ETC 2.23859E+11

DISCRETE CERAMICS
DATA SHEET
Class 2, Y5V 16 V, 25 V and 50 V
Surface mount ceramic
multilayer capacitors
Product specification
Supersedes data of 6th December 1999
File under Discrete Ceramics, ACM2
2000 May 24
Philips Components
Product specification
Surface mount ceramic
multilayer capacitors
FEATURES
Class 2, Y5V 16 V, 25 V and 50 V
QUICK REFERENCE DATA
• Five standard sizes
DESCRIPTION
• High capacitance per unit volume
• Supplied in tape on reel
• Nickel-barrier end terminations.
VALUE
Rated voltage UR (DC)
16 V, 25 V, 50 V
Capacitance range (E6 series)
1 nF to 4.7 µF; note 1
Tolerance on capacitance
after 1000 hours
±20% (M); −20% to +80% (Z)
APPLICATIONS
Test voltage (DC) for 1 minute
2.5 × UR
Consumer electronics, for example:
Sectional specifications
IEC 60384-10, second edition 1989-04;
also based on CECC 32 100
Detailed specification
based on CECC 32 101-801
• Tuners
• Television receivers
• Video recorders
• All types of cameras
End terminations
NiSn
Climatic category (IEC 60068)
25/85/21
Note
• Mobile telephones.
1. Measured at 25 °C, 1 V and 1 kHz, using a four-gauge method.
DESCRIPTION
The capacitor consists of a
rectangular block of ceramic dielectric
in which a number of interleaved
metal electrodes are contained. This
structure gives rise to a high
capacitance per unit volume.
terminations
,
,
,
The inner electrodes are connected to
the two terminations and finally
covered with a layer of plated tin
(NiSn). A cross section of the
structure is shown in Fig.1.
electrodes
MLB457
ceramic material
Fig.1 Construction of a ceramic multilayer capacitor.
2000 May 24
2
Philips Components
Product specification
Surface mount ceramic
multilayer capacitors
Class 2, Y5V 16 V, 25 V and 50 V
MECHANICAL DATA
W
T
L2
L4
L3
MBB211
L1
For dimensions see Table 1.
Fig.2 Component outline.
Physical dimensions
Table 1
Capacitor dimensions
T
CASE SIZE
L1
L2 and L3
MIN.
MAX.
MIN.
MAX.
L4
MIN.
W
Dimensions in millimetres
0201
0.6 ±0.03
0.3 ±0.03
0.027
0.033
0.10
0.20
0.20
0402
1.0 ±0.05
0.50 ±0.05
0.45
0.55
0.15
0.30
0.40
0603
1.6 ±0.10
0.8 ±0.07
0.73
0.87
0.25
0.65
0.40
0805
2.0 ±0.10
1.25 ±0.10
0.50
1.35
0.25
0.75
0.55
1206
3.2 ±0.15
1.6 ±0.15
0.50
1.75
0.25
0.75
1.40
Dimensions in inches
0201
0.024 ±0.001
0.012 ±0.001
0.011
0.013
0.004
0.008
0.008
0402
0.040 ±0.002
0.020 ±0.002
0.018
0.022
0.008
0.012
0.016
0603
0.063 ±0.004
0.032 ±0.003
0.029
0.035
0.010
0.026
0.016
0805
0.079 ±0.004
0.049 ±0.004
0.020
0.053
0.010
0.030
0.022
1206
0.126 ±0.006
0.063 ±0.006
0.020
0.069
0.010
0.030
0.056
2000 May 24
3
Philips Components
Product specification
Surface mount ceramic
multilayer capacitors
Class 2, Y5V 16 V, 25 V and 50 V
SELECTION CHART FOR 16 V AND 25 V
C
(nF)
LAST
TWO DIGITS
OF 12NC
1
23
1.5
25
2.2
27
3.3
29
4.7
32
6.8
34
16 V
0201
0402
25 V
0603
0805
1206
0603
0805
0.3 ±0.03
10
36
15
38
22
41
33
43
47
45
68
47
100
49
0.6 ±0.1
150
52
0.85 ±0.1
220
54
330
56
470
58
680
61
1000
63
1500
65
2200
67
2700
68
3300
69
3900
71
4700
72
0.5 ±0.05
0.8 ±0.07
Values in shaded cells indicate
thickness classification.
0.8 ±0.07
LAST
TWO DIGITS
OF 12NC
10
05
15
06
22
07
33
08
47
09
68
11
100
12
150
13
220
14
330
15
470
16
680
17
1000
18
2000 May 24
0.6 ±0.1
1.25 ±0.1
0.85 ±0.1
0.85 ±0.1
0.85 ±0.1
1.15 ±0.1
1.25 ±0.1
1.15 ±0.1
SELECTION CHART FOR 50 V
C
(nF)
1206
50 V
0603
0805
0.8 ±0.07
0.6 ±0.1
0.85 ±0.1
1206
0.6 ±0.1
1.25 ±0.1
0.85 ±0.1
Values in shaded cells indicate thickness classification.
4
1.15 ±0.1
Philips Components
Product specification
Surface mount ceramic
multilayer capacitors
Class 2, Y5V 16 V, 25 V and 50 V
Thickness classification and packaging quantities
8 mm TAPE WIDTH
AMOUNT PER REEL
THICKNESS
CLASSIFICATION
(mm)
∅180 mm; 7"
AMOUNT
PER BULK CASE
∅330 mm; 13"
0201
0402
0603
0805
PAPER
BLISTER
PAPER
BLISTER
0.3 ±0.03
10000
−
50000
−
50000
−
−
−
0.5 ±0.05
10000
−
50000
−
−
50000
−
10000
0.6 ±0.1
4000
−
10000
−
−
−
−
10000
0.85 ±0.1
4000
−
10000
−
−
−
−
4000
4000
15000
15000
−
−
15000
1.25 ±0.1
−
3000
−
10000
−
−
−
5000
1.15 ±0.1
−
3000
−
10000
−
−
−
−
0.8 ±0.07
8000
−
ORDERING INFORMATION
Components may be ordered by using either a simple 15-digit clear text code or Philips unique 12NC.
Clear text code
Example: 12062F105M8BB0D
SIZE
CODE
0201
TEMP.
CHAR.
2F = Y5V
0402
0603
0805
1206
CAPACITANCE
105 = 1000000 pF;
the third digit
signifies the
multiplying factor:
2 = × 100
3 = × 1000
4 = × 10000
5 = × 100000
TOL.
VOLTAGE
TERMINATION
M = ±20%
7 = 16 V
B = NiSn
Z = −20%/+80%
PACKAGING
MARKING
SERIES
2 = 180 mm; 7" paper
0 = no marking
D = BME
8 = 25 V
3 = 330 mm; 13" paper
9 = 50 V
B = 180 mm; 7" blister
2 = 2-character
marking in North
America only
F = 330 mm; 13" blister
P = bulk case
Ordering code 12NC
handbook, full pagewidth
2 2 X X
X X X
X 9 X X X
Carrier type
22 blister
38 paper
54 bulk
Capacitance value(1)
Rated voltage - Termination
78 16 V; NiSn
91 25 V; NiSn
58 50 V; NiSn
Tolerance
7 ±20%
8 −20/+80%
Size
8 0201
7 0402
6 0603
0 0805
1 1206
CCA620
Packaging(2)
1 reel: ∅180 mm; 7"
5 reel: ∅330 mm; 13"
4 bulk case
(1) Refer to chapters “Selection chart for 16 V and 25 V” and “Selection chart for 50 V”.
(2) Amount on reel depends on thickness classification, see section “Thickness classification and packaging quantities”.
2000 May 24
5
Philips Components
Product specification
Surface mount ceramic
multilayer capacitors
Class 2, Y5V 16 V, 25 V and 50 V
ELECTRICAL CHARACTERISTICS
Class 2 capacitors; Y5V base metal electrode dielectric; NiSn terminations
Unless otherwise stated all electrical values apply at an ambient temperature of 25 ±1 °C, an atmospheric pressure of
86 to 105 kPa, and a relative humidity of 63 to 67%.
DESCRIPTION
VALUE
Capacitance range (E6 series); note 1
1 nF to 4.7 µF
Tolerance on capacitance after 1000 hours
±20% (M); −20% to +80% (Z)
Tan δ; note 1:
all 25 V and 50 V (except 1206 and 1 µF; 0603 and 100 nF; 0805 and 330 nF)
≤5%
sizes 1206 and 1 µF; 0603 and 100 nF; 0805 and 330 nF
≤7%
all 16 V (except 0402; 0603 and 330 nF, 470 nF; 0805 and 2.2 µF;
1206 and 3.3 µF, 4.7 µF)
≤9%
sizes 0201; 0402; 0603 and 330 nF, 470 nF; 0805 and 2.2 µF;
1206 and 3.3 µF, 4.7 µF
≤12.5%
Insulation resistance after 1 minute at UR (DC)
IR × C > 500 seconds
Maximum capacitance change with respect to capacitance at 25 °C
(for typical values see Fig.5)
+22% to −82%
Ageing
typical 7% per time decade
Resistance to soldering heat
260 °C; 10 seconds
Note
1. Measured at 25 °C, 1 V and 1 kHz, using a four-gauge method.
2000 May 24
6
Philips Components
Product specification
Surface mount ceramic
multilayer capacitors
∆C
C
(%)
Class 2, Y5V 16 V, 25 V and 50 V
MBD076
0
MBD078
2000
tan δ
(x 10 4 )
20
1500
40
1000
60
500
80
100
0
10
0
Fig.3
∆C
C
(%)
20
30
40
50
V DC (V)
25
Typical capacitance change with respect
to the capacitance at 1 V as a function
of DC voltage at 25 °C.
0
25
50
75
100
25
Fig.5
2000 May 24
0
25
50
75
25
50
75
100
T ( oC)
Fig.4 Typical tan δ as a function of temperature.
MBD077
25
0
100
T ( oC)
Typical capacitance change as
a function of temperature.
7
Philips Components
Product specification
Surface mount ceramic
multilayer capacitors
Class 2, Y5V 16 V, 25 V and 50 V
TESTS AND REQUIREMENTS
Table 2
Test procedures and requirements
IEC
IEC
60384-10/
60068-2
CECC 32 100
TEST
CLAUSE
METHOD
TEST
PROCEDURE
REQUIREMENTS
4.4
mounting
the capacitors may be mounted
no visible damage
on printed-circuit boards or
ceramic substrates by applying
wave soldering, reflow soldering
(including vapour phase
soldering) or conductive adhesive
4.5
visual inspection and any applicable method using
dimension check
×10 magnification
in accordance with specification
4.6.1
capacitance
f = 1 kHz; measuring voltage
1 Vrms at 25 °C
within specified tolerance
4.6.2
tan δ
f = 1 kHz; measuring voltage
1 Vrms at 25 °C
in accordance with specification
4.6.3
insulation resistance at UR (DC) for 1 minute
RiCR ≥ 500 s
4.6.4
voltage proof
2.5 × UR for 1 minutes
no breakdown or flashover
4.7.1
temperature
characteristic
between minimum and maximum
temperature
in accordance with specification
4.8
adhesion
a force of 5 N applied for 10 s to
the line joining the terminations
and in a plane parallel to the
substrate
no visible damage
4.9
bond strength of
plating on end face
mounted in accordance with
CECC 32 100, paragraph 4.4
no visible damage
conditions: bending
1 mm at a rate of 1 mm/s,
radius jig 340 mm
∆C/C: ±30%
preconditioning: 120 to 150 °C
during 1 minute; 260 ±5 °C for
10 ±0.5 s in a static solder bath
the terminations shall be well
tinned after recovery
4.10
Tb
resistance to
soldering heat
∆C/C: ±20%
tan δ: original specification
Rins: original specification
4.11
2000 May 24
Ta
resistance to
leaching
260 ±5 °C for 30 ±1 s
in a static solder bath
using visual enlargement of
×10, dissolution of the
terminations shall not
exceed 10%
solderability
zero hour test, and test after
storage (20 to 24 months) in
original packing in normal
atmosphere;
unmounted chips completely
immersed for 2 ±0.5 s in a solder
bath at 235 ±5 °C
the terminations shall be well
tinned
8
Philips Components
Product specification
Surface mount ceramic
multilayer capacitors
IEC
IEC
60384-10/
60068-2
CECC 32 100
TEST
CLAUSE
METHOD
4.12
4.14
Na
Ca
TEST
rapid change of
temperature
damp heat,
steady state
damp heat,
with UR load
4.15
2000 May 24
Class 2, Y5V 16 V, 25 V and 50 V
endurance
PROCEDURE
REQUIREMENTS
preconditioning:
between minimum and maximum
temperature, 5 cycles
no visual damage
initialization:
48 ±4 hours after UR
at 40 °C for 1 hour
(for initial value measurement);
500 ±12 hours at 40 °C;
90 to 95% RH; UR applied
no visual damage
after 48 hours recovery:
∆C/C: ±20%
after 48 hours recovery:
∆C/C: +30%/−40%
tan δ: ≤15%
Rins: 500 MΩ or RiCR ≥ 100 s,
whichever is less
initialization:
48 hours after UR
at 40 °C for 1 hour
(for initial value measurement);
500 ±12 hours at 40 °C;
90 to 95% RH; UR applied
preconditioning:
UR at 40 °C for 1 hour
initialization:
2 × UR at 85 °C for 1 hour
(initial value is measured after
48 ±4 hours);
2 × UR at 85 °C for 1000 hours,
recovery 48 ±4 hours at room
temperature
after 48 hours recovery:
9
after 48 hours recovery:
∆C/C: +30%/−40%
tan δ: ≤15%
Rins: 500 MΩ or RiCR ≥ 25 s,
whichever is less
∆C/C: +30%/−40%
tan δ: ≤15%
Rins: 1000 MΩ or RiCR ≥ 50 s,
whichever is less