C0402C0G1C220JT [TDK]

MULTILAYER CERAMIC CHIP CAPACITORS;


型号：	C0402C0G1C220JT
厂家：	TDK ELECTRONICS
描述：	MULTILAYER CERAMIC CHIP CAPACITORS
文件：	总34页 (文件大小：577K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

SPEC. No. C-General-b

D A T E : 2014 June.

SPECIFICATION

Non-Controlled Copy

Upon the acceptance of this spec.

previous spec. (C2004-816-031)

shall be abolished.

CUSTOMER’S PRODUCT NAME

TDK PRODUCT NAME

MULTILAYER CERAMIC CHIP CAPACITORS

C Series / Commercial Grade

General (Up to 50V)

Mid voltage (100 to 630V)

Please return this specification to TDK representatives.

If orders are placed without returned specification, please allow us to judge that specification is

accepted by your side.

RECEIPT CONFIRMATION

DATE:

YEAR

MONTH

DAY

TDK Corporation

Sales

TDK-EPC Corporation

Engineering

Ceramic Capacitors Business Group

Electronic Components

Sales & Marketing Group

APPROVED

Person in charge

APPROVED

CHECKED

Person in charge

1. SCOPE

This specification is applicable to chip type multilayer ceramic capacitors with a priority over the other

relevant specifications.

Production places defined in this specification shall be TDK-EPC Corporation Japan,

TDK (Suzhou) Co., Ltd and TDK Components U.S.A. Inc.

EXPLANATORY NOTE:

This specification warrants the quality of the ceramic chip capacitors. The chips should be evaluated

or confirmed a state of mounted on your product.

If the use of the chips goes beyond the bounds of the specification, we can not afford to guarantee.

2. CODE CONSTRUCTION

(Example)

C2012

(1)

X7R

(2)

(3)

105

(4)

(5)

125

(6)

Catalog Number :

(Web)

(7) (8)

Item Description : C2012

(1)

X7R

(2)

(3)

105

(4)

(5)

(9)

xxxx

(10)

(1) Type

Terminal electrode

Internal electrode

Ceramic dielectric

Please refer to product list for the dimension of each product.

(2) Temperature Characteristics (Details are shown in table 1 No.7 and No.8 at page 5)

(3) Rated Voltage

Symbol

2 J

Rated Voltage

DC 630 V

DC 450 V

DC 350 V

DC 250 V

DC 100 V

DC 50 V

DC 35 V

DC 25 V

DC 16 V

DC 10 V

DC 6.3 V

DC 4 V

2 W

2 V

2 E

2 A

1 H

1 V

1 E

1 C

1 A

0 J

0 G

— 1 —

(4) Rated Capacitance

Stated in three digits and in units of pico farads (pF).

The first and Second digits identify the first and second significant figures of the capacitance,

the third digit identifies the multiplier.

R is designated for a decimal point.

Example 2R2

105

→

2.2pF

1,000,000pF

(5) Capacitance tolerance

Symbol

Tolerance

Capacitance

0.1 pF

0.25 pF

0.5 pF

5 %

10pF and under

± 10 %

± 20 %

Over 10pF

(6) Thickness code (Only Catalog Number)

(7) Package code (Only Catalog Number)

(8) Special code (Only Catalog Number)

(9) Packaging (Only Item Description)

Symbol

Packaging

Bulk

Taping

(10) Internal code (Only Item Description)

— 2 —

3. RATED CAPACITANCE AND CAPACITANCE TOLERANCE

3.1 Standard combination of rated capacitance and tolerances

Temperature

Characteristics

Class

Capacitance tolerance

B (±0.1 pF)

Rated capacitance

0.5, 1, 1.5, 2, 2.2, 3, 3.3, 4, 4.7, 5

6, 6.8, 7, 8, 9, 10

10pF and

C (±0.25pF)

under

D (±0.5pF)

C H

C0G

12pF to

E – 12 series

J (± 5 %)

10,000pF

Over

10,000pF

K (± 10 %)

E – 6 series

J B

X5R

X6S

X7R

X7S

X7T

K (± 10 %)

M (± 20 %)

10uF and

under

E – 6 series

Over 10uF

M (± 20 %)

3.2 Capacitance Step in E series

E series

Capacitance Step

2.2

E- 3

E- 6

E-12

1.0

4.7

1.0

1.5

2.2

3.3

4.7

6.8

1.0 1.2 1.5 1.8 2.2 2.7 3.3 3.9 4.7 5.6 6.8 8.2

4. OPERATING TEMPERATURE RANGE

Min. operating

Temperature

Max. operating

Temperature

Reference

Temperature

T.C.

C H

J B

-25°C

-55°C

85°C

20°C

25°C

X5R

X6S

85°C

105°C

X7R

X7S

X7T

C0G

-55°C

125°C

25°C

5. STORING CONDITION AND TERM

5 to 40°C at 20 to 70%RH

6 months Max.

6. P.C. BOARD

When mounting on an aluminum substrate, large case sizes such as C3225, C4532 and C5750

types are more likely to be affected by heat stress from the substrate.

Please inquire separate specification for the large case sizes when mounted on the substrate.

7. INDUSTRIAL WASTE DISPOSAL

Dispose this product as industrial waste in accordance with the Industrial Waste Law.

— 3 —

8. PERFORMANCE

table 1

Performance

No.

Item

Test or inspection method

External Appearance No defects which may affect

performance.

Inspect with magnifying glass (3×), in case

of C0402 and C0603 type, with magnifying

glass (10×)

Insulation Resistance 10,000MΩ or 500MΩ·μF min.

(As for the capacitors of rated

Apply rated voltage for 60s.

voltage 16, 10V DC and lower,

10,000 MΩ or 100MΩ·μF min.,)

whichever smaller.

Voltage Proof

Withstand test voltage without

insulation breakdown or other

damage.

Class

Rated voltage

100V and under

Apply voltage

3 × rated voltage

Over 100V

Class1

1.5 × rated voltage

1.3× rated voltage

500V and under

Over 500V

100V and under 2.5 × rated voltage

Over 100V

Class2

1.5 × rated voltage

500V and under

Over 500V

1.3× rated voltage

Above DC voltage shall be applied for

1s.

Charge / discharge current shall not

exceed 50mA.

Capacitance

Within the specified tolerance.

Rated

Capacitance

Measuring

frequency

Measuring

voltage

Class

1000pF and

under

1MHz±10%

1kHz±10%

Class1

0.5-5 Vrms.

Over 1000pF

0.5±0.2Vrms.

1.0±0.2Vrms.

10uF and

under

1kHz±10%

Class2

Over 10uF

120Hz±20% 0.5±0.2Vrms.

For information which product has which

measuring voltage, please contact with our

sales representative.

See No.4 in this table for measuring

condition.

Rated Capacitance

30pF and over

Under 30pF

(Class1)

1,000 min.

400+20×C min.

C : Rated capacitance (pF)

Dissipation Factor

(Class2)

See No.4 in this table for measuring

condition.

T.C.

D.F.

J B

0.025 max.

0.03 max.

0.05 max.

0.075 max.

0.10 max.

0.15 max.

X5R

X6S

X7R

X7S

X7T

For information which product has which

Dissipation Factor, please contact with our

sales representative.

— 4 —

(continued)

No.

Item

Performance

Test or inspection method

Temperature

Characteristics

of Capacitance

(Class1)

Temperature coefficient shall be

calculated based on values at 25°C and

85°C temperature.

Temperature Coefficient

(ppm/°C)

T.C.

C H

0 ± 60

0 ± 30

C0G

Measuring temperature below 20°C shall

be -10°C and -25°C.

Capacitance drift

Within ± 0.2% or ±0.05pF,

whichever larger.

Temperature

Characteristics

of Capacitance

(Class2)

Capacitance shall be measured by the

steps shown in the following table after

thermal equilibrium is obtained for each

step.

Capacitance Change (%)

No voltage

applied

With voltage

applied

J B : ±10

J B : + 10

− 30

∆C be calculated ref. STEP3 reading

Step

Temperature(°C)

Reference temp. ± 2

Min. operating temp. ± 2

Reference temp. ± 2

Max. operating temp. ± 2

: + 10

− 50

: + 10

− 60

: ——

X5R : ±15

X6S : ±22

X7R : ±15

X7S : ±22

X7T : +22

-33

——

Measuring voltage: 0.1, 0.2, 0.5, 1.0Vrms.

For information which product has which

applied voltage, please contact with our

sales representative.

Robustness of

Terminations

No sign of termination coming off, Reflow solder the capacitors on a

breakage of ceramic, or other

abnormal signs.

P.C.Board shown in Appendix 1a or

Appendix 1b and apply a pushing force

of 2N (C0603, C1005) or 5N (C1608,

C2012, C3216, C3225, C4532, C5750)

with 10±1s.

(Not applicable to C0402.)

Pushing force

P.C.Board

Capacitor

Bending

No mechanical damage.

Reflow solder the capacitors on a

P.C.Board shown in Appendix 2a or

Appendix 2b and bend it for 1mm.

R230

(Unit : mm)

— 5 —

(continued)

No.

Item

Performance

Test or inspection method

11 Solderability

(C0402)

Completely soak both terminations in

solder at 235±5°C for 2 ± 0.5s.

Both end faces and the contact areas

shall be covered with a smooth and

bright solder coating with no more than

a small amount of scattered

imperfections such as pinholes or

un-wetted or de-wetted areas.

These imperfections shall not be

concentrated in one area.

Solder : H63A (JIS Z 3282)

Flux: Isopropyl alcohol (JIS K 8839)

Rosin (JIS K 5902) 25% solid

solution.

(Others)

Only reflow soldering applicable to

New solder to cover over 75% of termination. C0402.

25% may have pin holes or rough spots

but not concentrated in one spot.

Ceramic surface of A sections shall not

be exposed due to melting or shifting of

termination material.

Peak condition

Temp. : 235±5°C

Time: 2±0.5s.

Preheating condition

Temp. : 150±10°C

Time: 1 to 2min.

A section

— 6 —

(continued)

No.

Item

Performance

Test or inspection method

12 Resistance External

No cracks are allowed and

Completely soak both terminations in

solder at 260±5°C for 5±1s.

to solder

heat

appearance terminations shall be covered at

least 60% with new solder.

Preheating condition

Temp. : 150±10°C

Time: 1 to 2min.

Capacitance

Change from the

Characteristics

value before test

Capacitance drift

Class

C H within ±2.5% or

C0G ±0.25pF,

Solder : H63A (JIS Z 3282)

whichever larger.

J B

X5R

Class X6S

± 7.5 %

Flux : Isopropyl alcohol (JIS K 8839)

Rosin (JIS K 5902) 25% solid

solution.

X7R

X7S

X7T

Leave the capacitors in ambient

condition for 6 to 24h (Class1) or 24±2h

(Class2) before measurement.

Rated Capacitance

30pF and over

Under 30pF

(Class1)

1,000 min.

Only reflow soldering applicable to

C0402.

400+20×C min.

C : Rated capacitance (pF)

Meet the initial spec.

Peak condition

D.F.

Temp. : 235±5°C

Time: 2±0.5s.

(Class2)

Preheating condition

Temp. : 150±10°C

Time : 1 to 2min.

Insulation

Resistance

Voltage

proof

Meet the initial spec.

No insulation breakdown or other

damage.

13 Vibration

External

No mechanical damage.

Reflow solder the capacitors on a

P.C.Board shown in Appendix 1a or

Appendix 1b before testing.

appearance

Capacitance

Change from the

Characteristics

value before test

Vibrate the capacitors with amplitude

of 1.5mm P-P changing the

frequencies from 10Hz to 55Hz and

back to 10Hz in about 1min.

Repeat this for 2h each in 3

perpendicular directions.

C H ±2.5% or ±0.25pF,

Class1

C0G whichever larger.

J B

± 7.5 %

X5R

X6S

X7R

X7S

X7T

Class2

Rated Capacitance

30pF and over

Under 30pF

(Class1)

1,000 min.

400+20×C min.

C : Rated capacitance (pF)

Meet the initial spec.

D.F.

(Class2)

— 7 —

(continued)

No.

Item

Performance

Test or inspection method

14 Temperature External

cycle appearance

Capacitance

No mechanical damage.

Reflow solder the capacitors on a

P.C.Board shown in Appendix1a or

Appendix1b before testing.

Change from the

value before test

Characteristics

Expose the capacitors in the condition

step1 through step 4 and repeat 5 times

consecutively.

±2.5% or

±0.25pF,

whichever larger.

C H

Class1

C0G

J B

X5R

X6S

X7R

X7S

X7T

Leave the capacitors in ambient

condition for 6 to 24h (Class 1) or

24±2h (Class 2) before measurement．

± 7.5 %

± 10 %

± 12.5 %

*Class2

Step Temperature(°C) Time (min.)

Min. operating

* Applied for some parts.

30 ± 3

temp. ± 3

Rated Capacitance

30pF and over

(Class1)

1,000 min.

Reference Temp.

2 - 5

Under 30pF

400+20×C min.

Max. operating

temp. ± 2

30 ± 2

2 - 5

C : Rated capacitance (pF)

Meet the initial spec.

D.F.

Reference Temp.

(Class2)

Insulation

Meet the initial spec.

Resistance

Voltage

proof

No insulation breakdown or other

damage.

— 8 —

(continued)

No.

Item

External

Performance

Test or inspection method

15 Moisture

No mechanical damage.

Reflow solder the capacitors on a

P.C.Board shown in Appendix 1a or

Appendix 1b before testing.

Resistance appearance

(Steady

Capacitance

State)

Change from the

value before test

Characteristics

Leave at temperature 40 ± 2°C, 90 to

95%RH for 500 +24,0h.

C H ±5% or ±0.5pF,

C0G whichever larger.

Class1

J B

X5R

X6S

X7R

Leave the capacitors in ambient

condition for 6 to 24h (Class1) or 24 ±

2h (Class2) before measurement.

± 10 %

*Class2

± 12.5 %

± 25 %

X7S

X7T

* Applied for some parts.

Rated Capacitance

30pF and over

10pF and over

(Class1)

350 min.

275+5/2×C min.

200+10×C min.

under 30pF

Under 10pF

C : Rated capacitance (pF)

200% of initial spec. max.

D.F.

(Class2)

Insulation

1,000MΩ or 50MΩ·μF min.

Resistance (As for the capacitors of rated

voltage 16, 10V DC and lower,

1,000 MΩ or 10MΩ·μF min.,)

whichever smaller.

— 9 —

(continued)

No.

16 Moisture

Item

External

Performance

Test or inspection method

No mechanical damage.

Reflow solder the capacitors on a

P.C.Board shown in Appendix1a or

Appendix 1b before testing.

Resistance appearance

Capacitance

Change from the

value before test

Apply the rated voltage at

temperature 40±2°C and 90 to

95%RH for 500 +24,0h.

Characteristics

C H ±7.5% or ±0.75pF,

C0G whichever larger.

Class1

Charge/discharge current shall not

exceed 50mA.

J B

X5R

X6S

X7R

X7S

X7T

± 10 %

*Class2

± 12.5 %

Leave the capacitors in ambient

condition for 6 to 24h (Class1) or

24±2h (Class2) before measurement.

± 25 %

* Applied for some parts.

Voltage conditioning (only for class 2)

Voltage treat the capacitors under

testing temperature and voltage for 1

hour.

Rated Capacitance

30pF and over

(Class1)

200 min.

Under 30pF

100+10/3×C min.

Leave the capacitors in ambient

condition for 24±2h before

measurement.

C : Rated capacitance (pF)

200% of initial spec. max.

D.F.

(Class2)

Use this measurement for initial

value.

Insulation

Resistance

500MΩ or 25MΩ·μF min.

(As for the capacitors of rated

voltage 16, 10V DC and lower, 500

MΩ or 5MΩ·μF min.,) whichever

smaller.

— 10 —

(continued)

No.

Item

External

Performance

Test or inspection method

17 Life

No mechanical damage.

Reflow solder the capacitors on a

P.C.Board shown in Appendix1a or

Appendix 1b before testing.

appearance

Capacitance

Change from the

value before test

Below the voltage shall be applied at

maximum operating temperature ±2°C

for 1,000 +48, 0h.

Characteristics

C H ±3% or ±0.3pF,

C0G whichever larger.

Class1

Applied voltage

Rated voltage x2

Rated voltage x1.5

Rated voltage x1.2

Rated voltage x1

J B

X5R

X6S

X7R

X7S

X7T

± 10 %

*Class2

± 12.5 %

± 25 %

* Applied for some parts.

For information which product has

which applied voltage, please contact

with our sales representative.

Rated Capacitance

(Class1)

30pF and over

350 min.

10pF and over under

275+5/2×C min.

200+10×C min.

30pF

Charge/discharge current shall not

exceed 50mA.

Under 10pF

C : Rated capacitance (pF)

200% of initial spec. max.

Leave the capacitors in ambient

condition for 6 to 24h (Class1) or

24±2h (Class2) before measurement.

D.F.

(Class2)

Insulation

1,000MΩ or 50MΩ·μF min.

Voltage conditioning (only for class 2)

Voltage treat the capacitors under

testing temperature and voltage for 1

hour.

Resistance (As for the capacitors of rated

voltage 16, 10V DC and lower,

1,000 MΩ or 10MΩ·μF min.,)

whichever smaller.

Leave the capacitors in ambient

condition for 24±2h before

measurement.

Use this measurement for initial value.

*As for the initial measurement of capacitors (Class2) on number 8,12,13,14 and 15, leave capacitors at 150

-10,0°C for 1 hour and measure the value after leaving capacitors for 24 ± 2h in ambient condition.

— 11 —

Appendix - 1a

Appendix - 1b

P.C. Board for reliability test

Applied for C0402, C0603, C1005, C1608, C2012, C3216

P.C. Board for reliability test

Applied for C3225, C4532, C5750

100

Copper

Solder resist

Copper

Solder resist

Slit

(Unit : mm)

(Unit：mm)

Appendix - 2b

Appendix - 2a

P.C. Board for bending test

Applied for C1608, C2012, C3216, C3225, C4532, C5750

P.C. Board for bending test

Applied for C0402, C0603, C1005

100

Copper

Solder resist

(Unit : mm)

Copper

Dimensions (mm)

TDK (EIA style)

Material : Glass Epoxy ( As per JIS C6484 GE4 )

C0402 (CC01005)

C0603 (CC0201)

C1005 (CC0402)

C1608 (CC0603)

C2012 (CC0805)

C3216 (CC1206)

C3225 (CC1210)

C4532 (CC1812)

C5750 (CC2220)

0.2

0.3

0.4

1.0

1.2

2.2

3.5

4.5

0.8

1.5

3.0

4.0

5.0

7.0

8.0

0.2

0.3

0.5

1.2

1.65

2.0

2.9

3.7

5.6

P.C. Board thickness : Appendix-2a

Appendix-1a, 1b, 2b

0.8mm

1.6mm

Copper ( thickness 0.035mm )

Solder resist

— 12 —

9. INSIDE STRUCTURE AND MATERIAL

MATERIAL

No.

NAME

Class1

CaZrO₃

Class2

BaTiO₃

Dielectric

Electrode

Nickel (Ni)

Copper (Cu)

Nickel (Ni)

Tin (Sn)

Termination

10. RECOMMENDATION

As for C3225, C4532 and C5750 types, It is recommended to provide a slit (about 1mm wide)

in the board under the components to improve washing Flux. And please make sure to dry

detergent up completely before.

11. SOLDERING CONDITION

As for C0402, C0603, C1005, C3225, C4532 and C5750 types, reflow soldering only.

— 13 —

12. Caution

No.

Process

Operating

Condition

1-1. Storage

1) The capacitors must be stored in an ambient temperature of 5 to 40°C with a

relative humidity of 20 to 70%RH. The products should be used within 6 months

upon receipt.

2) The capacitors must be operated and stored in an environment free of dew

condensation and these gases such as Hydrogen Sulphide, Hydrogen Sulphate,

Chlorine, Ammonia and sulfur.

(Storage,

Transportation)

3) Avoid storing in sun light and falling of dew.

4) Do not use capacitors under high humidity and high and low atmospheric pressure

which may affect capacitors reliability.

5) Capacitors should be tested for the solderability when they are stored for long time.

1-2. Handling in transportation

In case of the transportation of the capacitors, the performance of the capacitors

may be deteriorated depending on the transportation condition.

(Refer to JEITA RCR-2335B 9.2 Handling in transportation)

2-1. Operating temperature

Circuit design

Operating temperature should be followed strictly within this specification, especially

be careful with maximum temperature.



Caution

1) Do not use capacitors above the maximum allowable operating temperature.

2) Surface temperature including self heating should be below maximum operating

temperature.

(Due to dielectric loss, capacitors will heat itself when AC is applied. Especially at

high frequencies around its SRF, the heat might be so extreme that it may damage

itself or the product mounted on. Please design the circuit so that the maximum

temperature of the capacitors including the self heating to be below the maximum

allowable operating temperature. Temperature rise at capacitor surface shall be

below 20°C)

3) The electrical characteristics of the capacitors will vary depending on the

temperature. The capacitors should be selected and designed in taking the

temperature into consideration.

2-2. Operating voltage

1) Operating voltage across the terminals should be below the rated voltage.

When AC and DC are super imposed, V_0-Pmust be below the rated voltage.

— (1) and (2)

AC or pulse with overshooting, V_P-Pmust be below the rated voltage.

— (3), (4) and (5)

When the voltage is started to apply to the circuit or it is stopped applying, the

irregular voltage may be generated for a transit period because of resonance or

switching. Be sure to use the capacitors within rated voltage containing these

Irregular voltage.

Voltage

(1) DC voltage

(2) DC+AC voltage

(3) AC voltage

Positional

Measurement

(Rated voltage)

V_0-P

V_P-P

Voltage

(4) Pulse voltage (A) (5) Pulse voltage (B)

Positional

Measurement

(Rated voltage)

V_P-P

— 14 —

No.

Process

Condition

2) Even below the rated voltage, if repetitive high frequency AC or pulse is applied, the

reliability of the capacitors may be reduced.

Circuit design



Caution

3) The effective capacitance will vary depending on applied DC and AC voltages.

The capacitors should be selected and designed in taking the voltages into

consideration.

2-3. Frequency

When the capacitors (Class 2) are used in AC and/or pulse voltages, the

capacitors may vibrate themselves and generate audible sound.

The amount of solder at the terminations has a direct effect on the reliability of the

capacitors.

1) The greater the amount of solder, the higher the stress on the chip capacitors,

and the more likely that it will break. When designing a P.C.board, determine the

shape and size of the solder lands to have proper amount of solder on the

terminations.

Designing

P.C.board

2) Avoid using common solder land for multiple terminations and provide individual

solder land for each terminations.

3) Size and recommended land dimensions.

Chip capacitors

Solder land

Solder resist

Flow soldering

Type

(mm)

C3216

C1608

C2012

Symbol

(CC0603)

(CC0805)

(CC1206)

2.1 - 2.5

1.1 - 1.3

1.0 - 1.3

0.7 - 1.0

0.8 - 1.0

0.6 - 0.8

1.0 - 1.3

1.0 - 1.2

0.8 - 1.1

Reflow soldering

(mm)

C0402

(CC01005)

C0603

(CC0201)

C1005

(CC0402)

C1608

(CC0603) (CC0805)

C2012

Type

Symbol

0.15 - 0.25 0.25 - 0.35

0.15 - 0.25 0.2 - 0.3

0.15 - 0.25 0.25 - 0.35

0.3 - 0.5

0.6 - 0.8

0.9 - 1.2

0.7 - 0.9

0.9 - 1.2

0.35 - 0.45

0.4 - 0.6

C3216

C3225

C4532

C5750

Type

Symbol

(CC1206)

(CC1210)

2.0 - 2.4

1.0 - 1.2

1.9 - 2.5

(CC1812)

3.1 - 3.7

1.2 - 1.4

2.4 - 3.2

(CC2220)

2.0 - 2.4

1.0 - 1.2

1.1 - 1.6

4.1 - 4.8

1.2 - 1.4

4.0 - 5.0

— 15 —

No.

Process

Condition

Designing

P.C.board

4) Recommended chip capacitors layout is as following.

Disadvantage against

bending stress

Advantage against

bending stress

Perforation or slit

Mounting

face

Break P.C.board with

mounted side up.

Break P.C.board with

mounted side down.

Mount perpendicularly to

perforation or slit

Mount in parallel with

perforation or slit

Perforation or slit

Chip

arrangement

(Direction)

Closer to slit is higher stress

Away from slit is less stress

₁

₂

Distance from

slit

(₁

₂

)

(₁< ₂)

— 16 —

No.

Process

Condition

Designing

P.C.board

5) Mechanical stress varies according to location of chip capacitors on the P.C.board.

Perforation

Slit

The stress in capacitors is in the following order.

A > B = C > D > E

6) Layout recommendation

Use of common

solder land with

other SMD

Use of common

solder land

Soldering with

chassis

Example

Lead wire

Chassis

Solder

land

Excessive solder

chip

Solder

Need to

avoid

Excessive solder

Missing

PCB

Adhesive

¹

Solder land

solder

Lead wire

Solder resist

Recommen-

dation

Solder resist

²

²¹

— 17 —

No.

Process

Condition

Mounting

4-1. Stress from mounting head

If the mounting head is adjusted too low, it may induce excessive stress in the chip

capacitors to result in cracking. Please take following precautions.

1) Adjust the bottom dead center of the mounting head to reach on the P.C.board

surface and not press it.

2) Adjust the mounting head pressure to be 1 to 3N of static weight.

3) To minimize the impact energy from mounting head, it is important to provide

support from the bottom side of the P.C.board.

See following examples.

Not recommended

Recommended

Single sided

mounting

Crack

Support pin

Double-sides

mounting

Solder

peeling

Crack

Support pin

When the centering jaw is worn out, it may give mechanical impact on the capacitors

to cause crack. Please control the close up dimension of the centering jaw and

provide sufficient preventive maintenance and replacement of it.

4-2. Amount of adhesive

Example : C2012 (CC0805), C3216 (CC1206)

0.2mm min.

70 - 100μm

Do not touch the solder land

— 18 —

No.

Process

Condition

5-1. Flux selection

Soldering

Although highly-activated flux gives better solderability, substances which increase

activity may also degrade the insulation of the chip capacitors. To avoid such

degradation, it is recommended following.

1) It is recommended to use a mildly activated rosin flux (less than 0.1wt% chlorine).

Strong flux is not recommended.

2) Excessive flux must be avoided. Please provide proper amount of flux.

3) When water-soluble flux is used, enough washing is necessary.

5-2. Recommended soldering profile by various methods

Reflow soldering

Wave soldering

Soldering

Preheating

Natural cooling

Preheating

Peak

Temp

Peak

Temp

△T

∆T

Over 60 sec.

Peak Temp time

Manual soldering

(Solder iron)

APPLICATION

As for C1608 (CC0603), C2012 (CC0805)

and C3216 (CC1206), applied to wave

soldering and reflow soldering.

300

As for C0402 (CC01005), C0603 (CC0201),

C1005 (CC0402), C3225 (CC1210), C4532

(CC1812), C5750 (CC2220), applied only to

reflow soldering.

∆T

Preheating

3sec. (As short as possible)

5-3. Recommended soldering peak temp and peak temp duration

Temp./Duration

Wave soldering

Reflow soldering

Peak temp(°C) Duration(sec.)

Solder

230 max.

260 max.

20 max.

10 max.

Sn-Pb Solder

250 max.

260 max.

3 max.

5 max.

Lead Free Solder

Recommended solder compositions

Sn-37Pb (Sn-Pb solder)

Sn-3.0Ag-0.5Cu (Lead Free Solder)

— 19 —

No.

Process

Condition

Type

Soldering

5-4. Avoiding thermal shock

Preheating condition

Soldering

Temp. (°C)

C1608(CC0603), C2012(CC0805),

C3216(CC1206)

Wave soldering

∆T ≤ 150

C0402(CC01005),C0603(CC0201),

C1005(CC0402), C1608(CC0603),

C2012(CC0805), C3216(CC1206)

C3225(CC1210), C4532(CC1812),

C5750(CC2220)

∆T ≤ 150

∆T ≤ 130

∆T ≤ 150

∆T ≤ 130

Reflow soldering

C0402(CC01005),C0603(CC0201),

C1005(CC0402), C1608(CC0603),

C2012(CC0805), C3216(CC1206)

C3225(CC1210), C4532(CC1812),

C5750(CC2220)

Manual soldering

Cooling condition

Natural cooling using air is recommended. If the chips are dipped into a solvent for

cleaning, the temperature difference (∆T) must be less than 100°C.

5-5. Amount of solder

Excessive solder will induce higher tensile force in chip capacitors when

temperature changes and it may result in chip cracking. In sufficient solder may

detach the capacitors from the P.C.board.

Higher tensile force in

chip capacitors to cause

crack

Excessive

solder

Maximum amount

Minimum amount

Adequate

Low robustness may

Insufficient

solder

cause contact failure or

chip capacitors come off

the P.C.board.

5-6. Solder repair by solder iron

1) Selection of the soldering iron tip

Tip temperature of solder iron varies by its type, P.C.board material and solder

land size. The higher the tip temperature, the quicker the operation. However,

heat shock may cause a crack in the chip capacitors.

Please make sure the tip temp. before soldering and keep the peak temp and

time in accordance with following recommended condition. (Please preheat the

chip capacitors with the condition in 5-4 to avoid the thermal shock.)

Recommended solder iron condition (Sn-Pb Solder and Lead Free Solder)

Temp. (°C)

300 max.

Duration (sec.)

3 max.

Wattage (W)

20 max.

Shape (mm)

Ø 3.0 max.

— 20 —

No.

Process

Condition

2) Direct contact of the soldering iron with ceramic dielectric of chip capacitors

may cause crack. Do not touch the ceramic dielectric and the terminations by

solder iron.

Soldering

5-7. Sn-Zn solder

Sn-Zn solder affects product reliability.

Please contact TDK in advance when utilize Sn-Zn solder.

5-8. Countermeasure for tombstone

The misalignment between the mounted positions of the capacitors and the land

patterns should be minimized. The tombstone phenomenon may occur especially

the capacitors are mounted (in longitudinal direction) in the same direction of the

reflow soldering.

(Refer to JEITA RCR-2335B Annex 1 (Informative) Recommendations to prevent the

tombstone phenomenon)

Cleaning

1) If an unsuitable cleaning fluid is used, flux residue or some foreign articles may

stick to chip capacitors surface to deteriorate especially the insulation resistance.

2) If cleaning condition is not suitable, it may damage the chip capacitors.

2)-1. Insufficient washing

(1) Terminal electrodes may corrode by Halogen in the flux.

(2) Halogen in the flux may adhere on the surface of capacitors, and lower the

insulation resistance.

(3) Water soluble flux has higher tendency to have above mentioned

problems (1) and (2).

2)-2. Excessive washing

When ultrasonic cleaning is used, excessively high ultrasonic energy output

can affect the connection between the ceramic chip capacitor's body and the

terminal electrode. To avoid this, following is the recommended condition.

Power : 20 W/max.

Frequency : 40 kHz max.

Washing time : 5 minutes max.

2)-3. If the cleaning fluid is contaminated, density of Halogen increases, and it may

bring the same result as insufficient cleaning.

— 21 —

No.

Process

Condition

1) When the P.C.board is coated, please verify the quality influence on the product.

Coating and

molding of the

P.C.board

2) Please verify carefully that there is no harmful decomposing or reaction gas

emission during curing which may damage the chip capacitors.

3) Please verify the curing temperature.

Handling after

chip mounted

1) Please pay attention not to bend or distort the P.C.board after soldering in handling

otherwise the chip capacitors may crack.



Caution

Bend

Twist

When functional check of the P.C.board is performed, check pin pressure tends

to be adjusted higher for fear of loose contact. But if the pressure is excessive

and bend the P.C.board, it may crack the chip capacitors or peel the terminations

off. Please adjust the check pins not to bend the P.C.board.

Item

Not recommended

Recommended

Termination

peeling

Support pin

Board

bending

Check pin

Handling of loose

chip capacitors

1) If dropped the chip capacitors may crack. Once dropped do not use it. Especially,

the large case sized chip capacitors are tendency to have cracks easily, so please

handle with care.

Crack

Floor

2) Piling the P.C.board after mounting for storage or handling, the corner of the P.C.

board may hit the chip capacitors of another board to cause crack.

P.C.board

Crack

— 22 —

No.

Process

Condition

The capacitors (Class 2) have aging in the capacitance. They may not be used in

precision time constant circuit. In case of the time constant circuit, the evaluation

should be done well.

10 Capacitance aging

As per the estimated life and the estimated failure rate depend on the temperature

and the voltage. This can be calculated by the equation described in JEITA

RCR-2335B Annex 6 (Informative) Calculation of the estimated lifetime and the

estimated failure rate ( Voltage acceleration coefficient : 3 multiplication rule,

Temperature acceleration coefficient : 10°C rule)

11 Estimated life and

estimated failure

rate of capacitors

The failure rate can be decreased by reducing the temperature and the voltage but

they will not be guaranteed.

The products listed on this specification sheet are intended for use in general

electronic equipment (AV equipment, telecommunications equipment, home

appliances, amusement equipment, computer equipment, personal equipment, office

equipment, measurement equipment, industrial robots) under a normal operation and

use condition.

12 Others



Caution

The products are not designed or warranted to meet the requirements of the

applications listed below, whose performance and/or quality require a more stringent

level of safety or reliability, or whose failure, malfunction or trouble could cause

serious damage to society, person or property. Please understand that we are not

responsible for any damage or liability caused by use of the products in any of the

applications below or for any other use exceeding the range or conditions set forth in

this specification sheet. If you intend to use the products in the applications listed

below or if you have special requirements exceeding the range or conditions set forth

in this specification, please contact us.

(1) Aerospace/Aviation equipment

(2) Transportation equipment (cars, electric trains, ships, etc.)

(3) Medical equipment

(4) Power-generation control equipment

(5) Atomic energy-related equipment

(6) Seabed equipment

(7) Transportation control equipment

(8) Public information-processing equipment

(9) Military equipment

(10) Electric heating apparatus, burning equipment

(11) Disaster prevention/crime prevention equipment

(12) Safety equipment

(13) Other applications that are not considered general-purpose applications

When designing your equipment even for general-purpose applications, you are

kindly requested to take into consideration securing protection circuit/device or

providing backup circuits in your equipment.

— 23 —

13. Packaging label

Packaging shall be done to protect the components from the damage during

transportation and storing, and a label which has the following information shall be

attached.

1) Inspection No.

2) TDK P/N

3) Customer's P/N

4) Quantity

*Composition of Inspection No.

Example

–

ΟΟ

–

ΟΟΟ

(a) (b) (c)

(d)

(e)

a) Line code

b) Last digit of the year

c) Month and A for January and B for February and so on. (Skip I)

d) Inspection Date of the month.

e) Serial No. of the day

14. Bulk packaging quantity

Total number of components in a plastic bag for bulk packaging: 1,000pcs.

As for C0402, C0603 and C1005 types, not available for bulk packaging.

— 24 —

15. TAPE PACKAGING SPECIFICATION

1. CONSTRUCTION AND DIMENSION OF TAPING

1-1. Dimensions of carrier tape

Dimensions of paper tape shall be according to Appendix 3, 4.

Dimensions of plastic tape shall be according to Appendix 5, 6.

1-2. Bulk part and leader of taping

Bulk

Chips

160mm

Leader

Drawing direction

400mm min

1-3. Dimensions of reel

Dimensions of Ø178 reel shall be according to Appendix 7, 8.

Dimensions of Ø330 reel shall be according to Appendix 9, 10.

1-4. Structure of taping

Top cover tape

Pitch hole

Paper carrier tape

(Bottom cover tape is not always applied.)

Plastic carrier tape

Bottom cover tape

— 25 —

2. CHIP QUANTITY

Chip quantity (pcs.)

φ178mm reel φ330mm reel

Thickness

of chip

Taping

Material

Type

C0402

C0603

C1005

C1608

0.20 mm

0.30 mm

0.50 mm

0.80 mm

0.60 mm

0.85 mm

1.25 mm

0.60 mm

0.85 mm

1.15 mm

1.30 mm

1.60 mm

1.15 mm

1.25 mm

1.30 mm

1.60 mm

2.00 mm

2.30 mm

2.50 mm

1.60 mm

2.00 mm

2.30 mm

2.50 mm

2.80 mm

3.20 mm

2.00 mm

2.30 mm

2.50 mm

2.80 mm

Paper

20,000

15,000

10,000

4,000

Paper

50,000

10,000

Paper

4,000

2,000

4,000

C2012

10,000

Paper or Plastic

Plastic

Paper

Paper or Plastic

10,000

C3216

Plastic

2,000

8,000

10,000

8,000

5,000

C3225

1,000

3,000

2,000

C4532

C5750

Plastic

500

3,000

2,000

— 26 —

3. PERFORMANCE SPECIFICATIONS

3-1. Fixing peeling strength (top tape)

0.05-0.7N. (See the following figure.)

Direction of cover tape pulling

Top cover tape

Carrier tape

0~15°

Direction of pulling

3-2. Carrier tape shall be flexible enough to be wound around a minimum radius

of 30mm with components in tape.

3-3. The missing of components shall be less than 0.1%

3-4. Components shall not stick to fixing tape.

3-5. The fixing tapes shall not protrude beyond the edges of the carrier tape

not shall cover the sprocket holes.

— 27 —

Appendix 3

Paper Tape

Pitch hole

(Unit : mm)

Symbol

Type

C0402

(C01005)

C0603

(CC0201)

C1005

(CC0402)

(0.25)

( 0.38 )

( 0.65 )

(0.45)

( 0.68 )

( 1.15 )

8.00 ± 0.30 3.50 ± 0.05 1.75 ± 0.10 2.00 ± 0.05

Symbol

Type

C0402

(C01005)

C0603

(CC0201)

C1005

(CC0402)

0.29 min.

0.40 min.

0.60±0.15

+0.10

2.00 ± 0.05 4.00 ± 0.10 Ø 1.5

* The values in the parentheses ( ) are for reference.

— 28 —

Appendix 4

Paper Tape

Pitch hole

(Unit : mm)

Symbol

Type

C1608

(CC0603)

C2012

(CC0805)

C3216

(CC1206)

( 1.10 )

( 1.50 )

( 1.90 )

( 2.30 )

( 3.50 )

8.00 ± 0.30 3.50 ± 0.05 1.75 ± 0.10 4.00 ± 0.10

Symbol

Type

C1608

(CC0603)

+0.10

C2012

(CC0805)

2.00 ± 0.05 4.00 ± 0.10 Ø 1.5

1.10 max.

C3216

(CC1206)

* The values in the parentheses ( ) are for reference.

— 29 —

Appendix 5

Plastic Tape

Pitch hole

(Unit : mm)

Symbol

Type

C2012

(CC0805)

C3216

(CC1206)

C3225

(CC1210)

( 1.50 )

( 1.90 )

( 2.90 )

( 2.30 )

( 3.50 )

( 3.60 )

3.50 ± 0.05

[5.50 ± 0.05]

8.00 ± 0.30

[12.0 ± 0.30]

1.75 ± 0.10 4.00 ± 0.10

Symbol

Type

C2012

(CC0805)

C3216

(CC1206)

C3225

2.50 max.

3.20 max.

0.30 max.

0.60 max.

+0.10

2.00 ± 0.05 4.00 ± 0.10 Ø 1.5

Ø 0.50 min.

(CC1210)

* The values in the parentheses ( ) are for reference.

* As for 2.5mm thickness products, apply values in the brackets [ ].

— 30 —

Appendix 6

Plastic Tape

Pitch hole

(Unit : mm)

Symbol

Type

C4532

(CC1812)

( 3.60 )

( 5.40 )

( 4.90 )

( 6.10 )

12.0 ± 0.30 5.50 ± 0.05 1.75 ± 0.10 8.00 ± 0.10

C5750

(CC2220)

Symbol

Type

C4532

(CC1812)

+0.10

2.00 ± 0.05 4.00 ± 0.10 Ø 1.5

6.50 max.

0.60 max.

Ø 1.50 min.

C5750

(CC2220)

* The values in the parentheses ( ) are for reference.

— 31 —

Appendix 7

C0402, C0603, C1005, C1608, C2012, C3216, C3225

( As for C3225 type, any thickness of the item except 2.5mm )

(Material : Polystyrene)

W₂

W₁

(Unit : mm)

Symbol

W₁

Dimension Ø178 ± 2.0 Ø60 ± 2.0

Ø13 ± 0.5

Ø21 ± 0.8

2.0 ± 0.5

9.0 ± 0.3

Symbol

W₂

Dimension 13.0 ± 1.4

1.0

Appendix 8

C3225, C4532, C5750 ( As for C3225 type, applied to 2.5mm thickness products )

(Material : Polystyrene)

W₂

W₁

(Unit : mm)

W₁

Symbol

Dimension Ø178 ± 2.0 Ø60 ± 2.0

Ø13 ± 0.5

Ø21 ± 0.8

2.0 ± 0.5

13.0 ± 0.3

Symbol

W₂

Dimension 17.0 ± 1.4

1.0

— 32 —

Appendix 9

C0603, C1005, C1608, C2012, C3216, C3225

( As for C3225 type, any thickness of the item except 2.5mm )

(Material : Polystyrene)

(Unit : mm)

Symbol

Ø382 max.

(Nominal

Ø330)

Dimension

Ø50 min.

Ø13 ± 0.5

Ø21 ± 0.8

2.0 ± 0.5

10.0 ± 1.5

Symbol

Dimension

2.0 ± 0.5

1.0

Appendix 10

C3225, C4532, C5750 ( As for C3225 type, applied to 2.5mm thickness products )

(Material : Polystyrene)

(Unit : mm)

Symbol

Ø382 max.

(Nominal

Ø330)

Dimension

Ø50 min.

Ø13 ± 0.5

Ø21 ± 0.8

2.0 ± 0.5

14.0 ± 1.5

Symbol

Dimension

2.0 ± 0.5

1.0

— 33 —

C0402C0G1C220JT [TDK]

相关型号：

C0402C0G1C220K020BC

C0402C0G1C220K020BC_16

C0402C0G1C220K020BC_17

C0402C0G1C220KT

C0402C0G1C240G

C0402C0G1C240J

C0402C0G1C270G

C0402C0G1C270J

C0402C0G1C270J020BC

C0402C0G1C270J020BC_16

C0402C0G1C270J020BC_17

C0402C0G1C270K020BC