T22C686K050CZS [VISHAY]

Wet Tantalum SMD Capacitors, Tantalum Metal Case With Glass-to-Tantalum Hermetic Seal;


型号：	T22C686K050CZS
厂家：	VISHAY
描述：	Wet Tantalum SMD Capacitors, Tantalum Metal Case With Glass-to-Tantalum Hermetic Seal
文件：	总10页 (文件大小：158K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

T22

Vishay

www.vishay.com

Wet Tantalum SMD Capacitors, Tantalum Metal Case With

Glass-to-Tantalum Hermetic Seal

FEATURES

• Advanced SMD packaging with high volumetric

efficiency, patents pending

Available

• Enhanced performance, high reliability design

• SMD, standard tin / lead (Sn / Pb), 100 ꢀ tin

(RoHS-compliant) available

• Mounting: surface-mount

Available

LINKS TO ADDITIONAL RESOURCES

•

Increased thermal shock capability of 300 cycles

• Designed for the avionics and aerospace applications

3D Models

• Material categorization: for definitions of compliance

please see www.vishay.com/doc?99912

PERFORMANCE CHARACTERISTICS

Operating Temperature: -55 °C to +85 °C

Note

(to +125 °C with voltage derating)

This datasheet provides information about parts that are

RoHS-compliant and / or parts that are non RoHS-compliant. For

example, parts with lead (Pb) terminations are not RoHS-compliant.

Please see the information / tables in this datasheet for details



DC Leakage Current (DCL Max.): at +25 °C and above:

leakage current shall not exceed the values listed in the

Standard Ratings table.



Capacitance Range: 10 μF to 68 μF

Capacitance Tolerance: 10 ꢀ, 20 ꢀ standard

Voltage Rating: 50 V_DCto 125 V_DC

ORDERING INFORMATION

T22

686

050

TYPE

CASE

CODE

CAPACITANCE

TOLERANCE

DC VOLTAGE

RATING AT +85 °C

TERMINATION /

PACKAGING

RELIABILITY

GRADE

ESR

See

Ratings

and

Case

Codes

table

This is expressed

in picofarads. The

first two digits are

the significant

figures. The third

is the number of

zeros to follow.

K = 10 ꢀ

M = 20 ꢀ

This is expressed

in volts. To

Sn / Pb solder

E = 7" (178 mm) reel

L = 7" (178 mm),

1/2 reel

S = 48 h

burn-in

Z = non-

established

reliability

S =

standard

complete the

three-digit block,

zeros precede the

voltage rating.

A decimal point is

indicated by an

“R” (6R3 = 6.3 V).

R = 7" (178 mm),

partial reel

100 % tin

C = 7" (178 mm), reel

H = 7" (178 mm),

1/2 reel

U = 7" (178 mm),

partial reel

DIMENSIONS in inches [millimeters]

T_W

WEIGHT

(AVERAGE)

CASE CODE

L (MAX.)

T_W

0.279 0.008

[7.1 0.2]

0.291 0.008

[7.4 0.2]

0.098 0.008

[2.5 0.2]

0.197 0.008

[5.0 0.2]

0.354

[9.0]

0.303 0.008

[7.7 0.2]

2.40

Revision: 13-May-2020

Document Number: 40187

For technical questions, contact: tantalum@vishay.com

THIS DOCUMENT IS SUBJECT TO CHANGE WITHOUT NOTICE. THE PRODUCTS DESCRIBED HEREIN AND THIS DOCUMENT

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MARKING

VOLTAGE CODE

CODE

Polarity mark

Capacitance

Voltage

Week

686T

YYXX

Year

100

Trademark

125

STANDARD RATINGS

MAX. DCL

(μA) AT

MAX. CAPACITANCE

CHANGE (%)

CAPACITANCE

MAX. ESR MAX. IMP.

RIPPLE

+85 °C

40 kHz

AT +25 °C

120 Hz

(μF)

CASE

CODE

AT +25 °C AT -55 °C

PART NUMBER

+85 °C

120 Hz

()

+25 °C

AND

-55 °C +85 °C +125 °C

()

(mA_RMS

1650

1310

1030

832

)

+125 °C

50 V_DCAT +85 °C; 30 V_DCAT +125 °C

T22C686(1)050(2)(3)(4) 1.50 35

75 V_DCAT +85 °C; 50 V_DCAT +125 °C

T22C336(1)075(2)(3)(4) 2.50 66

100 V_DCAT +85 °C; 65 V_DCAT +125 °C

T22C156(1)100(2)(3)(4) 3.50 125

125 V_DCAT +85 °C; 85 V_DCAT +125 °C

T22C106(1)125(2)(3)(4) 5.50 175

-25

-18

-15

Note

Part number definitions:

•

(1) Capacitance tolerance: K, M

(2) Termination and packaging: C, H, E, L, R, U

(3) Reliability level: Z, S

(4) ESR: S

POWER DISSIPATION

CASE CODE

MAXIMUM PERMISSIBLE POWER DISSIPATION AT +25 °C (W) IN FREE AIR

0.9

STANDARD PACKAGING QUANTITY

UNITS PER REEL

CASE CODE

7" FULL REEL

100

7" HALF REEL

7" PARTIAL REEL

Revision: 13-May-2020

Document Number: 40187

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TAPE AND REEL PACKAGING in inches [millimeters]

0.157 0.004

[4.0 0.10]

10 pitches cumulative

tolerance on tape

0.008 [0.200]

T₂

(max.)

Deformation

between

embossments

0.059 + 0.004 - 0.0

[1.5 + 0.10 - 0.0]

Embossment

0.024

[0.600]

max.

0.079 0.002

[2.0 0.05]

0.069 0.004

[1.75 0.10]

Top

cover

tape

A₀

0.030 [0.75]

min. ⁽³⁾

20°

B₁(max.) ⁽⁶⁾

K₀

Top

cover

tape

Maximum

component

rotation

B₀

P₁

0.030 [0.75]

min. ⁽⁴⁾

(Side or front sectional view)

Center lines

of cavity

For tape feeder

reference only

including draft.

D₁(min.) for components

0.004 [0.10]

max.

(5)

0.079 x 0.047 [2.0 x 1.2] and larger

USER DIRECTION

OF FEED

Maximum

cavity size ⁽¹⁾

Concentric around B₀

Cathode (-)

R minimum:

16 mm = 1.181" (30 mm)

min.

Anode (+)

DIRECTION OF FEED

Bending radius ⁽²⁾

3.937 [100.0]

20° maximum

component rotation

0.039 [1.0]

max.

Typical

component

Tape

cavity

center line

0.039 [1.0]

B₀

max.

0.9843 [250.0]

Typical

Camber

component

center line

(Top view)

A₀

(Top view)

Allowable camber to be 0.039/3.937 [1/100]

Non-cumulative over 9.843 [250.0]

Notes

•

(1)

Metric dimensions will govern. Dimensions in inches are rounded and for reference only.

A₀, B₀, K₀, are determined by the maximum dimensions to the ends of the terminals extending from the component body and / or the body

dimensions of the component. The clearance between the ends of the terminals or body of the component to the sides and depth of the

cavity (A₀, B₀, K₀) must be within 0.002" (0.05 mm) minimum and 0.020" (0.50 mm) maximum. The clearance allowed must also prevent

rotation of the component within the cavity of not more than 20°.

(2)

(3)

(4)

(5)

(6)

Tape with components shall pass around radius “R” without damage. The minimum trailer length may require additional length to provide

“R” minimum for 12 mm embossed tape for reels with hub diameters approaching N minimum.

This dimension is the flat area from the edge of the sprocket hole to either outward deformation of the carrier tape between the embossed

cavities or to the edge of the cavity whichever is less.

This dimension is the flat area from the edge of the carrier tape opposite the sprocket holes to either the outward deformation of the carrier

tape between the embossed cavity or to the edge of the cavity whichever is less.

The embossed hole location shall be measured from the sprocket hole controlling the location of the embossment. Dimensions of

embossment location shall be applied independent of each other.

B₁dimension is a reference dimension tape feeder clearance only.

CARRIER TAPE DIMENSIONS in inches [millimeters]

TAPE WIDTH

P₂

E₁

E₂MIN.

0.630 + 0.012 / - 0.004

[16.0 + 0.3 / - 0.1]

0.079 0.004

[2.0 0.1]

0.295 0.004

[7.5 0.1]

0.069 0.004

[1.75 0.1]

0.561

[14.25]

16 mm

Revision: 13-May-2020

Document Number: 40187

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CARRIER TAPE DIMENSIONS in inches [millimeters]

TAPE WIDTH W

TYPE

CASE CODE

P₁

K₀MAX.

B₁MAX.

(mm)

0.476 0.004

[12.0 0.1]

0.31

[7.9]

0.45

[11.3]

T22

RECOMMENDED REFLOW PROFILES

Capacitors should withstand reflow profile as per J-STD-020 standard

T_P

T_C- 5 °C

t_p

Max. ramp-up rate = 3 °C/s

Max. ramp-down rate = 6 °C/s

T_L

t_L

T_{s max.}

Preheat area

T_{s min.}

t_s

Time 25 °C to peak

TIME (s)

PROFILE FEATURE

Preheat / soak

SnPb EUTECTIC ASSEMBLY

LEAD (Pb)-FREE ASSEMBLY

Temperature min. (T_{s min.}

)

100 °C

150 °C

200 °C

Temperature max. (T_{s max.}

)

Time (t_s) from (T_{s min.}to T_{s max.}

Ramp-up

)

60 s to 120 s

Ramp-up rate (T_Lto T_P)

Liquidus temperature (T_L)

Time (t_L) maintained above T_L

3 °C/s max.

183 °C

3 °C/s max.

217 °C

60 s to 150 s

220

60 s to 150 s

245

Peak package body temperature (T_p)

Time (t_p) within 5 °C of the specified

classification temperature (T_C)

20 s

30 s

Time 25 °C to peak temperature

Ramp-down

6 min max.

8 min max.

Ramp-down rate (T_Pto T_L)

Time 25 °C to peak temperature

6 °C/s max.

6 min max.

6 °C/s max.

8 min max.

PAD DIMENSIONS in inches [millimeters]

CASE CODE

A (MIN.)

B (NOM.)

C (NOM.)

0.100 [2.50]

D (NOM.)

0.295 [7.50]

0.138 [3.50]

0.374 [9.50]

Revision: 13-May-2020

Document Number: 40187

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THIS DOCUMENT IS SUBJECT TO CHANGE WITHOUT NOTICE. THE PRODUCTS DESCRIBED HEREIN AND THIS DOCUMENT

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TYPICAL PERFORMANCE CHARACTERISTICS OF T22 CAPACITORS

ELECTRICAL PERFORMANCE CHARACTERISTICS

ITEM

PERFORMANCE CHARACTERISTICS

-55 °C to +85 °C (to +125 °C with voltage derating)

20 ꢀ, 10 ꢀ at +25 °C, 120 Hz

Category temperature range

Capacitance tolerance

Capacitance change by temperature Limit per Standard Ratings table

ESR

Limit per Standard Ratings table, at +25 °C, 120 Hz

Impedance

Limit per Standard Ratings table, at -55 °C, 120 Hz

Limit per Standard Ratings table

DCL (leakage current)

AC ripple current

Reverse voltage

Limit per Standard Ratings table, at +85 °C and 40 kHz

Reverse voltage shall be in accordance with MIL-PRF-39006, paragraphs 3.23 and 4.8.19, except DC

potential will be maximum of 3 V

Maximum operating voltage

OPERATING TEMPERATURE

+85 °C

+125 °C

RATED VOLTAGE

SURGE VOLTAGE

(V_DC

DERATED VOLTAGE

(V_DC

)

(V_DC

)

57.5

86.2

100

125

115.0

144.0

Surge voltage

The DC surge voltage is the maximum voltage to which the capacitor can be subjected under any

conditions including transients and peak ripple at the highest line voltage.

The DC surge voltage is 115 ꢀ of rated DC voltage

PERFORMANCE CHARACTERISTICS

ITEM

CONDITION

POST TEST PERFORMANCE

Surge voltage In accordance with MIL-PRF-39006:

85 °C 1000 successive test cycles at

the applicable DC surge voltage

Capacitance change

Leakage current

Within 10 ꢀ of initial measured value

Not to exceed specified value

specified in series with a 1 k resistor

at the rate of 30 s ON, 5.5 min OFF

Life testing

In accordance with MIL-PRF-39006:

capacitors shall be capable of

Capacitance change

Leakage current at 85 °C / 125 °C Not to exceed 125 ꢀ of initial specified value

+10 ꢀ / -20 ꢀ of initial measured value

withstanding a 2000 h life test at a

Leakage current at 25 °C

Not to exceed specified value

temperature +85 °C at rated voltage, ESR

or a 2000 h life test at a temperature

+125 °C at derated voltage

Not to exceed 200 ꢀ of specified value

AC ripple life

In accordance with MIL-PRF-39006: 2000 h, +85 °C

Revision: 13-May-2020

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ENVIRONMENTAL CHARACTERISTICS

ITEM

CONDITION

POST TEST PERFORMANCE

Stability at low and

high temperatures

As specified in MIL-PRF-39006

The capacitors shall meet the requirements of MIL-PRF-39006

Seal

MIL-PRF-39006

Method 112 of MIL-STD-202,

conditions A and C

When the capacitors are tested as specified in MIL-PRF-39006,

there shall be no evidence of leakage.

Moisture resistance

MIL-PRF-55365

DC leakage

Not exceed 125 ꢀ of the specified value

Method 106 of MIL-STD-202,

Capacitance change Within 10 ꢀ of the initial measured value

number of cycles: 10 continuous cycles except ESR

Not exceed the specified value

that steps 7a and 7b shall be omitted.

Barometricpressure Method 105 of MIL-STD-202, condition E

There shall be no mechanical or visual damage to capacitors

post-conditioning.

(reduced)

(150 000 feet) (45,720.1 m).

Low temperature

storage

MIL-PRF-39006

Method 502 of MIL-STD-810,

Storage temperature: - 62 °C + 0 °C, - 3 °C

Exposure time: 72 h followed by a 1 h exposure

at + 125 °C + 7 °C, - 0 °C within 24 h after low

temperature storage.

DC leakage

Capacitance change Within 10 ꢀ of the initial measured value

ESR Not exceed the specified value

Not to exceed 125 ꢀ of the specified value

Salt atmosphere

(corrosion)

MIL-PRF-39006

Method 101 of MIL-STD-202,

condition B (48 h), applicable salt solution: 5 ꢀ

There shall be no harmful corrosion. Marking shall remain legible.

MECHANICAL PERFORMANCE CHARACTERISTICS

ITEM

CONDITION

POST TEST PERFORMANCE

Shear test

AEC-Q200-006

DC leakage

Capacitance change Within 10 ꢀ of the initial measured value

ESR Not exceed the specified value

Not to exceed 125 ꢀ of the specified value

Apply a pressure load of 5 N for 10 s 1 s

horizontally to the center of capacitor

side body.

There shall be no mechanical or visual damage to capacitors

post-conditioning.

Solderability

MIL-STD-202, method 208, test B

ANSI/J-STD-002:

SnPb solder - test B

All terminations shall exhibit a continuous solder coating free

from defects for a minimum of 95 ꢀ of the critical area of any

individual lead.

Pb-free solder - test B1

Resistance

to solvent

MIL-STD-202, method 215

There shall be no mechanical or visual damage to capacitors

post-conditioning. Marking shall remain legible, no degradation

of the can material.

Insulation

resistance

Method 302 of MIL-STD-202, condition B

(500 V_DC10 ꢀ)

The insulation resistance shall be not less than 100 M.

The capacitors shall meet the requirements of MIL-PRF-39006.

Shock

MIL-STD-202, method 213,condition D (500 g) The capacitors shall meet the requirements of MIL-PRF-39006.

(specified pulse)

Vibration,

high frequency

MIL-STD-202, method 204, condition H

(80 g peak)

The capacitors shall meet the requirements of MIL-PRF-39006.

Random vibration

Thermal shock

MIL-STD-202, method 214, condition II-G

(overall RMS 27.78 G)

MIL-STD-202, method 107, condition A

Thermal shock shall be in accordance with MIL-PRF-39006 when

tested for 300 cycles.

Resistance to

soldering heat

MIL-STD-202, method 210, condition J,

except with only one heat cycle

Capacitance change Within 10 ꢀ of initial

ESR

Initial specified value or less

Leakage current

Initial specified value or less

There shall be no mechanical or visual damage to capacitors

post-conditioning.

Revision: 13-May-2020

Document Number: 40187

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TYPICAL CURVES OF IMPEDANCE AS A FUNCTION OF FREQUENCY AT VARIOUS TEMPERATURES

“C” Case 50 V Capacitors

100

-55 °C

-40 °C

-20 °C

1.0

+25 °C

+85 °C

+125 °C

0.1

100

100K

10K

Frequency (Hz)

10M

PERFORMANCE CHARACTERISTICS

1. Operating Temperature: capacitors are designed to

6. Equivalent Series Resistance: measurements shall be

made by the bridge method at, or referred to, a

frequency of 120 Hz at a temperature of +25 °C. A

operate over a temperature range of -55 °C to +125 °C.

UP TO +85 °C

(V)

AT +125 °C

(V)

maximum of

measurement.

V_RMSshall be applied during

6.1 The equivalent series resistance shall not exceed the

maximum value in ohms listed in the Standard Ratings

table for each capacitor.

100

125

6.2 The dissipation factor may be calculated from the

equivalent series resistance and capacitance values as

shown:

2. DC Working Voltage: the DC working voltage is the

maximum operating voltage for continuous duty at the

rated temperature.

2fRC

3. Surge Voltage: the surge voltage rating is the maximum

voltage to which the capacitors should be subjected

under any conditions. This includes transients and peak

ripple at the highest line voltage.

-----------------

DF =

10⁴

where:

DF = dissipation factor in ꢀ

R = ESR in 

C = capacitance in μF

3.1 The surge voltage of capacitors is 115 ꢀ of rated DC

working voltage.

3.2 Surge Voltage Test: capacitors shall withstand the

surge voltage applied through a 1000  10 ꢀ resistor

in series with the capacitor and voltage source at the

rate of one-half minute on, five and one-half minutes off,

for 1000 successive test cycles at +85 °C.

f = frequency in Hz

At 120 Hz, the above equation becomes:

R x C

13.26

--------------

DF =

3.3 Following the surge voltage test, the capacitance at

+25 °C shall not have changed by more than 10 ꢀ and

the equivalent series resistance and DC leakage current

will not exceed the values shown in the Standard

Ratings table for each capacitor.



For example, percent dissipation factor of a 30 μF, 6 V

capacitor, which has a maximum ESR of 4.0  at

+25 °C and 120 Hz, would be calculated as shown:

2 x 120 x 4 x 30

4 x 30

13.26

---------------------------------------------

---------------

= 9.05 ꢀ

DF =

4. Capacitance Tolerance: the capacitance of all

capacitors shall be within the specified tolerance limits

of the nominal rating.

10⁴

7. Leakage Current: measurements shall be made at the

applicable rated working voltage at +25 °C 5 °C

4.1 Measurements shall be made by the bridge method at

or referred to a frequency of 120 Hz at a temperature of

+25 °C. The maximum voltage applied to the capacitors

during measurement shall be 1 V_RMS. Measurement

accuracy of the bridge shall be within 2 ꢀ.

through application of a steady source of power, such

as a regulated power supply. A 1000  resistor to limit

the charging current shall be connected in series with

each capacitor under test. Rated working voltage shall

be applied to capacitors for 5 minutes before making

leakage current measurements.

5. Capacitance Change With Temperature: the

capacitance change with temperature shall not exceed

the values given in the Standard Ratings table for each

capacitor.

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7.1 The maximum leakage current for any capacitor shall

not exceed the maximum value in μA listed in the

Standard Ratings table for each capacitor.

Note

10. Ripple Life Test at +85 °C: capacitors shall be tested

accordance

with

military

specification

MIL-PRF-39006 except that:

a) Operation conditions: this test shall be run at a

frequency of 40 kHz 2 kHz sinusoidal and at the

RMS ripple current levels specified in the Standard

Ratings table.

b) Applied DC voltage shall be reduced so that the

peak AC voltage plus DC voltage shall not exceed

the rated voltage of the capacitor in either the

forward or reverse direction.

•

Leakage current varies with applied voltage. See graph next

column for the appropriate adjustment factor

8. Low Temperature Impedance: the impedance of any

capacitor at -55 °C at 120 Hz, shall not exceed the

values given in the Standard Ratings table.

9. Life Test: capacitors are capable of withstanding a

2000 h life test at a temperature of +85 °C or +125 °C at

the applicable rated DC working voltage.

10.1 When tested as specified above, capacitors shall meet

the following requirements:

a) The DC leakage current at +25 °C and at +85 °C

shall not exceed the original requirements.

b) The capacitance shall not change more than 15 ꢀ

from the initial measured value.

c) The dissipation factor shall not exceed the original

requirements.

d) Visual examination: There shall be no damage,

obliteration of marking or leakage of electrolyte.

9.1 Following the life test, the capacitors shall be returned

to 25 °C

5 °C. The leakage current, measured at

the +85 °C rated voltage, shall not be in excess of

the original requirement; the capacitance value shall

not exceed 150 ꢀ of the initial requirement; the

capacitance value shall not change more than + 10 ꢀ /

- 20 ꢀ from the initial measurement.

TYPICAL LEAKAGE CURRENT FACTOR

RANGE

GUIDE TO APPLICATION

1. AC Ripple Current: subjecting a capacitor to an AC

voltage causes an AC current to flow through it. The

amplitude of the current is dependent on the impedance

of the capacitor at the frequency of the applied signal:

1.0

0.9

0.8

0.7

0.6

---

I =

0.5

0.4

where:

I = ripple current

V = applied AC voltage

0.3

0.2

Z = impedance of capacitor (frequency dependent)

This current causes heating in the capacitor because of

I²R losses (R is the equivalent series resistance at the

applied frequency). This heating or power dissipation, is

one of the limiting factors of the capacitor’s ripple current

rating.

0.1

These power dissipation ratings are based on a

calculated +50 °C internal temperature rise in still air. The

maximum allowable ripple currents given in the Standard

Ratings table are based on these ratings and the

maximum equivalent series resistance at that frequency.

0.09

0.08

0.07

0.06

The relationship is written as follows:

0.05

0.04

P = I²R

where:

0.03

0.02

P = maximum power

I = maximum ripple current

R = equivalent series resistance

Therefore:

0.01

I = ---

10 20 30 40 50 60 70 80 90 100

where:

PERCENT OF RATED VOLTAGE

R is in 

P is in W

I is in A_RMS

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2. AC Ripple Voltage: in operation, the peak voltage

across the capacitor (DC working voltage plus peak

ripple voltage) must not exceed the rated working

voltage of the capacitor. The DC component of the

applied voltage should be sufficiently large to prevent

polarity reversal in excess of 3 V at +85 °C or 2 V at

125 °C.

TYP. ESR AS A FUNCTION OF FREQUENCY

1.4

1.2

1.0

0.8

0.6

0.4

0.2

There will be a point at the lower frequency and

capacitance values when the peak AC voltage will be

the limiting factor on the ripple current - not its heating

effects.

3. Ripple Current Multipliers: the Standard Ratings table

list the maximum permissible RMS ripple current at

40 kHz for each rating. These values are based on the

maximum power dissipation allowed at that frequency.

100

10K

40K 100K

FREQUENCY (Hz)

This ripple current, will cause heating, which adds to the



ambient

temperature.

The

higher

ambient

temperatures, voltage derating or current derating is

required (see “Ripple Current Multipliers” table). Also

shown are the multipliers for ripple currents at various

frequencies, caused by the frequency dependence of

the (ESR) equivalent series resistance. (see “Typical

ESR as a Function of Frequency” chart)

RIPPLE CURRENT MULTIPLIERS VS. FREQUENCY, TEMPERATURE AND APPLIES PEAK VOLTAGE

FREQUENCY

OF APPLIED

120 Hz

800 Hz

1 kHz

10 kHz

40 kHz

100 kHz

RIPPLE

CURRENT

AMBIENT STILL

AIR TEMP. IN °C

 55 85 105 125  55 85 105 125  55 85 105 125  55 85 105 125  55 85 105 125  55 85 105 125

100 ꢀ 0.60 0.39

90 ꢀ 0.60 0.46

0.71 0.43

0.71 0.55

0.72 0.46

0.72 0.55

0.88 0.55

0.88 0.67

1.0 0.63

1.0 0.77

1.1 0.69

1.1 0.85

% of

85 °C

rated

peak

80 ꢀ 0.60 0.52 0.35

70 ꢀ 0.60 0.58 0.44

0.71 0.62 0.42

0.71 0.69 0.52

0.72 0.62 0.42

0.72 0.70 0.52

0.88 0.76 0.52

0.88 0.85 0.64

1.0 0.87 0.59

1.0 0.97 0.73

1.1 0.96 0.65

1.1 1.07 0.80

voltage

66 2/3 ꢀ 0.60 0.60 0.46 0.27 0.71 0.71 0.55 0.32 0.72 0.72 0.55 0.32 0.88 0.88 0.68 0.40 1.0 1.0 0.77 0.45 1.1 1.1 0.85 0.50

Revision: 13-May-2020

Document Number: 40187

For technical questions, contact: tantalum@vishay.com

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Document Number: 91000

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