Leaded ceramic multilayer capacitors - General Data - Philips Semiconductors / NXP Semiconductors

1997 Nov 04 81

Philips Components

Leaded ceramic multilayer capacitors General data

PACKAGING

The monolithic ceramic capacitors are supplied in bulk packaging, taped on reel, or in ammopack; see Tables 1 and 3.

Mono-axialTM capacitors

Table 1 Packaging quantities and box dimensions

Note

1. Non-standard SPQ for 2222 series and US 15-digit code (including FE 15-digit code with suffix XV) which will be

phased out in the future.

Capacitors on bandolier, Mono-axial series

PACKAGING SIZE CODE SMALLEST PACKAGING QUANTITY (SPQ) BOX DIMENSIONS

L×W×H

(mm)

2252 SERIES

FE 15-digit 2222 SERIES

US 15-digit

Tape on reel 15; 20 7000 5000(1) 370 ×370 ×90

29 4000 2500(1)

Ammopack 15; 20 4000 4000 265 ×85 ×95

29 2000 2000

Fig.1 Capacitors on bandolier, Mono-axial series.

Maximum 0.1% of the total number of capacitors per reel may be missing.

A maximum of 1 consecutive vacant position is followed by 6 consecutive components.

Tape begins and ends with minimum of 60 empty positions (300 mm tape).

Maximum of 5 splices per reel.

For dimensions see Table 2.

MGA347

1997 Nov 04 82

Philips Components

Leaded ceramic multilayer capacitors General data

Table 2 Dimensions of bandolier; see Fig.1

REEL DATA,MONO-AXIAL SERIES

SYMBOL PARAMETER DIMENSIONS

mm inch

B inside tape spacing 52.4 ±1.5 2.062 ±0.059

C centre-to-tape-spacing ±0.8 ±0.031

P cumulative pitch, 6 consecutive components ±1.5 ±0.059

A components pitch 5 ±0.5 0.197 ±0.015

M lead bend <1.2 <0.047

S exposed adhesive <0.8 <0.031

T tape width 6.35 0.250

H lead sandwich >3.96 >0.156

Fig.2 Reel with capacitors on tape; Mono-axial series.

Dimensions in mm.

Maximum 0.1% of the total number of capacitors per reel may be missing.

A maximum of 1 consecutive vacant position is followed by 6 consecutive components.

Tape begins and ends with minimum of 60 empty positions (300 mm tape).

Maximum of 5 splices per reel.

For capacitor length (L) and diameter (∅D) refer to this handbook,

Chapter

“Leaded ceramic multilayer capacitors”

, Section

“Mono-axial



”

“Table 1”

355.6

max

arbor hole

MGA351 - 1

direction

unreeling Ø 28–

–

69.85

1.5

1997 Nov 04 83

Philips Components

Leaded ceramic multilayer capacitors General data

Mono-kapTM capacitors

Table 3 Packaging quantities and box dimensions

Notes

1. SPQ contains 1 or a multiple of poly-bags, 1000 units per bag.

2. Non-standard SPQ for 2222 series and US 15-digit code (including FE 15-digit code with suffix XV) which will be

phased out in the future.

Capacitors on tape, lead spacing 5.0 and 2.5 mm, Mono-kap series

PACKAGING SIZE CODE SMALLEST PACKAGING QUANTITY (SPQ) BOX DIMENSIONS

L×W×H

(mm)

2252 SERIES

FE 15-digit 2222 SERIES

US 15-digit

Bulk; note 1 15; 20 5000 5000 245 ×120 ×65

30 3000 3000

Tape on reel 15 4000 2500(2)

370 ×370 ×6020 3000 2500(2)

30 2500 2500

Ammopack 15; 20 2500 2500 335 ×290 ×50

30 2000 2000

Fig.3 Capacitors, with lead spacing 5.0 and 2.5 mm, for Mono-kap series on tape.

Lead space (F) shall be measured at 3.6 ±0.5 mm from the capacitor seating plane.

Maximum 0.5% of the total number of capacitors per reel may be missing.

A maximum of 1 consecutive vacant position is followed by 6 consecutive components.

Tape begins and ends with minimum of 24 empty positions (300 mm tape).

Maximum of 5 splices per reel.

For dimensions see Table 4.

handbook, full pagewidth

detail A

CCA017

∆ h

D0d

P1H0

LW1

direction of unreeling

W0W

seating

plane

1997 Nov 04 84

Philips Components

Leaded ceramic multilayer capacitors General data

Table 4 Dimensions of tape; see Fig.3

Notes

1. Tape width of 6 mm (0.236 inches) permissible.

2. e = 2.54 mm.

SYMBOL PARAMETER DIMENSIONS

mm inch

L cut off length <11 <0.443

L1lead end protrusion <2 <0.079

H height to seating plane >16 >0.630

H0height to seating plane (formed leads) 16 ±0.5 0.630 ±0.020

H1top of component height <32 <1.260

∆h body inclination 0.0 ±<1.0 0 ±<0.039

W carrier tape width 18 +1.0/−0.5 0.709 +0.039/−0.020

W0hold down tape width 15 ref.; note 1 0.591 ref.; note 1

W1sprocket hole position 9 +0.075/−0.5 0.354 +0.030/−0.020

F1e lead space; note 2 2.5 +0.6/−0.4 0.100 +0.024/−0.016

2e lead space; note 2 5.0 +0.6/−0.4 0.200 +0.024/−0.016

P0sprocket hole pitch 12.7 ±0.3 0.500 ±0.012

P11e sprocket hole centre to lead centre; note 2 5.08 ±0.7 0.200 ±0.028

2e sprocket hole centre to lead centre; note 2 3.85 ±0.7 0.151 ±0.028

D0sprocket hole diameter 4 ±0.3 0.157 ±0.012

t overall tape thickness <0.9 <0.035

d wire lead diameter 0.5 ±0.05 0.02 ±0.002

P taping pitch 12.7 ref. 0.500 ref.

1997 Nov 04 85

Philips Components

Leaded ceramic multilayer capacitors General data

REEL AND TAPE DATA,MONO-KAP SERIES

355.6

max

55.1

max

arbor hole

MGA350 - 1

Ø 28–

48 + 0

– 2.0

direction

unreeling

Fig.4 Reel with capacitors on tape; Mono-kap series.

Dimensions in mm.

Maximum 0.5% of the total number of capacitors per reel may be missing.

A maximum of 2 consecutive vacant position is followed by 6 consecutive components.

Tape begins and ends with minimum of 24 empty positions (300 mm tape).

Maximum of 5 splices per reel.

Cumulative pitch tolerance over 20 consecutive units not to exceed ±1.0 mm.

Lead space (F) shall be measured at 3.6 ±0.5 mm from the capacitor seating plane.

1997 Nov 04 86

Philips Components

Leaded ceramic multilayer capacitors General data

Fig.5 Ammopack with capacitors on tape; Mono-kap series.

Dimensions in mm.

Maximum 0.5% of the total number of capacitors per box may be missing.

A maximum of 2 consecutive vacant positions is followed by 6 consecutive components.

Tape begins and ends with minimum of 24 empty positions (300 mm tape).

Maximum of 5 splices per box.

Cumulative pitch tolerance over 20 consecutive units not to exceed ±1.0 mm.

Lead space (F) shall be measured at 3.6 ±0.5 mm from the capacitor seating plane.

CCA878

290

335 50

1997 Nov 04 87

Philips Components

Leaded ceramic multilayer capacitors General data

CHARACTERISTIC CURVES

Fig.6 Typical capacitance change as a function of temperature.

For NP0/C0G.

0.4

−0.8 −50 0

CCA033

−0.4

25−25 50 75 100 125

T (oC)

∆ C

(%)

Fig.7 Typical capacitance change as a function of temperature.

80 50 0

MSA649

25 50 75 100 125

T ( C)

∆

(%)

For Z5U.

1997 Nov 04 88

Philips Components

Leaded ceramic multilayer capacitors General data

Fig.8 Typical capacitance change as a function of temperature.

80 50 0

MSA650

25 50 75 100 125

T ( C)

∆

(%)

For X7R.

Fig.9 Typical capacitance change as a function of DC voltage.

handbook, full pagewidth

100 515

MSA651

45 50

V (V)

0202530354010

X7R

Z5U

NP0/COG

∆

(%)

1997 Nov 04 89

Philips Components

Leaded ceramic multilayer capacitors General data

Fig.10 Typical capacitance change as a function of frequency.

handbook, full pagewidth

106107

105

104

103

102

MSA652

f (Hz)

Z5U

NP0/COG

X7R

∆

(%)

1997 Nov 04 90

Philips Components

Leaded ceramic multilayer capacitors General data

TESTS AND REQUIREMENTS

Class 1 capacitors

After manufacture, each capacitor is checked on capacitance, tan δ and test voltage. Apart from this the following quality

checks are carried out by frequent inspections.

Essentially all tests mentioned in the schedule of

“IEC publication 384-8”

, category 55/125/21 (temperature range

−55/+125 °C; damp heat, long term, 21 days) are carried out in accordance with

“IEC publication 68”

Table 5 Test procedures and requirements

IEC 384-8

CLAUSE

IEC 68-2

TEST

METHOD TEST PROCEDURE REQUIREMENTS

4.4 robustness of

terminations:

pull-off pull velocity 15 cm/minute; load 5 N no lead breakage

Ua1tensile strength axial force 10 N no lead breakage

Ub bending load 5 N; 4 ×90°no lead breakage

4.6 Ta

method 1 solderability

(solder bath) 235 °C; 2 s good tinning

4.5 Tb

method 1A resistance to

soldering heat 260 °C; 10 s no visible damage

∆C/C: ±≤0.5% or ±0.5 pF

after 1 to 2 hours

4.7 Na rapid change of

temperature 30 minutes at −55 °C and

30 minutes at +125 °C; 5 cycles no damage after 24 hours

∆C/C: ±≤0.5% or ±0.5 pF

4.8 Fc vibration 10 to 55 to 10 Hz;

0.75 mm displacement;

3 directions; 6 hours

no visible damage

4.9 Eb bump 4000 bumps in 2 directions;

40 g; pulse time 6 ms no visible damage

inﬂammability 15 s; 35 mm above bunsen burner

with ﬂame-height 40 to 60 mm self-extinguishing within 15 s

after removal of bunsen burner

4.3 temperature

coefﬁcient between +20 and −55 °C, and

between +20 and +125 °Cwithin tolerance as speciﬁed for

each particular material

1997 Nov 04 91

Philips Components

Leaded ceramic multilayer capacitors General data

4.11 climatic sequence:

4.11.2 B dry heat 16 hours; +125 °C no visible damage

4.11.3 Db damp heat

(accelerated)

1st cycle

12 hours; +55 °C; 90 to 96% RH

12 hours; +25 °C; 95 to 100% RH after recovery of 1 to 2 hours

immediately followed by cold

test

4.11.4 A cold 2 hours; −55 °C no visible damage

4.11.5 M low air pressure 1 hour at 8.5 kPa,

last 2 minutes rated voltage no breakdown or ﬂashover

4.11.6 Db damp heat

(accelerated)

remaining cycle

12 hours; +55 °C; 90 to 96% RH

12 hours; +25 °C; 95 to 100% RH ∆C/C: ±≤1% or ±1pF

tan δ:≤2×speciﬁed tan δ

Rins after 1 to 2 hours:

>5000 MΩ

4.12 Ca damp heat,

steady state

(half number of the

lot at rated voltage,

other half at zero

voltage)

21 days; +40 °C; 90 to 95% RH ∆C/C: ±≤1% or ±1pF

tan δ:≤2×speciﬁed tan δ

Rins after 1 to 2 hours:

>5000 MΩ

4.13 endurance 1000 hours at maximum

temperature, at 1.5 ×rated voltage ∆C/C: ±≤1% or ±1pF

tan δ:≤1.5 ×speciﬁed tan δ

Rins:>3000 MΩ

resistance to

solvents 3 minutes ultrasonic washing in

trichloroethylene;

1 minute drying; 30 °C;

10 brush strokes

marking and colour code must

remain legible and not be

discoloured; no mechanical or

electrical damage or

deterioration of the material

IEC 384-8

CLAUSE

IEC 68-2

TEST

METHOD TEST PROCEDURE REQUIREMENTS

1997 Nov 04 92

Philips Components

Leaded ceramic multilayer capacitors General data

Class 2 capacitors

After manufacture, each capacitor is checked on capacitance, tan δ and test voltage. Apart from this the following quality

checks are carried out by frequent inspections.

Essentially all tests mentioned in the schedule of

“IEC publication 384-9”

, categories 55/125/21 and 10/85/21

respectively for X7R-2C1 and Z5U (temperature ranges −55/+125 °C and +10/+85 °C; damp heat, long term, 21 days)

are carried out in accordance with

“IEC publication 68”

Table 6 Test procedures and requirements

IEC 384-9

CLAUSE

IEC 68-2

TEST

METHOD TEST PROCEDURE REQUIREMENTS

4.1 pre-conditioning 1 hour; +150 °C; reference

measurement after 24 hours

4.5 robustness of

terminations:

pull-off pull velocity 15 cm/minute; load 5 N no lead breakage

Ua1tensile strength axial force 10 N no lead breakage

Ub bending load 5 N; 4 ×90°no lead breakage

4.7 Ta

method 1 solderability

(solder bath) 235 °C; 2 s good tinning

4.6 Tb

method 1A resistance to

soldering heat pre-conditioning: 260 °C; 10 s no visible damage

4.8 Na rapid change of

temperature pre-conditioning:

for X7R: −55/+125 °C; 5 cycles;

for Z5U: +10/+85 °C; 5 cycles

no damage

∆C/C after 24 hours:

X7R: ±≤10%

Z5U: ±≤20%

4.9 Fb vibration 10 to 55 to 10 Hz;

0.75 mm displacement;

3 directions; 6 hours

no visible damage

4.10 Eb bump 4000 bumps in 2 directions;

40 g; pulse time 6 ms no visible damage

inﬂammability 15 s; 35 mm above bunsen burner

with ﬂame-height 40 to 60 mm self-extinguishing within 15 s

after removal of bunsen burner

resistance to

solvents 3 minutes ultrasonic washing in

trichloroethylene; 1 minute drying;

30 °C; 10 brush strokes

marking and colour code must

remain legible and not be

discoloured; no mechanical or

electrical damage or

deterioration of the material

1997 Nov 04 93

Philips Components

Leaded ceramic multilayer capacitors General data

4.12 climatic sequence:

4.12.1 pre-conditioning 1 hour; +150 °C

4.12.2 Ba dry heat 16 hours at maximum temperature no visible damage

4.12.3 Db damp heat

(accelerated)

1st cycle

12 hours; +55 °C; 90 to 96% RH

12 hours; +25 °C; 95 to 100% RH no visible damage; after

recovery of 1 to 2 hours

immediately followed by cold

test

4.12.4 Aa cold 2 hours at minimum temperature no visible damage

4.12.5 M low air pressure 1 hour at 8.5 kPa,

last 2 minutes rated voltage no breakdown or ﬂashover

4.12.6 Db damp heat

(accelerated)

remaining cycle

12 hours; +55 °C; 90 to 96% RH

12 hours; +25 °C; 95 to 100% RH after 24 hours recovery:

∆C/C:

X7R: ±≤15%

Z5U: ±≤20%

tan δ:≤7%

Rins:>1000 MΩ

4.13 Ca damp heat,

steady state

(half number of

samples at rated

voltage, other half

of samples no

voltage applied)

pre-conditioning:

21 days; +40 °C; 90 to 95% RH no visible damage

after 24 hours:

∆C/C:

X7R: ±≤15%

Z5U: ±≤30%

tan δ:≤7%

Rins:>1000 MΩ

4.14 endurance pre-conditioning after 24 hours:

∆C/C:

X7R: ±≤20%

Z5U: ±≤30%

tan δ:≤7%

Rins:>2000 MΩ

4.4 temperature

characteristic pre-conditioning: minimum and

maximum temperature in accordance with speciﬁcation

IEC 384-9

CLAUSE

IEC 68-2

TEST

METHOD TEST PROCEDURE REQUIREMENTS