P4KE16 [TSC]

Transient Voltage Suppressor Diodes; 瞬态电压抑制二极管


型号：	P4KE16
厂家：	TAIWAN SEMICONDUCTOR COMPANY, LTD
描述：	Transient Voltage Suppressor Diodes 瞬态电压抑制二极管二极管
文件：	总4页 (文件大小：91K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

P4KE SERIES

Transient Voltage Suppressor Diodes

Voltage Range

6.8 to 440 Volts

400 Watts Peak Power

DO-41

Features

ꢀ

UL Recognized File # E-96005

Plastic package has Underwriters Laboratory Flammability

ꢀ

Classification 94V-0

ꢀ

400W surge capability at 10 x 100us waveform, duty cycle:

0.01%

ꢀ

Excellent clamping capability

Low zener impedance

Fast response time: Typically less than 1.0ps from 0 volts to

VBR for unidirectional and 5.0 ns for bidirectional

Typical I_Rless than 1 uA above 10V

High temperature soldering guaranteed: 260°C / 10 seconds

/ .375”,(9.5mm) lead length / 5lbs.,(2.3kg) tension

ꢀ

Mechanical Data

ꢀ

Case: Molded plastic

ꢀ

Lead: Axial leads, solderable per MIL-STD-

202, Method 208

ꢀ

Polarity: Color band denotes cathode except bipolar

Weight: 0.012 ounce,0.3 gram

Dimensions in inches and (millimeters)

Maximum Ratings and Electrical Characteristics

Rating at 25°C ambient temperature unless otherwise specified.

Single phase, half wave, 60 Hz, resistive or inductive load.

For capacitive load, derate current by 20%

Type Number

Symbol

Value

Units

Peak Power Dissipation at T_A=25°C, Tp=1ms

(Note 1)

P_PK

Minimum 400

Watts

Steady State Power Dissipation at T_L=75°C

Lead Lengths .375”, 9.5mm (Note 2)

Peak Forward Surge Current, 8.3 ms Single Half

Sine-wave Superimposed on Rated Load

(JEDEC method) (Note 3)

P_D

1.0

Watts

Amps

I_FSM

40.0

Maximum Instantaneous Forward Voltage at

25.0A for Unidirectional Only (Note 4)

V_F

3.5 / 6.5

Volts

°C

Operating and Storage Temperature Range

T_J, T_STG

-55 to + 175

Notes: 1. Non-repetitive Current Pulse Per Fig. 3 and Derated above T_A=25^OC Per Fig. 2.

Notes: 2. Mounted on Copper Pad Area of 1.6 x 1.6” (40 x 40 mm) Per Fig. 4.

Notes: 3. 8.3ms Single Half Sine-wave or Equivalent Square Wave, Duty Cycle=4 Pulses Per Minutes

Notes: 3. Maximum.

≤

Notes: 4. V_F=3.5V for Devices of V_BR200V and V_F=6.5V Max. for Devices V_BR>200V.

Devices for Bipolar Applications

Notes: 1. For Bidirectional Use C or CA Suffix for Types P4KE6.8 thru Types P4KE440.

Notes: 2. Electrical Characteristics Apply in Both Directions.

- 628 -

RATINGS AND CHARACTERISTIC CURVES (P4KE SERIES)

FIG.1- PEAK PULSE POWER RATING CURVE

FIG.2- PULSE DERATING CURVE

100

NON-REPETITIVE

PULSE WAVEFORM

SHOWN in FIG.3

TJ=25⁰C

0.1

0.1ms

1.0ms

10ms

100ms

10ms

1.0ms

100

125

150

175

200

TA, AMBIENT TEMPERATURE, ^oC

tp, PULSE WIDTH, sec.

FIG.3- PULSE WAVEFORM

FIG.4- STEADY STATE POWER DERATING CURVE

1.00

0.75

0.50

0.25

150

PULSE WIDTH (td) is DEFINED

as the POINT WHERE the PEAK

CURRENT DECAYS

L=0.375"(9.5mm)

LEAD LENGTHS

60Hz

RESISTIVE OR INDUCTIVE LOAD

tr=10msec.

to 50% of lPPM

PEAK VALUE

PPM

100

HALF VALUE- lPPM

1.6 X 1.6 X .040"

(40 X 40 X 1mm.)

COPPER HEAT SINKS

10/1000 sec. WAVEFORM

as DEFINED by R.E.A.

1.0

2.0

3.0

4.0

100

125

150

175

200

TL, LEAD TEMPERATURE, ^oC

t, TIME, ms

FIG.5- MAXIMUM NON-REPETITIVE FORWARD SURGE

CURRENT UNIDIRECTIONAL ONLY

FIG.7- TYPICAL JUNCTION CAPACITANCE

UNIDIRECTIONAL

100,000

Tj=Tj max.

8.3ms Single Half Sine Wave

JEDEC Method

Tj=25⁰C

f=1.0MHz

Vsig=50mVp-p

10,000

MEASURED at

ZERO BIAS

60 80 100

NUMBER OF CYCLES AT 60Hz

1,000

MEASURED at

STAND-OFF

VOLTAGE, VWM

FIG.6- TYPICAL REVERSE LEAKAGE CHARACTERASTICS

100

MEASURED AT DEVICES

STAND-OFF

VOLTAGE, VWM

200

100

V(BR), BREAKDOWN VOLTAGE. VOLTS

0.1

TJ=25⁰C

0.01

400

100

200

300

500

V(BR), BREAKDOWN VOLTAGE. VOLTS

- 629 -

ELECTRICAL CHARACTERISTICS (TA=25^OC unless otherwise noted)

Test

Current

@IT

Stand-Off

Voltage

VWM

Maximum

Reverse Leakage

at VWM

Maximum

Peak Pulse

Current IPPM

Maximum

Clamping

Voltage at IPPM

Maximum

Temperature

Coefficient

of VBR(% / ^OC)

Breakdown Voltage

VBR

(Volts) (Note 1)

Device

Nominal

Voltage

(Volts)

Min

Max

(mA)

(Volts)

ID (uA)

(Note 2)(Amps)

VC(Volts)

P4KE6.8

6.8

7.5

8.2

9.1

6.12

6.46

6.75

7.13

7.38

7.79

8.19

8.65

9.00

9.50

9.90

10.5

10.8

11.4

11.7

12.4

13.5

14.3

14.4

15.2

16.2

17.1

18.0

19.0

19.8

20.9

21.6

22.8

24.3

25.7

27.0

28.5

29.7

31.4

32.4

34.2

35.1

37.1

38.7

40.9

42.3

44.7

45.9

48.5

50.4

53.2

55.8

58.9

61.2

64.6

67.5

71.3

73.8

77.9

81.9

86.5

90.0

95.0

99.0

105.0

108.0

114.0

117.0

124.0

135.0

143.0

144.0

152.0

153.0

162.0

171.0

180.0

190.0

198.0

209.0

225.0

237.0

270.0

285.0

315.0

332.0

360.0

380.0

396.0

418.0

7.48

7.14

8.25

7.88

9.02

8.61

10.0

9.55

11.0

10.5

12.1

11.6

13.2

12.6

14.3

13.7

16.5

15.8

17.6

16.8

19.8

18.9

22.0

21.0

24.2

23.1

26.4

25.2

29.7

28.4

33.0

31.5

36.3

34.7

39.6

37.8

42.9

41.0

47.3

45.2

51.7

49.4

56.1

53.6

61.6

58.8

68.2

65.1

74.8

71.4

82.5

78.8

90.2

86.1

100.0

95.5

110.0

105.0

121.0

116.0

132.0

126.0

143.0

137.0

165.0

158.0

176.0

168.0

187.0

179.0

198.0

189.0

220.0

210.0

242.0

231.0

275.0

263.0

330.0

315.0

385.0

368.0

440.0

420.0

484.0

462.0

5.50

5.80

6.05

6.40

6.63

7.02

7.37

7.78

8.10

8.55

8.92

9.40

9.72

10.2

10.5

11.1

12.1

12.8

12.9

13.6

14.5

15.3

16.2

17.1

17.8

18.8

19.4

20.5

21.8

23.1

24.3

25.6

26.8

28.2

29.1

30.8

31.6

33.3

34.8

36.8

38.1

40.2

41.3

43.6

45.4

47.8

50.2

53.0

55.1

58.1

60.7

64.1

66.4

70.1

73.7

77.8

81.0

85.5

89.2

94.0

97.2

102.0

105.0

111.0

121.0

128.0

130.0

136.0

138.0

145.0

146.0

154.0

162.0

171.0

175.0

185.0

202.0

214.0

243.0

256.0

284.0

300.0

324.0

342.0

356.0

376.0

1000

500

200

10.8

10.5

11.7

11.3

12.5

12.1

13.8

13.4

15.0

14.5

16.2

15.6

17.3

16.7

19.0

18.2

22.0

21.2

23.5

22.5

26.5

25.5

29.1

27.7

31.9

30.6

34.7

33.2

39.1

37.5

43.5

41.4

47.7

45.7

52.0

49.9

56.4

53.9

61.9

59.3

67.8

64.8

73.5

70.1

80.5

77.0

89.0

85.0

98.0

0.057

0.061

0.065

0.068

0.073

0.075

0.078

0.081

0.084

0.086

0.088

0.090

0.092

0.094

0.096

0.097

0.098

0.099

0.100

0.101

0.102

0.103

0.104

0.105

0.106

0.107

0.108

0.110

P4KE6.8A

P4KE7.5

P4KE7.5A

P4KE8.2

P4KE8.2A

P4KE9.1

P4KE9.1A

P4KE10

P4KE10A

P4KE11

P4KE11A

P4KE12

P4KE12A

P4KE13

P4KE13A

P4KE15

P4KE15A

P4KE16

P4KE16A

P4KE18

P4KE18A

P4KE20

P4KE20A

P4KE22

P4KE22A

P4KE24

P4KE24A

P4KE27

P4KE27A

P4KE30

P4KE30A

P4KE33

P4KE33A

P4KE36

P4KE36A

P4KE39

P4KE39A

P4KE43

P4KE43A

P4KE47

P4KE47A

P4KE51

P4KE51A

P4KE56

P4KE56A

P4KE62

P4KE62A

P4KE68

K4PE68A

P4KE75

P4KE75A

P4KE82

1.0

5.0

17.8

18.6

16.5

13.7

12.6

10.7

11.0

9.6

8.8

9.0

8.0

8.4

7.4

7.7

6.7

7.0

6.2

6.4

5.7

6.0

5.2

5.4

4.7

5.0

4.2

4.5

3.8

4.0

3.5

3.7

3.2

3.3

2.9

3.0

2.6

2.7

2.4

2.5

2.2

2.3

1.9

2.0

1.8

1.9

1.7

1.8

1.6

1.7

1.4

1.51

1.2

1.3

1.1

1.2

0.97

1.0

0.83

0.87

0.73

0.76

0.66

0.69

92.0

108.0

103.0

118.0

113.0

131.0

125.0

144.0

137.0

158.0

152.0

173.0

165.0

187.0

179.0

215.0

207.0

230.0

219.0

244.0

234.0

258.0

246.0

287.0

274.0

344.0

328.0

360.0

344.0

430.0

414.0

504.0

482.0

574.0

548.0

631.0

600.0

P4KE82A

P4KE91

P4KE91A

P4KE100

P4KE100A

P4KE110

P4KE110A

P4KE120

P4KE120A

P4KE130

P4KE130A

P4KE150

P4KE150A

P4KE160

P4KE160A

P4KE170

P4KE170A

P4KE180

P4KE180A

P4KE200

P4KE200A

P4KE220

P4KE220A

P4KE250

P4KE250A

P4KE300

P4KE300A

P4KE350

P4KE350A

P4KE400

P4KE400A

P4KE440

P4KE440A

100

110

120

130

150

160

170

180

200

220

250

300

350

400

440

Notes:

1. V^BRmeasured after I^Tapplied for 300us, I^T=square wave pulse or equivalent.

2. Surge current waveform per Figure 3 and derate per Figure 2.

3. For bipolar types having V^WMof 10 volts and under, the I^Dlimit is doubled.

4. All terms and symbols are consistent with ANSI/IEEE C62.35.

- 630 -

TVS APPLICATION NOTES:

Transient Voltage Suppressors may be used at various points in a circuit to provide various degrees of

protection. The following is a typical linear power supply with transient voltage suppressor units placed at

different points. All provide protection of the load.

FIGURE 1

Transient Voltage Suppressors 1 provides maximum protection. However, the system will probably require

replacement of the line fuse(F) since it provides a dominant portion of the series impedance when a surge is

encountered.

However, we do not recommend to use the TVS diode here, unless we can know the electric circuit

impedance and the magnitude of surge rushed into the circuit. Otherwise the TVS diode is easy to be

destroyed by voltage surge.

Transient Voltage Suppressor 2 provides execllent protection of circuitry excluding the transformer(T).

However, since the transformer is a large part of the series impedance, the chance of the line fuse opening

during the surge condition is reduced.

Transient Voltage Suppressor 3 provides the load with complete protection. It uses a unidirectional

Transient Voltage Suppressor, which is a cost advantage. The series impedance now includes the line fuse,

transformer, and bridge rectifier(B) so failure of the line fuse is further reduced. If only Transient Voltage

Suppressor 3 is in use, then the bridge rectifier is unprotected and would require a higher voltage and current

rating to prevent failure by transients.

Any combination of these three, or any one of these applications, will prevent damage to the load. This would

require varying trade-offs in power supply protection versus maintenance(changing the time fuse).

An additional method is to utilize the Transient Voltage Suppressor units as a controlled avalanche bridge.

This reduces the parts count and incorporates the protection within the bridge rectifier.

FIGURE 2

- 631 -

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