M39003/01-2596 Vishay, M39003/01-2596 Datasheet - Page 14

M39003/01-2596

Manufacturer Part Number

M39003/01-2596

Description

CAPACITOR TANT 1UF, 50V, AXIAL

Manufacturer

Vishay

Datasheet

1.M3900301-2304.pdf (16 pages)

Specifications of M39003/01-2596

Capacitance Tolerance

Â± 10%

Voltage Rating

50VDC

Capacitor Case Style

Axial

No. Of Pins

Mil Spec

MIL-C-39003/01

Capacitor Mounting

Through Hole

Termination Type

Axial Leaded

Capacitance

1ÂµF

Capacitor Terminals

Axial Leaded

Rohs Compliant

Lead Free Status / RoHS Status

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M39003/01/03/09

Vishay Sprague

WEIBULL DISTRIBUTION METHOD FOR DETERMINING FAILURE RATE, MIL-PRF-39003

The current issue of Military Specification MIL-PRF-39003

incorporates Weibull distribution techniques as a means for

calculating failure rates for solid tantalum capacitors. The

exponential failure rates (M, P, R and S) are inactive for new

designs. Weibull graded failure rate level “B“ capacitors

supersede exponential failure rates M, P, R and S.

Increasingly, more stringent quality measurement systems

are being used in the electronics industry. AQL sample plans

are being replaced by programs measuring component

quality in PPM (Parts Per Million). Product quality

specifications seemingly approach perfection. Procedures

used to calculate PPM quality levels are based on

manufacturers in-process controls and final inspection

results and by users data at incoming inspection and

equipment assembly.

Initial quality requirements are only part of a good product

specification. Reliability and useful life should be considered

as well - to fit the reliability and useful life requirements of end

equipment.

Reliability is a measure of the expected failure rate during the

useful life of the capacitor. When plotted the failure rate

follows a characteristic “bathtub“ curve, covering three

periods in the typical capacitor life cycle.

The bathtub curve shows the early time period called infant

failure period, the uniform failure rate period or useful life and

a period of increasing failure rate due to wearout.

The Weibull shape parameter beta (β) is shown as less than

one (β < 1) during infant mortality, one (β = 1) during the

useful life and greater than one (β > 1) during the wearout

period. Since Weibull distribution works well on units with a

beta less than 1, solid tantalum capacitors can use this

method for determining failure rates. Solid tantalum

capacitors fail early in life (normally during the aging or

burnin cycles) and show a slightly decreasing failure rate

with time - however, there is no known wearout failure mode.

The processing of solid tantalum capacitors is not “perfectly

clean”. Impurities in the tantalum powders along with

microscopic dust particles can cause flaws in the dielectric

tantalum oxide. These flaws in the dielectric can cause

failure sites which are normally found during the in-process

aging or burn-in cycles. A very large percentage of failures

occur during these burn-ins. Since the worst flaws are

www.vishay.com

RELIABILITY LIFE CYCLE -

TYPICAL “BATHTUB” CURVE

INFANT

FAILURE

PERIOD

USEFUL LIFE PERIOD

TIME

Military MIL-PRF-39003 Qualified, Styles CSR13, 21, 23

For technical questions, contact:

Solid-Electrolyte T

WEAROUT

PERIOD

tantalum@vishay.com

ANTALEX

presumed to fail first, we eventually arrive at flaw sizes which

are presumably too small to cause further degradation.

Weibull states that the failure rate of a component that shows

a decreasing failure rate with time can be predicted within a

short period of time under accelerated conditions.

Accelerated conditions for solid tantalum capacitors can be

imposed by means of either voltage or temperature stress.

Since temperatures above + 125 °C can cause degradation

of the solid manganese dioxide electrolyte, voltage

acceleration is performed instead.

The Navy's Crane NAD facility completed testing on solid

tantalum capacitors from several manufacturers in late 1981.

During testing, acceleration factors (A.F.) were derived from

life test results and the following formula used:

The acceleration factors used in MIL-C-39003 are as shown:

FOR EXAMPLE:

If a 15 µF, 20 V part is placed on test for 1 h at + 85 °C and

26 V (V

+ 85 °C and 20 V (exponential grading).

To explain the Weibull analysis, several formulas must be

shown. The basic Weibull formula is as shown:

To calculate Weibull failure rates, special burn-in ovens must

be used which will record an actual time to failure for each of

the units on test.

To perform the test, 100 % of the units (or 500 pieces

whichever is less) are placed in the Weibull oven and taken

to test conditions (+ 85 °C and voltage stress per the

acceleration factors chosen). For lots over 500 pieces, the

balance of the lot is placed in a standard burn-in oven at the

same Weibull conditions. Failures that occur during the

start-up are not used in the calculation. After test conditions

are reached (< 5 min), the start time is considered to be t

A count of good pieces is taken at no later than 15 minutes

after t

lot must be put back on test and recounted after 10 h.

, the number of failures are counted. If no failures occur, the

. This will be the sample size. At least two hours after

A.F. = 7.034 x 10-9 e (18.7724 V

F(x) = Cumulative fraction failed (P) at time (t)

t = Actual test time

β = Weibull shape parameter (beta)

α = Weibull scale parameter (alpha)

= Rated voltage of unit under test

= Voltage stress

= 1.3), this is equivalent to 279 hours of testing at

Capacitors,

1.0

1.1

1.2

1.3

1.4

1.5

1.527

F x ( )

A.F.

1.0

6.53

42.7

279.0

1824.0

11 923.0

20 000.00

1 e

–

⎛ ⎞

⎝ ⎠

Document Number: 40018

tβ

---- -

Revision: 14-Sep-09

)

M39003/01-2596 Vishay, M39003/01-2596 Datasheet - Page 14

M39003/01-2596

Specifications of M39003/01-2596

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