P6KE100ARL

® P6KE TRANSIL™ FEATURES ■ Peak pulse power: 600 W (10/1000 µs ) ■ Stand-off voltage range 6.8 to 440V ■ Unidirectional and Bidirectional types ■ Low clamping factor ■ ■ Fast response time UL recognized DESCRIPTION Transil diodes provide high overvoltage protection by clamping action. Their instantaneous response to transient overvoltages makes them particularly suited to protect voltage sensitive devices such as MOS Technology and low voltage supplied IC’s. DO-15 (DO-204AC) Table 1: Order Codes Part Number P6KExxxx Marking See page 2 Table 2: Absolute Maximum Ratings (Tamb = 25°C) Symbol PPP P IFSM Tstg Tj TL Parameter Peak pulse power dissipation (see note 1) Power dissipation on infinite heatsink Non repetitive surge peak forward current Storage temperature range Maximum junction temperature Maximum lead temperature for soldering during 10 s at 5mm from case Tj initial = Tamb Tamb = 75°C tp = 10 ms Tj initial = Tamb Value 600 5 100 -65 to 175 175 230 Unit W W A °C °C Note 1: For a surge greater than the maximum values, the diode will fail in short-circuit. Table 3: Thermal Resistances Symbol Rth(j-l) Rth(j-a) Junction to leads Junction to ambient on printed circuit. Llead = 10mm Parameter Value 20 75 Unit °C/W °C/W October 2004 REV. 5 1/6 P6KE Table 4: Electrical Characteristics (Tamb = 25°C) Symbol VRM VBR VCL IRM IPP αT VF Parameter Stand-off voltage Breakdown voltage Clamping voltage Leakage current @ VRM Peak pulse current Voltage temperature coefficient Forward voltage drop IRM @ VRM TYPES Unidirectional P6KE6V8A P6KE7V5A P6KE10A P6KE12A P6KE15A P6KE18A P6KE22A P6KE24A P6KE27A P6KE30A P6KE33A P6KE36A P6KE39A P6KE47A P6KE56A P6KE68A P6KE82A P6KE100A P6KE120A P6KE150A P6KE180A P6KE200A P6KE220A P6KE250A P6KE300A P6KE350A P6KE400A P6KE440A max VBR @ IR min nom max note2 V V V mA 6.45 6.8 7.14 10 7.13 7.5 7.88 10 9.5 10 10.5 1 11.4 12 12.6 1 14.3 15 15.8 1 17.1 18 18.9 1 20.9 22 23.1 1 22.8 24 25.2 1 25.7 27 28.4 1 28.5 30 31.5 1 31.4 33 24.7 1 34.2 36 37.8 1 37.1 39 41.0 1 44.7 47 49.4 1 53.2 56 58.8 1 64.6 68 71.4 1 77.9 82 86.1 1 95.0 100 105 1 114 120 126 1 143 150 158 1 171 180 189 1 190 200 210 1 209 220 231 1 237 250 263 1 285 300 315 1 332 350 368 1 380 400 420 1 418 440 462 1 VCL @ IPP max 10/1000µs V A 10.5 57 11.3 53 14.5 41 16.7 36 21.2 28 25.2 24 30.6 20 33.2 18 37.5 16 41.5 14.5 45.7 13.1 49.9 12 53.9 11.1 64.8 9.3 77 7.8 92 6.5 113 5.3 137 4.4 165 3.6 207 2.9 246 2.4 274 2.2 328 1.85 344 1.75 414 1.45 482 1.25 548 1.1 603 1.0 I PP VCL VBR V RM VF I RM V IF I Bidirectional µA V P6KE6.8CA 1000 5.8 P6KE7.5CA 500 6.4 P6KE10CA 10 8.55 P6KE12CA 5 10.2 P6KE15CA 1 12.8 P6KE18CA 1 15.3 P6KE22CA 1 18.8 P6KE24CA 1 20.5 P6KE27CA 1 23.1 P6KE30CA 1 25.6 P6KE33CA 1 28.2 P6KE36CA 1 30.8 P6KE39CA 1 33.3 P6KE47CA 1 40.2 P6KE56CA 1 47.8 P6KE68CA 1 58.1 P6KE82CA 1 70.1 P6KE100CA 1 85.5 P6KE120CA 1 102 P6KE150CA 1 128 P6KE180CA 1 154 P6KE200CA 1 171 P6KE220CA 1 188 P6KE250CA 1 213 P6KE300CA 1 256 P6KE350CA 1 299 P6KE400CA 1 342 P6KE440CA 1 376 VCL @ IPP αT C max max typ 8/20µs note3 note4 V A 10-4/°C pF 13.4 298 5.7 4000 14.5 276 6.1 3700 18.6 215 7.5 2800 21.7 184 7.8 2300 27.2 147 8.4 1900 32.5 123 8.8 1600 39.3 102 9.2 1350 42.8 93 9.4 1250 48.3 83 9.6 1150 53.5 75 9.7 1075 59 68 9.8 1000 64.3 62 9.9 950 69.7 57 10.0 900 84 48 10.1 800 100 40 10.3 700 121 33 10.4 625 146 27 10.5 550 178 22.5 10.6 500 212 19 10.7 450 265 15 10.8 400 317 12.6 10.8 360 353 11.3 10.8 350 388 10.3 10.8 330 442 9 11 310 529 7.6 11 290 618 6.5 11 270 706 5.7 11 360 776 5.2 11 350 Note 2: Pulse test : tp < 50 ms. Note 3: ∆VBR = αT . (Ta - 25) . VBR(25°C). Note 4: VR = 0 V, F = 1 MHz. For bidirectional types, capacitance value is divided by 2. 2/6 P6KE Figure 1: Pulse waveform (10/1000µs) Figure 2: Peak power dissipation versus initial junction temperature (printed circuit board) % 100 % I PP 100 10µs 80 PULSE WAVEFORM 10/1000µs 60 40 20 50 0 1000µs t Tj initialø (°C) 0 0 20 40 60 80 100 120 140 160 180 200 Figure 3: Peak pulse power versus exponential pulse duration Ppp (W) Figure 4: Clamping voltage versus peak pulse current (note 5) VCL (V) 1000 P6KE 440A % Ipp 100 Tj initial = 25ø °C P6KE 220A 50 0 P6KE 100A 100 P6KE 68A P6KE 39A P6KE 22A P6KE 12A 10 P6KE 6V8A tr tp t t r < 10 s Exponential waveform: tp = 20µs tp = 1ms tp = 10ms 1 0.001 0.01 0.1 1 10 100 Ipp (A) 100 1000 0.1 1 10 Note 5: The curves of the figure 4 are specified for a junction temperature of 25°C before surge. The given results may be extrapolated for other junction temperatures by using the following formula : ∆VBR = αT * [Tamb -25] * VBR(25°C) For intermediate voltages, extrapolate the given results. Figure 5: Capacitance versus reverse applied voltage for unidirectional types (typical values) C (pF) 10000 P 6K E 6 1000 V8A Tj = 25°C ø F= 1 MHz Figure 6: Capacitance versus reverse applied voltage for bidirectional types (typical values) C (pF) 10000 Tj = 25°C ø F= 1 MHz P6 KE 6V 8CA P 6K E 1 5A P 6K E 6 8A P 6 KE 2 00A 1000 P6KE 15CA P6KE 68CA P6 KE2 00 C A 100 100 V R (V) 10 1 10 100 500 0 10 1 10 100 V R (V) 500 0 3/6 P6KE Figure 7: Peak forward voltage drop versus peak forward current for unidirectional types (typical values) Note: multiply by 2 for units with VBR ≥ 200V Figure 8: Transient thermal impedance junction to ambient versus pulse duration (for FR4 PC Board with Llead = 10mm) Zth (j-a) (°C/W) 100 10 tp 1 0.01 0.1 1 10 100 1000 Figure 9: Relative variation of leakage current versus junction temperature Figure 10: Ordering Information Scheme P6 KE 100 CA RL Peak Pulse Power P6 = 600W Breakdown Voltage 100 = 100V Types A = Unidirectional CA = Bidirectional Packaging Blank = Ammopack tape RL = Tape and reel 4/6 P6KE Figure 11: DO-15 (DO-204AC) Package Mechanical Data DIMENSIONS REF. A B D C A C Millimeters Min. 6.05 2.95 26 0.71 Max. 6.75 3.53 31 0.88 Inches Min. 0.238 0.116 1.024 0.028 Max. 0.266 0.139 1.220 0.035 C B D Table 5: Ordering Information Part Number P6KExxxx P6KExxxxRL Marking See page 2 Package DO-15 Weight 0.4 g Base qty 1000 6000 Delivery mode Ammopack Tape & reel Marking: Logo, data code, type code, cathode band (for unidirectional types only) Table 6: Revision History Date Feb-2003 Oct-2004 Revision 4B 5 Last update. 1/ Note 5, figure 7 on page 4, updated from VBR > 220V to VBR ≥ 200V. 2/ Types table on page 2: IPP (@10/1000µs) changed for P6KE220xx to P6KE440xx Description of Changes 5/6 P6KE Information furnished is believed to be accurate and reliable. However, STMicroelectronics assumes no responsibility for the consequences of use of such information nor for any infringement of patents or other rights of third parties which may result from its use. No license is granted by implication or otherwise under any patent or patent rights of STMicroelectronics. Specifications mentioned in this publication are subject to change without notice. This publication supersedes and replaces all information previously supplied. STMicroelectronics products are not authorized for use as critical components in life support devices or systems without express written approval of STMicroelectronics. The ST logo is a registered trademark of STMicroelectronics. All other names are the property of their respective owners © 2004 STMicroelectronics - All rights reserved STMicroelectronics group of companies Australia - Belgium - Brazil - Canada - China - Czech Republic - Finland - France - Germany - Hong Kong - India - Israel - Italy - Japan Malaysia - Malta - Morocco - Singapore - Spain - Sweden - Switzerland - United Kingdom - United States of America www.st.com 6/6