Z2068U - HV Component Associates, Inc.

Description/Features

TRANZAP’s are silicon PN junction diodes designed,

manufactured and specified as Transient Voltage Suppressors

having a non-linear current-voltage characteristic which

sustains an almost constant voltage over a wide range of

current. They are ideally suited to many transient voltage

protection applications and their high clamping efficiency and

low steady state power dissipation offer considerable circuit

advantages over most existing methods of protection.

During operation, the ZAP idles at a low current level at the

nominal voltage. When a transient voltage occurs, ZAP

current increases rapidly, its voltage remaining virtually con-

stant, and the transient energy content is thus absorbed.

Repetitive surge capability

Peak pulse power is fixed under non-repetitive conditions.

However, in practical use, there are cases when the surge is

often repeatedly applied.

In this case, even though the one pulse power remains

within the peak pulse power, the power is accumulative and

exceeds the peak pulse power in some cases.

Response time

Response time of psec order however, in its operating

response time, it depends largely on the influence of

capacitance, and the effect of the response time with respect

to the clamping voltages is negligible.

Capacitance

Capacitance is determined by the area of a silicon chip and

the breakdown voltage. The capacitance decreases as the

bias voltage increases as shown in Figure 8.

Taping

Standard taping is available upon request.

Forming

Standard forming is available upon request.

Features

■High surge current capability

■Excellent voltage clamping (1.2 @ 50% peak power)

■Symmetrical characteristic - use on AC or DC (bipolar)

■Instantaneous response (pico- second order)

■Low idling current (5

-Amps)

Applications

■Protection of all types of semiconductors

■Absorption of surges associated with lightning

■Suppression of switching surges

■Protection in inductive switching circuits

■Prolongation of contact life

■Voltage clipping

Construction

ZAP construction features

PN junctions on both faces

of a silicon chip and has

been sufficiently designed

for thermal dissipation of

high surge power in a short

period of time.

Lead wire

Epoxy resin

Header

Solder

Silicon chip

Surge suppression characteristics

Surge suppression is shown in Figure 2 when

standard surge is applied to test circuit of Figure 3.

Electrical characteristics

Figure 4 shows an almost symmetrical breakdown voltage

) ratio between

forward (V

) and

reverse breakdown

voltage (V

Typically

0.9 1.10

Stand-off voltage

TRANZAP’s are designed for transient voltage suppression, it

is not preferable to consume power at the operating voltage.

Stand-off voltage is fixed to be of a value 0.9 times the

minimum breakdown voltage.

Leakage current

The current when the stand-off voltage is applied is fixed as

the maximum leakage current. This leakage current is an

important factor when used in circuits with high impedance.

Breakdown voltage

The terminal voltage when a test current is passed, is fixed

to be the breakdown voltage. The breakdown voltage is

measured in air 25°C. The test current is normally 1 mA .

Continuous operating power

The PN junction temperature is determined by the

following equation:

Tj=(P

+Ta

P: Applied power

Thermal resistance

Ta: Ambient temperature

Where,

is thermal resistance from the PN junction to

ambient space and is determined by following equation:

=(1/K)x(L/S)

K: Thermal conductivity

L: Length of lead wire

S: Sectional area of lead wire

In case of Ta=50°C, Tj = 150°C, the maximum

operating power is as follows:

Z1 type: 500m Watts

Z2 type: 1 Watt

Z6 type: 3 Watts

Surge capability

Surge capability (P) is determined by the following equation:

P=ƒi(t)(V(t)dt)

it : Pulse current wave

Vt : clamping voltage wave

Allowable surge capability (Pm) is determined by the

following equation:

Pm=IPx VC

IP: Peak current

VC: Maximum clamping voltage

The allowable surge capability (peak pulse power) is as

shown in Figure 5 and the surge capability derating

characteristic as shown in Figure 6.

Peak current

Test pulse wave form

Test pulse

ROZAP

V(t)

105

104

103

102

100

Z6 Type

Z1 Type

Peak pulse power (w)

Power ratio (%)

Z2 Type

10-4 10-3 10-2 10-1 11010

Time (msec)

20 40 50 80 100 120 140

Ambient temperature (°C)

I(t)

Maximum clamping voltage

Clamping voltage waveform

Current

Voltage

Time

Figure 1

Figure 2

Figure 3

Figure 4

Figure 5

Figure 6

ILIT

VS: Stand-off voltage

VB: Break down voltage

VC: Maximum clamping voltage

IL: Maximum leakage current

IT: Test current

IP: Peak pulse current

ITIP

1 2 5 10 20 50 100 200 500 1000 2000 5000 10000

Repeating time (msec)

Pulse power ratio (%)

100

O Bias

1nF

100PF

10PF

O Bias

70% Bias

Z6 Type

Capacitance

Z2 Type

Z1 Type

Break down voltage (V)

15 20 30 40 50 60 80 100 200

50% Bias

Figure 7

Figure 8

CKE ■P.O. Box 211 ■Lucernemines, PA ■Phone (724) 479-3533 ■Fax (724) 479-3537 ■www.cke.com ■info@cke.com

Stand-off Maximum Breakdown Test Maximum clamping voltage & Max

Bi-polar voltage leakage voltage current Maximum peak pulse current temp.

type current 10/1000 msec 8/20 msec coef. of

VSITVCIPVCIPVB

LVBmA V A V A %/°C

Z1015 12.1 5 13.5–16.5 1 22.0 11.4 28.5 106 0.076

Z1018 14.5 5 16.2–19.8 1 26.5 9.43 34.4 88.0 0.079

Z1022 17.8 5 19.8–24.2 1 31.9 7.84 41.4 73.1 0.082

Z1027 21.8 5 24.3–29.7 1 39.1 6.39 50.7 59.7 0.085

Z1033 26.8 5 29.7–36.3 1 47.7 5.24 61.8 49.0 0.087

Z1039 31.6 5 35.1–42.9 1 56.4 4.43 73.1 41.4 0.090

Z1047 38.1 5 42.3–51.7 1 67.8 3.69 88.1 34.4 0.092

Z1056 45.4 5 50.4–61.6 1 80.5 3.11 10.4 29.1 0.094

Z1068 55.1 5 61.2–74.8 1 98.0 2.55 127 23.8 0.096

Z1082 66.4 5 73.8–90.2 1 118 2.12 153 19.8 0.099

Z1100 81.0 5 90.0–110 1 144 1.74 187 16.2 0.101

Z1120 97.2 5 108–132 1 173 1.45 224 13.5 0.103

Z1150 121 5 135-165 1 215 1.16 279 10.8 0.105

Stand-off Maximum Breakdown Test Maximum clamping voltage &

Bi-polar Uni-polar voltage leakage voltage current Maximum peak pulse current

type type current 10/1000 msec 8/20 msec

VSILVBITVCIPVCIP

VmAVmAVAVA

Z2008 Z2008U 6.63 500 7.38–9.02 10 12.5 48.0 16.2 449

Z2010 Z2010U 8.10 10 9.00–11.0 1 15.0 40.0 19.4 375

Z2012 Z2012U 9.72 5 10.8–13.2 1 17.3 34.6 22.4 325

Z2015 Z2015U 12.1 5 13.5–16.5 1 22.0 27.2 28.5 255

Z2018 Z2018U 14.5 5 16.2–19.8 1 26.5 22.6 34.4 298

Z2022 Z2022U 17.8 5 19.8–24.2 1 31.9 18.8 41.4 175

Z2027 Z2027U 21.8 5 24.3–29.7 1 39.1 15.3 50.7 143

Z2033 Z2033U 26.8 5 29.7–36.3 1 47.7 12.5 61.8 117

Z2039 Z2039U 31.6 5 35.1–42.9 1 56.4 10.6 73.1 99.5

Z2047 Z2047U 38.1 5 42.3–51.7 1 67.8 8.84 78.9 92.2

Z2056 Z2056U 45.4 5 50.4–61.6 1 80.5 7.45 104 70.0

Z2068 Z2068U 55.1 5 61.2–74.8 1 98.0 6.12 127 60.6

Z2082 Z2082U 66.4 5 73.8–90.2 1 118 5.08 153 47.5

Z2100 Z2100U 81.0 5 90.0–110 1 144 4.16 187 38.9

Z2120 Z2120U 97.2 5 108–132 1 173 3.46 224 32.5

Z2150 Z2150U 121 5 135–165 1 215 2.79 279 26.0

Z2180 Z2180U 146 5 162–198 1 258 2.32 335 21.7

Stand-off Maximum Breakdown Test Maximum clamping voltage &

Bi-polar Uni-polar voltage leakage voltage current Maximum peak pulse current

type type current 10/1000 msec 8/20 msec

VSILVBITVCIPVCIP

VmAVmAVAVA

– Z6008U 6.63 500 7.38–9.02 10 12.5 120 16.2 1124

Z6010 Z6010U 8.10 10 9.00–11.0 1 15.0 100 19.4 938

Z6012 Z6012U 9.72 5 10.8–13.2 1 17.3 87 22.4 813

Z6015 Z6015U 12.1 5 13.5–16.5 1 22.0 68 28.5 639

Z6018 Z6018U 14.5 5 16.2–19.8 1 26.5 56 34.4 529

Z6022 Z6022U 17.8 5 19.8–24.2 1 31.9 47 41.4 440

Z6027 Z6027U 21.8 5 24.3–29.7 1 39.1 38 50.7 359

Z6033 Z6033U 26.8 5 29.7–36.3 1 47.7 31 61.8 295

Z6039 Z6039U 31.6 5 35.1–42.9 1 56.4 26 73.1 249

Z6047 Z6047U 38.1 5 42.3–51.7 1 67.8 22.2 78.9 231

Z6056 Z6056U 45.4 5 50.4–61.6 1 80.5 18.6 104 175

Z6068 Z6068U 55.1 5 61.2–74.8 1 98.0 15.3 127 143

Z6082 Z6082U 66.4 5 73.8–90.2 1 118 12.7 153 119

Z6100 Z6100U 81.0 5 90.0–110 1 144 10.4 187 97.4

Z6120 Z6120U 97.2 5 108–132 1 173 8.7 224 81.3

Z6150 Z6150U 121 5 135–165 1 215 7.0 279 65.2

VZ±10% and Bi-polar

Note: Nonsuffix: VZ±10% and Bi-polar, suffix “U”: Uni-polar

Maximum ratings

Peak pulse power: 250 watt (10 x 1,000 msec)

3.03 KWatt (8 x 20 msec)

Steady state power dissipation:

500 mWatts

Operating and storage temperature:

-40°C to 150°C

Symbol mark

Maximum ratings

Peak pulse power: 1.5 KWatt (10 x 1,000msec)

18.2 KWatt (8 x 20msec)

Steady state power dissipation:

3 Watts

Operating and storage temperature:

-40°C to 150°C

Symbol mark

26±2

5.3±0.5

Type No. & Lot No.

Cathode mark Epoxy resin

Soldered copper wire

9±0.5

Maximum ratings

Peak pulse power: 600 Watt (10/1,000msec)

7.28 KWatt (8/20msec)

Steady state power dissipation:

1 Watt

Operating and storage temperature:

-40°C to 150°C

Symbol mark

27.5±1

3.6±0.3

Type No. & Lot No.

Cathode mark Epoxy resin

0.8

Soldered copper wire

6±0.3

27.5±1

3.6±0.3

Type No. & Lot No.

Cathode mark Epoxy resin

0.8

Soldered copper wire

6±0.3

Z1 type (Bidirectional)

Z2 type

Z6 type