GDZJ33

DATA SHEET GDZJ2.0~GDZJ56 AXIAL LEAD ZENER DIODES VOLTAGE 2.0 to 56 Volts POWER 500 mWatts DO-35 Unit: inch (mm) FEATURES • 500mW Power Dissipation • Ideally Suited for Automated Assembly Processes • P b free product are available : 99% Sn above can meet Rohs environment substance directive request .153(3.9)MAX. 1.02(26.0)MIN. • Planar Die construction .020(0.52)TYP. MECHANICAL DATA • Case: Molded Glass DO-35 • Terminals: Solderable per MIL-STD-202G, Method 208 • Polarity: See Diagram Below • Approx. Weight: 0.13 grams • Mounting Position: Any • Ordering information: Suffix : “ -35 ” to order DO-35 Package • Packing information B - 2K per Bulk box T/R - 10K per 13" plastic Reel T/B - 5K per horiz. tape & Ammo box MAXIMUM RATINGS AND ELECTRICAL CHARACTERISTICS P ar m et r a e P ow erD i si aton atTam b = 25 spi Juncton Tem per t r i aue S t r ge Tem per t r R ange oa aue O S ym bol 1.02(26.0)MIN. .079(2.0)MAX. Val e u 500 175 - 5 t +175 6o U nis t mW O C P TO T TJ TS C C O Vald pr vi ed t atl ads ata di t nce of10m m fom case ar keptatam bi ntt m per t r . i od he sa r e ee aue P ar m et r a e Ther alR esi t nce Juncton t A m bi ntA i m sa io e r For ar Volage atI = 100m A wd t F S ym bol M i. n - Typ. M ax. 0. 3 1 U nis t K/ W m V Rt A h VF - Vald pr vi ed t atl ads ata di t nce of10m m fom case ar keptatam bi ntt m per t r . i od he sa r e ee aue STAD-NOV.24.2004 PAGE . 1 Part Number GDZJ 2.0 GDZJ 2.2 GDZJ 2.4 GDZJ 2.7 GDZJ 3.0 GDZJ 3.3 GDZJ 3.6 GDZJ 3.9 C LA S S A B A B A B A B A B A B A B A B A B C A V Z @ IZT M i n. V 1.88 2.02 2.12 2.22 2.33 2.43 2.54 2.69 2.85 3.01 3.16 3.32 3.455 3.60 3.74 3.89 4.04 4.17 4.30 4.44 4.55 4.68 4.81 4.94 5.09 5.28 5.45 5.61 5.78 5.96 6.12 6.29 6.49 6.66 6.85 7.07 7.29 7.53 7.78 8.03 8.29 8.57 8.83 9.12 9.41 9.70 9.94 10.18 10.50 10.82 M a x. V 2.10 2.20 2.30 2.41 2.52 2.63 2.75 2.91 3.07 3.22 3.38 3.53 3.695 3.845 4.01 4.16 4.29 4.43 4.57 4.68 4.80 4.93 5.07 5.20 5.37 5.55 5.73 5.91 6.09 6.27 6.44 6.63 6.83 7.01 7.22 7.45 7.67 7.92 8.19 8.45 8.73 9.01 9.30 9.59 9.90 10.20 10.44 10.71 11.05 11.38 IZ (m A ) 5 5 5 5 5 5 5 5 VR (V ) 0.5 0.7 1.0 1.0 1.0 1.0 1.0 1.0 IR ( u A ) MA X 120 100 120 100 50 20 10 5 Iz t (mA ) 5 5 5 5 5 5 5 5 Z ZT ( Ω ) MA X 100 100 100 110 120 120 100 100 Iz k (mA ) 0.5 0.5 0.5 0.5 0.5 0.5 1 1 Z ZK ( Ω ) MA X 1000 1000 1000 1000 1000 1000 1000 1000 M A RK ING C OD E Z2A0 Z2B0 Z2A2 Z2B2 Z2A4 Z2B4 Z2A7 Z2B7 Z3A0 Z3B0 Z3A3 Z3B3 Z3A6 Z3B6 Z3A9 Z3B9 Z4A3 Z4B3 Z4C3 Z4A7 GDZJ 4.3 5 1.0 5 5 100 1 1000 GDZJ 4.7 B C A 5 1.0 5 5 90 1 900 Z4B7 Z4C7 Z5A1 GDZJ 5.1 B C A 5 1.5 5 5 80 1 800 Z5B1 Z5C1 Z5A6 GDZJ 5.6 B C A 5 2.5 5 5 60 1 500 Z5B6 Z5C6 Z6A2 GDZJ 6.2 B C A 5 3.0 5 5 60 1 300 Z6B2 Z6C2 Z6A8 GDZJ 6.8 B C A 5 3.5 2 5 20 0.5 150 Z6B8 Z6C8 Z7A5 GDZJ 7.5 B C A 5 4.0 0.5 5 20 0.5 120 Z7B5 Z7C5 Z8A2 GDZJ 8.2 B C A 5 5.0 0.5 5 20 0.5 120 Z8B2 Z8C2 Z9A1 GDZJ 9.1 B C A B C D A 5 6.0 0.5 5 25 0.5 120 Z9B1 Z9C1 Z10A Z10B Z10C Z11D Z11A GDZJ 10 5 7.0 0.2 5 30 0.5 120 GDZJ 11 B C 5 8.0 0.2 5 30 0.5 120 Z11B Z11C STAD-NOV.24.2004 PAGE . 2 Part Number C LA S S A V Z @ IZT M i n. V 11.13 11.44 11.74 12.11 12.55 12.99 13.44 13.89 14.35 14.80 15.25 15.69 16.22 16.82 17.42 18.02 18.63 19.23 19.72 20.15 20.64 21.08 21.52 22.05 22.61 23.12 23.63 24.26 24.97 25.63 26.29 26.99 27.70 28.36 29.02 29.68 30.32 30.90 31.49 32.14 32.79 33.40 34.01 34.68 35.36 36.00 36.63 40.00 44.00 48.00 53.00 M a x. V 11.71 12.03 12.35 12.75 13.21 13.66 14.13 14.62 15.09 15.57 16.04 16.51 17.06 17.70 18.33 18.96 19.59 20.22 20.72 21.20 21.71 22.17 22.63 23.18 23.77 24.31 24.85 25.52 26.26 26.95 27.64 28.39 29.13 29.82 30.51 31.22 31.88 32.50 33.11 33.79 34.49 35.13 35.77 36.47 37.19 37.85 38.52 45.00 49.00 54.00 60.00 IZ (m A ) 5 VR (V ) 9.0 IR ( u A ) MA X 0.2 Iz t (mA ) 5 Z ZT ( Ω ) MA X 30 Iz k (mA ) 0.5 Z ZK ( Ω ) MA X 110 M A RK ING C OD E Z12A Z12B Z12C Z13A GDZJ 12 B C A GDZJ 13 B C A 5 10 0.2 5 35 0.5 110 Z13B Z13C Z15A GDZJ 15 B C A 5 11 0.2 5 40 0.5 110 Z15B Z15C Z16A GDZJ 16 B C A 5 12 0.2 5 40 0.5 150 Z16B Z16C Z18A GDZJ 18 B C A B C D A B C D A B C D A B C D A B C D A B C D A B C D A B C D 5 13 0.2 5 45 0.5 150 Z18B Z18C Z20A Z20B Z20C Z20D Z22A Z22B Z22C Z22D Z24A Z24B Z24C Z24D Z27A Z27B Z27C Z27D Z30A Z30B Z30C Z30D Z33A Z33B Z33C Z33D Z36A Z36B Z36C Z36D Z39A Z39B Z39C Z39D Z41 Z43 Z47 Z51 GDZJ 20 5 15 0.2 5 55 0.5 200 GDZJ 22 5 17 0.2 5 30 0.5 200 GDZJ 24 5 19 0.2 5 35 0.5 200 GDZJ 27 5 21 0.2 5 45 0.5 250 GDZJ 30 5 23 0.2 5 55 0.5 250 GDZJ 33 5 25 0.2 5 65 0.5 250 GDZJ 36 5 27 0.2 5 75 0.5 250 GDZJ 39 5 30 0.2 5 85 0.5 250 GDZJ 43 GDZJ 47 GDZJ 51 GDZJ 56 5 5 5 5 33 36 39 43 0.2 0.2 0.2 0.2 5 5 5 5 90 90 110 110 ----- ----- STAD-NOV.24.2004 PAGE . 3 Typical Characteristics (Tamb = 25 °C unless otherwise specified) RthJA –Therm.Resist.Junction/ Ambient ( K/W) 500 VZtn – Relative VoltageChange 1.3 V Ztn=V Zt/V Z(25°C) 400 1.2 1.1 1.0 0.9 0.8 –60 TK VZ =10 x 10–4/K 300 l l 8 x 10–4/K 6 x 10–4/K 4 x 10–4/K 2 x 10–4/K 0 –2 x 10–4/K –4 x 10–4/K 200 100 TL=constant 0 0 5 10 15 20 l – Lead Length ( mm ) 0 60 120 180 240 95 961 1 95 9599 Tj – Junction Temperature (°C ) Fig. 1 Thermal Resistance vs. Lead Length Fig. 4 Typical Change of Working Voltage vs. Junction Temperature TK VZ –Temperature Coefficient of VZ ( 10–4 /K) P –Total Power Dissipation ( mW) tot 600 500 400 300 200 15 10 5 I Z=5mA 0 100 0 –5 0 10 20 30 40 0 40 80 120 160 200 50 95 9602 Tamb – Ambient T emperature(°C ) 95 9600 V Z – Z-Voltage ( V ) Fig. 2 Total Power Dissipation vs. Ambient Temperature Fig. 5 Temperature Coefficient of Vz vs. Z-Voltage 1000 CD – Diode Capacitance ( pF ) 200 VZ –VoltageChange mV ) ( Tj =25°C 150 V R=2V Tj =25°C 100 100 I Z=5mA 10 50 1 0 95 9598 0 5 10 15 20 25 95 9601 0 5 10 15 20 25 V Z – Z-Voltage ( V ) V Z – Z-Voltage ( V ) Fig. 3 Typical Change of Working Voltage under Operating Conditions at Tamb=25°C Fig. 6 Diode Capacitance vs. Z-Voltage STAD-NOV.24.2004 PAGE . 4 100 I F – Forward Current ( mA) 50 40 30 20 10 0 Ptot=500mW Tamb=25°C Tj =25°C 1 0.1 0.01 0.001 0 0.2 0.4 0.6 0.8 1.0 IZ – Z-Current ( mA) 10 15 95 9607 20 25 30 35 95 9605 V F – Forward Voltage ( V ) V Z – Z-Voltage ( V ) Fig. 7 Forward Current vs. Forward Voltage Fig. 9 Z-Current vs. Z-Voltage IZ – Z-Current ( mA) 80 60 40 20 0 0 4 8 12 r Z – Differential Z-Resistance ( Ω ) 100 1000 Ptot=500mW Tamb=25°C I Z=1mA 100 5mA 10 10mA 1 Tj =25°C 0 5 10 15 20 25 V Z – Z-Voltage ( V ) 16 20 95 9606 95 9604 V Z – Z-Voltage ( V ) Fig. 8 Z-Current vs. Z-Voltage Zthp –ThermalResistance PulseCond.(K/W) for Fig. 10 Differential Z-Resistance vs. Z-Voltage 1000 tp/T=0.5 100 tp/T=0.2 Single Pulse 10 tp/T=0.1 RthJA=300K/W T=Tjmax–Tamb tp/T=0.01 tp/T=0.02 tp/T=0.05 i ZM =(–VZ+(V Z2+4rzj x T/Zthp)1/2)/(2rzj) 1 10–1 100 101 tp – Pulse Length ( ms ) 102 95 9603 Fig. 11 Thermal Response STAD-NOV.24.2004 PAGE . 5