Download: DISCRETE SEMICONDUCTORS DATA SHEET BZW03 series Voltage regulator diodes Product specification 1996 May 14 Supersedes data of April 1992 File under Discrete Semiconductors, SC01

DISCRETE SEMICONDUCTORS DATA SHEET handbook, 2 columns M3D118 BZW03 series Voltage regulator diodes Product specification 1996 May 14 Supersedes data of April 1992 File under Discrete Semiconductors, SC01 FEATURES DESCRIPTION construction. This package is hermetically sealed and fatigue free • Glass passivated Rugged glass SOD64 package, using as coefficients of expansion of all • High maximum operating a high temperature alloyed used parts are matched. temperature • Low leakage current • Excellent stability • Zener working voltage range: 7.5 to 270 V for 38 types 2/3 page k(Datasheet) a • Tra...
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DISCRETE SEMICONDUCTORS

DATA SHEET

handbook, 2 columns M3D118

BZW03 series Voltage regulator diodes

Product specification 1996 May 14 Supersedes data of April 1992 File under Discrete Semiconductors, SC01, FEATURES DESCRIPTION construction. This package is hermetically sealed and fatigue free • Glass passivated Rugged glass SOD64 package, using as coefficients of expansion of all • High maximum operating a high temperature alloyed used parts are matched. temperature • Low leakage current • Excellent stability • Zener working voltage range: 7.5 to 270 V for 38 types 2/3 page k(Datasheet) a • Transient suppressor stand-off voltage range: MAM205 6.2 to 430 V for 45 types • Available in ammo-pack • Also available with preformed leads Fig.1 Simplified outline (SOD64) and symbol. for easy insertion. LIMITING VALUES In accordance with the Absolute Maximum Rating System (IEC 134). SYMBOL PARAMETER CONDITIONS MIN. MAX. UNIT Ptot total power dissipation Ttp = 25 °C; lead length 10 mm; see Fig.2 − 6.00 W Tamb = 45 °C; see Fig.2; − 1.75 W PCB mounted (see Fig.6) PZRM repetitive peak reverse power − 20 W dissipation PZSM non-repetitive peak reverse tp = 100 µs; square pulse; − 1000 W power dissipation Tj = 25 °C prior to surge; see Fig.3 PRSM non-repetitive peak reverse 10/1000 µs exponential pulse (see Fig.7); − 500 W power dissipation Tj = 25 °C prior to surge; see Fig.4 Tstg storage temperature −65 +175 °C Tj junction temperature −65 +175 °C 1996 May 14 2, ELECTRICAL CHARACTERISTICS Total series Tj = 25 °C unless otherwise specified. SYMBOL PARAMETER CONDITIONS MAX. UNIT VF forward voltage IF = 1 A; see Fig.5 1.2 V Per type when used as voltage regulator diodes Tj = 25 °C unless otherwise specified. DIFFERENTIAL TEMPERATURE TEST REVERSE CURRENT at TYPE WORKING VOLTAGE RESISTANCE COEFFICIENT CURRENT REVERSE VOLTAGE No. SUFFIX VZ (V) at IZ rdif (Ω) at IZ SZ (%/K) at IZ IR (µA) (1) IZ (mA) at VR (V) MIN. NOM. MAX. TYP. MAX. MIN. MAX. MAX. C7V5 7.0 7.5 7.9 0.7 1.5 0.00 0.07 175 1500 5.6 C8V2 7.7 8.2 8.7 0.8 1.5 0.03 0.08 150 1200 6.2 C9V1 8.5 9.1 9.6 0.9 2.0 0.03 0.08 150 40 6.8 C10 9.4 10 10.6 1.0 2.0 0.05 0.09 125 20 7.5 C11 10.4 11 11.6 1.1 2.5 0.05 0.10 125 15 8.2 C12 11.4 12 12.7 1.1 2.5 0.05 0.10 100 10 9.1 C13 12.4 13 14.1 1.2 2.5 0.05 0.10 100 4 10 C15 13.8 15 15.6 1.2 2.5 0.05 0.10 75 2 11 C16 15.3 16 17.1 1.3 2.5 0.06 0.11 75 2 12 C18 16.8 18 19.1 1.3 2.5 0.06 0.11 65 2 13 C20 18.8 20 21.2 1.5 3.0 0.06 0.11 65 2 15 C22 20.8 22 23.3 1.6 3.5 0.06 0.11 50 2 16 C24 22.8 24 25.6 1.8 3.5 0.06 0.11 50 2 18 C27 25.1 27 28.9 2.5 5 0.06 0.11 50 2 20 C30 28 30 32480.06 0.11 40 2 22 C33 31 33 35 5 10 0.06 0.11 40 2 24 C36 34 36 38 6 11 0.06 0.11 30 2 27 C39 37 39 41 7 14 0.06 0.11 30 2 30 C43 40 43 46 10 20 0.07 0.12 30 2 33 C47 44 47 50 12 25 0.07 0.12 25 2 36 C51 48 51 54 14 27 0.07 0.12 25 2 39 C56 52 56 60 18 35 0.07 0.12 20 2 43 C62 58 62 66 20 42 0.08 0.13 20 2 47 C68 64 68 72 22 44 0.08 0.13 20 2 51 C75 70 75 79 25 45 0.08 0.13 20 2 56 C82 77 82 87 30 65 0.08 0.13 15 2 62 C91 85 91 96 40 75 0.09 0.13 15 2 68 1996 May 14 3, DIFFERENTIAL TEMPERATURE TEST REVERSE CURRENT at TYPE WORKING VOLTAGE RESISTANCE COEFFICIENT CURRENT REVERSE VOLTAGE No. SUFFIX VZ (V) at IZ rdif (Ω) at IZ SZ (%/K) at IZ IR (µA) (1) IZ (mA) at VR (V) MIN. NOM. MAX. TYP. MAX. MIN. MAX. MAX. C100 94 100 106 45 90 0.09 0.13 12 2 75 C110 104 110 116 65 125 0.09 0.13 12 2 82 C120 114 120 127 90 170 0.09 0.13 10 2 91 C130 124 130 141 100 190 0.09 0.13 10 2 100 C150 138 150 156 150 330 0.09 0.1382110 C160 153 160 171 180 350 0.09 0.1382120 C180 168 180 191 210 430 0.09 0.1352130 C200 188 200 212 250 500 0.09 0.1352150 C220 208 220 233 350 700 0.09 0.1352160 C240 228 240 256 450 900 0.09 0.1352180 C270 251 270 289 600 1200 0.09 0.1352200 Note 1. To complete the type number the suffix is added to the basic type number, e.g. BZW03-C100. 1996 May 14 4, Per type when used as transient suppressor diodes Tj = 25 °C unless otherwise specified. TEMPERATURE TEST CLAMPING CURRENT at

BREAKDOWN

COEFFICIENT CURRENT VOLTAGE STAND-OFF TYPE VOLTAGE VOLTAGE

NUMBER

V(BR)R (V) VS (%/K) at I (CL)R at I atIZtest I RSM I (µA) test test (V) R at V (A) R (mA) (V) MIN. MIN. MAX. MAX. note 1 MAX. BZW03-C7V5 7.0 0.00 0.07 175 11.3 44.2 3000 6.2 BZW03-C8V2 7.7 0.03 0.08 150 12.3 40.6 2400 6.8 BZW03-C9V1 8.5 0.03 0.08 150 13.3 37.6 100 7.5 BZW03-C10 9.4 0.05 0.09 125 14.8 34.0 40 8.2 BZW03-C11 10.4 0.05 0.10 125 15.7 31.8 30 9.1 BZW03-C12 11.4 0.05 0.10 100 17.0 29.4 20 10 BZW03-C13 12.4 0.05 0.10 100 18.9 26.4 10 11 BZW03-C15 13.8 0.05 0.10 75 20.9 23.9 10 12 BZW03-C16 15.3 0.06 0.11 75 22.9 21.8 10 13 BZW03-C18 16.8 0.06 0.11 65 25.6 19.5 10 15 BZW03-C20 18.8 0.06 0.11 65 28.4 17.6 10 16 BZW03-C22 20.8 0.06 0.11 50 31.0 16.1 10 18 BZW03-C24 22.8 0.06 0.11 50 33.8 14.8 10 20 BZW03-C27 25.1 0.06 0.11 50 38.1 13.1 10 22 BZW03-C30 28 0.06 0.11 40 42.2 11.8 10 24 BZW03-C33 31 0.06 0.11 40 46.2 10.8 10 27 BZW03-C36 34 0.06 0.11 30 50.1 10.0 10 30 BZW03-C39 37 0.06 0.11 30 54.1 9.2 10 33 BZW03-C43 40 0.07 0.12 30 60.7 8.2 10 36 BZW03-C47 44 0.07 0.12 25 65.5 7.6 10 39 BZW03-C51 48 0.07 0.12 25 70.8 7.0 10 43 BZW03-C56 52 0.07 0.12 20 78.6 6.3 10 47 BZW03-C62 58 0.08 0.13 20 86.5 5.8 10 51 BZW03-C68 64 0.08 0.13 20 94.4 5.3 10 56 BZW03-C75 70 0.08 0.13 20 103.5 4.8 10 62 BZW03-C82 77 0.08 0.13 15 114.0 4.3 10 68 BZW03-C91 85 0.09 0.13 15 126 3.9 10 75 BZW03-C100 94 0.09 0.13 12 139 3.6 10 82 BZW03-C110 104 0.09 0.13 12 152 3.3 10 91 BZW03-C120 114 0.09 0.13 10 167 3.0 10 100 BZW03-C130 124 0.09 0.13 10 185 2.7 10 110 BZW03-C150 138 0.09 0.13 8 204 2.4 10 120 BZW03-C160 153 0.09 0.13 8 224 2.2 10 130 1996 May 14 5, TEMPERATURE TEST CLAMPING CURRENT at

BREAKDOWN

COEFFICIENT CURRENT VOLTAGE STAND-OFF TYPE VOLTAGE VOLTAGE

NUMBER

V(BR)R (V) VS (%/K) at I (CL)R at IZ test I RSM I (µA)at I test (V) R at Vtest (A) R (mA) (V) MIN. MIN. MAX. MAX. note 1 MAX. BZW03-C180 168 0.09 0.13 5 249 2.0 10 150 BZW03-C200 188 0.09 0.13 5 276 1.8 10 160 BZW03-C220 208 0.09 0.13 5 305 1.6 10 180 BZW03-C240 228 0.09 0.13 5 336 1.5 10 200 BZW03-C270 251 0.09 0.13 5 380 1.3 10 220 BZW03-C300 280 0.09 0.13 5 419 1.2 10 240 BZW03-C330 310 0.09 0.13 5 459 1.1 10 270 BZW03-C360 340 0.09 0.13 5 498 1.0 10 300 BZW03-C390 370 0.09 0.13 5 537 0.93 10 330 BZW03-C430 400 0.09 0.13 5 603 0.83 10 360 BZW03-C470 440 0.09 0.13 5 655 0.76 10 390 BZW03-C510 480 0.09 0.13 5 707 0.71 10 430 Note 1. Non-repetitive peak reverse current in accordance with “IEC 60-1, Section 8” (10/1000 µs pulse); see Fig.7. THERMAL CHARACTERISTICS SYMBOL PARAMETER CONDITIONS VALUE UNIT Rth j-tp thermal resistance from junction to tie-point lead length = 10 mm 25 K/W Rth j-a thermal resistance from junction to ambient note 1 75 K/W Note 1. Device mounted on an epoxy-glass printed-circuit board, 1.5 mm thick; thickness of Cu-layer ≥40 µm, see Fig.6. For more information please refer to the ‘General Part of Handbook SC01’. 1996 May 14 6, GRAPHICAL DATA MBH447 4 MBH4486 10 handbook, halfpage handbook, halfpage Ptot PZSM (W) (W) 4 103 2 102 0 10 0 100 T (°C) 200 10−2 10−1 1 tp (ms) 10 Solid line: tie-point temperature; lead length = 10 mm. Dotted line: ambient temperature; device mounted as Tj = 25 °C prior to surge. shown in Fig.6. Fig.3 Maximum non-repetitive peak reverse Fig.2 Maximum total power dissipation as a power dissipation as a function of pulse function of temperature. duration (square pulse). 4 MBH449 MBH45010 6 handbook, halfpage handbook, halfpage

IF

(A)

PRSM

(W) 102 0 10−2 10−1 1 t2 (ms) 1001VF (V) Tj = 25 °C prior to surge. For definition of exponential pulse see Fig.7. Tj = 25 °C. Fig.4 Maximum non-repetitive peak reverse power dissipation as a function of pulse Fig.5 Forward current as a function of forward duration (exponential pulse). voltage; typical values. 1996 May 14 7, handbIRooSkM, h alfpage50 handbook, halfpage (%) 2 103tt1 MGA200 t2 MGD521 In accordance with “IEC 60-1, Section 8”. t1 = 10 µs. t2 = 1000 µs. Dimensions in mm. Fig.7 Non-repetitive peak reverse current Fig.6 Device mounted on a printed-circuit board. pulse definition. 1996 May 14 8, PACKAGE OUTLINE handbook, full pagewidthka1.35 max 4.5 max 28 min 5.0 max 28 min MBC049 Dimensions in mm. The marking band indicates the cathode. Fig.8 SOD64.

DEFINITIONS

Data sheet status Objective specification This data sheet contains target or goal specifications for product development. Preliminary specification This data sheet contains preliminary data; supplementary data may be published later. Product specification This data sheet contains final product specifications. Limiting values Limiting values given are in accordance with the Absolute Maximum Rating System (IEC 134). Stress above one or more of the limiting values may cause permanent damage to the device. These are stress ratings only and operation of the device at these or at any other conditions above those given in the Characteristics sections of the specification is not implied. Exposure to limiting values for extended periods may affect device reliability. Application information Where application information is given, it is advisory and does not form part of the specification. LIFE SUPPORT APPLICATIONS These products are not designed for use in life support appliances, devices, or systems where malfunction of these products can reasonably be expected to result in personal injury. Philips customers using or selling these products for use in such applications do so at their own risk and agree to fully indemnify Philips for any damages resulting from such improper use or sale. 1996 May 14 9]
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