker test DEVICES FOR BI-DIRECTION APPLICATIONS Note * 1.5KE250A to 1.5KE540A and 1.5KE250CA to 1.5KE440CA for commercial grade only For bi-directional types, use CA suffix (e.g. 1.5KE440CA) Eletrical characteristics apply in both directions. Polarity: For uni-directional types the color band denotes cathode end, no marking on bi-directional types MAXIMUM RATINGS (TA = 25 C unless otherwise noted) PARAMETER Peak pulse power dissipation with a 10/1000 s waveform SYMBOL (1) (fig. 1) Peak pulse current with a 10/1000 s waveform (1) Power dissipation on infinite heatsink at TL = 75 C (fig. 5) Peak forward surge current 8.3 ms single half sine-wave uni-directional only Maximum instantaneous forward voltage at 100 A for uni-directional only (3) Operating junction and storage temperature range (2) VALUE UNIT PPPM 1500 W IPPM See next table A PD 6.5 W IFSM 200 A VF 3.5/5.0 V TJ, TSTG - 55 to 175 C Notes (1) Non-repetitive current pulse, per fig. 3 and derated above T = 25 C per fig. 2 A (2) Measured on 8.3 ms single half sine-wave or equivalent square wave, duty cycle = 4 pulses per minute maximum (3) V = 3.5 V for 1.5KE220A and below; V = 5.0 V for 1.5KE250A and above F F Revision: 22-Jan-14 Document Number: 88301 1 For technical questions within your region: DiodesAmericas@vishay.com, DiodesAsia@vishay.com, DiodesEurope@vishay.com THIS DOCUMENT IS SUBJECT TO CHANGE WITHOUT NOTICE. THE PRODUCTS DESCRIBED HEREIN AND THIS DOCUMENT ARE SUBJECT TO SPECIFIC DISCLAIMERS, SET FORTH AT www.vishay.com/doc?91000 1.5KE6.8A thru 1.5KE540A, 1N6267A thru 1N6303A www.vishay.com Vishay General Semiconductor ELECTRICAL CHARACTERISTICS (TA = 25 C unless otherwise noted) JEDEC(R) TYPE NUMBER 1N6267A 1N6268A 1N6269A 1N6270A 1N6271A 1N6272A 1N6273A 1N6274A 1N6275A 1N6276A 1N6277A 1N6278A 1N6279A 1N6280A 1N6281A 1N6282A 1N6283A 1N6284A 1N6285A 1N6286A 1N6287A 1N6288A 1N6289A 1N6290A 1N6291A 1N6292A 1N6293A 1N6294A 1N6295A 1N6296A 1N6297A 1N6298A 1N6299A 1N6300A 1N6301A 1N6302A 1N6303A - GENERAL SEMICONDUCTOR PART NUMBER (+)1.5KE6.8A (+)1.5KE7.5A (+)1.5KE8.2A (+)1.5KE9.1A (+)1.5KE10A (+)1.5KE11A (+)1.5KE12A (+)1.5KE13A (+)1.5KE15A (+)1.5KE16A (+)1.5KE18A (+)1.5KE20A (+)1.5KE22A (+)1.5KE24A (+)1.5KE27A (+)1.5KE30A (+)1.5KE33A (+)1.5KE36A (+)1.5KE39A (+)1.5KE43A (+)1.5KE47A (+)1.5KE51A (+)1.5KE56A (+)1.5KE62A (+)1.5KE68A (+)1.5KE75A (+)1.5KE82A (+)1.5KE91A (+)1.5KE100A (+)1.5KE 110A (+)1.5KE120A (+)1.5KE130A (+)1.5KE150A (+)1.5KE160A (+)1.5KE170A 1.5KE180A 1.5KE200A* 1.5KE220A* 1.5KE250A 1.5KE300A 1.5KE350A 1.5KE400A 1.5KE440A 1.5KE480A 1.5KE510A 1.5KE540A BREAKDOWN MAXIMUM VOLTAGE TEST STAND-OFF REVERSE VBR AT IT (1) CURRENT VOLTAGE LEAKAGE (V) IT VWM AT VWM (mA) (V) ID (4) MIN. MAX. (A) 6.45 7.14 10 5.80 1000 7.13 7.88 10 6.40 500 7.79 8.61 10 7.02 200 8.65 9.55 1.0 7.78 50 9.50 10.5 1.0 8.55 10 10.5 11.6 1.0 9.40 5.0 11.4 12.6 1.0 10.2 5.0 12.4 13.7 1.0 11.1 5.0 14.3 15.8 1.0 12.8 1.0 15.2 16.8 1.0 13.6 1.0 17.1 18.9 1.0 15.3 1.0 19.0 21.0 1.0 17.1 1.0 20.9 23.1 1.0 18.8 1.0 22.8 25.2 1.0 20.5 1.0 25.7 28.4 1.0 23.1 1.0 28.5 31.5 1.0 25.6 1.0 31.4 34.7 1.0 28.2 1.0 34.2 37.8 1.0 30.8 1.0 37.1 41.0 1.0 33.3 1.0 40.9 45.2 1.0 36.8 1.0 44.7 49.4 1.0 40.2 1.0 48.5 53.6 1.0 43.6 1.0 53.2 58.8 1.0 47.8 1.0 58.9 65.1 1.0 53.0 1.0 64.6 71.4 1.0 58.1 1.0 71.3 78.8 1.0 64.1 1.0 77.9 86.1 1.0 70.1 1.0 86.5 95.5 1.0 77.8 1.0 95.0 105 1.0 85.5 1.0 105 116 1.0 94.0 1.0 114 126 1.0 102 1.0 124 137 1.0 111 1.0 143 158 1.0 128 1.0 152 168 1.0 136 1.0 162 179 1.0 145 1.0 171 189 1.0 154 1.0 190 210 1.0 171 1.0 209 231 1.0 185 1.0 237 263 1.0 214 1.0 285 315 1.0 256 1.0 333 368 1.0 300 1.0 380 420 1.0 342 1.0 418 462 1.0 376 1.0 456 504 1.0 408 1.0 485 535 1.0 434 1.0 513 567 1.0 459 1.0 MAXIMUM MAXIMUM MAXIMUM PEAK CLAMPING TEMPERATURE PULSE VOLTAGE COEFFICENT CURRENT AT IPPM OF VBR IPPM (2) VC (V) (%/C) (A) 143 10.5 0.057 133 11.3 0.061 124 12.1 0.065 112 13.4 0.068 103 14.5 0.073 96.2 15.6 0.075 89.8 16.7 0.078 82.4 18.2 0.081 70.8 21.2 0.084 66.7 22.5 0.086 59.5 25.2 0.089 54.2 27.7 0.09 49.0 30.6 0.092 45.2 33.2 0.094 40.0 37.5 0.096 36.2 41.4 0.097 32.8 45.7 0.098 30.1 49.9 0.099 27.8 53.9 0.1 25.3 59.3 0.101 23.1 64.8 0.101 21.4 70.1 0.102 19.5 77.0 0.103 17.6 85.0 0.104 16.3 92.0 0.104 14.6 104 0.105 13.3 113 0.105 12.0 125 0.106 10.9 137 0.106 9.9 152 0.107 9.1 165 0.107 8.4 179 0.107 7.2 207 0.106 6.8 219 0.108 6.4 234 0.108 6.1 246 0.108 5.5 274 0.108 4.6 328 0.108 4.4 344 0.110 3.6 414 0.110 3.1 482 0.110 2.7 548 0.110 2.5 602 0.110 2.28 658 0.110 2.15 698 0.110 2.03 740 0.110 Notes (1) Pulse test: t 50 ms p (2) Surge current waveform per fig. 3 and derate per fig. 2 (3) All terms and symbols are consistent with ANSI/IEEE CA62.35 (4) For bi-directional types with V 10 V and less the I limit is doubled R D * Bi-directional versions are UL approved under component across the line protection, ULV1414 file number E108274 (1.5KE200CA, 1.5KE220CA) (+) Underwriters laboratory recognition for the classification of protectors (QVGQ2) under the UL standard for safety 497B and file number E136766 for both uni-directional and bi-directional devices Revision: 22-Jan-14 Document Number: 88301 2 For technical questions within your region: DiodesAmericas@vishay.com, DiodesAsia@vishay.com, DiodesEurope@vishay.com THIS DOCUMENT IS SUBJECT TO CHANGE WITHOUT NOTICE. THE PRODUCTS DESCRIBED HEREIN AND THIS DOCUMENT ARE SUBJECT TO SPECIFIC DISCLAIMERS, SET FORTH AT www.vishay.com/doc?91000 1.5KE6.8A thru 1.5KE540A, 1N6267A thru 1N6303A www.vishay.com Vishay General Semiconductor THERMAL CHARACTERISTICS (TA = 25 C unless otherwise noted) PARAMETER SYMBOL VALUE Typical thermal resistance, junction to ambient RJA 75 Typical thermal resistance, junction to lead RJL 15.4 UNIT C/ W ORDERING INFORMATION (Example) PREFERRED PIN UNIT WEIGHT (g) PREFERRED PACKAGE CODE BASE QUANTITY DELIVERY MODE 1.5KE6.8A-E3/54 0.968 54 1400 13" diameter paper tape and reel 1.5KE6.8AHE3/54 (1) 0.968 54 1400 13" diameter paper tape and reel Note (1) AEC-Q101 qualified RATINGS AND CHARACTERISTICS CURVES (TA = 25 C unless otherwise noted) 150 IPPM - Peak Pulse Current, % IRSM PPPM - Peak Pulse Power (kW) 100 10 1 0.1 0.1 s Peak Value IPPM 100 Half Value - IPP IPPM 2 50 10/1000 s Waveform as defined by R.E.A. td 0 1.0 s 10 s 100 s 1.0 ms 10 ms 1.0 0 td - Pulse Width (s) 3.0 2.0 4.0 t - Time (ms) Fig. 1 - Peak Pulse Power Rating Curve Fig. 3 - Pulse Waveform 100 10 000 Uni-Directional Bi-Directional 75 CJ - Capacitance (pF) Peak Pulse Power (PPP) or Current (IPP) Derating in Percentage, % TJ = 25 C Pulse Width (td) is defined as the Point where the Peak Current decays to 50 % of IPPM tr = 10 s 50 25 VR = 0 1000 VR = Rated Stand-Off Voltage 100 TJ = 25 C f = 1.0 MHz Vsig = 50 mVp-p 0 0 25 50 75 100 125 150 175 200 TJ - Initial Temperature (C) Fig. 2 - Pulse Power or Current vs. Initial Junction Temperature Revision: 22-Jan-14 10 5 10 100 500 VBR - Breakdown Voltage (V) Fig. 4 - Typical Junction Capacitance Document Number: 88301 3 For technical questions within your region: DiodesAmericas@vishay.com, DiodesAsia@vishay.com, DiodesEurope@vishay.com THIS DOCUMENT IS SUBJECT TO CHANGE WITHOUT NOTICE. THE PRODUCTS DESCRIBED HEREIN AND THIS DOCUMENT ARE SUBJECT TO SPECIFIC DISCLAIMERS, SET FORTH AT www.vishay.com/doc?91000 1.5KE6.8A thru 1.5KE540A, 1N6267A thru 1N6303A www.vishay.com Vishay General Semiconductor 8.0 VC - Incremental Clamping Voltage 100 PD - Power Dissipation (W) 7.0 6.0 5.0 4.0 3.0 L = 0.375" (9.5 mm) Lead Lengths 2.0 1.0 0 25 50 75 100 125 150 175 20 1.5KE75 10 1.5KE39 2.0 1.5KE33 1.5KE6.8 1.5KE9.1 1.0 0.2 0.5 200 1 10 2 50 TL - Lead Temperature (C) IPP - Peak Pulse Current (A) Fig. 5 - Power Derating Curve Fig. 8 - Incremental Clamping Voltage Curve (Uni-directional) 100 200 TJ = TJ max. 8.3 ms Single Half Sine-Wave VC - Incremental Clamping Voltage Peak Forward Surge Current (A) 1.5KE200 1.5KE130 0.1 0 100 10 1 Waveform: 10/1000 s Impulse VC = VC - VBR 100 1.5KE200C 20 10 1.5KE75C 1.5KE39C 1.5KE30C 1.5KE15C 11C 1.5KE7.5C 2.0 1.0 0.2 0.1 0.5 10 2 1 10 20 50 Number of Cycles at 60 Hz IPP - Peak Pulse Current (A) Fig. 6 - Maximum Non-Repetitive Forward Surge Current Uni-Directional only Fig. 9 - Incremental Clamping Voltage Curve (Bi-directional) 100 Waveform: 8/20 s Impulse VC = VC - VBR 1.5KE200 1.5KE130 20 1.5KE100 10 1.5KE75 2.0 1.5KE39 1.5KE33 1.5KE6.8 1.5KE9.1 1.5KE18 1.5KE12 1.0 0.2 VC - Incremental Clamping Voltage 100 VC - Incremental Clamping Voltage Waveform: 10/1000 s Impulse VC = VC - VBR 20 Waveform: 8/20 s Impulse VC = VC - VBR 1.5KE200C 1.5KE75C 10 1.5KE39C 1.5KE30C 1.5KE15C 2 1.5KE11C 1 1.5KE7.5C 0.2 0.1 0.1 0.5 1 2 10 20 50 0.5 1 2.0 10 20 50 IPP - Peak Pulse Current (A) IPP - Peak Pulse Current (A) Fig. 7 - Incremental Clamping Voltage Curve (Uni-Directional) Fig. 10 - Incremental Clamping Voltage Curve (Bi-Directional) Revision: 22-Jan-14 Document Number: 88301 4 For technical questions within your region: DiodesAmericas@vishay.com, DiodesAsia@vishay.com, DiodesEurope@vishay.com THIS DOCUMENT IS SUBJECT TO CHANGE WITHOUT NOTICE. THE PRODUCTS DESCRIBED HEREIN AND THIS DOCUMENT ARE SUBJECT TO SPECIFIC DISCLAIMERS, SET FORTH AT www.vishay.com/doc?91000 1.5KE6.8A thru 1.5KE540A, 1N6267A thru 1N6303A www.vishay.com Vishay General Semiconductor 100 Transient Thermal Impedance (C/W) Instantaneous Forward Current (A) 100 10 1 TJ = 25 C Pulse Width = 300 s 1 % Duty Cycle 0.4 0.8 1.2 1.6 1 0.1 0.001 0.1 0 10 2.0 0.01 0.1 1 10 100 1000 tp - Pulse Duration (s) Instantaneous Forward Voltage (V) Fig. 11 - Instantaneous Forward Voltage Characteristics Curve Fig. 12 - Typical Transient Thermal Impedance PACKAGE OUTLINE DIMENSIONS in inches (millimeters) Case Style 1.5KE 1.0 (25.4) MIN. 0.210 (5.3) 0.190 (4.8) DIA. 0.375 (9.5) 0.285 (7.2) 1.0 (25.4) MIN. 0.042 (1.07) 0.038 (0.96) DIA. APPLICATION NOTES * This series of Silicon Transient Suppressors is used in applications where large voltage transients can permanently damage voltage-sensitive components. * The TVS diode can be used in applications where induced lightning on rural or remote transmission lines presents a hazard to electronic circuitry (ref: R.E.A. specification P.E. 60). Revision: 22-Jan-14 * This Transient Voltage Suppressor diode has a pulse power rating of 1500 W for 1 ms. The response time of TVS diode clamping action is effectively instantaneous (1 x 10-9 s bi-directional); therefore, they can protect integrated circuits, MOS devices, hybrids, and other voltage sensitive semiconductors and components. TVS diodes can also be used in series or parallel to increase the peak power ratings. Document Number: 88301 5 For technical questions within your region: DiodesAmericas@vishay.com, DiodesAsia@vishay.com, DiodesEurope@vishay.com THIS DOCUMENT IS SUBJECT TO CHANGE WITHOUT NOTICE. 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No license, express or implied, by estoppel or otherwise, to any intellectual property rights is granted by this document or by any conduct of Vishay. Product names and markings noted herein may be trademarks of their respective owners. Revision: 13-Jun-16 1 Document Number: 91000