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MOTOROLA SEMICONDUCTOR TECHNICAL DATA GENERAL 1–1.3 Watt DO-41 Glass DATA Zener Voltage Regulator Diodes GENERAL DATA APPLICABLE TO ALL SERIES IN 1–1.3 WATT THIS GROUP DO-41 GLASS One Watt Hermetically Sealed Glass Silicon Zener Diodes 1 WATTZENER REGULATOR DIODES Specification Features: 3.3–100 VOLTS • Complete Voltage Range — 3.3 to 100 Volts • DO-41 Package • Double Slug Type Construction • Metallurgically Bonded Construction • Oxide Passivated Die Mechanical Characteristics: CASE: Double slug type, hermetically sealed glass MAXIMUM LEAD TEMPERATURE FOR SOLDERING PURPOSES: 230°C, 1/16″ from...
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MOTOROLA SEMICONDUCTOR TECHNICAL DATA GENERAL

1–1.3 Watt DO-41 Glass DATA

Zener Voltage Regulator Diodes GENERAL DATA APPLICABLE TO ALL SERIES IN 1–1.3 WATT THIS GROUP DO-41 GLASS One Watt Hermetically Sealed Glass Silicon Zener Diodes 1 WATTZENER REGULATOR DIODES

Specification Features: 3.3–100 VOLTS • Complete Voltage Range — 3.3 to 100 Volts • DO-41 Package • Double Slug Type Construction • Metallurgically Bonded Construction • Oxide Passivated Die Mechanical Characteristics: CASE: Double slug type, hermetically sealed glass MAXIMUM LEAD TEMPERATURE FOR SOLDERING PURPOSES: 230°C, 1/16″ from case for 10 seconds FINISH: All external surfaces are corrosion resistant with readily solderable leads CASE 59-03 DO-41 POLARITY: Cathode indicated by color band. When operated in zener mode, cathode GLASS will be positive with respect to anode MOUNTING POSITION: Any WAFER FAB LOCATION: Phoenix, Arizona ASSEMBLY/TEST LOCATION: Seoul, Korea MAXIMUM RATINGS Rating Symbol Value Unit DC Power Dissipation @ TA = 50°C PD 1 Watt Derate above 50°C 6.67 mW/°C Operating and Storage Junction Temperature Range TJ, Tstg – 65 to +200 °C 1.25 L = LEAD LENGTH L = 1″ TO HEAT SINK1L= 1/8″ L = 3/8″ 0.75 0.5 0.25 0 20 40 60 80 100 120 140 160 180 200 TL, LEAD TEMPERATURE (°C) Figure 1. Power Temperature Derating Curve 6-20 PD , MAXIMUM DISSIPATION (WATTS), a. Range for Units to 12 Volts b. Range for Units to 12 to 100 Volts +12 100 +10 50 +8 30 +6 +4 10 RANGE VZ @ IZT +2 5 RANGE VZ @ IZT03–2 2 –412345678910 11 12 10 20 30 50 70 100 VZ, ZENER VOLTAGE (VOLTS) VZ, ZENER VOLTAGE (VOLTS)

Figure 2. Temperature Coefficients

(–55°C to +150°C temperature range; 90% of the units are in the ranges indicated.) 175 +6 150 VZ @ I+4 ZTA = 25°C +2 100 20 mA 75 0 0.01 mA 50 1 mA –2 NOTE: BELOW 3 VOLTS AND ABOVE 8 VOLTS 25 NOTE: CHANGES IN ZENER CURRENT DO NOT NOTE: EFFECT TEMPERATURE COEFFICIENTS 0 –4 0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.91345678L, LEAD LENGTH TO HEAT SINK (INCHES) VZ, ZENER VOLTAGE (VOLTS)

Figure 3. Typical Thermal Resistance Figure 4. Effect of Zener Current

versus Lead Length 70 RECTANGULAR 50 11 V–100 V NONREPETITIVE WAVEFORM TJ = 25°C PRIOR TO 30 5% DUTY CYCLE 3.3 V–10 V NONREPETITIVE INITIAL PULSE 10 10% DUTY CYCLE 20% DUTY CYCLE 0.01 0.02 0.05 0.1 0.2 0.512510 20 50 100 200 500 1000 PW, PULSE WIDTH (ms) This graph represents 90 percentile data points. For worst case design characteristics, multiply surge power by 2/3.

Figure 5. Maximum Surge Power

6-21 Ppk , PEAK SURGE POWER (WATTS) θJL , JUNCTION-TO-LEAD THERMAL RESISTANCE (mV/°C/W) θVZ , TEMPERATURE COEFFICIENT (mV/°C) θVZ , TEMPERATURE COEFFICIENT (mV/°C) θVZ , TEMPERATURE COEFFICIENT (mV/°C), 1000 1000 500 TJ = 25°C 700 TJ = 25°C VZ = 2.7 V iZ(rms) = 0.1 IZ(dc) 500 iZ(rms) = 0.1 IZ(dc) f = 60 Hz IZ = 1 mA f = 60 Hz 200 200 47 V 100 100 5 mA 50 27 V 20 20 20 mA 10 6.2 V 105522110.1 0.2 0.512510 20 50 1001235710 20 30 50 70 100 IZ, ZENER CURRENT (mA) VZ, ZENER CURRENT (mA)

Figure 6. Effect of Zener Current Figure 7. Effect of Zener Voltage

on Zener Impedance on Zener Impedance 10000 400 7000 300 TYPICAL LEAKAGE CURRENT 200 2000 AT 80% OF NOMINAL0VBIAS BREAKDOWN VOLTAGE 100 10001VBIAS 500 50 50 10 8 50% OF BREAKDOWN BIAS 1012510 20 50 100 5 VZ, NOMINAL VZ (VOLTS)

Figure 9. Typical Capacitance versus VZ

0.7 0.5 1000 MINIMUM +125°C 500 MAXIMUM 0.2 0.1 0.07 100 0.05 0.02 20 75°C 0.01 10 0.007 +25°C 0.005 25°C5 150°C 0°C 0.002 2 0.0011345678910 11 12 13 14 15 0.4 0.5 0.6 0.7 0.8 0.9 1 1.1 VZ, NOMINAL ZENER VOLTAGE (VOLTS) VF, FORWARD VOLTAGE (VOLTS)

Figure 8. Typical Leakage Current Figure 10. Typical Forward Characteristics

6-22IR, LEAKAGE CURRENT (µ A) ZZ, DYNAMIC IMPEDANCE (OHMS) I F, FORWARD CURRENT (mA) C, CAPACITANCE (pF) ZZ, DYNAMIC IMPEDANCE (OHMS), APPLICATION NOTE Since the actual voltage available from a given zener diode temperature and may be found as follows: is temperature dependent, it is necessary to determine junc- ∆TJL = θJLPD. tion temperature under any set of operating conditions in order to calculate its value. The following procedure is recom- θJL may be determined from Figure 3 for dc power condi- mended: tions. For worst-case design, using expected limits of IZ, limits Lead Temperature, T , should be determined from: of PD and the extremes of TJ(∆TJ) may be estimated. ChangesL in voltage, V T = θ P + T . Z , can then be found from: L LADA∆V = θVZ ∆TJ. θLA is the lead-to-ambient thermal resistance (°C/W) and PD is the power dissipation. The value forθθ, the zener voltage temperature coefficient, is found fromLA will vary and depends VZ on the device mounting method. θLA is generally 30 to 40°C/W Figure 2. for the various clips and tie points in common use and for Under high power-pulse operation, the zener voltage will printed circuit board wiring. vary with time and may also be affected significantly by the The temperature of the lead can also be measured using a zener resistance. For best regulation, keep current excursions thermocouple placed on the lead as close as possible to the tie as low as possible. point. The thermal mass connected to the tie point is normally Surge limitations are given in Figure 5. They are lower than large enough so that it will not significantly respond to heat would be expected by considering only junction temperature, surges generated in the diode as a result of pulsed operation as current crowding effects cause temperatures to be ex- once steady-state conditions are achieved. Using the mea- tremely high in small spots, resulting in device degradation sured value of T , the junction temperature may be deter- should the limits of Figure 5 be exceeded.L mined by: TJ = TL + ∆TJL. ∆TJL is the increase in junction temperature above the lead 6-23, *ELECTRICAL CHARACTERISTICS (TA = 25°C unless otherwise noted) VF = 1.2 V Max, IF = 200 mA for all types. Nominal Maximum Zener Impedance (Note 4) Leakage Current Zener Voltage Test Surge Current @ JEDEC VZ @ IZT Current TA = 25°C Type No. Volts IZT ZZT @ IZT ZZK @ IZK IZK IR VR ir – mA (Note 1) (Notes 2 and 3) mA Ohms Ohms mA µA Max Volts (Note 5) 1N4728A 3.3 76 10 400 1 100 1 1380 1N4729A 3.6 69 10 400 1 100 1 1260 1N4730A 3.9 64 9 400 1 50 1 1190 1N4731A 4.3 58 9 400 1 10 1 1070 1N4732A 4.7 53 8 500 1 10 1 970 1N4733A 5.1 49 7 550 1 10 1 890 1N4734A 5.6 45 5 600 1 10 2 810 1N4735A 6.2 41 2 700 1 10 3 730 1N4736A 6.8 37 3.5 700 1 10 4 660 1N4737A 7.5 34 4 700 0.5 10 5 605 1N4738A 8.2 31 4.5 700 0.5 10 6 550 1N4739A 9.1 28 5 700 0.5 10 7 500 1N4740A 10 25 7 700 0.25 10 7.6 454 1N4741A 11 23 8 700 0.25 5 8.4 414 1N4742A 12 21 9 700 0.25 5 9.1 380 1N4743A 13 19 10 700 0.25 5 9.9 344 1N4744A 15 17 14 700 0.25 5 11.4 304 1N4745A 16 15.5 16 700 0.25 5 12.2 285 1N4746A 18 14 20 750 0.25 5 13.7 250 1N4747A 20 12.5 22 750 0.25 5 15.2 225 1N4748A 22 11.5 23 750 0.25 5 16.7 205 1N4749A 24 10.5 25 750 0.25 5 18.2 190 1N4750A 27 9.5 35 750 0.25 5 20.6 170 1N4751A 30 8.5 40 1000 0.25 5 22.8 150 1N4752A 33 7.5 45 1000 0.25 5 25.1 135 1N4753A 36 7 50 1000 0.25 5 27.4 125 1N4754A 39 6.5 60 1000 0.25 5 29.7 115 1N4755A 43 6 70 1500 0.25 5 32.7 110 1N4756A 47 5.5 80 1500 0.25 5 35.8 95 1N4757A 51 5 95 1500 0.25 5 38.8 90 1N4758A 56 4.5 110 2000 0.25 5 42.6 80 1N4759A 62 4 125 2000 0.25 5 47.1 70 1N4760A 68 3.7 150 2000 0.25 5 51.7 65 1N4761A 75 3.3 175 2000 0.25 5 56 60 1N4762A 82 3 200 3000 0.25 5 62.2 55 1N4763A 91 2.8 250 3000 0.25 5 69.2 50 1N4764A 100 2.5 350 3000 0.25 5 76 45 *Indicates JEDEC Registered Data. NOTE 1. TOLERANCE AND TYPE NUMBER DESIGNATION NOTE 4. ZENER IMPEDANCE (ZZ) DERIVATION The JEDEC type numbers listed have a standard tolerance on the nominal zener voltage of The zener impedance is derived from the 60 cycle ac voltage, which results when an ac cur- ±5%. C for ±2%, D for ±1%. rent having an rms value equal to 10% of the dc zener current (IZT or IZK) is superimposed on IZT or IZK. NOTE 2. SPECIALS AVAILABLE INCLUDE: Nominal zener voltages between the voltages shown and tighter voltage tolerances. For detailed information on price, availability, and delivery, contact your nearest Motorola rep- NOTE 5. SURGE CURRENT (ir) NON-REPETITIVE resentative. The rating listed in the electrical characteristics table is maximum peak, non-repetitive, re- NOTE 3. ZENER VOLTAGE (VZ) MEASUREMENT verse surge current of 1/2 square wave or equivalent sine wave pulse of 1/120 second dura- Motorola guarantees the zener voltage when measured at 90 seconds while maintaining the tion superimposed on the test current, IZT, per JEDEC registration; however, actual device lead temperature (TL) at 30°C ± 1°C, 3/8″ from the diode body. capability is as described in Figure 5 of the General Data — DO-41 Glass. 6-24,

ELECTRICAL CHARACTERISTICS (TA = 25°C unless otherwise noted.) (VF = 1.2 V Max, IF = 200 mA for all types.)

Zener Voltage Zener Impedance Leakage VZT (V) ZZ (ohms) Current Surge (Notes 2 and 3) Test (Note 4) (µA) Current Current Max at I TA = 25°C Type VZ VZ I

Z

ZT Max IR ir (mA) (Note 1) Min Max (mA) at IZT (mA) VR (V) Max (Note 5) BZX85C3V3RL 3.1 3.5 80 20 4001160 1380 BZX85C3V6RL 3.4 3.8 60 15 5001130 1260 BZX85C3V9RL 3.7 4.1 60 15 5001151190 BZX85C4V3RL 4 4.6 50 13 5001131070 BZX85C4V7RL 4.4 5 45 13 600 1 1.5 3 970 BZX85C5V1RL 4.8 5.4 45 10 500121890 BZX85C5V6RL 5.2 6 45 7 400121810 BZX85C6V2RL 5.8 6.6 35 4 300131730 BZX85C6V8RL 6.4 7.2 35 3.5 300141660 BZX85C7V5RL 7 7.9 35 3 200 0.5 4.5 1 605 BZX85C8V2RL 7.7 8.7 25 5 200 0.551550 BZX85C9V1RL 8.5 9.6 25 5 200 0.5 6.5 1 500 BZX85C10RL 9.4 10.6 25 7 200 0.5 7 0.5 454 BZX85C11RL 10.4 11.6 20 8 300 0.5 7.7 0.5 414 BZX85C12RL 11.4 12.7 20 9 350 0.5 8.4 0.5 380 BZX85C13RL 12.4 14.1 20 10 400 0.5 9.1 0.5 344 BZX85C15RL 13.8 15.6 15 15 500 0.5 10.5 0.5 304 BZX85C16RL 15.3 17.1 15 15 500 0.5 11 0.5 285 BZX85C18RL 16.8 19.1 15 20 500 0.5 12.5 0.5 250 BZX85C20RL 18.8 21.2 10 24 600 0.5 14 0.5 225 BZX85C22RL 20.8 23.3 10 25 600 0.5 15.5 0.5 205 BZX85C24RL 22.8 25.6 10 25 600 0.5 17 0.5 190 BZX85C27RL 25.1 28.9 8 30 750 0.25 19 0.5 170 BZX85C30RL 28 32 8 30 1000 0.25 21 0.5 150 BZX85C33RL 31 35 8 35 1000 0.25 23 0.5 135 BZX85C36RL 34 38 8 40 1000 0.25 25 0.5 125 BZX85C39RL 37 41 6 45 1000 0.25 27 0.5 115 BZX85C43RL 40 46 6 50 1000 0.25 30 0.5 110 BZX85C47RL 44 50 4 90 1500 0.25 33 0.5 95 BZX85C51RL 48 54 4 115 1500 0.25 36 0.5 90 BZX85C56RL 52 60 4 120 2000 0.25 39 0.5 80 BZX85C62RL 58 66 4 125 2000 0.25 43 0.5 70 BZX85C68RL 64 72 4 130 2000 0.25 47 0.5 65 BZX85C75RL 70 80 4 150 2000 0.25 51 0.5 60 BZX85C82RL 77 87 2.7 200 3000 0.25 56 0.5 55 BZX85C91RL 85 96 2.7 250 3000 0.25 62 0.5 50 BZX85C100RL 96 106 2.7 350 3000 0.25 68 0.5 45 NOTE 1. TOLERANCE AND TYPE NUMBER DESIGNATION NOTE 4. ZENER IMPEDANCE (ZZ) DERIVATION The type numbers listed have zener voltage min/max limits as shown. Device tolerance of The zener impedance is derived from the 1 kHz cycle ac voltage, which results when an ac ±2% are indicated by a “B” instead of “C.” current having an rms value equal to 10% of the dc zener current (IZT) or (IZK) is superim- posed on IZT or I .NOTE 2. SPECIALS AVAILABLE INCLUDE: ZK Nominal zener voltages between the voltages shown and tighter voltage tolerances. For detailed information on price, availability, and delivery, contact your nearest Motorola rep- NOTE 5. SURGE CURRENT (i ) NON-REPETITIVE resentative. r The rating listed in the electrical characteristics table is maximum peak, non-repetitive, re- NOTE 3. ZENER VOLTAGE (VZ) MEASUREMENT verse surge current of 1/2 square wave or equivalent sine wave pulse of 1/120 second dura- VZ is measured after the test current has been applied to 40 ± 10 msec., while maintaining tion superimposed on the test current IZT. However, actual device capability is as described the lead temperature (TL) at 30°C ± 1°C, 3/8″ from the diode body. in Figure 5 of General Data DO-41 glass. 6-25,

ELECTRICAL CHARACTERISTICS (TA = 25°C unless otherwise noted) VF = 1.2 V Max, IF = 200 mA for all types.

Zener Impedance Surge Zener Voltage (V) (Note 4) Blocking Current (Notes 2 and 3) Test Current f = 1 kHz (ohms) Volt Min (V) TA = 25°C Type No. IZT ir (ma) (Note 1) VZ Min VZ Max (mA) Typ Max IR = 1 µA (Note 5) MZPY3.9RL 3.7 4.1 10047— 1190 MZPY4.3RL 4 4.6 10047— 1070 MZPY4.7RL 4.4 5 10047— 970 MZPY5.1RL 4.8 5.4 100250.7 890 MZPY5.6RL 5.2 6 100121.5 810 MZPY6.2RL 5.8 6.6 100122730 MZPY6.8RL 6.4 7.2 100123660 MZPY7.5RL 7 7.9 100125605 MZPY8.2RL 7.7 8.7 100126550 MZPY9.1RL 8.5 9.6 50247500 MZPY10RL 9.4 10.6 50247.5 454 MZPY11RL 10.4 11.6 50378.5 414 MZPY12RL 11.4 12.7 50379380 MZPY13RL 12.4 14.1 504910 344 MZPY15RL 14.2 15.8 504911 304 MZPY16RL 15.3 17.1 25 5 10 12 285 MZPY18RL 16.8 19.1 25 5 11 14 250 MZPY20RL 18.8 21.2 25 6 12 15 225 MZPY22RL 20.8 23.3 25 7 13 17 205 MZPY24RL 22.8 25.6 25 8 14 18 190 MZPY27RL 25.1 28.9 25 9 15 20 170 MZPY30RL 28 32 25 10 20 22.5 150 MZPY33RL 31 35 25 11 20 25 135 MZPY36RL 34 38 10 25 60 27 125 MZPY39RL 37 41 10 30 60 29 115 MZPY43RL 40 46 10 35 80 32 110 MZPY47RL 44 50 10 40 80 35 95 MZPY51RL 48 54 10 45 100 38 90 MZPY56RL 52 60 10 50 100 42 80 MZPY62RL 58 66 10 60 130 47 70 MZPY68RL 64 72 10 65 130 51 65 MZPY75RL 70 79 10 70 160 56 60 MZPY82RL 77 88 10 80 160 61 55 MZPY91RL 85 96 5 120 250 68 50 MZPY100RL 94 106 5 130 250 75 45 NOTE 1. TOLERANCE AND TYPE NUMBER DESIGNATION For detailed information on price, availability, and delivery, contact your nearest Motorola rep- The type numbers listed have zener voltage min/max limits as shown. Device tolerance of resentative. ±2% are indicated by a “C” and ±1% by a “D” suffix. NOTE 3. ZENER VOLTAGE (VZ) MEASUREMENT NOTE 2. SPECIALS AVAILABLE INCLUDE: VZ is measured after the test current has been applied to 40 ± 10 msec., while maintaining Nominal zener voltages between the voltages shown and tighter voltage tolerances. the lead temperature (TL) at 30°C ± 1°C, 3/8″ from the diode body. 6-26,

Zener Voltage Regulator Diodes — Axial Leaded

1–1.3 Watt DO-41 Glass

B

NOTES: 1. ALL RULES AND NOTES ASSOCIATED WITH JEDEC DO-41 OUTLINE SHALL APPLY. K D 2. POLARITY DENOTED BY CATHODE BAND.3. LEAD DIAMETER NOT CONTROLLED WITHINFFDIMENSION. MILLIMETERS INCHES DIM MIN MAX MIN MAXAA4.07 5.20 0.160 0.205 B 2.04 2.71 0.080 0.107 D 0.71 0.86 0.028 0.034FF— 1.27 — 0.050 K 27.94 — 1.100 —

K

CASE 59-03 DO-41

GLASS

(Refer to Section 10 for Surface Mount, Thermal Data and Footprint Information.)

MULTIPLE PACKAGE QUANTITY (MPQ) REQUIREMENTS

Package Option Type No. Suffix MPQ (Units) Tape and Reel RL, RL2 6K Tape and Ammo TA, TA2 4K NOTE: 1. The “2” suffix refers to 26 mm tape spacing. (Refer to Section 10 for more information on Packaging Specifications.) NOTE 4. ZENER IMPEDANCE (ZZ) DERIVATION 6-27, The zener impedance is derived from the 1 kHz cycle ac voltage, which results when an ac current having an rms value equal to 10% of the dc zener current (IZT) of (IZK) is superim- posed on IZT or IZK. NOTE 5. SURGE CURRENT (ir) NON-REPETITIVE The rating listed in the electrical characteristics table is maximum peak, non-repetitive, re- verse surge current of 1/2 square wave or equivalent sine wave pulse of 1/120 second dura- tion superimposed on the test current IZT, however, actual device capability is as described in Figure 5 of General Data DO-41 glass. 6-28]
15

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