CL03A104KP3NNNC Spec

Samsung Electro-Mechanics

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Datasheet

- Miniature Size
- Wide Capacitance and Voltage Range
- Tape & Reel for Surface Mount Assembly
- Low ESR
- General Electronic Circuit
General Features
Applications
Part Numbering
CL 10 B 104 K B 8 N N N C
1
2
3
4
5
6
7
8
9
10
11
Samsung Multilayer Ceramic Capacitor
1
SIZE(mm)
2
General Multilayer Ceramic Capacitors
General Capacitors
Code EIA CODE Size(mm)
03 0201 0.6 ×0.3
05 0402 1.0 ×0.5
10 0603 1.6 ×0.8
21 0805 2.0 ×1.25
31 1206 3.2 ×1.6
32 1210 3.2 ×2.5
43 1812 4.5 ×3.2
55 2220 5.7 ×5.0
Samsung Multilayer Ceramic Capacitor Thickness Option
Size(mm) Product & Plating Method
Capacitance Temperature Characteristic Samsung Control Code
Nominal Capacitance Reserved For Future Use
Capacitance Tolerance Packaging Type
Rated Voltage
1
2
3
4
5
6
7
8
9
108
118
MLCC is an electronic part that temporarily stores an electrical charge and the
most prevalent type of capacitor today. New technologies have enabled the
MLCC manufacturers to follow the trend dictated by smaller and
smaller electronic devices such as Cellular telephones, Computers, DSC, DVC
Code Temperature Characteristics Temperature
Range
C
Class
COG C0±30(ppm/)
-55 ~ +125
PP2H P-150±60
RR2H R-220±60
SS2H S-330±60
TT2H T-470±60
UU2J U-750±60
LS2L S+350 ~ -1000
A
Class
X5R X5R ±15% -55 ~ +85
BX7R X7R ±15% -55 ~ +125
XX6S X6S ±22% -55 ~ +105
FY5V Y5V +22 ~ -82% -30 ~ +85
Temperature
Characteristics Below 2.0pF 2.2 ~ 3.9pF Above 4.0pF Above 10pF
CΔC0G C0G C0G C0G
PΔ-P2J P2H P2H
RΔ-R2J R2H R2H
SΔ-S2J S2H S2H
TΔ-T2J T2H T2H
UΔ-U2J U2J U2J
Temperature Characteristic
J : ±120PPM/, H : ±60PPM/, G : ±30PPM/
CAPACITANCE TEMPERATURE CHARACTERISTIC
3
Nominal capacitance is identified by 3 digits.
The first and second digits identify the first and second significant figures of the capacitance.
The third digit identifies the multiplier. 'R' identifies a decimal point.
Code Nominal Capacitance
1R5 1.5pF
103 10,000pF, 10nF, 0.01μF
104 100,000pF, 100nF, 0.1μF
NOMINAL CAPACITANCE
4
Example
General Capacitors
Code Tolerance Nominal Capacitance
A±0.05pF
Less than 10pF
(Including 10pF)
B±0.1pF
C±0.25pF
D±0.5pF
F±1pF
F±1%
More than 10pF
G±2%
J±5%
K±10%
M±20%
Z+80, -20%
Code Rated Voltage Code Rated Voltage
R4.0V D200V
Q6.3V E250V
P10V G500V
O16V H630V
A25V I1,000V
L35V J2,000V
B50V K3,000V
C100V
CAPACITANCE TOLERANCE
5
RATED VOLTAGE
6
General Capacitors
THICKNESS OPTION
7
General Capacitors
Code Electrode Termination Plating Type
APd Ag Sn_100%
NNi Cu Sn_100%
GCu Cu Sn_100%
Code Description of the code Code Description of the code
AArray (2-element) NNormal
BArray (4-element) PAutomotive
CHigh - Q LLICC
PRODUCT & PLATING METHOD
8
SAMSUNG CONTROL CODE
9
Size Code Thickness(T) Size Code Thickness(T)
0201(0603) 30.30±0.03
1812(4532)
F1.25±0.20
0402(1005) 50.50±0.05 H1.6±0.20
0603(1608) 80.80±0.10 I2.0±0.20
0805(2012)
A0.65±0.10 J2.5±0.20
C0.85±0.10 L3.2±0.30
F1.25±0.10
2220(5750)
F1.25±0.20
Q1.25±0.15 H1.6±0.20
Y1.25±0.20 I2.0±0.20
1206(3216)
C0.85±0.15 J2.5±0.20
F1.25±0.15 L3.2±0.30
H1.6±0.20
1210(3225)
F1.25±0.20
H1.6±0.20
I2.0±0.20
J2.5±0.20
V2.5±0.30
Code Description of the code
N Reserved for future use
Code Packaging Type Code Packaging Type
B Bulk F Embossing 13" (10,000EA)
P Bulk Case L Paper 13" (15,000EA)
C Paper 7" O Paper 10"
D Paper 13" (10,000EA) S Embossing 10"
E Embossing 7"
RESERVED FOR FUTURE USE
10
6
PACKAGING TYPE
11
General Capacitors
APPEARANCE AND DIMENSION
L
BW
TW
CODE EIA CODE DIMENSION ( mm )
L W T(MAX) BW
03 0201 0.6 ±0.03 0.3 ±0.03 0.33 0.15 ±0.05
05 0402 1.0 ±0.05 0.5 ±0.05 0.55 0.2 +0.15/-0.1
10 0603 1.6 ±0.1 0.8 ±0.1 0.9 0.3 ±0.2
21 0805 2.0 ±0.1 1.25 ±0.1 1.35 0.5 +0.2/-0.3
31 1206 3.2 ±0.15 1.6 ±0.15 1.40 0.5 +0.2/-0.3
3.2 ±0.2 1.6 ±0.2 1.8 0.5 +0.3/-0.3
32 1210 3.2 ±0.3 2.5 ±0.2 2.7 0.6 ±0.3
3.2 ±0.4 2.5 ±0.3 2.8
43 1812 4.5 ±0.4 3.2 ±0.3 3.5 0.8 ±0.3
55 2220 5.7 ±0.4 5.0 ±0.4 3.5 1.0 ±0.3
General Capacitors
NO ITEM PERFORMANCE TEST CONDITION
1 Appearance No Abnormal Exterior Appearance Through Microscope(×10)
2Insulation
Resistance
10,000or 500·whichever is smaller
Rated Voltage is below 16V ;
10,000or 100·whichever is smaller
Apply the Rated Voltage For 60 ~ 120 Sec.
3Withstanding
Voltage
No Dielectric Breakdown or
Mechanical Breakdown
Class: 300% of the Rated Voltage for 1~5 sec.
Class:250% of the Rated Voltage for 1~5 sec. is applied
with less than 50current
4Capacita
nce
Class
Within the specified tolerance
Capacitance Frequency Voltage
1,0001±10% 0.5 ~ 5 Vrms
>1,0001±10%
Class
Within the specified tolerance
Capacitance Frequency Voltage
101±10% 1.0.2Vrms
>10120±20% 0.5±0.1Vrms
5Q
Class
Capacitance 30:Q1,000
<30
:Q400 +20C
( C : Capacitance )
Capacitance Frequency Voltage
1,0001±10% 0.5 ~ 5 Vrms
>1,0001±10%
6Tan
δClass
1. Characteristic : A(X5R), B(X7R), X(X6S)
2. Characteristic : F(Y5V)
Capacitance Frequency Voltage
101±10% 1.0.2Vrms
>10120±20% 0.5±0.1Vrms
Rated Voltage Spec
25V 0.025 max
16V 0.035 max
10V 0.05 max
6.3V 0.05 max/ 0.10max*1
Rated Voltage Spec
50V 0.05 max, 0.07max*2
35V 0.07 max
25V 0.05 max/
0.07 max*3/ 0.09max*4
16V 0.09 max/ 0.125max*5
10V 0.125 max/ 0.16max*6
6.3V 0.16max
*3. 0402 C0.033uF, 0603 C>0.1uF
All 0805, 1206 size, 1210 C6.8uF
*4.. 1210 C>6.8uF
*5.. 0402 C0.22uF
*6.. All 1812 size
*2.. 0603 C0.47uF, 0805 C1uF
*1. 0201 C0.022uF, 0402 C0.22uF, 0603 C2.2uF,
0805 C4.7uF, 1206 C10uF, 1210 C22uF,
1812 C47uF, 2220 C100uF,
All Low Profile Capacitors (P.16).
RELIABILTY TEST CONDITION
General Capacitors
NO ITEM PERFORMANCE TEST CONDITION
7
Temperature
Characteristics
of Capacitance
Class
Capacitance shall be measured by the steps
shown in the following table.
(1) Class
Temperature Coefficient shall be calculated from
the formula as below.
C1×T×10
6[ppm/]
C2 - C1
Temp, Coefficient =
C1; Capacitance at step 3
C2: Capacitance at 85
T: 60(=85-25)
(2) CLASS
Capacitance Change shall be calculated from the
formula as below.
×100(%)
C2 - C1
C1
C=
C1; Capacitance at step 3
C2: Capacitance at step 2 or 4
Class
8Adhesive Strength
of Termination
No Indication Of Peeling Shall Occur On The
Terminal Electrode.
Apply 500g.f * Pressure for 10±1sec.
* 200g.f for 0201 case size.
9Bending
Strength
Apperance No mechanical damage shall occur. Bending limit ; 1mm
Test speed ; 1.0mm/SEC.
Keep the test board at the limit point in 5 sec.,
Then measure capacitance.
Capacitance
Characteristics Capacitance Change
Class I
Within ±5% or ±0.
5 pF whichever is
larger
Class II
A(X5R)/
B(X7R)/
X(X6S)
Within ±12.5%
F(Y5V) Within ±30%
Characteristics Capacitance Change
with No Bias
A(X5R)/
B(X7R) ±15%
X(X6S) ±22%
F(Y5V) +22% ~ -82%
500g.f
Characteristics Temp. Coefficient
(PPM/)
C0G 0 ±30
PH -150 ±60
RH -220 ±60
SH -330 ±60
TH -470 ±60
UL -750 ±120
SL +350 ~ -1000
Step Temp.()
125
±2
2 Min. operating temp. ±2
325
±2
4 Max. operating temp ±2
525
±2
○○
50
R=230
20
45±145±1Bending limit
RELIABILTY TEST CONDITION
General Capacitors
NO ITEM PERFORMANCE TEST CONDITION
10 Solderability
More Than 75% of the terminal surface is to
be soldered newly, So metal part does not
come out or dissolve
11 Resistance to
Soldering heat
Apperance No mechanical damage shall occur. Solder Temperature : 270±5
Dip Time : 10±1 sec.
Each termination shall be fully immersed and
preheated as below :
Leave the capacitor in ambient condition for
specified time* before measurement
*24±2hours(Class)
24 ± 2 hours (Class )
Capacitance
Characteristics Capacitance Change
Class
Within ±2.5% or
±0.25whichever is
larger
Class
A(X5R)/
B(X7R) Within ±7.5%
X(X6S) Within ±15%
F Within ±20%
Q
(Class )
Capacitance 30:Q
1000
<30:Q
400+20×C
(C: Capacitance)
Tanδ
(Class )Within the specified initial value
Insulation
Resistance Within the specified initial value
Withstanding
Voltage Within the specified initial value
12 Vibration
Test
Appearance No mechanical damage shall occur.
The capacitor shall be subjected to a
Harmonic Motion having a total amplitude of
1.5mm changing frequency from 10Hz to 55Hz
and back to 10Hz In 1 min.
Repeat this for 2hours each in 3 mutually
perpendicular directions
Capacitance
Characteristics Capacitance Change
Class
Within ±2.5% or
±0.25whichever is
larger
Class
A(X5R)/
B(X7R) Within ±5%
X(X6S) Within ±10%
F(Y5V) Within ±20%
Q
(Class )Within the specified initial value
Tanδ
(Class )Within the specified initial value
Insulation
Resistance Within the specified initial value
STEP TEMP.() TIME(SEC.)
1 80~100 60
2 150~180 60
Solder Sn-3Ag-0.5Cu 63Sn-37Pb
Solder
Temp. 245±5235±5
Flux RMA Type
Dip Time 3±0.3 sec. 5±0.5 sec.
Pre-heating at 80~120for 10~30 sec.
RELIABILTY TEST CONDITION
General Capacitors
NO ITEM PERFORMANCE TEST CONDITION
13
Humidity
(Steady
State)
Appearance No mechanical damage shall occur. Temperature : 40±2
Relative humidity : 90~95 %RH
Duration time : 500 +12/-0 hr.
Leave the capacitor in ambient
condition for specified time* before
measurement.
CLASS:24±2Hr.
CLASS:24±2Hr.
Capacitance
Characteristics Capacitance Change
Class Within ±5.0% or ±0.5
whichever is larger
Class
A(X5R)/
B(X7R)/
X(X6S)
Within ±12.5%
F(Y5V) Within ±30%
Q
CLASS
Capacitance 30:Q
350
10Capacitance <30:Q
275 + 2.5×C
Capacitance < 10pF : Q200 + 10×C (C: Capacitance)
Tanδ
CLASS
1. Characteristic : A(X5R),
B(X7R)
0.05max (16V and over)
0.075max (10V)
0.075max
(6.3V except Table 1)
0.125max*
(refer to Table 1)
2. Characteristic : F(Y5V)
0.075max (25V and over)
0.1max (16V, C<1.0)
0.125max(16V, C1.0)
0.15max (10V)
0.195max (6.3V)
Insulation
Resistance 1,000 or 50·whichever is smaller.
14
Moisture
Resistance
Appearance No mechanical damage shall occur. Applied Voltage : rated voltage
Temperature : 40±2
Humidity : :90~95%RH
Duration Time : 500 +12/-0 Hr.
Charge/Discharge Current : 50max.
Perform the initial measurement according to
Note1 .
Perform the final measurement according to
Note2.
Capacitance
Characteristics Capacitance Change
Class Within ±5.0% or ±0.5
whichever is larger
Class
A(X5R)/
B(X7R)/
X(X6S)
Within ±12.5%
Within ±12.5%
Within ±30%
F(Y5V)
Within ±30%
Within ±30%
Q
(Class )
Capacitance 30:Q
200
Capacitance <30:Q
100 + 10/C (C: Capacitance)
Tanδ
(Class )
1. Characteristic : A(X5R),
B(X7R)
0.05max (16V and over)
0.075max (10V)
0.075max
(6.3V except Table 1)
0.125max*
(refer to Table 1)
2. Characteristic : F(Y5V)
0.075max (25V and over)
0.1max (16V, C<1.0)
0.125max(16V, C1.0)
0.15max (10V)
0.195max (6.3V)
X(X6S) 0.11max (6.3V and below)
Insulation
Resistance 500 or 25·whichever is smaller.
RELIABILTY TEST CONDITION
General Capacitors
NO ITEM PERFORMANCE TEST CONDITION
15
High
Temperature
Resistance
Appearance No mechanical damage shall occur. Applied Voltage : 200%* of the rated voltage
Temperature : max. operating temperature
Duration Time : 1000 +48/-0 Hr.
Charge/Discharge Current : 50max.
* refer to table(3) : 150%/100% of the rated
voltage
Perform the initial measurement according to
Note1 for Class
Perform the final measurement according to
Note2.
Capacitance
Characteristics Capacitance Change
Class Within ±3% or ±0.3,
Whichever is larger
Class
A(X5R)/
B(X7R) Within ±12.5%
X(X6S) Within ±25%
F(Y5V) Within ±30%
Within ±30%
Q
(Class )
Capacitance 30:Q350
10Capacitance <30 :Q275 + 2.5×C
Capacitance < 10:Q 200 +1C (C: Capacitance)
Tanδ
(Class )
1. Characteristic : A(X5R),
B(X7R)
0.05max
(16V and over)
0.075max (10V)
0.075max
(6.3V except Table 1)
0.125max*
(refer to Table 1)
2. Characteristic : F(Y5V)
0.075max
(25V and over)
0.1max(16V, C<1.0)
0.125max(16V, C1.0)
0.15max (10V)
0.195max (6.3V)
X(X6S) 0.11max (6.3V and below)
Insulation
Resistance 1,000 or 50·whichever is smaller.
16 Temperature
Cycle
Appearance No mechanical damage shall occur. Capacitor shall be subjected to 5 cycles.
Condition for 1 cycle :
Step Temp.() Time(min.)
1Min. operating
temp.+0/-3 30
225 2~3
3Max. operating
temp.+3/-0 30
425 2~3
Leave the capacitor in ambient condition
for specified time* before measurement
*22hours(Class)
24 ± 2 hours (Class )
Capacitance
Characteristics Capacitance Change
Class Within ±2.5% or ±0.25
Whichever is larger
Class
A(X5R)/
B(X7R)/ Within ±7.5%
X(X6S) Within ±15%
F(Y5V) Within ±20%
Q
(Class )Within the specified initial value
Tanδ
(Class )Within the specified initial value
Insulation
Resistance Within the specified initial value
RELIABILTY TEST CONDITION
General Capacitors
RELIABILTY TEST CONDITION
Note1. Initial Measurement For Class
Perform the heat treatment at 150+0/-10for 1 hour. Then Leave the capacitor in ambient condition for 48±4 hours before measurement.
Then perform the measurement.
Note2. Latter Measurement
1. CLASS
Leave the capacitor in ambient condition for 24±2 hours before measurement
Then perform the measurement.
2. Class
Perform the heat treatment at 150+0/-10for 1 hour. Then Leave the capacitor in ambient condition for 48±4 hours before measurement.
Then perform the measurement.
*Table1. *Table2. *Table3.
Note3. All Size In Reliability Test Condition Section is "inch"
18
Recommended Soldering Method
Recommended
Soldering Method
By Size & Capacitance
Size
inch (mm)
Temperature
Characteristic Capacitance Condition
Flow Reflow
0201 (0603) ---
0402 (1005)
0603 (1608)
Class I - ○○
Class II C1○○
C1-
0805 (2012)
Class I - ○○
Class II C4.7○○
C4.7-
Array - -
1206 (3216)
Class I - ○○
Class II C10○○
C10-
Array - -
1210 (3225)
---
1808 (4520)
1812 (4532)
2220 (5750)
High Temperature Resistance test
Applied
Voltage
100% of the rated
voltage
150% of the rated
voltage
Class
A(X5R),
B(X7R),
X(X6S),
F(Y5V)
0201 C 0.1
0402 C 1.0
0603 C 4.7
0805 C 22.0
1206 C 47.0
1210 C 100.0
All Low Profile
Capacitors (P.16).
0201 C 0.022
0402 C 0.47
0603 C 2.2
0805 C 4.7
1206 C 10.0
1210 C 22.0
1812 C 47.0
2220 C 100.0
High Temperature Resistance test
ΔC(Y5V) ±30%
Class
F(Y5V)
0402 C 0.47
0603 C 2.2
0805 C 4.7
1206 C 10.0
1210 C 22.0
1812 C 47.0
2220 C 100.0
Tanδ0.125max*
Class
A(X5R),
B(X7R)
0201 C 0.022
0402 C 0.22
0603 C 2.2
0805 C 4.7
1206 C 10.0
1210 C 22.0
1812 C 47.0
2220 C 100.0
All Low Profile
Capacitors (P.16).
PACKAGING
General Capacitors
Symbol A B W F E P1 P2 P0 D t
Type
D
i
m
e
n
s
i
o
n
0603
(1608) 1.1
±0.2 1.9
±0.2
8.0
±0.3 3.5
±0.05 1.75
±0.1 4.0
±0.1 2.0
±0.05 4.0
±0.1
Φ1.5
+0.1/-0 1.1
Below
0805
(2012) 1.6
±0.2 2.4
±0.2
1206
(3216) 2.0
±0.2 3.6
±0.2
unit : mm
Symbol A B W F E P1 P2 P0 D t
Type
D
i
m
e
n
s
i
o
n
0201
(0603) 0.38
±0.03 0.68
±0.03 8.0
±0.3 3.5
±0.05 1.75
±0.1 2.0
±0.05 2.0
±0.05 4.0
±0.1
Φ1.5
+0.1/-0.03
0.37
±0.03
0402
(1005) 0.62
±0.04 1.12
±0.04 0.6
±0.05
unit : mm
A
B
Feeding Hole D
P0 P1P2
W
F
E
t
A
B
Feeding Hole Chip Inserting Hole D
P0 P1P2
W
F
E
t
Chip Inserting Hole
CARDBOARD PAPER TAPE (4mm)
CARDBOARD PAPER TAPE (2mm)
PACKAGING
General Capacitors
Symbol A B W F E P1 P2 P0 Dt1 t0
Type
D
i
m
e
n
s
i
o
n
0805
(2012) 1.45
±0.2 2.3
±0.2
8.0
±0.3 3.5
±0.05
1.75
±0.1
4.0
±0.1
2.0
±0.05 4.0
±0.1
Φ1.5
+0.1/-0
2.5
max
0.6
Below
1206
(3216) 1.9
±0.2 3.5
±0.2
1210
(3225) 2.9
±0.2 3.7
±0.2
1808
(4520) 2.3
±0.2 4.9
±0.2
12.0
±0.3 5.60
±0.05 8.0
±0.1 3.8
max
1812
(4532) 3.6
±0.2 4.9
±0.2
2220
(5750) 5.5
±0.2 6.2
±0.2
unit : mm
A
B
Feeding Hole Chip inserting Hole D
P0 P1P2
W
F
E
t1
t0
Empty Section
45 Pitch Packed Part
Empty Section
50 Pitch
Loading Section
35 Pitch
STARTEND
Type Symbol Size Cardboard
Paper Tape Symbol Size Embossed
Plastic Tape
7" Reel C
0201(0603) 10,000
E
All Size 3216
1210(3225),1808(4520)
(t1.6mm) 2,000
0402(1005) 10,000 1210(3225)(t2.0mm) 1,000
OTHERS 4,000 1808(4520)(t2.0mm) 1,000
10" Reel O - 10,000 - - -
13" Reel
D0402(1005) 50,000
F
All Size 3216
1210(3225),1808(4520)
(t<1.6mm) 10,000
OTHERS 10,000 1210(3225)(1.6t<2.0mm)
1206(3216)(1.6t) 8,000
L
0603(1608) 10,000 or 15,000 1210(3225),1808(4520)
(t2.0mm) 4,000
0805(2012)
(t0.85mm) 15,000 or
10,000(Option) 1812(4532)(t2.0mm) 4,000
1206(3216)
(t0.85mm) 10,000 1812(4532)(t>2.0mm)
5750(2220) 2,000
EMBOSSED PLASTIC TAPE
TAPING SIZE
General Capacitors
REEL DIMENSION
E
C
D
R
A
W
B
t
unit : mm
Symbol A B C D E W t R
7" Reel φ180+0/ -3 φ60+1/ -3 φ13±0.3 25±0.5 2.0±0.5 9±1.5 1.2±0.2 1.0
13" Reel φ330±2.0 φ80+1/ -3 2.2±0.2
PACKAGING
General Capacitors
BULK CASE PACKAGING
ABT
C
D
E
FW
L
G
H
I
unit : mm
Symbol A B T C D E
Dimension 6.8±0.1 8.8±0.1 12±0.1 1.5+0.1/-0 2+0/-0.1 3.0+0.2/-0
Symbol F W G H L I
Dimension 31.5+0.2/-0 36+0/-0.2 19±0.35 7±0.35 110±0.7 5±0.35
QUANTITY OF BULK CASE PACKAGING
Size 0402(1005) 0603(1608) 0805(2012)
T=0.65mm T=0.85mm
Quantity 50,000 10,000 or 15,000 10,000 5,000 or 10,000
unit :
p
cs
- Bulk case packaging can reduce the stock space and transportation costs.
- The bulk feeding system can increase the productivity.
- It can eliminate the components loss.
APPLICATION MANUAL
General Capacitors
ELECTRICAL CHARACTERISTICS
CAPACITANCE CHANGE - AGING
IMPEDANCE - FREQUENCY CHARACTERISTICS
CAPACITANCE - DC VOLTAGE CHARACTERISTICS
C0G
0.01
0.1
1
10
100
1.E+06 1.E+07 1.E+08 1.E+09 1.E+10
Ohm
1MHz 10MHz 100MHz 1GHz 10GHz
1000pF
100pF
10pF
X7R/X5R/Y5V
0.01
0.1
1
10
100
1.E+06 1.E+07 1.E+08 1.E+09
Ohm
0.1
0.01
0.001
1MHz 10MHz 100MHz 1GHz
CAPACITANCE - TEMPERATURE CHARACTERISTICS
40
20
-20
-4 0
-60
-80
-20-4 0-60 25 40 60 80 100 120
X7R
X5R
Y5V
% C
40
20
-20
-4 0
-60
-80
-20-4 0-60 25 40 60 80 100 120
X7R
X5R
Y5V
% C
20
10 20 30 40 50
X7R 50V
X7R 16V
Y5V
C %
Vdc
COG
X5R 50V
10
0
-10
-20
-30
-40
-50
-60
-70
-80
-90
-100
20
10 20 30 40 50
X7R 50V
X7R 16V
Y5V
C %
Vdc
COG
X5R 50V
10
0
-10
-20
-30
-40
-50
-60
-70
-80
-90
-100
1 10 100 1000 10000
Time(hr)
Δ
C/C [%]
Y5V
C0G
X7R/X5R
5
10
15
1 10 100 1000 10000
Time(hr)
Δ
C/C [%]
Y5V
C0G
X7R/X5R
5
10
15
8
6
4
2
-4
-6
-8
-10
-2
-55 -40 -20 25 40 60 80 100 125
S2L
U2J
COG
% C
Temp.(
o
C)
o
8
6
4
2
-4
-6
-8
-10
-2
-55 -40 -20 25 40 60 80 100 125
S2L
U2J
COG
% C
Temp.(
o
C)
o
W b
a
Solder
Land
Solder Resist
2/3W < b < W
TSolder Resist
2/3T < a < T
General Capacitors
STORAGE CONDITION
Storage Environment
The electrical characteristics of MLCCs were degraded by the environment of high temperature or
humidity. Therefore, the MLCCs shall be stored in the ambient temperature and the relative humidity
of less than 40and 70%, respectively.
Guaranteed storage period is within 6 months from the outgoing date of delivery.
Corrosive Gases
Since the solderability of the end termination in MLCC was degraded by a chemical atmosphere
such as chlorine, acid or sulfide gases, MLCCs must be avoid from these gases.
Temperature Fluctuations
Since dew condensation may occur by the differences in temperature when the MLCCs are taken
out of storage, it is important to maintain the temperature-controlled environment.
DESIGN OF LAND PATTERN
When designing printed circuit boards, the shape and size of the lands must allow for the proper
amount of solder on the capacitor.
The amount of solder at the end terminations has a direct effect on the crack.
The crack in MLCC will be easily occurred by the tensile stress which was due to too much amount
of solder. In contrast, if too little solder is applied, the termination strength will be insufficiently.
Use the following illustrations as guidelines for proper land design.
Recommendation of Land Shape and Size.
ADHESIVES
When flow soldering the MLCCs, apply the adhesive in accordance with the following conditions.
Requirements for Adhesives
They must have enough adhesion, so that, the chips will not fall off or move during the handling of the
circuit board.
They must maintain their adhesive strength when exposed to soldering temperature.
They should not spread or run when applied to the circuit board.
They should harden quickly. They should not corrode the circuit board or chip material.
They should be a good insulator. They should be non-toxic, and not produce harmful gases, nor be
harmful when touched.
Application Method
It is important to use the proper amount of adhesive. Too little and much adhesive will cause poor
adhesion and overflow into the land, respectively.
Adhesive hardening Characteristics
To prevent oxidation of the terminations, the adhesive must harden at 160or less, within 2 minutes
or less.
MOUNTING
Mounting Head Pressure
Excessive pressure will cause crack to MLCCs. The pressure of nozzle will be 300g maximum during
mounting.
Solder Resist
Land
PCB
aa
b
cc
Type 21 31
a0.2 min 0.2 min
b70~10070~100
c>0 >0
unit : mm
General Capacitors
Too much
Solder
Not enough
Solder
Cracks tend to occur due
to large stress
Weak holding force may
cause bad connections or
detaching of the capacitor
Good
support pin
force
nozzle
General Capacitors
Bending Stress
When double-sided circuit boards are used, MLCCs first are mounted and soldered onto one side of the
board. When the MLCCs are mounted onto the other side,
it is important to support the board as shown in the illustration. If the circuit board is not supported,
the crack occur to the ready-installed MLCCs by the bending stress.
Manual Soldering
Manual soldering can pose a great risk of creating thermal cracks in chip capacitors.
The hot soldering iron tip comes into direct contact with the end terminations, and operator's
carelessness may cause the tip of the soldering iron to come into direct contact with the ceramic
body of the capacitor.
Therefore the soldering iron must be handled carefully, and close attention must be paid
to the selection of the soldering iron tip and to temperature control of the tip.
Amount of Solder
Pre-heating Gradual cooling
in the air
Soldering
Temp.(℃ )
260+0/-5℃
10sec.max.
Time(sec)
Reflow
200℃
150℃
General Capacitors
Cooling
Natural cooling using air is recommended. If the chips are dipped into solvent for cleaning, the
temperature difference(T) must be less than 100
Cleaning
If rosin flux is used, cleaning usually is unnecessary. When strongly activated flux is used, chlorine in
the flux may dissolve into some types of cleaning fluids, thereby affecting the chip capacitors. This
means that the cleaning fluid must be carefully selected, and should always be new.
Notes for Separating Multiple, Shared PC Boards.
A multi-PC board is separated into many individual circuit boards after soldering has been completed.
If the board is bent or distorted at the time of separation, cracks may occur in the chip capacitors.
Carefully choose a separation method that minimizes the bending often circuit board.
Recommended Soldering Profile
T
i) 1206(3216) and
below
: 150max.
Pre-heating Gradual Cooling
in the air
Soldering
Temp. ()
Pre-heating
Temp. ()
120 sec. min.
260±3
5 sec. max.
Time (sec.)
Flow
Soldering Iron
Variation of Temp. Soldering
Temp ()
Pre-heating
Time (Sec)
Soldering
Time(Sec)
Cooling
Time(Sec)
T130 300±10max 60 4-
Condition of Iron facilities
Wattage Tip Diameter Soldering Time
20W Max 3Max 4SecMax
* Caution - Iron Tip Should Not Contact With Ceramic Body Directly.
General Capacitors

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