PANJIT 3KP90A, 3KP9.0, 3KP85A, 3KP85, 3KP8.0A Datasheet

GLASS PASSIVA TED JUNCTION TRANSIENT VOLTAGE SUPPRESSOR

FEATURE

S

MECHANICAL DATA

DEVICES FOR BIPOLAR APPLICATION

S

MAXIMUM RATINGS AND CHARACTERISTICS

PPM

PPM

M(AV)

FSM

STG

P-600

VOLTA GE - 5.0 TO 170 Volts 3000 Watt Peak Pulse Power

l

Plastic package has Underwriters Laboratory

Flammability Classification 94V-O

l

Glass passivated junction

l

3000W Peak Pulse Power capability on

10/1000 £gS waveform

l

Excellent clamping capability

l

Repetition rate(Duty Cycle): 0.05%

l

Low incremental surge resistance

l

Fast response time: typically less

than 1.0 ps from 0 volts to BV

l

Typical ID less than 1£gA above 10V

l

High temperature soldering guaranteed:

300¢J/10 seconds/.375”,(9.5mm) lead
length/5lbs., (2.3kg) tension

3KP SERIES

Case: Molded plastic over glass passivated junction
Terminals: Plated Axial leads, solderable per
MIL-STD-750, Method 2026
Polarity: Color band denoteds positive
end(cathode)
Mounting Position: Any
Weight: 0.07 ounce, 2.1 grams

For Bidirectional use C or CA Suffix for types

Electrical characteristics apply in both directions.

Ratings at 25¢Jambient temperature unless otherwise specified.
RATING SYMBOL VALUE UNITS
Peak Pulse Power Dissipation on 10/1000 £g S waveform

P

Minimum 3000 Watts
(Note 1, FIG.1)
Peak Pulse Current of on 10/1000 £gS waveform

I

SEE TABLE 1 Amps
(Note 1, FIG.3)
Steady State Power Dissipation at TL=75¢JLead

P

8.0 Watts

Lengths .375”,(9.5mm) (Note 2)
Peak Forward Surge Current, 8.3ms Single Half Sine-Wave

I

250 Amps
Superimposed on Rated Load, Unidirectional only
(JECED Method) (Note 3)
Operating Junction and Storage Temperature Range TJ,T

-55 to +175 ¢J

NOTES:

1. Non-repetitive current pulse, per Fig. 3 and derated above TA=25 ¢J per Fig. 2.

2. Mounted on Copper Leaf area of 0.79in2(20mm2).

3. Measured on 8.3ms single half sine-wave or equivalent square wave, duty cycle= 4 pulses per minutes maximum.

RATING AND CHARACTERISTIC CURVES 3KP SERIES

100

0

TA, AMBIENT TEMPERATURE,

tf = 10£gs

ec

t, TIME , m

s

2

1

MEASURED AT

STAND-OFF

M

W

0

TL, LEAD TEMPERATURE,

NUMBER OF CYCLES AT 60H

z

E

P

Ip

C

W

100

10

1.0

, PEAK PULSE POWER,KW

0.1

PPM

0.1£gs 1.0£gs 10£gs 100£gs 1.0ms 10ms

NON-REPETITIVE PULSE
WAVEFORM SHOWN IN
FIGURE 3 TA = 25

td, PULSE WIDTH, SEC

¢J

Fig. 1-PEAK PULSE POWER VS PULSE TIME

150

100

50

pm, PEAK PULSE CURRENT, %

0

td

0 1.0 2.0 3.0 4.0

TA = 25

¢J

Pulse Width(td) is Defined as the
Point Where the Peak Current
Decays to 50% of lppPeak Value Ippm

Half Value-Ipp

2

10/1000£gsec Waveform
as Defined by R.E.A.

e-kt

75

50

25

DERATING IN PERCENTAGE%

AK PULSE POWER(Ppp) OR CURRENT(lpp)

0 25 50 75 100 125 150 175 200

¢J

Fig. 2-DERATING CURVE

0,000
0,000

1,000

J,CAPACITANCE, pF

ZERO BIAS

MEASURED AT

100

VOLTAGE(V

TJ = 25

¢J

f = 1.0MHz
Vsig = 50mVp-p

)

Fig. 3-PULSE WAVEFORM

10.0

6.0

ATTS

4.0

2.0

DISSIPATION,

Pm(AV) STEADY STATE POWER

0 25 50 75 100 125 150 175 200

L = 375" (9.5mm)

20mm × 20mm × 1mm CU

(0.8" × 0.8" × 0.40")

¢J

Fig. 5-STEADY STATE POWER DERATING

10

1.0 2.0 10 20 100

200 400

V(WM), REVERSE STAND-OFF VOLTAGE, VOLTS

Fig. 4-TYPICAL CAPACITANCE VS STAND-OFF

VOLTAGE

300

250

200

150

AMPERES

100

50

IFSM, PEAK FORWARD SURGE CURRENT,

1 2 5 10 20 50 100

TJ = TJ max

8.3ms SINGLE HALF SINCE-WAVE JEDEC
METHOD

Fig. 6-MAXIMUM NON-REPETITIVE PEAK FORWARD

SURGE CURRENT