M83530/1-2200D - Harris Semiconductor

13-3

High Reliability Varistors

High Reliability Series Mechanical and

Environmental Testing for Aerospace,

Military and High Reliability Applications

The high reliability Harris varistor is the latest step in

increased product performance, and is available for

applications requiring quality and reliability assurance levels

consistent with military or other standards. (MIL-STD-19500,

MIL-S-750, Method 202). Additionally, Harris varistors are

inherently radiation hardened compared to silicon diode

suppressors as illustrated in Figure 1.

This series of high-reliability varistors involve ﬁve categories:

• DESC Qualified Parts List (QPL) MIL-R-83530

4 types presently available

• DESC Standard Military Drawings based on MIL-R-83530

63 types presently available:

- ZA Series - Drawing #87063

- DB Series - Drawing #90065

• Harris high reliability series offers TX equivalents

29 types presently available

• Custom types processed to customer-specific require-

ments - (SCD) or to standard military flow

• SP720 - High Reliability Electronic Protection Array

Credentials

Harris varistors and quality management systems are:

• DESC approved

• QPL listed

• CECC approved

• ISO approved

• UL approved

• CSA approved

DESC Qualiﬁed Parts List (QPL) MIL-R-83530

TABLE 1. MIL-R-83530/1 RATINGS AND CHARACTERISTICS

PART

NUMBER

M83530/

NOMINAL

VARISTOR

VOLTAGE

(V) TOLERANCE

(%)

VOLTAGE

RATING

(V) ENERGY

RATING

(J)

CLAMPING

VOLTAGE

AT 100A

(V)

CAPACITANCE

AT 1MHz

(pF)

CLAMPING

VOLTAGE

AT PEAK

CURRENT

RATING

(V) ITM

(A)

NEAREST

COMMERCIAL

EQUIVALENT(RMS) (DC)

1-2000B 200 ±10 130 175 50 325 3800 570 6000 V130LA20B

1-2200D 220 +10, -5 150 200 55 360 3200 650 6000 V150LA20B

1-4300E 430 +5, -10 275 369 100 680 1800 1200 6000 V275LA40B

1-5100E 510 +5, -10 320 420 120 810 1500 1450 6000 V320LA40B

This series of varistors are screened and conditioned in accordance with MIL-R-83530 as outlined in Table 2. Manufacturing system con-

forms to MIL-I-45208; MIL-Q-9858.

13-4

High Reliability Series

MIL-R-83530 Inspections

TABLE 2. MIL-R-83530 GROUP A, B, AND C INSPECTIONS

INSPECTION

AQL

(PERCENT

DEFECTIVE) MAJOR MINOR NUMBER OF

SAMPLE UNITS FAILURES

ALLOWED

Group A SUBGROUP 1

High Temperature Life (Stabilization Bake) 100% - - - -

Thermal Shock 100% - - - -

Power Burn-In 100% - - - -

Clamping Voltage 100% - - - -

Nominal Varistor Voltage 100% - - - -

SUBGROUP 2

Visual and Mechanical Examination - 1.0% AQL

7.6% LQ 25% AQL

13.0% LQ Per Plan -

Body Dimensions - Per Plan -

Diameter and Length of Leads - Per Plan -

Marking - Per Plan -

Workmanship - Per Plan -

SUBGROUP 3

Solderability - - - Per Plan -

Group B SUBGROUP 1

Dielectric Withstanding Voltage - - - Per Plan -

SUBGROUP 2

Resistance to Solvents - - - Per Plan -

SUBGROUP 3

Terminal Strength (Lead Fatigue) - - - Per Plan -

Moisture Resistance - - - Per Plan -

Peak Current - - - Per Plan -

Energy - - - Per Plan -

Group C EVERY 3 MONTHS

High Temperature Storage - - - 10 0

Operating Life (Steady State) - - - 10 0

Pulse Life - - - 10 0

Shock - - - 10 0

Vibration - - - 10 0

Constant Acceleration - - - 10 0

Energy - - - 10 0

13-5

High Reliability Series

DESC Standard Military Drawing # 87063

Based on MIL-R-83530

TABLE 3. ZA SERIES RATINGS AND SPECIFICATIONS

87063

DASH

NO.

NEAREST

COMM.

NO. (NOTE 1)

SIZE

MAXIMUM RATINGS (+85oC) SPECIFICATIONS (+25oC)

CONTINUOUS TRANSIENT

VARISTOR VOLTAGE

AT 1mADC

TEST CURRENT

MAXIMUM

CLAMPING

VOLTAGE

VC AT TEST

CURRENT

(8/20µs) TYPICAL

CAPACITANCERMS DC

ENERGY

(10/

1000µs)

PEAK

CURRENT

(8/20µs)

VM(AC) VM(DC) WTM ITM MIN VN(DC) MAX VCICf = 1MHz

(V) (V) (J) (A) (V) (V) (V) (V) (A) (pF)

001 V22ZA05 1 14 18 0.2 35 18.7 22 26 51 2 400

002 V22ZA1 2 14 18 0.9 150 18.7 22 26 47 5 1600

003 V22ZA2 3 14 18 2.0 350 18.7 22 26 43 5 4000

004 V22ZA3 4 14 18 4.0 750 18.7 22 26 43 10 9000

005 V24ZA50 5 14 18 6.5 1500 19.2 24

(Note 2) 26 43 20 18000

006 V27ZA05 1 17 22 0.25 35 23 27 31.1 59 2 300

007 V27ZA1 2 17 22 1.0 150 23 27 31.1 57 5 1300

008 V27ZA2 3 17 22 2.5 350 23 27 31.1 53 5 3000

009 V27ZA4 4 17 22 5.0 750 23 27 31.1 53 10 7000

010 V27ZA60 5 17 22 8.0 1500 23 27

(Note 2) 31.1 50 20 15000

011 V33ZA05 1 20 26 0.3 35 29.5 33 38 67 2 250

012 V33ZA1 2 20 26 1.2 150 29.5 33 36.5 68 5 1100

013 V33ZA2 3 20 26 3.0 350 29.5 33 36.5 64 5 2700

014 V33ZA5 4 20 26 6.0 750 29.5 33 36.5 64 10 6000

015 V33ZA70 5 21 27 9.0 1500 29.5 33

(Note 2) 36.5 58 20 13000

016 V36ZA80 5 23 31 10.0 1500 32 36

(Note 2) 40 63 20 12000

017 V39ZA05 1 25 31 0.35 35 35 39 46 79 2 220

018 V39ZA1 2 25 31 1.5 150 35 39 43 79 5 900

019 V39ZA3 3 25 31 3.5 350 35 39 43 76 5 2200

020 V39ZA6 4 25 31 7.2 750 35 39 43 76 10 5000

021 V47ZA05 1 30 38 0.4 35 42 47 55 90 2 200

022 V47ZA1 2 30 38 1.8 150 42 47 52 92 5 800

023 V47ZA3 3 30 38 4.5 350 42 47 52 89 5 2000

024 V47ZA7 4 30 38 8.8 750 42 47 52 89 10 4500

025 V56ZA05 1 35 45 0.5 35 50 56 66 108 2 180

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High Reliability Series

026 V56ZA2 2 35 45 2.3 150 50 56 62 107 5 700

027 V56ZA3 3 35 45 5.5 350 50 56 62 103 5 1800

028 V56ZA8 4 35 45 10.0 750 50 56 62 103 10 3900

029 V68ZA05 1 40 56 0.6 35 61 68 80 127 2 150

030 V68ZA2 2 40 56 3.0 150 61 68 75 127 5 600

031 V68ZA3 3 40 56 6.5 350 61 68 75 123 5 1500

032 V68ZA10 4 40 56 13.0 750 61 68 75 123 10 3300

033 V82ZA05 1 50 66 1.2 70 73 82 97 145 2 120

034 V82ZA2 2 50 66 3.5 300 73 82 91 135 10 500

035 V82ZA4 3 50 66 7.3 750 73 82 91 135 25 1100

036 V82ZA12 4 50 66 13.0 1500 73 82 91 145 50 2500

037 V100ZA05 1 60 81 1.5 70 90 100 117 175 2 90

038 V100ZA3 2 60 81 4.3 300 90 100 110 165 10 400

039 V100ZA4 3 60 81 8.9 750 90 100 110 165 25 900

040 V100ZA15 4 60 81 16.0 1500 90 100 110 175 50 2000

041 V120ZA05 1 75 102 1.8 100 108 120 138 205 2 70

042 V120ZA1 2 75 102 5.3 400 108 120 132 205 10 300

043 V120ZA4 3 75 102 11.0 1000 108 120 132 200 25 750

044 V120ZA6 4 75 102 19.0 2000 108 120 132 210 50 1700

045 V150ZA05 1 92 127 2.3 100 135 150 173 240 2 60

046 V150ZA1 2 95 127 6.5 400 135 150 165 250 10 250

047 V150ZA4 3 95 127 13.0 1000 135 150 165 250 25 600

048 V150ZA8 4 95 127 23.0 2000 135 150 165 255 50 1400

049 V180ZA05 1 110 153 2.7 150 162 180 207 290 2 50

050 V180ZA1 2 115 153 7.7 500 162 180 198 295 10 200

051 V180ZA5 3 115 153 16.0 1500 162 180 198 300 25 500

052 V180ZA10 4 115 153 27.0 3000 162 180 198 300 50 1100

NOTES:

1. Size 1-5mm, 2-7mm, 3-10mm, 4-14mm, 5-20mm

2. 10mA DC test current.

TABLE 3. ZA SERIES RATINGS AND SPECIFICATIONS (Continued)

87063

DASH

NO.

NEAREST

COMM.

NO. (NOTE 1)

SIZE

MAXIMUM RATINGS (+85oC) SPECIFICATIONS (+25oC)

CONTINUOUS TRANSIENT

VARISTOR VOLTAGE

AT 1mADC

TEST CURRENT

MAXIMUM

CLAMPING

VOLTAGE

VC AT TEST

CURRENT

(8/20µs) TYPICAL

CAPACITANCERMS DC

ENERGY

(10/

1000µs)

PEAK

CURRENT

(8/20µs)

VM(AC) VM(DC) WTM ITM MIN VN(DC) MAX VCICf = 1MHz

(V) (V) (J) (A) (V) (V) (V) (V) (A) (pF)

13-7

High Reliability Series

DESC Standard Military Drawing # 90065

Based on MIL-R-83530

Harris High Reliability Series TX Equivalents

TABLE 5. AVAILABLE TX MODEL TYPES

TABLE 4. DB SERIES RATINGS AND SPECIFICATIONS

90065

DASH

NO.

VOLTAGE

RATING

MAX.

(RMS)

ENERGY

MAX

(J)

PEAK

CURRENT

(A)

NOMINAL

VARISTOR

VOLTAGE

(V)

MAX CLAMPING

VOLTAGE AT

TEST CURRENT TYPICAL

CAPACITANCE

(pF)(V) (I)

012 130 170 22500 200 +28, -16 345 200 10000

013 150 200 22500 240 ±28 405 200 8000

014 250 270 22500 390 +39, -36 650 200 5000

015 275 300 22500 430 ±43 730 200 4500

016 320 350 22500 510 +29, -48 830 200 3800

017 420 460 28800 680 +68, -70 1130 200 3000

018 480 510 28800 750 +74, -80 1240 200 2700

019 510 550 28800 820 +91, -85 1350 200 2500

020 575 600 28800 910 +95, -105 1480 200 2200

021 660 690 28800 1050 ±110 1720 200 2000

022 750 810 28800 1200 ±120 2000 200 1800

TX MODEL MODEL

SIZE DEVICE

MARK

NEAREST

COMMERCIAL

EQUIVALENT

V8ZTX1 7mm 8TX1 V8ZA1

V8ZTX2 10mm 8TX2 V8ZA2

V12ZTX1 7mm 12TX1 V12ZA1

V12ZTX2 10mm 12TX2 V12ZA2

V22ZTX1 7mm 22TX1 V22ZA1

V22ZTX3 14mm 22TX3 V22ZA3

V24ZTX50 20mm 24TX50 V24ZA50

V33ZTX1 7mm 33TX1 V33ZA1

V33ZTX5 14mm 33TX5 V33ZA5

V33ZTX70 20mm 33TX70 V33ZA70

V68ZTX2 7mm 68TX2 V68ZA2

V68ZTX10 14mm 68TX10 V68ZA10

V82ZTX2 7mm 82TX2 V82ZA2

V82ZTX12 14mm 82TX12 V82ZA12

V130LTX2 7mm 130TX V130LA2

V130LTX10A 14mm 130TX10 V130LA10A

V130LTX20B 20mm 130TX20 V130LA20A

V150LTX2 7mm 150TX V150LA2

V150LTX10A 14mm 150TX10 V150LA10A

V150LTX20B 20mm 150TX20 V150LA20B

V250LTX4 7mm 250TX V250LA4

V250LTX20A 14mm 250TX20 V250LA20A

V250LTX40B 20mm 250TX40 V250LA40B

V420LTX20A 14mm 420TX20 V420LA20A

V420LTX40B 20mm 420TX40 V420LA40B

V480LTX40A 14mm 480TX40 V480LA40A

V480LTX80B 20mm 480TX80 V480LA80B

V510LTX40A 14mm 510TX40 V510LA40A

V510LTX80B 20mm 510TX80 V510LA80B

TX MODEL MODEL

SIZE DEVICE

MARK

NEAREST

COMMERCIAL

EQUIVALENT

13-8

High Reliability Series

The TX series of varistors are 100% screened and conditioned in accordance with MIL-STD-750. Tests are as outlined in

Table 6.

TABLE 6. TX EQUIVALENTS SERIES 100% SCREENING

SCREEN MIL-STD-750

METHOD CONDITION TX

REQUIREMENTS

High Temperature Life

(stabilization bake) 1032 24 hours min. at max. rated storage temperature. 100%

Thermal Shock

(temperature cycling) 1051 No dwell is required at 25oC. Test condition A1, 5 cycles

-55oC to +125 oC (extremes). >10 minutes 100%

Humidity Life 85oC, 85% R.H., 168 hours. 100%

Interim Electrical VN(DC) VC

(Note 1) As speciﬁed, but including delta parameter as a mini-

mum. 100% Screen

Power Burn-In 1038 Condition B, 85oC, Rated VM(AC), 72 hours min 100%

Final Electrical +VN(DC) VC

(Note 1) As speciﬁed — All parameter measurements must be

completed within 96 hours after removal from burn-in

conditions.

100% Screen

External Visual Examination 2071 To be performed after complete marking. 100%

NOTE:

1. Delta Parameter - VN(DC)

Maximum allowable shift ±10% Max.

Applicable lot PDA - 10% Max.

Peak current and energy ratings are derated by 10% and 30%, respectively, from standard parts.

TABLE 7. QUALITY ASSURANCE ACCEPTANCE TEST

MIL-STD-105

LTPDLEVEL AQL

Electrical (Bidirectional)

VN(DC), VC (Per specifications table) II 0.1 -

Dielectric Withstand Voltage

MIL-STD-202, Method 301, 2500V min. at 1.0µADC

--15

Solderability

MIL-STD-202, Method 208, no aging, non-activated --15

INSPECTION LOTS

FORMED AFTER

ASSEMBLY

LOTS PROPOSED

FOR TX TYPES 100% SCREENING

REVIEW OF DATA

TX PREPARATION

FOR DELIVERY

QA ACCEPTANCE

SAMPLE PER

APPLICABLE DEVICE

SPECIFICATION

13-9

High Reliability Series

TABLE 8. MECHANICAL AND ENVIRONMENTAL CAPABILITIES (TYPICAL CONDITIONS)

TEST NAME TEST METHOD DESCRIPTION

Terminal Strength MIL-STD-750-2036 3 Bends, 90o Arc, 16oz. Weight

Drop Shock MIL-STD-750-2016 1500g's, 0.5ms, 5 Pulses, X1, V1, Z1

Variable Frequency Vibration MIL-STD-750-2056 20g's, 100-2000Hz, X1, V1, Z1

Constant Acceleration MIL-STD-750-2006 V2, 20,000g's Min

Salt Atmosphere MIL-STD-750-1041 35oC, 24 hrs, 10-50g/m2 Day

Soldering Heat/Solderability MIL-STD-750-2031/2026 260oC, 10s, 3 Cycles, Test Marking

Resistance to Solvents MIL-STD-202-215 Permanence, 3 Solvents

Flammability MIL-STD-202-111 15s Torching, 10s to Flameout

Flammability UL1414 3 x 15s Torching

Cyclical Moisture Resistance MIL-STD-202-106 10 Days

Steady-State Moisture Resistance 85/85 96 Hrs.

Biased Moisture Resistance Not Recommended for High-Voltage Types

Temperature Cycle MIL-STD-202-107 -55oC to +125oC, 5 Cycles

High-Temperature Life (Nonoperating) MIL-STD-750-1032 125oC, 24 Hrs.

Burn-In MIL-STD-750-1038 Rated Temperature and VRMS

Hermetic Seal MIL-STD-750-1071 Condition D

Custom Types

In addition to our comprehensive high-reliability series as

referenced above, Harris can screen and condition to

customer-speciﬁc requirements.

Additional mechanical and environmental capabilities are

deﬁned in Table 8.

Radiation Hardness

For space applications, an extremely important property of a

protection device is its response to imposed radiation

effects.

Electron Irradiation

A Harris MOV and a silicon transient suppression diode

were exposed to electron irradiation. The V-I Curves, before

and after test, are shown in Figure 1.

It is apparent that the Harris MOV was virtually unaffected,

even at the extremely high dose of 108 rads, while the silicon

transient suppression diode showed a dramatic increase in

leakage current.

FIGURE 1. RADIATION SENSITIVITY OF HARRIS V130LA1

AND SILICON TRANSIENT SUPPRESSION DIODE

200

100

20108106104102

SILICON

TRANSIENT

CURRENT (A)

PRE TEST

108 RADS,

18MeV ELECTRONS

HARRIS MOV

SUPPRESSION

DIODE

13-10

High Reliability Series

Neutron Effects

A second MOV-Zener comparison was made in response to

neutron ﬂuence. The selected devices were equal in area.

Figure 2 shows the clamping voltage response of the

MOV and the zener to neutron irradiation to as high as

1015 N/cm2. It is apparent that in contrast to the large

change in the zener, the MOV is unaltered. At higher cur-

rents where the MOV's clamping voltage is again

unchanged, the zener device clamping voltage increases by

as much as 36%.

FIGURE 2. V-I CHARACTERISTIC RESPONSE TO NEUTRON

IRRADIATION FOR MOV AND ZENER DIODE

DEVICES

Counterclockwise rotation of the V-I characteristics is

observed in silicon devices at high neutron irradiation levels;

in other words, increasing leakage at low current levels and

increasing clamping voltage at higher current levels.

The solid and open circles for a given ﬂuence represent the

high and low breakdown currents for the sample of devices

tested. Note that there is a marked decrease in current (or

energy) handling capability with increased neutron ﬂuence.

Failure threshold of silicon semiconductor junctions is further

reduced when high or rapidly increasing currents are

applied. Junctions develop hot spots, which enlarge until a

short occurs if current is not limited or quickly removed.

VOLTS

200

100

108

10 107106104103

AMPERES

300

10 10 105

1.5K 200

AT 1015

1.5K 200 INITIAL

VARISTOR V130A2

INITIAL AT 1015

1.5K 200

AT 1014

1.5K 200

AT 1013

1.5K 200

AT 1012

The characteristic voltage current relationship of a PN-Junc-

tion is shown in Figure 3.

FIGURE 3. V-I CHARACTERISTIC OF PN-JUNCTION

At low reverse voltage, the device will conduct very little

current (the saturation current). At higher reverse voltage

VBO (breakdown voltage), the current increases rapidly as

the electrons are either pulled by the electric ﬁeld (Zener

effect) or knocked out by other electrons (avalanching). A

further increase in voltage causes the device to exhibit a

negative resistance characteristic leading to secondary

breakdown.

This manifests itself through the formation of hotspots, and

irreversible damage occurs. This failure threshold decreases

under neutron irradiation for zeners, but not for Zinc Oxide

Varistors.

Gamma Radiation

Radiation damage studies were performed on type V130LA2

varistors. Emission spectra and V-I characteristics were

collected before and after irradiation with 106 rads Co60

gamma radiation.

Both show no change, within experimental error, after

irradiation.

SATURATION

CURRENT

BREAKDOWN

VOLTAGE

REDUCTION IN

FAILURE STRESSHOLD

BY RADIAL

SECONDARY

BREAKDOWN

REVERSE

BIAS

FORWARD

BIAS