BZW06 Transil™ Datasheet - production data 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. Table 1: Order codes Features Part number Marking BZW06-xxxx See Table 4. 600 W peak pulse power (10/1000 µs) Stand-off voltage range 5.8 to 376 V Unidirectional and bidirectional types Low clamping factor Fast response time UL recognized, file: E136224 April 2017 DocID2972 Rev 4 This is information on a product in full production. 1/9 www.st.com Characteristics 1 BZW06 Characteristics Table 2: Absolute maximum ratings (Tamb = 25 °C) Symbol Parameter Value Peak pulse power Tj initial = Tamb 600 Power dissipation on infinite heatsink Tamb = 75 °C 1.7 IFSM Non repetitive surge peak forward current tp = 10 ms Tj initial = Tamb 100 Tstg Storage junction temperature range -65 to +175 Tj Operating junction temperature range -55 to +175 TL Maximum temperature for soldering during 10 s at 5 mm from case Ppp P Unit W A °C 260 Figure 1: Electrical characteristics (definitions) Table 3: Thermal resistances Symbol 2/9 Parameter Value Rth(j-l) Junction to leads 60 Rth(j-a) Junction to ambient on printed circuit. Llead = 10 mm 100 DocID2972 Rev 4 Unit °C/W BZW06 Characteristics Table 4: Electrical characteristics (Tamb = 25 °C) IRM at VRM(1) VBR at IR(2) Max. Min. VCL at IPP VCL at IPP αT(3) C(4) Max. Typ. 10-4/°C pF Types (marking) Max. Max. Unidirectional Bidirectional µA V V mA 10/1000 µs BZW06-5V8 BZW06-5V8B 20 5.8 6.45 10 10.5 57.0 13.4 298 5.7 4000 BZW06-6V4 BZW06-6V4B 10 6.4 7.13 10 11.3 53.0 14.5 276 6.1 3700 BZW06-8V5 BZW06-8V5B 1 8.5 9.5 1 14.5 41 18.6 215 7.3 2800 BZW06-10 BZW06-10B 0.2 10 11.4 1 16.7 36.0 21.7 184 7.8 2300 BZW06-13 BZW06-13B 0.2 13 14.3 1 21.2 28.0 27.2 147 8.4 1900 BZW06-15 BZW06-15B 0.2 15 17.1 1 25.2 24.0 32.5 123 8.8 1600 BZW06-19 BZW06-19B 0.2 19 20.9 1 30.6 19.6 39.3 102 9.2 1350 BZW06-20 BZW06-20B 0.2 20 22.8 1 33.2 18.0 42.8 93 9.4 1250 BZW06-23 BZW06-23B 0.2 23 25.7 1 37.5 16.0 48.3 83 9.6 1150 BZW06-26 BZW06-26B 0.2 26 28.5 1 41.5 14.5 53.5 75 9.7 1075 BZW06-28 BZW06-28B 0.2 28 31.4 1 45.7 13.1 59 68 9.8 1000 BZW06-31 BZW06-31B 0.2 31 34.2 1 49.9 12.0 64.3 62 9.9 950 BZW06-33 BZW06-33B 0.2 33 37.1 1 53.9 11.1 69.7 57 10.0 900 BZW06-37 BZW06-37B 0.2 36.8 40.9 1 59.3 10.1 76 53 10.1 850 BZW06-40 BZW06-40B 0.2 40 44.7 1 64.8 9.3 84 48 10.1 800 BZW06-48 BZW06-48B 0.2 48 53.2 1 77.0 7.8 100 40 10.3 700 BZW06-58 BZW06-58B 0.2 58 64.6 1 92.0 6.5 121 33 10.4 625 BZW06-70 BZW06-70B 0.2 70 77.9 1 113 5.3 146 27.0 10.5 550 BZW06-85 BZW06-85B 0.2 85 95.0 1 137 4.4 178 22.5 10.6 500 BZW06-102 BZW06-102B 0.2 102 114 1 165 3.6 212 19.0 10.7 450 BZW06-128 BZW06-128B 0.2 128 143 1 207 2.9 265 15.0 10.8 400 BZW06-154 BZW06-154B 0.2 154 171 1 246 2.4 317 12.6 10.8 360 BZW06-171 BZW06-171B 0.2 171 190 1 274 2.2 353 11.3 10.8 350 BZW06-188 BZW06-188B 0.2 188 209 1 328 1.85 388 10.3 10.8 330 BZW06-213 BZW06-213B 0.2 213 237 1 344 1.75 442 9.0 11.0 310 BZW06-256 BZW06-256B 0.2 256 285 1 414 1.45 529 7.6 11.0 290 BZW06-273 BZW06-273B 0.2 273 304 1 438 1.40 564 7.1 11.0 280 BZW06-299 BZW06-299B 0.2 299 332 1 482 1.25 618 6.5 11.0 271 BZW06-342 BZW06-342B 0.2 342 380 1 548 1.1 706 5.7 11.0 360 BZW06-376 BZW06-376B 0.2 376 418 1 603 1 776 5.7 11.0 350 8/20 µs Notes: (1)For bidirectional types having VRM ≤ 10 V, IRM is multiplied by 2 (2)Pulse test : tp < 50 ms (3)To calculate VBR or VCL versus junction temperature, use the following formulas: VBR at Tj = VBR at 25 °C x (1 + αT x (Tj - 25)) or VCL at Tj = VCL at 25 °C x (1 + αT x (Tj - 25)) (4)V R = 0 V, F = 1 MHz. For bidirectional types, capacitance value is divided by 2 DocID2972 Rev 4 3/9 Characteristics 1.1 BZW06 Characteristics (curves) Figure 2: Pulse waveform (10/1000 μs) % Ipp 10 µs 100 Pulse waveform 10/1000 µs 50 0 t 1000 µs Figure 3: Peak pulse power dissipation versus initial junction temperature PPP(W) 700 Figure 4: Peak pulse power versus exponential pulse duration 100.0 PPP(kW) 10/1000 µs Tj initial = 25 °C 600 500 10.0 400 300 1.0 200 100 Tj (°C) t P(ms) 0 0 25 50 75 100 125 150 175 0.1 1.0E-03 200 Figure 5: Clamping voltage versus peak pulse current (maximum values). 1000.0 IPP(A) 1.0E-02 1.0E-01 1.0E+00 1.0E+01 Figure 6: Junction capacitance versus reverse applied voltage (unidirectional types) C(pF) 10000 Tj initial = 25 °C 8/20 µs F = 1 MHz Vosc = 30 mVRMS Tj = 25 °C 10/1000 µs BZW06-5V8 10 ms 100.0 1000 BZW06-13 10.0 BZW06-58 100 0.1 1 4/9 10 100 BZW06-376 BZW06-188 BZW06-85 BZW06-58 BZW06-33 BZW06-19 BZW06-5V8 BZW06-10 BZW06-171 1.0 VCL(V) 1000 DocID2972 Rev 4 VR(V) 10 1 10 100 1000 BZW06 Characteristics Figure 8: Peak forward voltage drop versus peak forward current Figure 7: Junction capacitance versus reverse applied voltage (bidirectional types) 10000 C(pF) 1.0E+02 IFM(A) F = 1 MHz Vosc = 30 mVRMS Tj = 25 °C 1.0E+01 BZW06-5V8B Tj = 125 °C 1000 BZW06-13B Tj = 25 °C 1.0E+00 BZW06-58B 100 BZW06-171B 1.0E-01 VFM(V) VR(V) 10 1 10 100 1000 1.0E-02 0.0 Figure 9: Relative variation of thermal impedance junction to ambient versus pulse duration (printed circuit board FR4, eCU = 35 µm) 1.0E+00 Zth(j-a) /Rth(j-a) 0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 Figure 10: Leakage current versus junction temperature 1.E+04 IR(nA) Recommended pad layout 1.E+03 VR = VRM VBR < 10 V 1.0E-01 1.E+02 1.E+01 1.0E-02 VR = VRM VBR > 10 V 1.E+00 t P(s) 1.0E-03 1.0E-02 Tj (°C) 1.E-01 1.0E-01 1.0E+00 1.0E+01 1.0E+02 1.0E+03 DocID2972 Rev 4 25 50 75 100 125 150 5/9 175 Package information 2 BZW06 Package information In order to meet environmental requirements, ST offers these devices in different grades of ECOPACK® packages, depending on their level of environmental compliance. ECOPACK ® specifications, grade definitions and product status are available at: www.st.com. ECOPACK® is an ST trademark. 2.1 DO-15 package information Figure 11: DO-15 package outline Table 5: DO-15 package mechanical data Dimensions Ref. 6/9 Millimeters Inches Min. Typ. Max. Min. Typ. Max. b 0.71 - 0.88 0.028 - 0.035 D 2.95 - 3.53 0.116 - 0.139 G 6.05 - 6.75 0.238 - 0.266 L 26 - 31 1.024 - 1.22 DocID2972 Rev 4 BZW06 3 Ordering information Ordering information Figure 12: Ordering information scheme BZW 06 - 10 B RL Peak pulse power 06 = 600W Stand-off voltage 10 = 10V Types No suffix = unidirectional B = bidirectional Packaging Blank = Ammopack RL = Tape and reel Table 6: Ordering information Order code BZW-06xxxx BZW-06xxxxRL Marking(1) Package Weight See Table 4 DO-15 0.4 g Base qty. Delivery mode 1000 Ammopack 6000 Tape and reel Notes: (1)Marking: logo, data code, type, cathode band (for unidirectional types only) DocID2972 Rev 4 7/9 Revision history 4 BZW06 Revision history Table 7: Document revision history Date Revision Feb-2003 3A 06-Apr-2017 8/9 4 Changes Last update. Updated Table 2: "Absolute maximum ratings (Tamb = 25 °C)", Table 4: "Electrical characteristics (Tamb = 25 °C)", Section 5.1: "Characteristics (curves)" and Section 6.1: "DO-15 package information". DocID2972 Rev 4 BZW06 IMPORTANT NOTICE – PLEASE READ CAREFULLY STMicroelectronics NV and its subsidiaries (“ST”) reserve the right to make changes, corrections, enhancements, modifications, and improvements to ST products and/or to this document at any time without notice. Purchasers should obtain the latest relevant information on ST products before placing orders. ST products are sold pursuant to ST’s terms and conditions of sale in place at the time of order acknowledgement. Purchasers are solely responsible for the choice, selection, and use of ST products and ST assumes no liability for application assistance or the design of Purchasers’ products. No license, express or implied, to any intellectual property right is granted by ST herein. Resale of ST products with provisions different from the information set forth herein shall void any warranty granted by ST for such product. ST and the ST logo are trademarks of ST. All other product or service names are the property of their respective owners. Information in this document supersedes and replaces information previously supplied in any prior versions of this document. © 2017 STMicroelectronics – All rights reserved DocID2972 Rev 4 9/9