Download: SEMICONDUCTOR 5 Watt Surmetic 40 1N5333B Silicon Zener Diodes through 1N5388B

MOTOROLA SEMICONDUCTOR TECHNICAL DATA 5 Watt Surmetic 40 1N5333B Silicon Zener Diodes through 1N5388B This is a complete series of 5 Watt Zener Diodes with tight limits and better operating characteristics that reflect the superior capabilities of silicon-oxide-passivated junctions. All this is in an axial-lead, transfer-molded plastic package that offers protection in all com- mon environmental conditions. 5 WATT Specification Features: ZENER REGULATOR • Up to 180 Watt Surge Rating @ 8.3 ms DIODES • Maximum Limits Guaranteed on Seven Electrical Parameters 3.3–200 VOLTS Mechanical Characterist...
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MOTOROLA SEMICONDUCTOR TECHNICAL DATA

5 Watt Surmetic 40 1N5333B

Silicon Zener Diodes through

1N5388B This is a complete series of 5 Watt Zener Diodes with tight limits and better operating characteristics that reflect the superior capabilities of silicon-oxide-passivated junctions. All this is in an axial-lead, transfer-molded plastic package that offers protection in all com- mon environmental conditions. 5 WATT Specification Features: ZENER REGULATOR • Up to 180 Watt Surge Rating @ 8.3 ms DIODES • Maximum Limits Guaranteed on Seven Electrical Parameters 3.3–200 VOLTS Mechanical Characteristics: CASE: Void-free, transfer-molded, thermosetting plastic FINISH: All external surfaces are corrosion resistant and leads are readily solderable POLARITY: Cathode indicated by color band. When operated in zener mode, cathode will be positive with respect to anode MOUNTING POSITION: Any WEIGHT: 0.7 gram (approx) WAFER FAB LOCATION: Phoenix, Arizona ASSEMBLY/TEST LOCATION: Seoul, Korea CASE 17

PLASTIC

MAXIMUM RATINGS Rating Symbol Value Unit DC Power Dissipation @ TL = 75°C PD 5 Watts Lead Length = 3/8″ Derate above 75°C 40 mW/°C Operating and Storage Junction Temperature Range TJ, Tstg – 65 to +200 °C L = LEAD LENGTH L = TO HEAT SINK L = 1/8″ L = (SEE FIGURE 5) L = 3/8″ L = 1″ 0 20 40 60 80 100 120 140 160 180 200 TL, LEAD TEMPERATURE (°C) Figure 1. Power Temperature Derating Curve 6-1 PD , MAXIMUM POWER DISSIPATION (WATTS), ELECTRICAL CHARACTERISTICS (TA = 25°C unless otherwise noted, VF = 1.2 Max @ IF = 1 A for all types) Nominal Max Reverse Maximum Zener Max Zener Impedance Leakage Current Max Regulator Voltage Test Surge Max Voltage Current JEDEC VZ @ IZT Current ZZT @IZT ZZK @ IZK = 1 mA Current Regulation IZM Type No. Volts IZT Ohms Ohms IR @ VR ir, Amps ∆VZ, Volt mA (Note 1) (Note 2) mA (Note 2) (Note 2) µA Volts (Note 3) (Note 4) (Note 5) 1N5333B 3.3 380 3 400 300 1 20 0.85 1440 1N5334B 3.6 350 2.5 500 150 1 18.7 0.8 1320 1N5335B 3.9 320 2 500 50 1 17.6 0.54 1220 1N5336B 4.3 290 2 500 10 1 16.4 0.49 1100 1N5337B 4.7 260 2 4505115.3 0.44 1010 1N5338B 5.1 240 1.5 4001114.4 0.39 930 1N5339B 5.6 220 1 4001213.4 0.25 865 1N5340B 6 200 1 3001312.7 0.19 790 1N5341B 6.2 200 1 2001312.4 0.1 765 1N5342B 6.8 175 1 200 10 5.2 11.5 0.15 700 1N5343B 7.5 175 1.5 200 10 5.7 10.7 0.15 630 1N5344B 8.2 150 1.5 200 10 6.2 10 0.2 580 1N5345B 8.7 150 2 200 10 6.6 9.5 0.2 545 1N5346B 9.1 150 2 150 7.5 6.9 9.2 0.22 520 1N5347B 10 125 2 125 5 7.6 8.6 0.22 475 1N5348B 11 125 2.5 125 5 8.4 8 0.25 430 1N5349B 12 100 2.5 125 2 9.1 7.5 0.25 395 1N5350B 13 100 2.5 100 1 9.9 7 0.25 365 1N5351B 14 100 2.5 75 1 10.6 6.7 0.25 340 1N5352B 15 75 2.5 75 1 11.5 6.3 0.25 315 1N5353B 16 75 2.5 75 1 12.2 6 0.3 295 1N5354B 17 70 2.5 75 0.5 12.9 5.8 0.35 280 1N5355B 18 65 2.5 75 0.5 13.7 5.5 0.4 265 1N5356B 19 65 3 75 0.5 14.4 5.3 0.4 250 1N5357B 20 65 3 75 0.5 15.2 5.1 0.4 237 1N5358B 22 50 3.5 75 0.5 16.7 4.7 0.45 216 1N5359B 24 50 3.5 100 0.5 18.2 4.4 0.55 198 1N5360B 25 50 4 110 0.5 19 4.3 0.55 190 1N5361B 27 50 5 120 0.5 20.6 4.1 0.6 176 1N5362B 28 50 6 130 0.5 21.2 3.9 0.6 170 1N5363B 30 40 8 140 0.5 22.8 3.7 0.6 158 1N5364B 33 40 10 150 0.5 25.1 3.5 0.6 144 1N5365B 36 30 11 160 0.5 27.4 3.3 0.65 132 1N5366B 39 30 14 170 0.5 29.7 3.1 0.65 122 1N5367B 43 30 20 190 0.5 32.7 2.8 0.7 110 1N5368B 47 25 25 210 0.5 35.8 2.7 0.8 100 1N5369B 51 25 27 230 0.5 38.8 2.5 0.9 93 1N5370B 56 20 35 280 0.5 42.6 2.3 1 86 1N5371B 60 20 40 350 0.5 42.5 2.2 1.2 79 1N5372B 62 20 42 400 0.5 47.1 2.1 1.35 76 1N5373B 68 20 44 500 0.5 51.7 2 1.5 70 1N5374B 75 20 45 620 0.5 56 1.9 1.6 63 1N5375B 82 15 65 720 0.5 62.2 1.8 1.8 58 1N5376B 87 15 75 760 0.5 66 1.7 2 54.5 1N5377B 91 15 75 760 0.5 69.2 1.6 2.2 52.5 1N5378B 100 12 90 800 0.5 76 1.5 2.5 47.5 1N5379B 110 12 125 1000 0.5 83.6 1.4 2.5 43 1N5380B 120 10 170 1150 0.5 91.2 1.3 2.5 39.5 1N5381B 130 10 190 1250 0.5 98.8 1.2 2.5 36.6 1N5382B 140 8 230 1500 0.5 106 1.2 2.5 34 (continued) 6-2,

ELECTRICAL CHARACTERISTICS — continued (TA = 25°C unless otherwise noted, VF = 1.2 Max @ IF = 1 A for all types) Nominal Max Reverse Maximum Zener Max Zener Impedance Leakage Current Max Regulator Voltage Test Surge Max Voltage Current JEDEC VZ @ IZT Current ZZT @IZT ZZK @ IZK = 1 mA Current Regulation IZM Type No. Volts IZT Ohms Ohms IR @ VR ir, Amps ∆VZ, Volt mA

(Note 1) (Note 2) mA (Note 2) (Note 2) µA Volts (Note 3) (Note 4) (Note 5) 1N5383B 150 8 330 1500 0.5 114 1.1 3 31.6 1N5384B 160 8 350 1650 0.5 122 1.1 3 29.4 1N5385B 170 8 380 1750 0.5 1291328 1N5386B 180 5 430 1750 0.5 1371426.4 1N5387B 190 5 450 1850 0.5 144 0.9 5 25 1N5388B 200 5 480 1850 0.5 152 0.9 5 23.6 NOTE 1. TOLERANCE AND TYPE NUMBER DESIGNATION NOTE 4. VOLTAGE REGULATION (∆VZ) The JEDEC type numbers shown indicate a tolerance of ±5%. Test conditions for voltage regulation are as follows: VZ measurements are made at 10% and then at 50% of the IZ max value listed in the electrical characteristics table. The test current time duration for each VZ measurement is 40 ± 10 ms. (T = 25°C +8, –2°C). Mounting contactNOTE 2. ZENER VOLTAGE (VZ) AND IMPEDANCE (ZZT & ZZK)

A

located as specified in Note 2. Test conditions for zener voltage and impedance are as follows: IZ is applied 40 ± 10 ms prior to reading. Mounting contacts are located 3/8″ to 1/2″ from the inside edge of mounting clips to the body of the diode. (T = 25°C +8, –2°C). NOTE 5. MAXIMUM REGULATOR CURRENT (IZM)A The maximum current shown is based on the maximum voltage of a 5% type unit, therefore, it applies only to the B-suffix device. The actual IZM for any device may not exceed the value NOTE 3. SURGE CURRENT (ir) of 5 watts divided by the actual VZ of the device. TL = 75°C at 3/8″ maximum from the device Surge current is specified as the maximum allowable peak, non-recurrent square-wave cur- body. rent with a pulse width, PW, of 8.3 ms. The data given in Figure 6 may be used to find the maximum surge current for a square wave of any pulse width between 1ms and 1000 ms by NOTE 6. SPECIALS AVAILABLE INCLUDE: plotting the applicable points on logarithmic paper. Examples of this, using the 3.3 V and 200 V zeners, are shown in Figure 7. Mounting contact located as specified in Note 3. (TA = Nominal zener voltages between the voltages shown and tighter voltage tolerance such as 25°C +8, –2°C.) ±1% and ±2%. Consult factory.

TEMPERATURE COEFFICIENTS

10 300

RANGE

2 20

RANGE

0 10 –25345678910 0 20 40 60 80 100 120 140 160 180 200 220 VZ, ZENER VOLTAGE @ IZT (VOLTS) VZ, ZENER VOLTAGE @ IZT (VOLTS)

Figure 2. Temperature Coefficient-Range Figure 3. Temperature Coefficient-Range

for Units 3 to 10 Volts for Units 10 to 220 Volts

Motorola TVS/Zener Device Data 5 Watt Surmetic 40 Data Sheet

6-3 θVZ, TEMPERATURE COEFFICIENT (mV/°C) @ I ZT θVZ, TEMPERATURE COEFFICIENT (mV/°C) @ I ZT, 10 D = 0.55D= 0.2 PPK t1 D = 0.1 2 t2 D = 0.05 1 DUTY CYCLE, D = t1/t2 D = 0.01 NOTE: BELOW 0.1 SECOND, THERMAL SINGLE PULSE ∆ TJL = θJL(t)PPK 0.5 NOTE: RESPONSE CURVE IS APPLICABLE REPETITIVE PULSES ∆ TJL = θJL(t, D)PPK D = 0 NOTE: TO ANY LEAD LENGTH (L).0.2 0.00 0.00 0.01 0.05 0.1 0.51510 20 50 10015t, TIME (SECONDS)

Figure 4. Typical Thermal Response L, Lead Length = 3/8 Inch

40 40 PW = 1 ms* PW = 8.3 ms* LL110 0.4 *SQUARE WAVE PRIMARY PATH OF PW = 100 ms* CONDUCTION IS THROUGH 0.2 THE CATHODE LEAD PW = 1000 ms* 0 0.1 0 0.2 0.4 0.6 0.81346810 20 30 40 60 80 100 200 L, LEAD LENGTH TO HEAT SINK (INCH) NOMINAL VZ (V)

Figure 5. Typical Thermal Resistance Figure 6. Maximum Non-Repetitive Surge Current

versus Nominal Zener Voltage (See Note 3) T = 25°C 10 V = 3.3 V 1000Z TC = 25°C 1 10 0.5 VZ = 200V10.2 PLOTTED FROM INFORMATION GIVEN IN FIGURE 6 0.1 0.1 1 10 100 10012345678910 PW, PULSE WIDTH (ms) 0 VZ, ZENER VOLTAGE (VOLTS)

Figure 7. Peak Surge Current versus Pulse Width Figure 8. Zener Voltage versus Zener Current

(See Note 3) VZ = 3.3 thru 10 Volts 6-4ir, PEAK SURGE CURRENT (AMPS) θJL, JUNCTION-TO-LEAD THERMAL RESISTANCE (°C/W) θJL (t, D), TRANSIENT THERMAL RESISTANCE JUNCTION-TO-LEAD (°C/W) I Z , ZENER CURRENT (mA) i r , PEAK SURGE CURRENT (AMPS), T = 25°C 100 100 10 10110.1 0.1 10 20 30 40 50 60 70 80 80 100 120 140 160 180 200 220 VZ, ZENER VOLTAGE (VOLTS) VZ, ZENER VOLTAGE (VOLTS) Figure 9. Zener Voltage versus Zener Current Figure 10. Zener Voltage versus Zener Current VZ = 11 thru 75 Volts VZ = 82 thru 200 Volts APPLICATION NOTE Since the actual voltage available from a given zener diode For worst-case design, using expected limits of IZ, limits of is temperature dependent, it is necessary to determine junc- PD and the extremes of TJ (∆TJ) may be estimated. Changes tion temperature under any set of operating conditions in order in voltage, VZ, can then be found from: to calculate its value. The following procedure is recom- ∆V = θVZ ∆TJ mended: θ , the zener voltage temperature coefficient, is found from Lead Temperature, TL, should be determined from:

VZ

Figures 2 and 3. TL = θLA PD + TA Under high power-pulse operation, the zener voltage will θLA is the lead-to-ambient thermal resistance and PD is the vary with time and may also be affected significantly by the power dissipation. zener resistance. For best regulation, keep current excursions Junction Temperature, TJ, may be found from: as low as possible. TJ = TL + ∆TJL Data of Figure 4 should not be used to compute surge capa- bility. Surge limitations are given in Figure 6. They are lower ∆TJL is the increase in junction temperature above the lead than would be expected by considering only junction tempera- temperature and may be found from Figure 4 for a train of ture, as current crowding effects cause temperatures to be ex- power pulses or from Figure 5 for dc power. tremely high in small spots resulting in device degradation ∆TJL = θJL PD should the limits of Figure 6 be exceeded. Motorola TVS/Zener Device Data 5 Watt Surmetic 40 Data Sheet 6-5IZ, ZENER CURRENT (mA) I Z , ZENER CURRENT (mA),

Zener Voltage Regulator Diodes — Axial Leaded

5 Watt Surmetic 40

B

NOTE: D 1. LEAD DIAMETER & FINISH NOT CONTROLLED WITHIN DIM F.

K

INCHES MILLIMETERS

F

2 DIM MIN MAX MIN MAX A 0.330 0.350 8.38 8.89 B 0.130 0.145 3.30 3.68 D 0.037 0.043 0.94 1.09AF— 0.050 — 1.27 K 1.000 1.250 25.40 31.75

F K

CASE 17-02

PLASTIC

(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 4K Tape and Ammo TA 2K (Refer to Section 10 for more information on Packaging Specifications.) 6-6]
15

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