Monolithic Ceramic Capacitors Catalog

Murata Electronics North America

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Leaded MLCC
C49E.pdf
May 10,2018
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C49E.pdf
May 10,2018
!Note • Please read rating and !CAUTION (for storage, operating, rating, soldering, mounting and handling) in this catalog to prevent smoking and/or burning, etc.
• This catalog has only typical specifications. Therefore, please approve our product specifications or transact the approval sheet for product specifications before ordering.
C49E.pdf
May 10,2018
!Note • Please read rating and !CAUTION (for storage, operating, rating, soldering, mounting and handling) in this catalog to prevent smoking and/or burning, etc.
• This catalog has only typical specifications. Therefore, please approve our product specifications or transact the approval sheet for product specifications before ordering.
Leaded MLCC for General Purpose
RDE Series (DC25V-DC1kV) p44
o Marking p45
Temperature Compensating Type, C0G/U2J Characteristics p45
High Dielectric Constant Type, X7R/X7S Characteristics p52
o Specifications and Test Methods p56
175°C/200°C Operation Leaded MLCC for Automotive
RHS Series (DC100V-DC500V) p34
o Marking p35
Temperature Compensating Type, CCG/UNJ Characteristics p35
High Dielectric Constant Type, XAL/XAN Characteristics p37
o Specifications and Test Methods p38
150°C Operation Leaded MLCC for Automotive
RHE Series (DC25V-DC100V) p25
o Marking p26
Temperature Compensating Type, X8G Characteristics p27
High Dielectric Constant Type, X8L Characteristics p28
o Specifications and Test Methods p31
Leaded MLCC for General Purpose
RDE Series Large Capacitance and High Allowable Ripple Current
(DC250V-DC630V) p60
o Marking p61
High Dielectric Constant Type, X7T Characteristics p61
o Specifications and Test Methods p63
Contents
Product specifications are as of February 2018.
Part Numbering p2
Characteristics Reference Data (Typical Example) p66
Packaging p67
!Caution p69
Notice p71
Leaded MLCC for Automotive
RCE Series (DC25V-DC1kV) p4
o Marking p6
Temperature Compensating Type, C0G/U2J Characteristics p6
High Dielectric Constant Type, X7R/X7S Characteristics p13
o Specifications and Test Methods p17
1
2
3
4
5
Please check the MURATA website (https://www.murata.com/)
if you cannot find a part number in this catalog.
1
2
3
4
5
C49E.pdf
May 10,2018
!Note • Please read rating and !CAUTION (for storage, operating, rating, soldering, mounting and handling) in this catalog to prevent smoking and/or burning, etc.
• This catalog has only typical specifications. Therefore, please approve our product specifications or transact the approval sheet for product specifications before ordering.
2
o Part Numbering
(Part Number)
2
1Product ID
2Series
RC
RH
RH
RD
E
E
S
E
Leaded MLCC for Automotive
150°C Operation Leaded MLCC for Automotive
175°C/200°C Operation Leaded MLCC for Automotive
Leaded MLCC for General Purpose
Product ID Series Code
RC
1
E
3
R7
4
1H
5
104
7
0
8
M1
6
K
9
H03
:
A
5Capacitance
Expressed by three figures. The unit is pico-farad (pF). The first
and second figures are significant digits, and the third figure
expresses the number of zeros that follow the two numbers.
If there is a decimal point, it is expressed by the capital letter "R."
In this case, all figures are significant digits.
6Capacitance Tolerance
Code
C
D
J
K
M
Leaded MLCC
3Temperature Characteristics
Code
25 to 125°C
-55 to 25°C
25 to 150°C
-55 to 25°C
-55 to 25°C
25 to 125°C
125 to 200°C
-55 to 25°C
25 to 125°C
125 to 200°C
25 to 125°C*2
-55 to 25°C
-55 to 125°C
-55 to 125°C
-55 to 175°C
-55 to 150°C
-55 to 175°C
-55 to 125°C
Temperature
Range
0±30ppm/°C
0+30/-72ppm/°C
0±30ppm/°C
0+30/-72ppm/°C
0+30/-72ppm/°C
0±30ppm/°C
0+72/-30ppm/°C
-750+120/-347ppm/°C
-750±120ppm/°C
-750+347/-120ppm/°C
-750±120ppm/°C
-750+120/-347ppm/°C
±22%
+22%, -33%
+15%, -40%
+15%, -40%
+15%, -60%
±15%
Capacitance Change or
Temperature Coefficient
-55 to 125°C
-55 to 150°C
-55 to 200°C
-55 to 200°C
-55 to 125°C
-55 to 125°C
-55 to 125°C
-55 to 175°C
-55 to 150°C
-55 to 175°C
-55 to 125°C
Operating
Temperature Range
C0G
X8G
CCG
UNJ
U2J
X7S
X7T
XAL
X8L
XAN
X7R
EIA
*1
*1
*1
EIA
EIA
EIA
*1
*1
*1
EIA
Public STD Code
Temperature Characteristic Temperature Characteristics
25°C
25°C
25°C
25°C
25°C
25°C
25°C
25°C
25°C
25°C
25°C
Reference
Temperature
5C
5G
7G
7J
7U
C7
D7
L1
L8
N1
R7
*1 Murata Temperature Characteristic Code.
*2 Rated Voltage 100Vdc max: 25 to 85°C
4Rated Voltage
Code
1E
1H
2A
2D
2E
2W
2H
2J
3A
DC25V
DC50V
DC100V
DC200V
DC250V
DC450V
DC500V
DC630V
DC1kV
Rated Voltage
±0.25pF
±0.5pF
±5%
±10%
±20%
Capacitance Tolerance
Continued on the following page.
C49E.pdf
May 10,2018
!Note • Please read rating and !CAUTION (for storage, operating, rating, soldering, mounting and handling) in this catalog to prevent smoking and/or burning, etc.
• This catalog has only typical specifications. Therefore, please approve our product specifications or transact the approval sheet for product specifications before ordering.
3
9Individual Specification Code
Expressed by three figures
8Lead Style
Code Lead Style Lead Spacing
A2
B1
DB/DG
E1
K1
M1/M2
P1
S1
2.5mm
5.0mm
2.5mm
5.0mm
5.0mm
5.0mm
2.5mm
2.5mm
Straight Long
Straight Long
Straight Taping
Straight Taping
Inside Crimp
Inside Crimp Taping
Outside Crimp
Outside Crimp Taping
:Packaging
Code
A
B
Ammo Pack
Bulk
Packaging
7Dimensions (LxW)
Code
0
1
2
3
4
5
U
W
RCE Series
RHE Series
RHS Series
RDE Series
RCE Series
RHE Series
RHS Series
RDE Series
3.6×3.5mm max.
3.8×3.5mm max.
4.0×3.5mm max. or
5.0×3.5mm max.
(Depends on Part Number List)
4.0×3.5mm max.
4.5×3.5mm max. or
5.0×3.5mm max.
(Depends on Part Number List)
5.5×4.0mm max.
5.5×5.0mm max.
7.5×5.5mm max.
7.5×7.5mm max.
(DC630V, DC1kV : 7.5×8.0mm max.)
7.5×12.5mm max.
(DC630V, DC1kV : 7.5×13.0mm max.)
5.5×7.5mm max.
Dimensions (LxW)
Continued from the preceding page.
Features
1. Small size and large capacitance
2. Low ESR and ESL suitable for high frequency
3. Meet AEC-Q200, ISO7637-2 (surge test) requirement
4. Meet LF (Lead Free) and HF (Halogen Free)
5. Flow soldering and welding are available.
(Re-flow soldering is not available.)
6. If copper wire is necessary at welding process,
copper wire is available based on request.
(in mm)
T max.
L max.
ød: 0.5±0.05
W max.25.0 min.
1.5 max.
F±0.8
· Lead Wire: Solder Coated CP Wire
Dimensions code: 0
Lead style code: A2
(in mm)
* Coating extension does not exceed the end of the lead bend.
· Lead Wire: Solder Coated CP Wire
ød: 0.5±0.05
T max.L max.
W max.25.0 min.
W1 max.
F±0.8
*
Dimensions code: 0
Lead style code: K1
(in mm)
T max.
L max.
ød: 0.5±0.05
W max.25.0 min.
1.5 max.
F±0.8
· Lead Wire: Solder Coated CP Wire
Dimensions code: 1
Lead style code: A2
(in mm)
* Coating extension does not exceed the end of the lead bend.
· Lead Wire: Solder Coated CP Wire
ød: 0.5±0.05
T max.L max.
W max.25.0 min.
W1 max.
F±0.8
*
Dimensions code: 1
Lead style code: K1
(in mm)
T max.
L max.
ød: 0.5±0.05
W max.25.0 min.
1.5 max.
F±0.8
· Lead Wire: Solder Coated CP Wire
Dimensions code: 2
Lead style code: A2
(in mm)
* Coating extension does not exceed the end of the lead bend.
· Lead Wire: Solder Coated CP Wire
ød: 0.5±0.05
T max.L max.
W max.25.0 min.
W1 max.
F±0.8
*
Dimensions code: 2
Lead style code: K1
(in mm)
T max.
L max.
ød: 0.5±0.05
W max.25.0 min.
1.5 max.
F±0.8
· Lead Wire: Solder Coated CP Wire
Dimensions code: 3
Lead style code: A2
Continued on the following page.
Leaded MLCC for Automotive
RCE Series (DC25V-DC1kV)
!Note • Please read rating and !CAUTION (for storage, operating, rating, soldering, mounting and handling) in this catalog to prevent smoking and/or burning, etc.
• This catalog has only typical specifications. Therefore, please approve our product specifications or transact the approval sheet for product specifications before ordering.
4
C49E.pdf
May 10,2018
1
Continued from the preceding page.
(in mm)
* Coating extension does not exceed the end of the lead bend.
· Lead Wire: Solder Coated CP Wire
ød: 0.5±0.05
T max.L max.
W max.25.0 min.
W1 max.
F±0.8
*
Dimensions code: 3
Lead style code: K1
(in mm)
* Coating extension does not exceed the end of the lead bend.
· Lead Wire: Solder Coated CP Wire
ød: 0.5±0.05
T max.L max.
W max.25.0 min.
W1 max.
F±0.8
*
Dimensions code: 4
Lead style code: K1
(in mm)
T max.
L max.
ød: 0.5±0.05
W max.25.0 min.
1.5 max.
F±0.8
· Lead Wire: Solder Coated CP Wire
Dimensions code: 5
Lead style code: B1
(in mm)
L max.
2.0 max.
F±0.8
W max.
25.0 min.
T max.
· Lead Wire: Solder Coated CP Wire
ød: 0.5±0.05
Dimensions code: U
Lead style code: B1
(in mm)
* Coating extension does not exceed the end of the lead bend.
· Lead Wire: Solder Coated CP Wire
ød: 0.5±0.05
T max.L max.
W max.25.0 min.
W1 max.
F±0.8
*
Dimensions code: W
Lead style code: K1
!Note • Please read rating and !CAUTION (for storage, operating, rating, soldering, mounting and handling) in this catalog to prevent smoking and/or burning, etc.
• This catalog has only typical specifications. Therefore, please approve our product specifications or transact the approval sheet for product specifications before ordering.
5
C49E.pdf
May 10,2018
1
Dimensions and
Lead Style Code
Dimensions (mm)
L W W1 T F d
0A2/0DB
0K1/0M1
1A2/1DB
1K1/1M1
2A2/2DB
2K1/2M1
3A2/3DB
3K1/3M1
4K1/4M1
5B1/5E1
UB1/UE1
WK1/WM1
0.5
0.5
0.5
0.5
0.5
0.5
0.5
0.5
0.5
0.5
0.5
0.5
2.5
5.0
2.5
5.0
2.5
5.0
2.5
5.0
5.0
5.0
5.0
5.0
-
6.0
-
5.0
-
6.0
-
7.5
8.0
-
-
10.0
3.5
3.5
3.5
3.5
4.0
4.0
5.0
5.0
5.5
7.5*
12.5*
7.5
3.6
3.6
4.0
4.0
5.5
5.5
5.5
5.5
7.5
7.5
7.7
5.5
See the individual
product specification
*DC630V, DC1kV: W+0.5mm
Dimensions
3, 4, W
0
1
5, U
2
105
K1C
M
224K
475
K2C
M
224K
226
K2C
M
105
K5C
M
224K
335
K5C
M
225
K1C
M
C0G
DC25V DC50V DC100V
DC250V DC630V
X7R X7S X7R X7S X7R X7R, U2J, C0GC0G
DC1kV
153
K7C
M
(X7R)
472
J7U
M
(U2J)
332
J7A
M
(C0G)
(X7R)
474
M7C
M
(U2J)
333
J7U
M
(X7R)
104
K7C
M
(U2J)
103
J7U
M
102
JAU
M
(U2J)
(X7R)
102
KAC
M
(C0G)
102
JAA
M
(X7R)
104
KAC
M
(U2J)
103
JAU
M
(X7R)
333
KAC
M
(U2J)
472
JAU
M
475
K5C
M
105K
106
K5C
M
A
102J
563
J5A
M
A
102J
103
J1A
M
103
J4U
M
(U2J)
473
K4C
M
(X7R)
153
J4A
M
(C0G)
(X7R)
474
K4C
M
(X7R)
224
K4C
M
(U2J)
473
J4U
M
U
102J
(U2J)
102K
(X7R)
Temperature
Characteristics
Nominal Capacitance
Capacitance Tolerance
Rated Voltage
Manufacturer's
Identification
Under 100pF: Actual value 100pF and over: Marked with 3 figures
Marked with code (C0G char.: A, X7S/X7R char.: C, U2J char.: U)
A part is omitted (Please refer to the marking example.)
Marked with code
A part is omitted (Please refer to the marking example.)
Marked with code (DC25V: 2, DC50V: 5, DC100V: 1, DC250V: 4, DC630V: 7, DC1kV: A)
A part is omitted (Please refer to the marking example.)
M
Marked with
A part is omitted (Please refer to the marking example.)
Rated
Voltage
Temp.
Char.
Dimensions
Code
Marking
Part Number Temp.
Char.
Rated
Voltage Capacitance
Dimensions
LxW
(mm)
Dimension
T
(mm)
Lead Space
F
(mm)
Lead Style
Code
Bulk
Lead Style
Code
Taping
RCE5C1H1R0C0ppH03pC0G (EIA) 50Vdc 1.0pF±0.25pF 3.6×3.5 2.5 2.5 A2 DB
RCE5C1H1R0C0ppH03pC0G (EIA) 50Vdc 1.0pF±0.25pF 3.6×3.5 2.5 5.0 K1 M1
RCE5C1H2R0C0ppH03pC0G (EIA) 50Vdc 2.0pF±0.25pF 3.6×3.5 2.5 2.5 A2 DB
RCE5C1H2R0C0ppH03pC0G (EIA) 50Vdc 2.0pF±0.25pF 3.6×3.5 2.5 5.0 K1 M1
RCE5C1H3R0C0ppH03pC0G (EIA) 50Vdc 3.0pF±0.25pF 3.6×3.5 2.5 2.5 A2 DB
RCE5C1H3R0C0ppH03pC0G (EIA) 50Vdc 3.0pF±0.25pF 3.6×3.5 2.5 5.0 K1 M1
RCE5C1H4R0C0ppH03pC0G (EIA) 50Vdc 4.0pF±0.25pF 3.6×3.5 2.5 2.5 A2 DB
RCE5C1H4R0C0ppH03pC0G (EIA) 50Vdc 4.0pF±0.25pF 3.6×3.5 2.5 5.0 K1 M1
RCE5C1H5R0C0ppH03pC0G (EIA) 50Vdc 5.0pF±0.25pF 3.6×3.5 2.5 2.5 A2 DB
RCE5C1H5R0C0ppH03pC0G (EIA) 50Vdc 5.0pF±0.25pF 3.6×3.5 2.5 5.0 K1 M1
Continued on the following page.
Temperature Compensating Type, C0G/U2J Characteristics
!Note • Please read rating and !CAUTION (for storage, operating, rating, soldering, mounting and handling) in this catalog to prevent smoking and/or burning, etc.
• This catalog has only typical specifications. Therefore, please approve our product specifications or transact the approval sheet for product specifications before ordering.
6
C49E.pdf
May 10,2018
1
Continued from the preceding page.
Part Number Temp.
Char.
Rated
Voltage Capacitance
Dimensions
LxW
(mm)
Dimension
T
(mm)
Lead Space
F
(mm)
Lead Style
Code
Bulk
Lead Style
Code
Taping
RCE5C1H6R0D0ppH03pC0G (EIA) 50Vdc 6.0pF±0.5pF 3.6×3.5 2.5 2.5 A2 DB
RCE5C1H6R0D0ppH03pC0G (EIA) 50Vdc 6.0pF±0.5pF 3.6×3.5 2.5 5.0 K1 M1
RCE5C1H7R0D0ppH03pC0G (EIA) 50Vdc 7.0pF±0.5pF 3.6×3.5 2.5 2.5 A2 DB
RCE5C1H7R0D0ppH03pC0G (EIA) 50Vdc 7.0pF±0.5pF 3.6×3.5 2.5 5.0 K1 M1
RCE5C1H8R0D0ppH03pC0G (EIA) 50Vdc 8.0pF±0.5pF 3.6×3.5 2.5 2.5 A2 DB
RCE5C1H8R0D0ppH03pC0G (EIA) 50Vdc 8.0pF±0.5pF 3.6×3.5 2.5 5.0 K1 M1
RCE5C1H9R0D0ppH03pC0G (EIA) 50Vdc 9.0pF±0.5pF 3.6×3.5 2.5 2.5 A2 DB
RCE5C1H9R0D0ppH03pC0G (EIA) 50Vdc 9.0pF±0.5pF 3.6×3.5 2.5 5.0 K1 M1
RCE5C1H100J0ppH03pC0G (EIA) 50Vdc 10pF±5% 3.6×3.5 2.5 2.5 A2 DB
RCE5C1H100J0ppH03pC0G (EIA) 50Vdc 10pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C1H120J0ppH03pC0G (EIA) 50Vdc 12pF±5% 3.6×3.5 2.5 2.5 A2 DB
RCE5C1H120J0ppH03pC0G (EIA) 50Vdc 12pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C1H150J0ppH03pC0G (EIA) 50Vdc 15pF±5% 3.6×3.5 2.5 2.5 A2 DB
RCE5C1H150J0ppH03pC0G (EIA) 50Vdc 15pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C1H180J0ppH03pC0G (EIA) 50Vdc 18pF±5% 3.6×3.5 2.5 2.5 A2 DB
RCE5C1H180J0ppH03pC0G (EIA) 50Vdc 18pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C1H220J0ppH03pC0G (EIA) 50Vdc 22pF±5% 3.6×3.5 2.5 2.5 A2 DB
RCE5C1H220J0ppH03pC0G (EIA) 50Vdc 22pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C1H270J0ppH03pC0G (EIA) 50Vdc 27pF±5% 3.6×3.5 2.5 2.5 A2 DB
RCE5C1H270J0ppH03pC0G (EIA) 50Vdc 27pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C1H330J0ppH03pC0G (EIA) 50Vdc 33pF±5% 3.6×3.5 2.5 2.5 A2 DB
RCE5C1H330J0ppH03pC0G (EIA) 50Vdc 33pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C1H390J0ppH03pC0G (EIA) 50Vdc 39pF±5% 3.6×3.5 2.5 2.5 A2 DB
RCE5C1H390J0ppH03pC0G (EIA) 50Vdc 39pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C1H470J0ppH03pC0G (EIA) 50Vdc 47pF±5% 3.6×3.5 2.5 2.5 A2 DB
RCE5C1H470J0ppH03pC0G (EIA) 50Vdc 47pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C1H560J0ppH03pC0G (EIA) 50Vdc 56pF±5% 3.6×3.5 2.5 2.5 A2 DB
RCE5C1H560J0ppH03pC0G (EIA) 50Vdc 56pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C1H680J0ppH03pC0G (EIA) 50Vdc 68pF±5% 3.6×3.5 2.5 2.5 A2 DB
RCE5C1H680J0ppH03pC0G (EIA) 50Vdc 68pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C1H820J0ppH03pC0G (EIA) 50Vdc 82pF±5% 3.6×3.5 2.5 2.5 A2 DB
RCE5C1H820J0ppH03pC0G (EIA) 50Vdc 82pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C1H101J0ppH03pC0G (EIA) 50Vdc 100pF±5% 3.6×3.5 2.5 2.5 A2 DB
RCE5C1H101J0ppH03pC0G (EIA) 50Vdc 100pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C1H121J0ppH03pC0G (EIA) 50Vdc 120pF±5% 3.6×3.5 2.5 2.5 A2 DB
RCE5C1H121J0ppH03pC0G (EIA) 50Vdc 120pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C1H151J0ppH03pC0G (EIA) 50Vdc 150pF±5% 3.6×3.5 2.5 2.5 A2 DB
RCE5C1H151J0ppH03pC0G (EIA) 50Vdc 150pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C1H181J0ppH03pC0G (EIA) 50Vdc 180pF±5% 3.6×3.5 2.5 2.5 A2 DB
RCE5C1H181J0ppH03pC0G (EIA) 50Vdc 180pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C1H221J0ppH03pC0G (EIA) 50Vdc 220pF±5% 3.6×3.5 2.5 2.5 A2 DB
RCE5C1H221J0ppH03pC0G (EIA) 50Vdc 220pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C1H271J0ppH03pC0G (EIA) 50Vdc 270pF±5% 3.6×3.5 2.5 2.5 A2 DB
RCE5C1H271J0ppH03pC0G (EIA) 50Vdc 270pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C1H331J0ppH03pC0G (EIA) 50Vdc 330pF±5% 3.6×3.5 2.5 2.5 A2 DB
RCE5C1H331J0ppH03pC0G (EIA) 50Vdc 330pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C1H391J0ppH03pC0G (EIA) 50Vdc 390pF±5% 3.6×3.5 2.5 2.5 A2 DB
RCE5C1H391J0ppH03pC0G (EIA) 50Vdc 390pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C1H471J0ppH03pC0G (EIA) 50Vdc 470pF±5% 3.6×3.5 2.5 2.5 A2 DB
RCE5C1H471J0ppH03pC0G (EIA) 50Vdc 470pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C1H561J0ppH03pC0G (EIA) 50Vdc 560pF±5% 3.6×3.5 2.5 2.5 A2 DB
RCE5C1H561J0ppH03pC0G (EIA) 50Vdc 560pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C1H681J0ppH03pC0G (EIA) 50Vdc 680pF±5% 3.6×3.5 2.5 2.5 A2 DB
RCE5C1H681J0ppH03pC0G (EIA) 50Vdc 680pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C1H821J0ppH03pC0G (EIA) 50Vdc 820pF±5% 3.6×3.5 2.5 2.5 A2 DB
RCE5C1H821J0ppH03pC0G (EIA) 50Vdc 820pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C1H102J0ppH03pC0G (EIA) 50Vdc 1000pF±5% 3.6×3.5 2.5 2.5 A2 DB
Continued on the following page.
!Note • Please read rating and !CAUTION (for storage, operating, rating, soldering, mounting and handling) in this catalog to prevent smoking and/or burning, etc.
• This catalog has only typical specifications. Therefore, please approve our product specifications or transact the approval sheet for product specifications before ordering.
7
C49E.pdf
May 10,2018
1
Continued from the preceding page.
Part Number Temp.
Char.
Rated
Voltage Capacitance
Dimensions
LxW
(mm)
Dimension
T
(mm)
Lead Space
F
(mm)
Lead Style
Code
Bulk
Lead Style
Code
Taping
RCE5C1H102J0ppH03pC0G (EIA) 50Vdc 1000pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C1H122J0ppH03pC0G (EIA) 50Vdc 1200pF±5% 3.6×3.5 2.5 2.5 A2 DB
RCE5C1H122J0ppH03pC0G (EIA) 50Vdc 1200pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C1H152J0ppH03pC0G (EIA) 50Vdc 1500pF±5% 3.6×3.5 2.5 2.5 A2 DB
RCE5C1H152J0ppH03pC0G (EIA) 50Vdc 1500pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C1H182J0ppH03pC0G (EIA) 50Vdc 1800pF±5% 3.6×3.5 2.5 2.5 A2 DB
RCE5C1H182J0ppH03pC0G (EIA) 50Vdc 1800pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C1H222J0ppH03pC0G (EIA) 50Vdc 2200pF±5% 3.6×3.5 2.5 2.5 A2 DB
RCE5C1H222J0ppH03pC0G (EIA) 50Vdc 2200pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C1H272J0ppH03pC0G (EIA) 50Vdc 2700pF±5% 3.6×3.5 2.5 2.5 A2 DB
RCE5C1H272J0ppH03pC0G (EIA) 50Vdc 2700pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C1H332J0ppH03pC0G (EIA) 50Vdc 3300pF±5% 3.6×3.5 2.5 2.5 A2 DB
RCE5C1H332J0ppH03pC0G (EIA) 50Vdc 3300pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C1H392J0ppH03pC0G (EIA) 50Vdc 3900pF±5% 3.6×3.5 2.5 2.5 A2 DB
RCE5C1H392J0ppH03pC0G (EIA) 50Vdc 3900pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C1H472J1ppH03pC0G (EIA) 50Vdc 4700pF±5% 4.0×3.5 2.5 2.5 A2 DB
RCE5C1H472J1ppH03pC0G (EIA) 50Vdc 4700pF±5% 4.0×3.5 2.5 5.0 K1 M1
RCE5C1H562J1ppH03pC0G (EIA) 50Vdc 5600pF±5% 4.0×3.5 2.5 2.5 A2 DB
RCE5C1H562J1ppH03pC0G (EIA) 50Vdc 5600pF±5% 4.0×3.5 2.5 5.0 K1 M1
RCE5C1H682J1ppH03pC0G (EIA) 50Vdc 6800pF±5% 4.0×3.5 2.5 2.5 A2 DB
RCE5C1H682J1ppH03pC0G (EIA) 50Vdc 6800pF±5% 4.0×3.5 2.5 5.0 K1 M1
RCE5C1H822J1ppH03pC0G (EIA) 50Vdc 8200pF±5% 4.0×3.5 2.5 2.5 A2 DB
RCE5C1H822J1ppH03pC0G (EIA) 50Vdc 8200pF±5% 4.0×3.5 2.5 5.0 K1 M1
RCE5C1H103J1ppH03pC0G (EIA) 50Vdc 10000pF±5% 4.0×3.5 2.5 2.5 A2 DB
RCE5C1H103J1ppH03pC0G (EIA) 50Vdc 10000pF±5% 4.0×3.5 2.5 5.0 K1 M1
RCE5C1H123J1ppH03pC0G (EIA) 50Vdc 12000pF±5% 4.0×3.5 2.5 2.5 A2 DB
RCE5C1H123J1ppH03pC0G (EIA) 50Vdc 12000pF±5% 4.0×3.5 2.5 5.0 K1 M1
RCE5C1H153J1ppH03pC0G (EIA) 50Vdc 15000pF±5% 4.0×3.5 2.5 2.5 A2 DB
RCE5C1H153J1ppH03pC0G (EIA) 50Vdc 15000pF±5% 4.0×3.5 2.5 5.0 K1 M1
RCE5C1H183J1ppH03pC0G (EIA) 50Vdc 18000pF±5% 4.0×3.5 2.5 2.5 A2 DB
RCE5C1H183J1ppH03pC0G (EIA) 50Vdc 18000pF±5% 4.0×3.5 2.5 5.0 K1 M1
RCE5C1H223J1ppH03pC0G (EIA) 50Vdc 22000pF±5% 4.0×3.5 2.5 2.5 A2 DB
RCE5C1H223J1ppH03pC0G (EIA) 50Vdc 22000pF±5% 4.0×3.5 2.5 5.0 K1 M1
RCE5C1H273J2ppH03pC0G (EIA) 50Vdc 27000pF±5% 5.5×4.0 3.15 2.5 A2 DB
RCE5C1H273J2ppH03pC0G (EIA) 50Vdc 27000pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C1H333J2ppH03pC0G (EIA) 50Vdc 33000pF±5% 5.5×4.0 3.15 2.5 A2 DB
RCE5C1H333J2ppH03pC0G (EIA) 50Vdc 33000pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C1H393J2ppH03pC0G (EIA) 50Vdc 39000pF±5% 5.5×4.0 3.15 2.5 A2 DB
RCE5C1H393J2ppH03pC0G (EIA) 50Vdc 39000pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C1H473J2ppH03pC0G (EIA) 50Vdc 47000pF±5% 5.5×4.0 3.15 2.5 A2 DB
RCE5C1H473J2ppH03pC0G (EIA) 50Vdc 47000pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C1H563J2ppH03pC0G (EIA) 50Vdc 56000pF±5% 5.5×4.0 3.15 2.5 A2 DB
RCE5C1H563J2ppH03pC0G (EIA) 50Vdc 56000pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C1H683J2ppH03pC0G (EIA) 50Vdc 68000pF±5% 5.5×4.0 3.15 2.5 A2 DB
RCE5C1H683J2ppH03pC0G (EIA) 50Vdc 68000pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C1H823J2ppH03pC0G (EIA) 50Vdc 82000pF±5% 5.5×4.0 3.15 2.5 A2 DB
RCE5C1H823J2ppH03pC0G (EIA) 50Vdc 82000pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C1H104J2ppH03pC0G (EIA) 50Vdc 0.1µF±5% 5.5×4.0 3.15 2.5 A2 DB
RCE5C1H104J2ppH03pC0G (EIA) 50Vdc 0.1µF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2A1R0C0ppH03pC0G (EIA) 100Vdc 1.0pF±0.25pF 3.6×3.5 2.5 2.5 A2 DB
RCE5C2A1R0C0ppH03pC0G (EIA) 100Vdc 1.0pF±0.25pF 3.6×3.5 2.5 5.0 K1 M1
RCE5C2A2R0C0ppH03pC0G (EIA) 100Vdc 2.0pF±0.25pF 3.6×3.5 2.5 2.5 A2 DB
RCE5C2A2R0C0ppH03pC0G (EIA) 100Vdc 2.0pF±0.25pF 3.6×3.5 2.5 5.0 K1 M1
RCE5C2A3R0C0ppH03pC0G (EIA) 100Vdc 3.0pF±0.25pF 3.6×3.5 2.5 2.5 A2 DB
RCE5C2A3R0C0ppH03pC0G (EIA) 100Vdc 3.0pF±0.25pF 3.6×3.5 2.5 5.0 K1 M1
RCE5C2A4R0C0ppH03pC0G (EIA) 100Vdc 4.0pF±0.25pF 3.6×3.5 2.5 2.5 A2 DB
RCE5C2A4R0C0ppH03pC0G (EIA) 100Vdc 4.0pF±0.25pF 3.6×3.5 2.5 5.0 K1 M1
Continued on the following page.
!Note • Please read rating and !CAUTION (for storage, operating, rating, soldering, mounting and handling) in this catalog to prevent smoking and/or burning, etc.
• This catalog has only typical specifications. Therefore, please approve our product specifications or transact the approval sheet for product specifications before ordering.
8
C49E.pdf
May 10,2018
1
Continued from the preceding page.
Part Number Temp.
Char.
Rated
Voltage Capacitance
Dimensions
LxW
(mm)
Dimension
T
(mm)
Lead Space
F
(mm)
Lead Style
Code
Bulk
Lead Style
Code
Taping
RCE5C2A5R0C0ppH03pC0G (EIA) 100Vdc 5.0pF±0.25pF 3.6×3.5 2.5 2.5 A2 DB
RCE5C2A5R0C0ppH03pC0G (EIA) 100Vdc 5.0pF±0.25pF 3.6×3.5 2.5 5.0 K1 M1
RCE5C2A6R0D0ppH03pC0G (EIA) 100Vdc 6.0pF±0.5pF 3.6×3.5 2.5 2.5 A2 DB
RCE5C2A6R0D0ppH03pC0G (EIA) 100Vdc 6.0pF±0.5pF 3.6×3.5 2.5 5.0 K1 M1
RCE5C2A7R0D0ppH03pC0G (EIA) 100Vdc 7.0pF±0.5pF 3.6×3.5 2.5 2.5 A2 DB
RCE5C2A7R0D0ppH03pC0G (EIA) 100Vdc 7.0pF±0.5pF 3.6×3.5 2.5 5.0 K1 M1
RCE5C2A8R0D0ppH03pC0G (EIA) 100Vdc 8.0pF±0.5pF 3.6×3.5 2.5 2.5 A2 DB
RCE5C2A8R0D0ppH03pC0G (EIA) 100Vdc 8.0pF±0.5pF 3.6×3.5 2.5 5.0 K1 M1
RCE5C2A9R0D0ppH03pC0G (EIA) 100Vdc 9.0pF±0.5pF 3.6×3.5 2.5 2.5 A2 DB
RCE5C2A9R0D0ppH03pC0G (EIA) 100Vdc 9.0pF±0.5pF 3.6×3.5 2.5 5.0 K1 M1
RCE5C2A100J0ppH03pC0G (EIA) 100Vdc 10pF±5% 3.6×3.5 2.5 2.5 A2 DB
RCE5C2A100J0ppH03pC0G (EIA) 100Vdc 10pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C2A120J0ppH03pC0G (EIA) 100Vdc 12pF±5% 3.6×3.5 2.5 2.5 A2 DB
RCE5C2A120J0ppH03pC0G (EIA) 100Vdc 12pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C2A150J0ppH03pC0G (EIA) 100Vdc 15pF±5% 3.6×3.5 2.5 2.5 A2 DB
RCE5C2A150J0ppH03pC0G (EIA) 100Vdc 15pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C2A180J0ppH03pC0G (EIA) 100Vdc 18pF±5% 3.6×3.5 2.5 2.5 A2 DB
RCE5C2A180J0ppH03pC0G (EIA) 100Vdc 18pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C2A220J0ppH03pC0G (EIA) 100Vdc 22pF±5% 3.6×3.5 2.5 2.5 A2 DB
RCE5C2A220J0ppH03pC0G (EIA) 100Vdc 22pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C2A270J0ppH03pC0G (EIA) 100Vdc 27pF±5% 3.6×3.5 2.5 2.5 A2 DB
RCE5C2A270J0ppH03pC0G (EIA) 100Vdc 27pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C2A330J0ppH03pC0G (EIA) 100Vdc 33pF±5% 3.6×3.5 2.5 2.5 A2 DB
RCE5C2A330J0ppH03pC0G (EIA) 100Vdc 33pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C2A390J0ppH03pC0G (EIA) 100Vdc 39pF±5% 3.6×3.5 2.5 2.5 A2 DB
RCE5C2A390J0ppH03pC0G (EIA) 100Vdc 39pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C2A470J0ppH03pC0G (EIA) 100Vdc 47pF±5% 3.6×3.5 2.5 2.5 A2 DB
RCE5C2A470J0ppH03pC0G (EIA) 100Vdc 47pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C2A560J0ppH03pC0G (EIA) 100Vdc 56pF±5% 3.6×3.5 2.5 2.5 A2 DB
RCE5C2A560J0ppH03pC0G (EIA) 100Vdc 56pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C2A680J0ppH03pC0G (EIA) 100Vdc 68pF±5% 3.6×3.5 2.5 2.5 A2 DB
RCE5C2A680J0ppH03pC0G (EIA) 100Vdc 68pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C2A820J0ppH03pC0G (EIA) 100Vdc 82pF±5% 3.6×3.5 2.5 2.5 A2 DB
RCE5C2A820J0ppH03pC0G (EIA) 100Vdc 82pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C2A101J0ppH03pC0G (EIA) 100Vdc 100pF±5% 3.6×3.5 2.5 2.5 A2 DB
RCE5C2A101J0ppH03pC0G (EIA) 100Vdc 100pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C2A121J0ppH03pC0G (EIA) 100Vdc 120pF±5% 3.6×3.5 2.5 2.5 A2 DB
RCE5C2A121J0ppH03pC0G (EIA) 100Vdc 120pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C2A151J0ppH03pC0G (EIA) 100Vdc 150pF±5% 3.6×3.5 2.5 2.5 A2 DB
RCE5C2A151J0ppH03pC0G (EIA) 100Vdc 150pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C2A181J0ppH03pC0G (EIA) 100Vdc 180pF±5% 3.6×3.5 2.5 2.5 A2 DB
RCE5C2A181J0ppH03pC0G (EIA) 100Vdc 180pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C2A221J0ppH03pC0G (EIA) 100Vdc 220pF±5% 3.6×3.5 2.5 2.5 A2 DB
RCE5C2A221J0ppH03pC0G (EIA) 100Vdc 220pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C2A271J0ppH03pC0G (EIA) 100Vdc 270pF±5% 3.6×3.5 2.5 2.5 A2 DB
RCE5C2A271J0ppH03pC0G (EIA) 100Vdc 270pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C2A331J0ppH03pC0G (EIA) 100Vdc 330pF±5% 3.6×3.5 2.5 2.5 A2 DB
RCE5C2A331J0ppH03pC0G (EIA) 100Vdc 330pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C2A391J0ppH03pC0G (EIA) 100Vdc 390pF±5% 3.6×3.5 2.5 2.5 A2 DB
RCE5C2A391J0ppH03pC0G (EIA) 100Vdc 390pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C2A471J0ppH03pC0G (EIA) 100Vdc 470pF±5% 3.6×3.5 2.5 2.5 A2 DB
RCE5C2A471J0ppH03pC0G (EIA) 100Vdc 470pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C2A561J0ppH03pC0G (EIA) 100Vdc 560pF±5% 3.6×3.5 2.5 2.5 A2 DB
RCE5C2A561J0ppH03pC0G (EIA) 100Vdc 560pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C2A681J0ppH03pC0G (EIA) 100Vdc 680pF±5% 3.6×3.5 2.5 2.5 A2 DB
RCE5C2A681J0ppH03pC0G (EIA) 100Vdc 680pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C2A821J0ppH03pC0G (EIA) 100Vdc 820pF±5% 3.6×3.5 2.5 2.5 A2 DB
Continued on the following page.
!Note • Please read rating and !CAUTION (for storage, operating, rating, soldering, mounting and handling) in this catalog to prevent smoking and/or burning, etc.
• This catalog has only typical specifications. Therefore, please approve our product specifications or transact the approval sheet for product specifications before ordering.
9
C49E.pdf
May 10,2018
1
Continued from the preceding page.
Part Number Temp.
Char.
Rated
Voltage Capacitance
Dimensions
LxW
(mm)
Dimension
T
(mm)
Lead Space
F
(mm)
Lead Style
Code
Bulk
Lead Style
Code
Taping
RCE5C2A821J0ppH03pC0G (EIA) 100Vdc 820pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C2A102J0ppH03pC0G (EIA) 100Vdc 1000pF±5% 3.6×3.5 2.5 2.5 A2 DB
RCE5C2A102J0ppH03pC0G (EIA) 100Vdc 1000pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C2A122J0ppH03pC0G (EIA) 100Vdc 1200pF±5% 3.6×3.5 2.5 2.5 A2 DB
RCE5C2A122J0ppH03pC0G (EIA) 100Vdc 1200pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C2A152J0ppH03pC0G (EIA) 100Vdc 1500pF±5% 3.6×3.5 2.5 2.5 A2 DB
RCE5C2A152J0ppH03pC0G (EIA) 100Vdc 1500pF±5% 3.6×3.5 2.5 5.0 K1 M1
RCE5C2A182J1ppH03pC0G (EIA) 100Vdc 1800pF±5% 4.0×3.5 2.5 2.5 A2 DB
RCE5C2A182J1ppH03pC0G (EIA) 100Vdc 1800pF±5% 4.0×3.5 2.5 5.0 K1 M1
RCE5C2A222J1ppH03pC0G (EIA) 100Vdc 2200pF±5% 4.0×3.5 2.5 2.5 A2 DB
RCE5C2A222J1ppH03pC0G (EIA) 100Vdc 2200pF±5% 4.0×3.5 2.5 5.0 K1 M1
RCE5C2A272J1ppH03pC0G (EIA) 100Vdc 2700pF±5% 4.0×3.5 2.5 2.5 A2 DB
RCE5C2A272J1ppH03pC0G (EIA) 100Vdc 2700pF±5% 4.0×3.5 2.5 5.0 K1 M1
RCE5C2A332J1ppH03pC0G (EIA) 100Vdc 3300pF±5% 4.0×3.5 2.5 2.5 A2 DB
RCE5C2A332J1ppH03pC0G (EIA) 100Vdc 3300pF±5% 4.0×3.5 2.5 5.0 K1 M1
RCE5C2A392J2ppH03pC0G (EIA) 100Vdc 3900pF±5% 5.5×4.0 3.15 2.5 A2 DB
RCE5C2A392J2ppH03pC0G (EIA) 100Vdc 3900pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2A472J2ppH03pC0G (EIA) 100Vdc 4700pF±5% 5.5×4.0 3.15 2.5 A2 DB
RCE5C2A472J2ppH03pC0G (EIA) 100Vdc 4700pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2A562J2ppH03pC0G (EIA) 100Vdc 5600pF±5% 5.5×4.0 3.15 2.5 A2 DB
RCE5C2A562J2ppH03pC0G (EIA) 100Vdc 5600pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2A682J2ppH03pC0G (EIA) 100Vdc 6800pF±5% 5.5×4.0 3.15 2.5 A2 DB
RCE5C2A682J2ppH03pC0G (EIA) 100Vdc 6800pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2A822J2ppH03pC0G (EIA) 100Vdc 8200pF±5% 5.5×4.0 3.15 2.5 A2 DB
RCE5C2A822J2ppH03pC0G (EIA) 100Vdc 8200pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2A103J2ppH03pC0G (EIA) 100Vdc 10000pF±5% 5.5×4.0 3.15 2.5 A2 DB
RCE5C2A103J2ppH03pC0G (EIA) 100Vdc 10000pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2E100J2ppH03pC0G (EIA) 250Vdc 10pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2E120J2ppH03pC0G (EIA) 250Vdc 12pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2E150J2ppH03pC0G (EIA) 250Vdc 15pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2E180J2ppH03pC0G (EIA) 250Vdc 18pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2E220J2ppH03pC0G (EIA) 250Vdc 22pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2E270J2ppH03pC0G (EIA) 250Vdc 27pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2E330J2ppH03pC0G (EIA) 250Vdc 33pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2E390J2ppH03pC0G (EIA) 250Vdc 39pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2E470J2ppH03pC0G (EIA) 250Vdc 47pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2E560J2ppH03pC0G (EIA) 250Vdc 56pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2E680J2ppH03pC0G (EIA) 250Vdc 68pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2E820J2ppH03pC0G (EIA) 250Vdc 82pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2E101J2ppH03pC0G (EIA) 250Vdc 100pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2E121J2ppH03pC0G (EIA) 250Vdc 120pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2E151J2ppH03pC0G (EIA) 250Vdc 150pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2E181J2ppH03pC0G (EIA) 250Vdc 180pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2E221J2ppH03pC0G (EIA) 250Vdc 220pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2E271J2ppH03pC0G (EIA) 250Vdc 270pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2E331J2ppH03pC0G (EIA) 250Vdc 330pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2E391J2ppH03pC0G (EIA) 250Vdc 390pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2E471J2ppH03pC0G (EIA) 250Vdc 470pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2E561J2ppH03pC0G (EIA) 250Vdc 560pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2E681J2ppH03pC0G (EIA) 250Vdc 680pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2E821J2ppH03pC0G (EIA) 250Vdc 820pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2E102J2ppH03pC0G (EIA) 250Vdc 1000pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2E122J2ppH03pC0G (EIA) 250Vdc 1200pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2E152J2ppH03pC0G (EIA) 250Vdc 1500pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2E182J2ppH03pC0G (EIA) 250Vdc 1800pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2E222J2ppH03pC0G (EIA) 250Vdc 2200pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2E272J2ppH03pC0G (EIA) 250Vdc 2700pF±5% 5.5×4.0 3.15 5.0 K1 M1
Continued on the following page.
!Note • Please read rating and !CAUTION (for storage, operating, rating, soldering, mounting and handling) in this catalog to prevent smoking and/or burning, etc.
• This catalog has only typical specifications. Therefore, please approve our product specifications or transact the approval sheet for product specifications before ordering.
10
C49E.pdf
May 10,2018
1
Continued from the preceding page.
Part Number Temp.
Char.
Rated
Voltage Capacitance
Dimensions
LxW
(mm)
Dimension
T
(mm)
Lead Space
F
(mm)
Lead Style
Code
Bulk
Lead Style
Code
Taping
RCE5C2E332J2ppH03pC0G (EIA) 250Vdc 3300pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2E392J2ppH03pC0G (EIA) 250Vdc 3900pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2E472J2ppH03pC0G (EIA) 250Vdc 4700pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2E562J2ppH03pC0G (EIA) 250Vdc 5600pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2E682J2ppH03pC0G (EIA) 250Vdc 6800pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2E822J2ppH03pC0G (EIA) 250Vdc 8200pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2E103J2ppH03pC0G (EIA) 250Vdc 10000pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2E123J2ppH03pC0G (EIA) 250Vdc 12000pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2E153J2ppH03pC0G (EIA) 250Vdc 15000pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2J100J2ppH03pC0G (EIA) 630Vdc 10pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2J120J2ppH03pC0G (EIA) 630Vdc 12pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2J150J2ppH03pC0G (EIA) 630Vdc 15pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2J180J2ppH03pC0G (EIA) 630Vdc 18pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2J220J2ppH03pC0G (EIA) 630Vdc 22pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2J270J2ppH03pC0G (EIA) 630Vdc 27pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2J330J2ppH03pC0G (EIA) 630Vdc 33pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2J390J2ppH03pC0G (EIA) 630Vdc 39pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2J470J2ppH03pC0G (EIA) 630Vdc 47pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2J560J2ppH03pC0G (EIA) 630Vdc 56pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2J680J2ppH03pC0G (EIA) 630Vdc 68pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2J820J2ppH03pC0G (EIA) 630Vdc 82pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2J101J2ppH03pC0G (EIA) 630Vdc 100pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2J121J2ppH03pC0G (EIA) 630Vdc 120pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2J151J2ppH03pC0G (EIA) 630Vdc 150pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2J181J2ppH03pC0G (EIA) 630Vdc 180pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2J221J2ppH03pC0G (EIA) 630Vdc 220pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2J271J2ppH03pC0G (EIA) 630Vdc 270pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2J331J2ppH03pC0G (EIA) 630Vdc 330pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2J391J2ppH03pC0G (EIA) 630Vdc 390pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2J471J2ppH03pC0G (EIA) 630Vdc 470pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2J561J2ppH03pC0G (EIA) 630Vdc 560pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2J681J2ppH03pC0G (EIA) 630Vdc 680pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2J821J2ppH03pC0G (EIA) 630Vdc 820pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2J102J2ppH03pC0G (EIA) 630Vdc 1000pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2J122J2ppH03pC0G (EIA) 630Vdc 1200pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2J152J2ppH03pC0G (EIA) 630Vdc 1500pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2J182J2ppH03pC0G (EIA) 630Vdc 1800pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2J222J2ppH03pC0G (EIA) 630Vdc 2200pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2J272J2ppH03pC0G (EIA) 630Vdc 2700pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C2J332J2ppH03pC0G (EIA) 630Vdc 3300pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C3A100J2ppH03pC0G (EIA) 1000Vdc 10pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C3A120J2ppH03pC0G (EIA) 1000Vdc 12pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C3A150J2ppH03pC0G (EIA) 1000Vdc 15pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C3A180J2ppH03pC0G (EIA) 1000Vdc 18pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C3A220J2ppH03pC0G (EIA) 1000Vdc 22pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C3A270J2ppH03pC0G (EIA) 1000Vdc 27pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C3A330J2ppH03pC0G (EIA) 1000Vdc 33pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C3A390J2ppH03pC0G (EIA) 1000Vdc 39pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C3A470J2ppH03pC0G (EIA) 1000Vdc 47pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C3A560J2ppH03pC0G (EIA) 1000Vdc 56pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C3A680J2ppH03pC0G (EIA) 1000Vdc 68pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C3A820J2ppH03pC0G (EIA) 1000Vdc 82pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C3A101J2ppH03pC0G (EIA) 1000Vdc 100pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C3A121J2ppH03pC0G (EIA) 1000Vdc 120pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C3A151J2ppH03pC0G (EIA) 1000Vdc 150pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C3A181J2ppH03pC0G (EIA) 1000Vdc 180pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C3A221J2ppH03pC0G (EIA) 1000Vdc 220pF±5% 5.5×4.0 3.15 5.0 K1 M1
Continued on the following page.
!Note • Please read rating and !CAUTION (for storage, operating, rating, soldering, mounting and handling) in this catalog to prevent smoking and/or burning, etc.
• This catalog has only typical specifications. Therefore, please approve our product specifications or transact the approval sheet for product specifications before ordering.
11
C49E.pdf
May 10,2018
1
Continued from the preceding page.
Part Number Temp.
Char.
Rated
Voltage Capacitance
Dimensions
LxW
(mm)
Dimension
T
(mm)
Lead Space
F
(mm)
Lead Style
Code
Bulk
Lead Style
Code
Taping
RCE5C3A271J2ppH03pC0G (EIA) 1000Vdc 270pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C3A331J2ppH03pC0G (EIA) 1000Vdc 330pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C3A391J2ppH03pC0G (EIA) 1000Vdc 390pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C3A471J2ppH03pC0G (EIA) 1000Vdc 470pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C3A561J2ppH03pC0G (EIA) 1000Vdc 560pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C3A681J2ppH03pC0G (EIA) 1000Vdc 680pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C3A821J2ppH03pC0G (EIA) 1000Vdc 820pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE5C3A102J2ppH03pC0G (EIA) 1000Vdc 1000pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE7U2E101J1ppH03pU2J (EIA) 250Vdc 100pF±5% 4.0×3.5 3.15 5.0 K1 M1
RCE7U2E151J1ppH03pU2J (EIA) 250Vdc 150pF±5% 4.0×3.5 3.15 5.0 K1 M1
RCE7U2E221J1ppH03pU2J (EIA) 250Vdc 220pF±5% 4.0×3.5 3.15 5.0 K1 M1
RCE7U2E331J1ppH03pU2J (EIA) 250Vdc 330pF±5% 4.0×3.5 3.15 5.0 K1 M1
RCE7U2E471J1ppH03pU2J (EIA) 250Vdc 470pF±5% 4.0×3.5 3.15 5.0 K1 M1
RCE7U2E681J1ppH03pU2J (EIA) 250Vdc 680pF±5% 4.0×3.5 3.15 5.0 K1 M1
RCE7U2E102J1ppH03pU2J (EIA) 250Vdc 1000pF±5% 4.0×3.5 3.15 5.0 K1 M1
RCE7U2E152J1ppH03pU2J (EIA) 250Vdc 1500pF±5% 4.0×3.5 3.15 5.0 K1 M1
RCE7U2E222J1ppH03pU2J (EIA) 250Vdc 2200pF±5% 4.0×3.5 3.15 5.0 K1 M1
RCE7U2E332J1ppH03pU2J (EIA) 250Vdc 3300pF±5% 4.0×3.5 3.15 5.0 K1 M1
RCE7U2E472J1ppH03pU2J (EIA) 250Vdc 4700pF±5% 4.0×3.5 3.15 5.0 K1 M1
RCE7U2E682J2ppH03pU2J (EIA) 250Vdc 6800pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE7U2E103J2ppH03pU2J (EIA) 250Vdc 10000pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE7U2J100J2ppH03pU2J (EIA) 630Vdc 10pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE7U2J150J2ppH03pU2J (EIA) 630Vdc 15pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE7U2J220J2ppH03pU2J (EIA) 630Vdc 22pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE7U2J330J2ppH03pU2J (EIA) 630Vdc 33pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE7U2J470J2ppH03pU2J (EIA) 630Vdc 47pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE7U2J680J2ppH03pU2J (EIA) 630Vdc 68pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE7U2J101J2ppH03pU2J (EIA) 630Vdc 100pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE7U2J151J2ppH03pU2J (EIA) 630Vdc 150pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE7U2J221J2ppH03pU2J (EIA) 630Vdc 220pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE7U2J331J2ppH03pU2J (EIA) 630Vdc 330pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE7U2J471J2ppH03pU2J (EIA) 630Vdc 470pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE7U2J681J2ppH03pU2J (EIA) 630Vdc 680pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE7U2J102J2ppH03pU2J (EIA) 630Vdc 1000pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE7U2J152J2ppH03pU2J (EIA) 630Vdc 1500pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE7U2J222J2ppH03pU2J (EIA) 630Vdc 2200pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE7U2J332J2ppH03pU2J (EIA) 630Vdc 3300pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE7U2J472J2ppH03pU2J (EIA) 630Vdc 4700pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE7U2J682J3ppH03pU2J (EIA) 630Vdc 6800pF±5% 5.5×5.0 4.0 5.0 K1 M1
RCE7U2J103J3ppH03pU2J (EIA) 630Vdc 10000pF±5% 5.5×5.0 4.0 5.0 K1 M1
RCE7U2J153J4ppH03pU2J (EIA) 630Vdc 15000pF±5% 7.5×5.5 4.0 5.0 K1 M1
RCE7U2J223J4ppH03pU2J (EIA) 630Vdc 22000pF±5% 7.5×5.5 4.0 5.0 K1 M1
RCE7U2J333J5ppH03pU2J (EIA) 630Vdc 33000pF±5% 7.5×8.0 4.0 5.0 B1 E1
RCE7U2J473J5ppH03pU2J (EIA) 630Vdc 47000pF±5% 7.5×8.0 4.0 5.0 B1 E1
RCE7U2J943JUppH03pU2J (EIA) 630Vdc 94000pF±5% 7.7×13.0 4.0 5.0 B1 E1
RCE7U3A100J2ppH03pU2J (EIA) 1000Vdc 10pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE7U3A150J2ppH03pU2J (EIA) 1000Vdc 15pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE7U3A220J2ppH03pU2J (EIA) 1000Vdc 22pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE7U3A330J2ppH03pU2J (EIA) 1000Vdc 33pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE7U3A470J2ppH03pU2J (EIA) 1000Vdc 47pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE7U3A680J2ppH03pU2J (EIA) 1000Vdc 68pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE7U3A101J2ppH03pU2J (EIA) 1000Vdc 100pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE7U3A151J2ppH03pU2J (EIA) 1000Vdc 150pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE7U3A221J2ppH03pU2J (EIA) 1000Vdc 220pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE7U3A331J2ppH03pU2J (EIA) 1000Vdc 330pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE7U3A471J2ppH03pU2J (EIA) 1000Vdc 470pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE7U3A681J2ppH03pU2J (EIA) 1000Vdc 680pF±5% 5.5×4.0 3.15 5.0 K1 M1
Continued on the following page.
!Note • Please read rating and !CAUTION (for storage, operating, rating, soldering, mounting and handling) in this catalog to prevent smoking and/or burning, etc.
• This catalog has only typical specifications. Therefore, please approve our product specifications or transact the approval sheet for product specifications before ordering.
12
C49E.pdf
May 10,2018
1
Part Number Temp.
Char.
Rated
Voltage Capacitance
Dimensions
LxW
(mm)
Dimension
T
(mm)
Lead Space
F
(mm)
Lead Style
Code
Bulk
Lead Style
Code
Taping
RCER71E104K0ppH03pX7R (EIA) 25Vdc 0.1µF±10% 3.6×3.5 2.5 2.5 A2 DB
RCER71E104K0ppH03pX7R (EIA) 25Vdc 0.1µF±10% 3.6×3.5 2.5 5.0 K1 M1
RCER71E154K0ppH03pX7R (EIA) 25Vdc 0.15µF±10% 3.6×3.5 2.5 2.5 A2 DB
RCER71E154K0ppH03pX7R (EIA) 25Vdc 0.15µF±10% 3.6×3.5 2.5 5.0 K1 M1
RCER71E224K0ppH03pX7R (EIA) 25Vdc 0.22µF±10% 3.6×3.5 2.5 2.5 A2 DB
RCER71E224K0ppH03pX7R (EIA) 25Vdc 0.22µF±10% 3.6×3.5 2.5 5.0 K1 M1
RCER71E334K1ppH03pX7R (EIA) 25Vdc 0.33µF±10% 4.0×3.5 2.5 2.5 A2 DB
RCER71E334K1ppH03pX7R (EIA) 25Vdc 0.33µF±10% 4.0×3.5 2.5 5.0 K1 M1
RCER71E474K1ppH03pX7R (EIA) 25Vdc 0.47µF±10% 4.0×3.5 2.5 2.5 A2 DB
RCER71E474K1ppH03pX7R (EIA) 25Vdc 0.47µF±10% 4.0×3.5 2.5 5.0 K1 M1
RCER71E684K1ppH03pX7R (EIA) 25Vdc 0.68µF±10% 4.0×3.5 2.5 2.5 A2 DB
RCER71E684K1ppH03pX7R (EIA) 25Vdc 0.68µF±10% 4.0×3.5 2.5 5.0 K1 M1
RCER71E105K1ppH03pX7R (EIA) 25Vdc 1.0µF±10% 4.0×3.5 2.5 2.5 A2 DB
RCER71E105K1ppH03pX7R (EIA) 25Vdc 1.0µF±10% 4.0×3.5 2.5 5.0 K1 M1
RCER71E155K2ppH03pX7R (EIA) 25Vdc 1.5µF±10% 5.5×4.0 3.15 2.5 A2 DB
RCER71E155K2ppH03pX7R (EIA) 25Vdc 1.5µF±10% 5.5×4.0 3.15 5.0 K1 M1
RCER71E225K2ppH03pX7R (EIA) 25Vdc 2.2µF±10% 5.5×4.0 3.15 2.5 A2 DB
RCER71E225K2ppH03pX7R (EIA) 25Vdc 2.2µF±10% 5.5×4.0 3.15 5.0 K1 M1
RCER71E335K2ppH03pX7R (EIA) 25Vdc 3.3µF±10% 5.5×4.0 3.15 2.5 A2 DB
RCER71E335K2ppH03pX7R (EIA) 25Vdc 3.3µF±10% 5.5×4.0 3.15 5.0 K1 M1
RCER71E475K2ppH03pX7R (EIA) 25Vdc 4.7µF±10% 5.5×4.0 3.15 2.5 A2 DB
RCER71E475K2ppH03pX7R (EIA) 25Vdc 4.7µF±10% 5.5×4.0 3.15 5.0 K1 M1
RCER71E106K3ppH03pX7R (EIA) 25Vdc 10µF±10% 5.5×5.0 4.0 2.5 A2 DB
RCER71E106K3ppH03pX7R (EIA) 25Vdc 10µF±10% 5.5×5.0 4.0 5.0 K1 M1
RCER71E226MWppH03p
X7R (EIA) 25Vdc 22µF±20% 5.5×7.5 4.0 5.0 K1 M1
RCER71H221K0ppH03pX7R (EIA) 50Vdc 220pF±10% 3.6×3.5 2.5 2.5 A2 DB
RCER71H221K0ppH03pX7R (EIA) 50Vdc 220pF±10% 3.6×3.5 2.5 5.0 K1 M1
RCER71H331K0ppH03pX7R (EIA) 50Vdc 330pF±10% 3.6×3.5 2.5 2.5 A2 DB
RCER71H331K0ppH03pX7R (EIA) 50Vdc 330pF±10% 3.6×3.5 2.5 5.0 K1 M1
RCER71H471K0ppH03pX7R (EIA) 50Vdc 470pF±10% 3.6×3.5 2.5 2.5 A2 DB
RCER71H471K0ppH03pX7R (EIA) 50Vdc 470pF±10% 3.6×3.5 2.5 5.0 K1 M1
RCER71H681K0ppH03pX7R (EIA) 50Vdc 680pF±10% 3.6×3.5 2.5 2.5 A2 DB
RCER71H681K0ppH03pX7R (EIA) 50Vdc 680pF±10% 3.6×3.5 2.5 5.0 K1 M1
RCER71H102K0ppH03pX7R (EIA) 50Vdc 1000pF±10% 3.6×3.5 2.5 2.5 A2 DB
RCER71H102K0ppH03pX7R (EIA) 50Vdc 1000pF±10% 3.6×3.5 2.5 5.0 K1 M1
RCER71H152K0ppH03pX7R (EIA) 50Vdc 1500pF±10% 3.6×3.5 2.5 2.5 A2 DB
RCER71H152K0ppH03pX7R (EIA) 50Vdc 1500pF±10% 3.6×3.5 2.5 5.0 K1 M1
RCER71H222K0ppH03pX7R (EIA) 50Vdc 2200pF±10% 3.6×3.5 2.5 2.5 A2 DB
RCER71H222K0ppH03pX7R (EIA) 50Vdc 2200pF±10% 3.6×3.5 2.5 5.0 K1 M1
RCER71H332K0ppH03pX7R (EIA) 50Vdc 3300pF±10% 3.6×3.5 2.5 2.5 A2 DB
RCER71H332K0ppH03pX7R (EIA) 50Vdc 3300pF±10% 3.6×3.5 2.5 5.0 K1 M1
RCER71H472K0ppH03pX7R (EIA) 50Vdc 4700pF±10% 3.6×3.5 2.5 2.5 A2 DB
Continued on the following page.
High Dielectric Constant Type, X7R/X7S Characteristics
Continued from the preceding page.
Part Number Temp.
Char.
Rated
Voltage Capacitance
Dimensions
LxW
(mm)
Dimension
T
(mm)
Lead Space
F
(mm)
Lead Style
Code
Bulk
Lead Style
Code
Taping
RCE7U3A102J2ppH03pU2J (EIA) 1000Vdc 1000pF±5% 5.5×4.0 3.15 5.0 K1 M1
RCE7U3A152J3ppH03pU2J (EIA) 1000Vdc 1500pF±5% 5.5×5.0 4.0 5.0 K1 M1
RCE7U3A222J3ppH03pU2J (EIA) 1000Vdc 2200pF±5% 5.5×5.0 4.0 5.0 K1 M1
RCE7U3A332J4ppH03pU2J (EIA) 1000Vdc 3300pF±5% 7.5×5.5 4.0 5.0 K1 M1
RCE7U3A472J4ppH03pU2J (EIA) 1000Vdc 4700pF±5% 7.5×5.5 4.0 5.0 K1 M1
RCE7U3A682J5ppH03pU2J (EIA) 1000Vdc 6800pF±5% 7.5×8.0 4.0 5.0 B1 E1
RCE7U3A103J5ppH03pU2J (EIA) 1000Vdc 10000pF±5% 7.5×8.0 4.0 5.0 B1 E1
RCE7U3A203JUppH03pU2J (EIA) 1000Vdc 20000pF±5% 7.7×13.0 4.0 5.0 B1 E1
!Note • Please read rating and !CAUTION (for storage, operating, rating, soldering, mounting and handling) in this catalog to prevent smoking and/or burning, etc.
• This catalog has only typical specifications. Therefore, please approve our product specifications or transact the approval sheet for product specifications before ordering.
13
C49E.pdf
May 10,2018
1
Two blank columns are filled with the lead style code. Please refer to the 3 columns on the right for the appropriate code.
The last blank column is filled with the packaging code. (B: bulk, A: ammo pack)
Continued from the preceding page.
Part Number Temp.
Char.
Rated
Voltage Capacitance
Dimensions
LxW
(mm)
Dimension
T
(mm)
Lead Space
F
(mm)
Lead Style
Code
Bulk
Lead Style
Code
Taping
RCER71H472K0ppH03pX7R (EIA) 50Vdc 4700pF±10% 3.6×3.5 2.5 5.0 K1 M1
RCER71H682K0ppH03pX7R (EIA) 50Vdc 6800pF±10% 3.6×3.5 2.5 2.5 A2 DB
RCER71H682K0ppH03pX7R (EIA) 50Vdc 6800pF±10% 3.6×3.5 2.5 5.0 K1 M1
RCER71H103K0ppH03pX7R (EIA) 50Vdc 10000pF±10% 3.6×3.5 2.5 2.5 A2 DB
RCER71H103K0ppH03pX7R (EIA) 50Vdc 10000pF±10% 3.6×3.5 2.5 5.0 K1 M1
RCER71H153K0ppH03pX7R (EIA) 50Vdc 15000pF±10% 3.6×3.5 2.5 2.5 A2 DB
RCER71H153K0ppH03pX7R (EIA) 50Vdc 15000pF±10% 3.6×3.5 2.5 5.0 K1 M1
RCER71H223K0ppH03pX7R (EIA) 50Vdc 22000pF±10% 3.6×3.5 2.5 2.5 A2 DB
RCER71H223K0ppH03pX7R (EIA) 50Vdc 22000pF±10% 3.6×3.5 2.5 5.0 K1 M1
RCER71H333K0ppH03pX7R (EIA) 50Vdc 33000pF±10% 3.6×3.5 2.5 2.5 A2 DB
RCER71H333K0ppH03pX7R (EIA) 50Vdc 33000pF±10% 3.6×3.5 2.5 5.0 K1 M1
RCER71H473K0ppH03pX7R (EIA) 50Vdc 47000pF±10% 3.6×3.5 2.5 2.5 A2 DB
RCER71H473K0ppH03pX7R (EIA) 50Vdc 47000pF±10% 3.6×3.5 2.5 5.0 K1 M1
RCER71H683K0ppH03pX7R (EIA) 50Vdc 68000pF±10% 3.6×3.5 2.5 2.5 A2 DB
RCER71H683K0ppH03pX7R (EIA) 50Vdc 68000pF±10% 3.6×3.5 2.5 5.0 K1 M1
RCER71H104K0ppH03pX7R (EIA) 50Vdc 0.10µF±10% 3.6×3.5 2.5 2.5 A2 DB
RCER71H104K0ppH03pX7R (EIA) 50Vdc 0.10µF±10% 3.6×3.5 2.5 5.0 K1 M1
RCER71H154K1ppH03pX7R (EIA) 50Vdc 0.15µF±10% 4.0×3.5 2.5 2.5 A2 DB
RCER71H154K1ppH03pX7R (EIA) 50Vdc 0.15µF±10% 4.0×3.5 2.5 5.0 K1 M1
RCER71H224K1ppH03pX7R (EIA) 50Vdc 0.22µF±10% 4.0×3.5 2.5 2.5 A2 DB
RCER71H224K1ppH03pX7R (EIA) 50Vdc 0.22µF±10% 4.0×3.5 2.5 5.0 K1 M1
RCER71H334K1ppH03pX7R (EIA) 50Vdc 0.33µF±10% 4.0×3.5 2.5 2.5 A2 DB
RCER71H334K1ppH03pX7R (EIA) 50Vdc 0.33µF±10% 4.0×3.5 2.5 5.0 K1 M1
RCER71H474K1ppH03pX7R (EIA) 50Vdc 0.47µF±10% 4.0×3.5 2.5 2.5 A2 DB
RCER71H474K1ppH03pX7R (EIA) 50Vdc 0.47µF±10% 4.0×3.5 2.5 5.0 K1 M1
RCER71H684K2ppH03pX7R (EIA) 50Vdc 0.68µF±10% 5.5×4.0 3.15 2.5 A2 DB
RCER71H684K2ppH03pX7R (EIA) 50Vdc 0.68µF±10% 5.5×4.0 3.15 5.0 K1 M1
RCEC71H105K1ppH03pX7S (EIA) 50Vdc 1.0µF±10% 4.0×3.5 2.5 2.5 A2 DB
RCEC71H105K1ppH03pX7S (EIA) 50Vdc 1.0µF±10% 4.0×3.5 2.5 5.0 K1 M1
RCER71H105K2ppH03pX7R (EIA) 50Vdc 1.0µF±10% 5.5×4.0 3.15 2.5 A2 DB
RCER71H105K2ppH03pX7R (EIA) 50Vdc 1.0µF±10% 5.5×4.0 3.15 5.0 K1 M1
RCER71H155K2ppH03pX7R (EIA) 50Vdc 1.5µF±10% 5.5×4.0 3.15 2.5 A2 DB
RCER71H155K2ppH03pX7R (EIA) 50Vdc 1.5µF±10% 5.5×4.0 3.15 5.0 K1 M1
RCER71H225K2ppH03pX7R (EIA) 50Vdc 2.2µF±10% 5.5×4.0 3.15 2.5 A2 DB
RCER71H225K2ppH03pX7R (EIA) 50Vdc 2.2µF±10% 5.5×4.0 3.15 5.0 K1 M1
RCER71H335K3ppH03pX7R (EIA) 50Vdc 3.3µF±10% 5.5×5.0 4.0 2.5 A2 DB
RCER71H335K3ppH03pX7R (EIA) 50Vdc 3.3µF±10% 5.5×5.0 4.0 5.0 K1 M1
RCEC71H475K2ppH03pX7S (EIA) 50Vdc 4.7µF±10% 5.5×4.0 3.15 2.5 A2 DB
RCEC71H475K2ppH03pX7S (EIA) 50Vdc 4.7µF±10% 5.5×4.0 3.15 5.0 K1 M1
RCER71H475K3ppH03pX7R (EIA) 50Vdc 4.7µF±10% 5.5×5.0 4.0 2.5 A2 DB
RCER71H475K3ppH03pX7R (EIA) 50Vdc 4.7µF±10% 5.5×5.0 4.0 5.0 K1 M1
RCEC71H106K3ppH03pX7S (EIA) 50Vdc 10µF±10% 5.5×5.0 4.0 2.5 A2 DB
RCEC71H106K3ppH03pX7S (EIA) 50Vdc 10µF±10% 5.5×5.0 4.0 5.0 K1 M1
RCER71H106MWppH03p
X7R (EIA) 50Vdc 10µF±20% 5.5×7.5 4.0 5.0 K1 M1
RCEC71H226MWppH03p
X7S (EIA) 50Vdc 22µF±20% 5.5×7.5 4.0 5.0 K1 M1
RCER72A221K0ppH03pX7R (EIA) 100Vdc 220pF±10% 3.6×3.5 2.5 2.5 A2 DB
RCER72A221K0ppH03pX7R (EIA) 100Vdc 220pF±10% 3.6×3.5 2.5 5.0 K1 M1
RCER72A331K0ppH03pX7R (EIA) 100Vdc 330pF±10% 3.6×3.5 2.5 2.5 A2 DB
RCER72A331K0ppH03pX7R (EIA) 100Vdc 330pF±10% 3.6×3.5 2.5 5.0 K1 M1
RCER72A471K0ppH03pX7R (EIA) 100Vdc 470pF±10% 3.6×3.5 2.5 2.5 A2 DB
RCER72A471K0ppH03pX7R (EIA) 100Vdc 470pF±10% 3.6×3.5 2.5 5.0 K1 M1
RCER72A681K0ppH03pX7R (EIA) 100Vdc 680pF±10% 3.6×3.5 2.5 2.5 A2 DB
RCER72A681K0ppH03pX7R (EIA) 100Vdc 680pF±10% 3.6×3.5 2.5 5.0 K1 M1
RCER72A102K0ppH03pX7R (EIA) 100Vdc 1000pF±10% 3.6×3.5 2.5 2.5 A2 DB
RCER72A102K0ppH03pX7R (EIA) 100Vdc 1000pF±10% 3.6×3.5 2.5 5.0 K1 M1
RCER72A152K0ppH03pX7R (EIA) 100Vdc 1500pF±10% 3.6×3.5 2.5 2.5 A2 DB
RCER72A152K0ppH03pX7R (EIA) 100Vdc 1500pF±10% 3.6×3.5 2.5 5.0 K1 M1
Continued on the following page.
!Note • Please read rating and !CAUTION (for storage, operating, rating, soldering, mounting and handling) in this catalog to prevent smoking and/or burning, etc.
• This catalog has only typical specifications. Therefore, please approve our product specifications or transact the approval sheet for product specifications before ordering.
14
C49E.pdf
May 10,2018
1
Continued from the preceding page.
Part Number Temp.
Char.
Rated
Voltage Capacitance
Dimensions
LxW
(mm)
Dimension
T
(mm)
Lead Space
F
(mm)
Lead Style
Code
Bulk
Lead Style
Code
Taping
RCER72A222K0ppH03pX7R (EIA) 100Vdc 2200pF±10% 3.6×3.5 2.5 2.5 A2 DB
RCER72A222K0ppH03pX7R (EIA) 100Vdc 2200pF±10% 3.6×3.5 2.5 5.0 K1 M1
RCER72A332K0ppH03pX7R (EIA) 100Vdc 3300pF±10% 3.6×3.5 2.5 2.5 A2 DB
RCER72A332K0ppH03pX7R (EIA) 100Vdc 3300pF±10% 3.6×3.5 2.5 5.0 K1 M1
RCER72A472K0ppH03pX7R (EIA) 100Vdc 4700pF±10% 3.6×3.5 2.5 2.5 A2 DB
RCER72A472K0ppH03pX7R (EIA) 100Vdc 4700pF±10% 3.6×3.5 2.5 5.0 K1 M1
RCER72A682K0ppH03pX7R (EIA) 100Vdc 6800pF±10% 3.6×3.5 2.5 2.5 A2 DB
RCER72A682K0ppH03pX7R (EIA) 100Vdc 6800pF±10% 3.6×3.5 2.5 5.0 K1 M1
RCER72A103K0ppH03pX7R (EIA) 100Vdc 10000pF±10% 3.6×3.5 2.5 2.5 A2 DB
RCER72A103K0ppH03pX7R (EIA) 100Vdc 10000pF±10% 3.6×3.5 2.5 5.0 K1 M1
RCER72A153K0ppH03pX7R (EIA) 100Vdc 15000pF±10% 3.6×3.5 2.5 2.5 A2 DB
RCER72A153K0ppH03pX7R (EIA) 100Vdc 15000pF±10% 3.6×3.5 2.5 5.0 K1 M1
RCER72A223K0ppH03pX7R (EIA) 100Vdc 22000pF±10% 3.6×3.5 2.5 2.5 A2 DB
RCER72A223K0ppH03pX7R (EIA) 100Vdc 22000pF±10% 3.6×3.5 2.5 5.0 K1 M1
RCER72A333K1ppH03pX7R (EIA) 100Vdc 33000pF±10% 4.0×3.5 2.5 2.5 A2 DB
RCER72A333K1ppH03pX7R (EIA) 100Vdc 33000pF±10% 4.0×3.5 2.5 5.0 K1 M1
RCER72A473K1ppH03pX7R (EIA) 100Vdc 47000pF±10% 4.0×3.5 2.5 2.5 A2 DB
RCER72A473K1ppH03pX7R (EIA) 100Vdc 47000pF±10% 4.0×3.5 2.5 5.0 K1 M1
RCER72A683K1ppH03pX7R (EIA) 100Vdc 68000pF±10% 4.0×3.5 2.5 2.5 A2 DB
RCER72A683K1ppH03pX7R (EIA) 100Vdc 68000pF±10% 4.0×3.5 2.5 5.0 K1 M1
RCER72A104K1ppH03pX7R (EIA) 100Vdc 0.10µF±10% 4.0×3.5 2.5 2.5 A2 DB
RCER72A104K1ppH03pX7R (EIA) 100Vdc 0.10µF±10% 4.0×3.5 2.5 5.0 K1 M1
RCER72A154K2ppH03pX7R (EIA) 100Vdc 0.15µF±10% 5.5×4.0 3.15 2.5 A2 DB
RCER72A154K2ppH03pX7R (EIA) 100Vdc 0.15µF±10% 5.5×4.0 3.15 5.0 K1 M1
RCER72A224K2ppH03pX7R (EIA) 100Vdc 0.22µF±10% 5.5×4.0 3.15 2.5 A2 DB
RCER72A224K2ppH03pX7R (EIA) 100Vdc 0.22µF±10% 5.5×4.0 3.15 5.0 K1 M1
RCER72A334K1ppH03pX7R (EIA) 100Vdc 0.33µF±10% 4.0×3.5 2.5 2.5 A2 DB
RCER72A334K1ppH03pX7R (EIA) 100Vdc 0.33µF±10% 4.0×3.5 2.5 5.0 K1 M1
RCER72A474K2ppH03pX7R (EIA) 100Vdc 0.47µF±10% 5.5×4.0 3.15 2.5 A2 DB
RCER72A474K2ppH03pX7R (EIA) 100Vdc 0.47µF±10% 5.5×4.0 3.15 5.0 K1 M1
RCER72A684K2ppH03pX7R (EIA) 100Vdc 0.68µF±10% 5.5×4.0 3.15 2.5 A2 DB
RCER72A684K2ppH03pX7R (EIA) 100Vdc 0.68µF±10% 5.5×4.0 3.15 5.0 K1 M1
RCER72A105K2ppH03pX7R (EIA) 100Vdc 1.0µF±10% 5.5×4.0 3.15 2.5 A2 DB
RCER72A105K2ppH03pX7R (EIA) 100Vdc 1.0µF±10% 5.5×4.0 3.15 5.0 K1 M1
RCEC72A155K3ppH03pX7S (EIA) 100Vdc 1.5µF±10% 5.5×5.0 4.0 2.5 A2 DB
RCEC72A155K3ppH03pX7S (EIA) 100Vdc 1.5µF±10% 5.5×5.0 4.0 5.0 K1 M1
RCEC72A225K3ppH03pX7S (EIA) 100Vdc 2.2µF±10% 5.5×5.0 4.0 2.5 A2 DB
RCEC72A225K3ppH03pX7S (EIA) 100Vdc 2.2µF±10% 5.5×5.0 4.0 5.0 K1 M1
RCEC72A475MWppH03p
X7S (EIA) 100Vdc 4.7µF±20% 5.5×7.5 4.0 5.0 K1 M1
RCER72E102K1ppH03pX7R (EIA) 250Vdc 1000pF±10% 4.0×3.5 3.15 5.0 K1 M1
RCER72E152K1ppH03pX7R (EIA) 250Vdc 1500pF±10% 4.0×3.5 3.15 5.0 K1 M1
RCER72E222K1ppH03pX7R (EIA) 250Vdc 2200pF±10% 4.0×3.5 3.15 5.0 K1 M1
RCER72E332K1ppH03pX7R (EIA) 250Vdc 3300pF±10% 4.0×3.5 3.15 5.0 K1 M1
RCER72E472K1ppH03pX7R (EIA) 250Vdc 4700pF±10% 4.0×3.5 3.15 5.0 K1 M1
RCER72E682K1ppH03pX7R (EIA) 250Vdc 6800pF±10% 4.0×3.5 3.15 5.0 K1 M1
RCER72E103K1ppH03pX7R (EIA) 250Vdc 10000pF±10% 4.0×3.5 3.15 5.0 K1 M1
RCER72E153K1ppH03pX7R (EIA) 250Vdc 15000pF±10% 4.0×3.5 3.15 5.0 K1 M1
RCER72E223K1ppH03pX7R (EIA) 250Vdc 22000pF±10% 4.0×3.5 3.15 5.0 K1 M1
RCER72E333K2ppH03pX7R (EIA) 250Vdc 33000pF±10% 5.5×4.0 3.15 5.0 K1 M1
RCER72E473K2ppH03pX7R (EIA) 250Vdc 47000pF±10% 5.5×4.0 3.15 5.0 K1 M1
RCER72E683K2ppH03pX7R (EIA) 250Vdc 68000pF±10% 5.5×4.0 3.15 5.0 K1 M1
RCER72E104K2ppH03pX7R (EIA) 250Vdc 0.10µF±10% 5.5×4.0 3.15 5.0 K1 M1
RCER72E154K3ppH03pX7R (EIA) 250Vdc 0.15µF±10% 5.5×5.0 4.0 5.0 K1 M1
RCER72E224K3ppH03pX7R (EIA) 250Vdc 0.22µF±10% 5.5×5.0 4.0 5.0 K1 M1
RCER72E334K4ppH03pX7R (EIA) 250Vdc 0.33µF±10% 7.5×5.5 4.0 5.0 K1 M1
RCER72E474K4ppH03pX7R (EIA) 250Vdc 0.47µF±10% 7.5×5.5 4.0 5.0 K1 M1
RCER72E684K5ppH03pX7R (EIA) 250Vdc 0.68µF±10% 7.5×7.5 4.0 5.0 B1 E1
Continued on the following page.
!Note • Please read rating and !CAUTION (for storage, operating, rating, soldering, mounting and handling) in this catalog to prevent smoking and/or burning, etc.
• This catalog has only typical specifications. Therefore, please approve our product specifications or transact the approval sheet for product specifications before ordering.
15
C49E.pdf
May 10,2018
1
Two blank columns are filled with the lead style code. Please refer to the 3 columns on the right for the appropriate code.
The last blank column is filled with the packaging code. (B: bulk, A: ammo pack)
Part Number Temp.
Char.
Rated
Voltage Capacitance
Dimensions
LxW
(mm)
Dimension
T
(mm)
Lead Space
F
(mm)
Lead Style
Code
Bulk
Lead Style
Code
Taping
RCER72E105K5ppH03pX7R (EIA) 250Vdc 1.0µF±10% 7.5×7.5 4.0 5.0 B1 E1
RCER72E225MUppH03pX7R (EIA) 250Vdc 2.2µF±20% 7.5×12.5 4.0 5.0 B1 E1
RCER72J102K2ppH03pX7R (EIA) 630Vdc 1000pF±10% 5.5×4.0 3.15 5.0 K1 M1
RCER72J152K2ppH03pX7R (EIA) 630Vdc 1500pF±10% 5.5×4.0 3.15 5.0 K1 M1
RCER72J222K2ppH03pX7R (EIA) 630Vdc 2200pF±10% 5.5×4.0 3.15 5.0 K1 M1
RCER72J332K2ppH03pX7R (EIA) 630Vdc 3300pF±10% 5.5×4.0 3.15 5.0 K1 M1
RCER72J472K2ppH03pX7R (EIA) 630Vdc 4700pF±10% 5.5×4.0 3.15 5.0 K1 M1
RCER72J682K2ppH03pX7R (EIA) 630Vdc 6800pF±10% 5.5×4.0 3.15 5.0 K1 M1
RCER72J103K2ppH03pX7R (EIA) 630Vdc 10000pF±10% 5.5×4.0 3.15 5.0 K1 M1
RCER72J153K2ppH03pX7R (EIA) 630Vdc 15000pF±10% 5.5×4.0 3.15 5.0 K1 M1
RCER72J223K2ppH03pX7R (EIA) 630Vdc 22000pF±10% 5.5×4.0 3.15 5.0 K1 M1
RCER72J333K3ppH03pX7R (EIA) 630Vdc 33000pF±10% 5.5×5.0 4.0 5.0 K1 M1
RCER72J473K3ppH03pX7R (EIA) 630Vdc 47000pF±10% 5.5×5.0 4.0 5.0 K1 M1
RCER72J683K4ppH03pX7R (EIA) 630Vdc 68000pF±10% 7.5×5.5 4.0 5.0 K1 M1
RCER72J104K4ppH03pX7R (EIA) 630Vdc 0.10µF±10% 7.5×5.5 4.0 5.0 K1 M1
RCER72J154K5ppH03pX7R (EIA) 630Vdc 0.15µF±10% 7.5×8.0 4.0 5.0 B1 E1
RCER72J224K5ppH03pX7R (EIA) 630Vdc 0.22µF±10% 7.5×8.0 4.0 5.0 B1 E1
RCER72J474MUppH03pX7R (EIA) 630Vdc 0.47µF±20% 7.7×13.0 4.0 5.0 B1 E1
RCER73A102K2ppH03pX7R (EIA) 1000Vdc 1000pF±10% 5.5×4.0 3.15 5.0 K1 M1
RCER73A152K2ppH03pX7R (EIA) 1000Vdc 1500pF±10% 5.5×4.0 3.15 5.0 K1 M1
RCER73A222K2ppH03pX7R (EIA) 1000Vdc 2200pF±10% 5.5×4.0 3.15 5.0 K1 M1
RCER73A332K2ppH03pX7R (EIA) 1000Vdc 3300pF±10% 5.5×4.0 3.15 5.0 K1 M1
RCER73A472K2ppH03pX7R (EIA) 1000Vdc 4700pF±10% 5.5×4.0 3.15 5.0 K1 M1
RCER73A682K2ppH03pX7R (EIA) 1000Vdc 6800pF±10% 5.5×4.0 3.15 5.0 K1 M1
RCER73A103K2ppH03pX7R (EIA) 1000Vdc 10000pF±10% 5.5×4.0 3.15 5.0 K1 M1
RCER73A153K3ppH03pX7R (EIA) 1000Vdc 15000pF±10% 5.5×5.0 4.0 5.0 K1 M1
RCER73A223K3ppH03pX7R (EIA) 1000Vdc 22000pF±10% 5.5×5.0 4.0 5.0 K1 M1
RCER73A333K4ppH03pX7R (EIA) 1000Vdc 33000pF±10% 7.5×5.5 4.0 5.0 K1 M1
RCER73A473K4ppH03pX7R (EIA) 1000Vdc 47000pF±10% 7.5×5.5 4.0 5.0 K1 M1
RCER73A683K5ppH03pX7R (EIA) 1000Vdc 68000pF±10% 7.5×8.0 4.0 5.0 B1 E1
RCER73A104K5ppH03pX7R (EIA) 1000Vdc 0.10µF±10% 7.5×8.0 4.0 5.0 B1 E1
RCER73A224MUppH03pX7R (EIA) 1000Vdc 0.22µF±20% 7.7×13.0 4.0 5.0 B1 E1
Continued from the preceding page.
!Note • Please read rating and !CAUTION (for storage, operating, rating, soldering, mounting and handling) in this catalog to prevent smoking and/or burning, etc.
• This catalog has only typical specifications. Therefore, please approve our product specifications or transact the approval sheet for product specifications before ordering.
16
C49E.pdf
May 10,2018
1
Temperature Compensating Type Specifications and Test Methods
* “room condition” Temperature: 15 to 35°C, Relative humidity: 45 to 75%, Atmosphere pressure: 86 to 106kPa
Apply the voltage shown in the table for 1000±12h at 125±3°C.
Let sit for 24±2h at room condition*, then measure.
The charge/discharge current is less than 50mA.
6
Operational Life The measured and observed characteristics should satisfy the
specifications in the following table.
Appearance
No defects or abnormalities
Capacitance
Change
Within ±3% or ±0.3pF (Whichever is larger)
Q
30pF <
= C: Q >
= 350
10pF <
= C < 30pF: Q >
= 275+5C/2
10pF > C: Q >
= 200+10C
C: Nominal Capacitance (pF)
I.R. 1000MΩ or 50MΩ F μF min. (Whichever is smaller)
Apply the rated voltage and DC1.3+0.2/-0V (add 100kΩ resistor)
at 85±3°C and 80 to 85% humidity for 1000±12h.
Remove and let sit for 24±2h at room condition*, then measure.
The charge/discharge current is less than 50mA.
5
Biased Humidity The measured and observed characteristics should satisfy the
specifications in the following table.
Appearance
No defects or abnormalities
Capacitance
Change
Within ±5% or ±0.5pF (Whichever is larger)
Q
30pF <
= C: Q >
= 200
30pF > C: Q >
= 100+10C/3
C: Nominal Capacitance (pF)
I.R. 500MΩ or 25MΩ F μF min. (Whichever is smaller)
Apply the 24h heat (25 to 65°C) and humidity (80 to 98%)
treatment shown below, 10 consecutive times.
Let sit for 24±2h at room condition*, then measure.
4
Moisture
Resistance
The measured and observed characteristics should satisfy the
specifications in the following table.
Appearance
No defects or abnormalities
Capacitance
Change
Within ±5% or ±0.5pF (Whichever is larger)
Q
30pF <
= C: Q >
= 200
30pF > C: Q >
= 100+10C/3
C: Nominal Capacitance (pF)
I.R. 500MΩ or 25MΩ F μF min. (Whichever is smaller)
Perform the 1000 cycles according to the four heat treatments
listed in the following table. Let sit for 24±2h at room condition*,
then measure.
3
Temperature
Cycling
The measured and observed characteristics should satisfy the
specifications in the following table.
Appearance
No defects or abnormalities
Capacitance
Change
Within ±5% or ±0.5pF (Whichever is larger)
Q
30pF <
= C: Q >
= 350
10pF <
= C < 30pF: Q >
= 275+5C/2
10pF > C: Q >
= 200+10C
C: Nominal Capacitance (pF)
I.R. 1000MΩ or 50MΩ F μF min. (Whichever is smaller)
Step 1
-55+0/-3
15±3
2
Room Temp.
1
3
125+3/-0
15±3
4
Room Temp.
1
Temp. (°C)
Time (min)
Sit the capacitor for 1000±12h at 150±3°C. Let sit for 24±2h at
room condition*, then measure.
2
High Temperature
Exposure (Storage)
The measured and observed characteristics should satisfy the
specifications in the following table.
Appearance
No defects or abnormalities
Capacitance
Change
Within ±3% or ±0.3pF (Whichever is larger)
Q
30pF <
= C: Q >
= 350
10pF <
= C < 30pF: Q >
= 275+5C/2
10pF > C: Q >
= 200+10C
C: Nominal Capacitance (pF)
I.R. More than 1000MΩ or 50MΩ F μF (Whichever is smaller)
1
Pre-and Post-Stress
Electrical Test
No. AEC-Q200 Test MethodSpecificationsAEC-Q200 Test Item
(°C)
70
65
60
55
50
45
40
35
30
25
20
15
10
5
0
-5
-10
Humidity
90-98%
Humidity
80-98%
Humidity
90-98%
Humidity
80-98%
Humidity
90-98%
+10
-2°C
Initial measurement
Temperature
One cycle = 24 hours
0123456789
1011 1213 1415 1617 1819 2021 2223 24
Hours
Rated Voltage Test Voltage
200% of the rated voltage
150% of the rated voltage
120% of the rated voltage
DC50V, DC100V
DC250V
DC630V, DC1kV
Continued on the following page.
!Note • Please read rating and !CAUTION (for storage, operating, rating, soldering, mounting and handling) in this catalog to prevent smoking and/or burning, etc.
• This catalog has only typical specifications. Therefore, please approve our product specifications or transact the approval sheet for product specifications before ordering.
17
C49E.pdf
May 10,2018
1
Temperature Compensating Type Specifications and Test Methods
Perform the 300 cycles according to the two heat treatments
listed in the following table (Maximum transfer time is 20s).
Let sit for 24±2h at room condition*, then measure.
14
Thermal Shock The measured and observed characteristics should satisfy the
specifications in the following table.
Appearance
No defects or abnormalities
Capacitance
Change
Within ±5% or ±0.5pF (Whichever is larger)
Q
30pF <
= C: Q >
= 350
10pF <
= C < 30p: Q >
= 275+5C/2
10pF > C: Q >
= 200+10C
C: Nominal Capacitance (pF)
I.R. 1000MΩ or 50MΩ F μF min. (Whichever is smaller)
Step 1
-55+0/-3
15±3
2
125+3/-0
15±3
Temp. (°C)
Time (min)
The lead wires should be immersed in the melted solder 1.5 to
2.0mm from the root of terminal at 260±5°C for 10±1s.
Post-treatment
Capacitor should be stored for 24±2h at room condition*.
13
-
1
Resistance to
Soldering Heat
(Non-Preheat)
The measured and observed characteristics should satisfy the
specifications in the following table.
Appearance
No defects or abnormalities
Capacitance
Change
Within ±2.5% or ±0.25pF (Whichever is larger)
Within ±2.5% or ±0.25pF (Whichever is larger)
Within ±2.5% or ±0.25pF (Whichever is larger)
Dielectric
Strength
(Between
Terminals)
No defects
First the capacitor should be stored at 120+0/-5°C for 60+0/-5s.
Then, the lead wires should be immersed in the melted solder 1.5
to 2.0mm from the root of terminal at 260±5°C for 7.5+0/-1s.
Post-treatment
Capacitor should be stored for 24±2h at room condition*.
13
-
2
Resistance to
Soldering Heat
(On-Preheat)
The measured and observed characteristics should satisfy the
specifications in the following table.
Appearance
No defects or abnormalities
Capacitance
Change
Dielectric
Strength
(Between
Terminals)
No defects
Test condition
Temperature of iron-tip: 350±10°C
Soldering time: 3.5±0.5s
Soldering position
Straight Lead: 1.5 to 2.0mm from the root of terminal.
Crimp Lead: 1.5 to 2.0mm from the end of lead bend.
Post-treatment
Capacitor should be stored for 24±2h at room condition*.
13
-
3
Resistance to
Soldering Heat
(soldering
iron method)
The measured and observed characteristics should satisfy the
specifications in the following table.
Appearance
No defects or abnormalities
Capacitance
Change
Dielectric
Strength
(Between
Terminals)
No defects
The capacitor should be subjected to a simple harmonic motion
having a total amplitude of 1.5mm, the frequency being varied
uniformly between the approximate limits of 10 and 2000Hz.
The frequency range, from 10 to 2000Hz and return to 10Hz,
should be traversed in approximately 20min. This motion
should be applied for 12 items in each 3 mutually perpendicular
directions (total of 36 times).
12 Vibration
Appearance
No defects or abnormalities
Capacitance
Within the specified tolerance
Q
30pF <
= C: Q >
= 1000
30pF > C: Q >
= 400+20C
C: Nominal Capacitance (pF)
Three shocks in each direction should be applied along
3 mutually perpendicular axes of the test specimen (18 shocks).
The specified test pulse should be Half-sine and should
have a duration: 0.5ms, peak value: 1500G and velocity change:
4.7m/s.
11
Mechanical
Shock
Appearance
No defects or abnormalities
Capacitance
Within the specified tolerance
Q
30pF <
= C : Q >
= 1000
30pF > C : Q >
= 400+20C
C : Nominal Capacitance (pF)
Per MIL-STD-202 Method 215
Solvent 1: 1 part (by volume) of isopropyl alcohol
3 parts (by volume) of mineral spirits
Solvent 2: Terpene defluxer
Solvent 3: 42 parts (by volume) of water
1 part (by volume) of propylene glycol
monomethyl ether
1 part (by volume) of monoethanolamine
10
Resistance
to Solvents
Appearance
No defects or abnormalities
Capacitance
Within the specified tolerance
Q30pF <
= C: Q >
= 1000
30pF > C: Q >
= 400+20C
C: Nominal Capacitance (pF)
I.R. More than 10000MΩ or 500MΩ F μF (Whichever is smaller)
* “room condition” Temperature: 15 to 35°C, Relative humidity: 45 to 75%, Atmosphere pressure: 86 to 106kPa
Visual inspection9 Marking To be easily legible
Using calipers and micrometers8 Physical Dimension Within the specified dimensions
Visual inspection7 External Visual No defects or abnormalities
No. AEC-Q200 Test MethodSpecificationsAEC-Q200 Test Item
Continued from the preceding page.
Continued on the following page.
!Note • Please read rating and !CAUTION (for storage, operating, rating, soldering, mounting and handling) in this catalog to prevent smoking and/or burning, etc.
• This catalog has only typical specifications. Therefore, please approve our product specifications or transact the approval sheet for product specifications before ordering.
18
C49E.pdf
May 10,2018
1
Temperature Compensating Type Specifications and Test Methods
Rated Voltage Test Voltage
250% of the rated voltage
200% of the rated voltage
DC1300V
DC25V, DC50V, DC100V
DC250V
DC630V, DC1kV
As in the figure, fix the capacitor body, apply the force
gradually to each lead in the radial direction of the capacitor
until reaching 10N and then keep the force applied for
10±1s.
18 Terminal
Strength
Tensile
Strength Termination not to be broken or loosened
Each lead wire should be subjected to a force of 2.5N and then
be bent 90° at the point of egress in one direction. Each wire is
then returned to the original position and bent 90° in the
opposite direction at the rate of one bend per 2 to 3s.
Bending
Strength Termination not to be broken or loosened
F
Visual inspection
17
Electrical
Charac-
terization
Appearance
No defects or abnormalities
The capacitance, Q should be measured at 25°C at the
frequency and voltage shown in the table.
Capacitance
Within the specified tolerance
Q
30pF <
= C: Q >
= 1000
30pF > C: Q >
= 400+20C
C: Nominal Capacitance (pF)
The insulation resistance should be measured with a DC
voltage shown in the table at 25°C within 2min
of charging.
I.R. Between Terminals 10000MΩ or 500MΩ F μF min.
(Whichever is smaller)
The capacitor should not be damaged when DC voltage
shown in the table is applied between the terminations
for 1 to 5s.
(Charge/Discharge current <
= 50mA.)
Between Terminals No defects or abnormalities
The capacitor is placed in a container with metal balls of 1mm
diameter so that each terminal, short-circuit is kept
approximately 2mm from the balls, and DC voltage shown in
the table is impressed for 1 to 5s between capacitor terminals
and metal balls.
(Charge/Discharge current <
= 50mA.)
Dielectric
Strength
Body Insulation No defects or abnormalities
Nominal Cap.
C <
= 1000pF
C > 1000pF
Frequency
1±0.1MHz
1±0.1kHz
Voltage
AC0.5 to 5V (r.m.s.)
AC1±0.2V (r.m.s.)
No. AEC-Q200 Test MethodSpecificationsAEC-Q200 Test Item
Rated Voltage Test Voltage
300% of the rated voltage
200% of the rated voltage
150% of the rated voltage
130% of the rated voltage
DC50V, DC100V
DC250V
DC630V
DC1kV
Should be placed into steam aging for 8h±15min.
The terminal of capacitor is dipped into a solution of ethanol
(JIS K 8101) and rosin (JIS K 5902) (25% rosin in weight
propotion). Immerse in solder solution for 2±0.5s.
In both cases the depth of dipping is up to about 1.5 to 2mm
from the terminal body.
16 Solderability Lead wire should be soldered with uniform coating on the axial
direction over 95% of the circumferential direction.
Per AEC-Q200-002
15 ESD
Appearance
No defects or abnormalities
Capacitance
Within the specified tolerance
Q
30pF <
= C: Q >
= 1000
30pF > C: Q >
= 400+20C
C: Nominal Capacitance (pF)
I.R. More than 10000MΩ or 500MΩ F μF (Whichever is smaller)
Rated Voltage
DC25V, DC50V, DC100V, DC250V
DC630V, DC1kV
Measuring Voltage
Rated Voltage
DC500V
Continued from the preceding page.
Continued on the following page.
!Note • Please read rating and !CAUTION (for storage, operating, rating, soldering, mounting and handling) in this catalog to prevent smoking and/or burning, etc.
• This catalog has only typical specifications. Therefore, please approve our product specifications or transact the approval sheet for product specifications before ordering.
19
C49E.pdf
May 10,2018
1
The capacitance change should be measured after 5min at
each specified temperature step.
The temperature coefficient is determind using the
capacitance measured in step 3 as a reference. When cycling
the temperature sequentially from step 1 through 5 (-55 to
+125°C) the capacitance should be within the specified
tolerance for the temperature coefficient.
The capacitance drift is caluculated by dividing the differences
betweeen the maximum and minimum measured values in the
step 1, 3 and 5 by the capacitance value in step 3.
19
Capacitance
Temperature
Characteristics
Step
1
2
3
4
5
Temperature (°C)
25±2
-55±3
25±2
125±3
25±2
No. AEC-Q200 Test MethodSpecificationsAEC-Q200 Test Item
Char. Temperature Coefficient
25 to 125°C: 0±30ppm/°C
−55 to 25°C: 0+30/−72ppm/°C
25 to 125°C: −750±120ppm/°C
−55 to 25°C: −750+120/−347ppm/°C
C0G
U2J
Continued from the preceding page.
Temperature Compensating Type Specifications and Test Methods
!Note • Please read rating and !CAUTION (for storage, operating, rating, soldering, mounting and handling) in this catalog to prevent smoking and/or burning, etc.
• This catalog has only typical specifications. Therefore, please approve our product specifications or transact the approval sheet for product specifications before ordering.
20
C49E.pdf
May 10,2018
1
High Dielectric Constant Type Specifications and Test Methods
* “room condition” Temperature: 15 to 35°C, Relative humidity: 45 to 75%, Atmosphere pressure: 86 to 106kPa
Apply the rated voltage and DC1.3+0.2/-0V (add 100kΩ resistor)
at 85±3°C and 80 to 85% humidity for 1000±12h.
Remove and let sit for 24±2h at room condition*, then measure.
The charge/discharge current is less than 50mA.
F0#20#2+#,2
Perform the heat treatment at 150+0/-10°C for 60±5min and
then let sit for 24±2h at room condition*.
5
Biased Humidity The measured and observed characteristics should satisfy the
specifications in the following table.
Appearance
No defects or abnormalities
Capacitance
Change
Within ±12.5%
D.F. 0.05 max.
I.R. 500MΩ or 25MΩ F μF min. (Whichever is smaller)
Apply the 24h heat (25 to 65°C) and humidity (80 to 98%)
treatment shown below, 10 consecutive times.
Let sit for 24±2h at room condition*, then measure.
F0#20#2+#,2
Perform the heat treatment at 150+0/-10°C for 60±5min and
then let sit for 24±2h at room condition*.
4
Moisture
Resistance
The measured and observed characteristics should satisfy the
specifications in the following table.
Appearance
No defects or abnormalities
Capacitance
Change
Within ±12.5%
D.F. 0.05 max.
I.R. 500MΩ or 25MΩ F μF min. (Whichever is smaller)
Perform the 1000 cycles according to the four heat treatments
listed in the following table. Let sit for 24±2h at room condition*,
then measure.
F0#20#2+#,2
Perform the heat treatment at 150+0/-10°C for 60±5min and
then let sit for 24±2h at room condition*.
3
Temperature
Cycling
The measured and observed characteristics should satisfy the
specifications in the following table.
Appearance
No defects or abnormalities
Capacitance
Change
Within ±12.5%
D.F. 0.05 max.
I.R. 1000MΩ or 50MΩ F μF min. (Whichever is smaller)
Sit the capacitor for 1000±12h at 150±3°C. Let sit for 24±2h
at room condition*, then measure.
F0#20#2+#,2
Perform the heat treatment at 150+0/-10°C for 60±5min
and then let sit for 24±2h at room condition*.
2
High Temperature
Exposure (Storage)
The measured and observed characteristics should satisfy the
specifications in the following table.
Appearance
No defects or abnormalities
Capacitance
Change
Within ±12.5%
D.F. 0.04 max.
I.R. More than 1000MΩ or 50MΩ F μF (Whichever is smaller)
1
Pre-and Post-Stress
Electrical Test
No. AEC-Q200 Test MethodSpecificationsAEC-Q200 Test Item
(°C)
70
65
60
55
50
45
40
35
30
25
20
15
10
5
0
-5
-10
Humidity
90-98%
Humidity
80-98%
Humidity
90-98%
Humidity
80-98%
Humidity
90-98%
+10
-2°C
Initial measurement
Temperature
One cycle = 24 hours
0123456789
1011 1213 1415 1617 1819 2021 2223 24
Hours
Step 1
-55+0/-3
15±3
2
Room Temp.
1
3
125+3/-0
15±3
4
Room Temp.
1
Temp. (°C)
Time (min)
Continued on the following page.
!Note • Please read rating and !CAUTION (for storage, operating, rating, soldering, mounting and handling) in this catalog to prevent smoking and/or burning, etc.
• This catalog has only typical specifications. Therefore, please approve our product specifications or transact the approval sheet for product specifications before ordering.
21
C49E.pdf
May 10,2018
1
High Dielectric Constant Type Specifications and Test Methods
* “room condition” Temperature: 15 to 35°C, Relative humidity: 45 to 75%, Atmosphere pressure: 86 to 106kPa
*1: below parts are applicable in rated voltage×150%.
The lead wires should be immersed in the melted solder 1.5 to
2.0mm from the root of terminal at 260±5°C for 10±1s.
Pre-treatment
Capacitor should be stored at 150+0/-10°C for 1h, then place
at room temperature for 24±2h before initial measurement.
Post-treatment
Capacitor should be stored for 24±2h at room condition*.
13
-
1
Resistance to
Soldering Heat
(Non-Preheat)
The measured and observed characteristics should satisfy the
specifications in the following table.
Appearance
Appearance
No defects or abnormalities
Capacitance
Change
Within ±7.5%
Dielectric
Strength
(Between
Terminals)
No defects
13
-
2
Resistance to
Soldering Heat
(On-Preheat)
The measured and observed characteristics should satisfy the
specifications in the following table.
No defects or abnormalities
Capacitance
Change
Within ±7.5%
Dielectric
Strength
(Between
Terminals)
No defects
The capacitor should be subjected to a simple harmonic motion
having a total amplitude of 1.5mm, the frequency being varied
uniformly between the approximate limits of 10 and 2000Hz.
The frequency range, from 10 to 2000Hz and return to 10Hz,
should be traversed in approximately 20min. This motion should
be applied for 12 items in each 3 mutually perpendicular
directions (total of 36 times).
12 Vibration
Appearance
No defects or abnormalities
Capacitance
Within the specified tolerance
D.F. 0.025 max.
Three shocks in each direction should be applied along
3 mutually perpendicular axes of the test specimen (18 shocks).
The specified test pulse should be Half-sine and should
have a duration: 0.5ms, peak value: 1500G and velocity change:
4.7m/s.
11
Mechanical
Shock
Appearance
No defects or abnormalities
Capacitance
Within the specified tolerance
D.F. 0.025 max.
Per MIL-STD-202 Method 215
Solvent 1: 1 part (by volume) of isopropyl alcohol
3 parts (by volume) of mineral spirits
Solvent 2: Terpene defluxer
Solvent 3: 42 parts (by volume) of water
1 part (by volume) of propylene glycol
monomethyl ether
1 part (by volume) of monoethanolamine
10
Resistance
to Solvents
Appearance
No defects or abnormalities
Capacitance
Within the specified tolerance
D.F. 0.025 max.
I.R.
Rated Voltage: DC25V, DC50V, DC100V
More than 10000MΩ or 500MΩ F μF (Whichever is smaller)
Rated Voltage: DC250V, DC500V, DC630V, DC1kV
More than 10000MΩ or 100MΩ F μF (Whichever is smaller)
No. AEC-Q200 Test MethodSpecificationsAEC-Q200 Test Item
Visual inspection9 Marking To be easily legible
Using calipers and micrometers8 Physical Dimension Within the specified dimensions
Visual inspection7 External Visual No defects or abnormalities
Apply the voltage shown in the table for 1000±12h at 125±3°C.
Let sit for 24±2h at room condition*, then measure.
The charge/discharge current is less than 50mA.
F0#20#2+#,2
Apply test voltage for 60±5min at test temperature.
Remove and let sit for 24±2h at room condition*.
6
Operational Life The measured and observed characteristics should satisfy the
specifications in the following table.
Appearance
No defects or abnormalities
Capacitance
Change
Within ±12.5%
D.F. 0.04 max.
I.R. 1000MΩ or 50MΩ F μF min. (Whichever is smaller)
Rated Voltage Test Voltage
200% of the rated voltage *1
150% of the rated voltage
120% of the rated voltage
110% of the rated voltage
DC25V, DC50V, DC100V
DC250V
DC630V
DC1kV
First the capacitor should be stored at 120+0/-5°C for 60+0/-5s.
Then, the lead wires should be immersed in the melted solder 1.5
to 2.0mm from the root of terminal at 260±5°C for 7.5+0/-1s.
Pre-treatment
Capacitor should be stored at 150+0/-10°C for 1h, then place at
room temperature for 24±2h before initial measurement.
Post-treatment
Capacitor should be stored for 24±2h at room condition*.
Char. Rated Voltage
C7
C7
C7
C7
R7
R7
C7
C7
1H
1H
1H
1H
2A
2A
2A
2A
Capacitance
105
475
106
226
334
474-105
155-225
475
Dimensions
1
2
3
W
1
2
3
W
Continued from the preceding page.
Continued on the following page.
!Note • Please read rating and !CAUTION (for storage, operating, rating, soldering, mounting and handling) in this catalog to prevent smoking and/or burning, etc.
• This catalog has only typical specifications. Therefore, please approve our product specifications or transact the approval sheet for product specifications before ordering.
22
C49E.pdf
May 10,2018
1
High Dielectric Constant Type Specifications and Test Methods
Visual inspection
17
Electrical
Charac-
terization
Appearance
No defects or abnormalities
The capacitance/D.F. should be measured at 25°C at the
frequency and voltage shown in the table.
Capacitance
Within the specified tolerance
D.F. 0.025 max.
I.R. Between Terminals
Rated Voltage: DC25V, DC50V, DC100V
More than 10000MΩ or 500MΩ F μF
(Whichever is smaller)
Rated Voltage: DC250V, DC500V,
DC630V, DC1kV
More than 10000MΩ or 100MΩ F μF
(Whichever is smaller)
The capacitor should not be damaged when DC voltage
shown in the table is applied between the terminations
for 1 to 5s.
(Charge/Discharge current <
= 50mA.)
Between Terminals No defects or abnormalities
The capacitor is placed in a container with metal balls of 1mm
diameter so that each terminal, short-circuit is kept
approximately 2mm from the balls, and 250% of the rated DC
voltage shown in the table is impressed for 1 to 5s between
capacitor terminals and metal balls.
(Charge/Discharge current <
= 50mA.)
Dielectric
Strength
Body Insulation No defects or abnormalities
No. AEC-Q200 Test MethodSpecificationsAEC-Q200 Test Item
* “room condition” Temperature: 15 to 35°C, Relative humidity: 45 to 75%, Atmosphere pressure: 86 to 106kPa
Rated Voltage Test Voltage
250% of the rated voltage
200% of the rated voltage
150% of the rated voltage
120% of the rated voltage
DC25V, DC50V, DC100V
DC250V
DC630V
DC1kV
Should be placed into steam aging for 8h±15min.
The terminal of capacitor is dipped into a solution of ethanol
(JIS K 8101) and rosin (JIS K 5902) (25% rosin in weight
propotion). Immerse in solder solution for 2±0.5s.
In both cases the depth of dipping is up to about 1.5 to 2mm
from the terminal body.
16 Solderability Lead wire should be soldered with uniform coating on the axial
direction over 95% of the circumferential direction.
Per AEC-Q200-002
15 ESD
Appearance
No defects or abnormalities
Capacitance
Within the specified tolerance
D.F. 0.025 max.
I.R.
Rated Voltage: DC25V, DC50V, DC100V
More than 10000MΩ or 500MΩ F μF (Whichever is smaller)
Rated Voltage: DC250V, DC500V, DC630V, DC1kV
More than 10000MΩ or 100MΩ F μF (Whichever is smaller)
Perform the 300 cycles according to the two heat treatments
listed in the following table (Maximum transfer time is 20s).
Let sit for 24±2h at room condition*, then measure.
F0#20#2+#,2
Perform the heat treatment at 150+0/-10°C for 60±5min
and then let sit for 24±2h at room condition*.
14
Thermal Shock The measured and observed characteristics should satisfy the
specifications in the following table.
Appearance
No defects or abnormalities
Capacitance
Change
Within ±12.5%
D.F. 0.05 max.
I.R. 1000MΩ or 50MΩ F μF min. (Whichever is smaller)
Step 1
-55+0/-3
15±3
2
125+3/-0
15±3
Temp. (°C)
Time (min)
Rated Voltage Test Voltage
250% of the rated voltage
200% of the rated voltage
DC1300V
DC25V, DC50V, DC100V
DC250V
DC630V, DC1kV
Continued on the following page.
Appearance
13
-
3
Resistance to
Soldering Heat
(Soldering
Iron Method)
The measured and observed characteristics should satisfy the
specifications in the following table.
No defects or abnormalities
Capacitance
Change
Within ±7.5%
Dielectric
Strength
(Between
Terminals)
No defects
Test condition
Temperature of iron-tip: 350±10°C
Soldering time: 3.5±0.5s.
Soldering position
Straight Lead: 1.5 to 2.0mm from the root of terminal.
Crimp Lead: 1.5 to 2.0mm from the end of lead bend.
Pre-treatment
Capacitor should be stored at 150+0/-10°C for 1h, then place
at room temperature for 24±2h before initial measurement.
Post-treatment
Capacitor should be stored for 24±2h at room condition*.
Continued from the preceding page.
The insulation resistance should be measured with a DC
voltage shown in the table at 25°C within 2min
of charging.
Rated Voltage
DC25V, DC50V, DC100V, DC250V
DC630V, DC1kV
Measuring Voltage
Rated Voltage
DC500V
Nominal Cap.
C <
= 10μF
C > 10μF
Frequency
1±0.1kHz
120±24kHz
Voltage
AC1.0±0.2V (r.m.s.)
AC0.5±0.1V (r.m.s.)
!Note • Please read rating and !CAUTION (for storage, operating, rating, soldering, mounting and handling) in this catalog to prevent smoking and/or burning, etc.
• This catalog has only typical specifications. Therefore, please approve our product specifications or transact the approval sheet for product specifications before ordering.
23
C49E.pdf
May 10,2018
1
High Dielectric Constant Type Specifications and Test Methods
* “room condition” Temperature: 15 to 35°C, Relative humidity: 45 to 75%, Atmosphere pressure: 86 to 106kPa
The capacitance change should be measured after 5min at
each specified temperature step.
The ranges of capacitance change compared with the above
25°C value over the temperature ranges shown in the table
should be within the specified ranges.
F0#20#2+#,2
Perform the heat treatment at 150+0/-10°C for 60±5min
and then let sit for 24±2h at room condition*.
Perform the initial measurement.
19
Capacitance
Temperature
Characteristics
Char. X7R: Within ±15%
Char. X7S: Within ±22%
Step
1
2
3
4
5
Temperature (°C)
25±2
-55±3
25±2
125±3
25±2
No. AEC-Q200 Test MethodSpecificationsAEC-Q200 Test Item
Continued from the preceding page.
As in the figure, fix the capacitor body, apply the force
gradually to each lead in the radial direction of the capacitor
until reaching 10N and then keep the force applied for
10±1s.
18 Terminal
Strength
Tensile
Strength Termination not to be broken or loosened
Each lead wire should be subjected to a force of 2.5N and then
be bent 90° at the point of egress in one direction. Each wire is
then returned to the original position and bent 90° in the
opposite direction at the rate of one bend per 2 to 3s.
Bending
Strength Termination not to be broken or loosened
F
!Note • Please read rating and !CAUTION (for storage, operating, rating, soldering, mounting and handling) in this catalog to prevent smoking and/or burning, etc.
• This catalog has only typical specifications. Therefore, please approve our product specifications or transact the approval sheet for product specifications before ordering.
24
C49E.pdf
May 10,2018
1
Features
1. Small size and large capacitance
2. Low ESR and ESL suitable for high frequency
3. Applied maximum temperature up to 150°C
Note: Maximum accumulative time to 150°C
is within 2000 hours.
4. Meet AEC-Q200, ISO7637-2 (surge test) requirement
5. Meet LF (Lead Free) and HF (Halogen Free)
6. Flow soldering and welding are available.
(Re-flow soldering is not available.)
7. If copper wire is necessary at welding process,
copper wire is available based on request.
(in mm)
T max.
L max.
ød: 0.5±0.05
W max.25.0 min.
1.5 max.
F±0.8
· Lead Wire: Solder Coated CP Wire
Dimensions code: 0
Lead style code: A2
150°C Operation Leaded MLCC for Automotive
RHE Series (DC25V-DC100V)
!Note • Please read rating and !CAUTION (for storage, operating, rating, soldering, mounting and handling) in this catalog to prevent smoking and/or burning, etc.
• This catalog has only typical specifications. Therefore, please approve our product specifications or transact the approval sheet for product specifications before ordering.
25
C49E.pdf
May 10,2018
2
(in mm)
* Coating extension does not exceed the end of the lead bend.
· Lead Wire: Solder Coated CP Wire
ød: 0.5±0.05
T max.L max.
W max.25.0 min.
W1 max.
F±0.8
*
Dimensions code: 0
Lead style code: K1
(in mm)
T max.
L max.
ød: 0.5±0.05
W max.25.0 min.
1.5 max.
F±0.8
· Lead Wire: Solder Coated CP Wire
Dimensions code: 1
Lead style code: A2
(in mm)
* Coating extension does not exceed the end of the lead bend.
· Lead Wire: Solder Coated CP Wire
ød: 0.5±0.05
T max.L max.
W max.25.0 min.
W1 max.
F±0.8
*
Dimensions code: 1
Lead style code: K1
(in mm)
T max.
L max.
ød: 0.5±0.05
W max.25.0 min.
1.5 max.
F±0.8
· Lead Wire: Solder Coated CP Wire
Dimensions code: 2
Lead style code: A2
(in mm)
* Coating extension does not exceed the end of the lead bend.
· Lead Wire: Solder Coated CP Wire
ød: 0.5±0.05
T max.L max.
W max.25.0 min.
W1 max.
F±0.8
*
Dimensions code: 2
Lead style code: K1
(in mm)
T max.
L max.
ød: 0.5±0.05
W max.25.0 min.
1.5 max.
F±0.8
· Lead Wire: Solder Coated CP Wire
Dimensions code: 3
Lead style code: A2
Continued on the following page.
Continued from the preceding page.
Dimensions
Dimensions and
Lead Style Code
Dimensions (mm)
L W W1 T F d
0A2/0DB
0K1/0M1
1A2/1DB
1K1/1M1
2A2/2DB
2K1/2M1
3A2/3DB
3K1/3M1
WK1/WM1
0.5
0.5
0.5
0.5
0.5
0.5
0.5
0.5
0.5
2.5
5.0
2.5
5.0
2.5
5.0
2.5
5.0
5.0
-
6.0
-
5.0
-
6.0
-
7.5
10.0
3.5
3.5
3.5
3.5
4.0
4.0
5.0
5.0
7.5
3.6
3.6
4.0
4.0
5.5
5.5
5.5
5.5
5.5
See the individual
product specification
!Note • Please read rating and !CAUTION (for storage, operating, rating, soldering, mounting and handling) in this catalog to prevent smoking and/or burning, etc.
• This catalog has only typical specifications. Therefore, please approve our product specifications or transact the approval sheet for product specifications before ordering.
26
C49E.pdf
May 10,2018
2
(in mm)
* Coating extension does not exceed the end of the lead bend.
· Lead Wire: Solder Coated CP Wire
ød: 0.5±0.05
T max.L max.
W max.25.0 min.
W1 max.
F±0.8
*
Dimensions code: 3
Lead style code: K1
(in mm)
* Coating extension does not exceed the end of the lead bend.
· Lead Wire: Solder Coated CP Wire
ød: 0.5±0.05
T max.L max.
W max.25.0 min.
W1 max.
F±0.8
*
Dimensions code: W
Lead style code: K1
Type
Rated Voltage
Temp. Char.
Dimensions
Code
1
0
2
DC25V, DC50V
X8LX8G
DC100V
Temperature Characteristics
Nominal Capacitance
Capacitance Tolerance
Rated Voltage
Manufacturer's Identification
Marked with 3 figures
Marked with code
Marked with code (X8G, X8L char.: 8)
Marked with code (DC25V: 2, DC50V: 5, DC100V: 1)
A part is omitted (Please refer to the marking example.)
M
Marked with
A part is omitted (Please refer to the marking example.)
8
104K
8
103K
105
K58
M
3, W ——
DC50V, DC100V
High Dielectric Constant Type
Temperature Compensating Type
8
102J
224
K18
M
335
K58
M
Marking
Part Number Temp.
Char.
Rated
Voltage Capacitance
Dimensions
LxW
(mm)
Dimension
T
(mm)
Lead Space
F
(mm)
Lead Style
Code
Bulk
Lead Style
Code
Taping
RHE5G1H101J0ppH03pX8G (Murata) 50Vdc 100pF±5% 3.6×3.5 2.5 2.5 A2 DB
RHE5G1H101J0ppH03pX8G (Murata) 50Vdc 100pF±5% 3.6×3.5 2.5 5.0 K1 M1
RHE5G1H121J0ppH03pX8G (Murata) 50Vdc 120pF±5% 3.6×3.5 2.5 2.5 A2 DB
RHE5G1H121J0ppH03pX8G (Murata) 50Vdc 120pF±5% 3.6×3.5 2.5 5.0 K1 M1
RHE5G1H151J0ppH03pX8G (Murata) 50Vdc 150pF±5% 3.6×3.5 2.5 2.5 A2 DB
RHE5G1H151J0ppH03pX8G (Murata) 50Vdc 150pF±5% 3.6×3.5 2.5 5.0 K1 M1
RHE5G1H181J0ppH03pX8G (Murata) 50Vdc 180pF±5% 3.6×3.5 2.5 2.5 A2 DB
RHE5G1H181J0ppH03pX8G (Murata) 50Vdc 180pF±5% 3.6×3.5 2.5 5.0 K1 M1
RHE5G1H221J0ppH03pX8G (Murata) 50Vdc 220pF±5% 3.6×3.5 2.5 2.5 A2 DB
RHE5G1H221J0ppH03pX8G (Murata) 50Vdc 220pF±5% 3.6×3.5 2.5 5.0 K1 M1
RHE5G1H271J0ppH03pX8G (Murata) 50Vdc 270pF±5% 3.6×3.5 2.5 2.5 A2 DB
RHE5G1H271J0ppH03pX8G (Murata) 50Vdc 270pF±5% 3.6×3.5 2.5 5.0 K1 M1
RHE5G1H331J0ppH03pX8G (Murata) 50Vdc 330pF±5% 3.6×3.5 2.5 2.5 A2 DB
RHE5G1H331J0ppH03pX8G (Murata) 50Vdc 330pF±5% 3.6×3.5 2.5 5.0 K1 M1
RHE5G1H391J0ppH03pX8G (Murata) 50Vdc 390pF±5% 3.6×3.5 2.5 2.5 A2 DB
RHE5G1H391J0ppH03pX8G (Murata) 50Vdc 390pF±5% 3.6×3.5 2.5 5.0 K1 M1
RHE5G1H471J0ppH03pX8G (Murata) 50Vdc 470pF±5% 3.6×3.5 2.5 2.5 A2 DB
RHE5G1H471J0ppH03pX8G (Murata) 50Vdc 470pF±5% 3.6×3.5 2.5 5.0 K1 M1
RHE5G1H561J0ppH03pX8G (Murata) 50Vdc 560pF±5% 3.6×3.5 2.5 2.5 A2 DB
RHE5G1H561J0ppH03pX8G (Murata) 50Vdc 560pF±5% 3.6×3.5 2.5 5.0 K1 M1
RHE5G1H681J0ppH03pX8G (Murata) 50Vdc 680pF±5% 3.6×3.5 2.5 2.5 A2 DB
RHE5G1H681J0ppH03pX8G (Murata) 50Vdc 680pF±5% 3.6×3.5 2.5 5.0 K1 M1
RHE5G1H821J0ppH03pX8G (Murata) 50Vdc 820pF±5% 3.6×3.5 2.5 2.5 A2 DB
RHE5G1H821J0ppH03pX8G (Murata) 50Vdc 820pF±5% 3.6×3.5 2.5 5.0 K1 M1
RHE5G1H102J0ppH03pX8G (Murata) 50Vdc 1000pF±5% 3.6×3.5 2.5 2.5 A2 DB
RHE5G1H102J0ppH03pX8G (Murata) 50Vdc 1000pF±5% 3.6×3.5 2.5 5.0 K1 M1
RHE5G1H122J0ppH03pX8G (Murata) 50Vdc 1200pF±5% 3.6×3.5 2.5 2.5 A2 DB
RHE5G1H122J0ppH03pX8G (Murata) 50Vdc 1200pF±5% 3.6×3.5 2.5 5.0 K1 M1
RHE5G1H152J0ppH03pX8G (Murata) 50Vdc 1500pF±5% 3.6×3.5 2.5 2.5 A2 DB
RHE5G1H152J0ppH03pX8G (Murata) 50Vdc 1500pF±5% 3.6×3.5 2.5 5.0 K1 M1
RHE5G1H182J0ppH03pX8G (Murata) 50Vdc 1800pF±5% 3.6×3.5 2.5 2.5 A2 DB
RHE5G1H182J0ppH03pX8G (Murata) 50Vdc 1800pF±5% 3.6×3.5 2.5 5.0 K1 M1
RHE5G1H222J0ppH03pX8G (Murata) 50Vdc 2200pF±5% 3.6×3.5 2.5 2.5 A2 DB
RHE5G1H222J0ppH03pX8G (Murata) 50Vdc 2200pF±5% 3.6×3.5 2.5 5.0 K1 M1
RHE5G1H272J0ppH03pX8G (Murata) 50Vdc 2700pF±5% 3.6×3.5 2.5 2.5 A2 DB
RHE5G1H272J0ppH03pX8G (Murata) 50Vdc 2700pF±5% 3.6×3.5 2.5 5.0 K1 M1
RHE5G1H332J0ppH03pX8G (Murata) 50Vdc 3300pF±5% 3.6×3.5 2.5 2.5 A2 DB
RHE5G1H332J0ppH03pX8G (Murata) 50Vdc 3300pF±5% 3.6×3.5 2.5 5.0 K1 M1
RHE5G1H392J0ppH03pX8G (Murata) 50Vdc 3900pF±5% 3.6×3.5 2.5 2.5 A2 DB
RHE5G1H392J0ppH03pX8G (Murata) 50Vdc 3900pF±5% 3.6×3.5 2.5 5.0 K1 M1
RHE5G1H472J1ppH03pX8G (Murata) 50Vdc 4700pF±5% 4.0×3.5 2.5 2.5 A2 DB
RHE5G1H472J1ppH03pX8G (Murata) 50Vdc 4700pF±5% 4.0×3.5 2.5 5.0 K1 M1
RHE5G1H562J1ppH03pX8G (Murata) 50Vdc 5600pF±5% 4.0×3.5 2.5 2.5 A2 DB
RHE5G1H562J1ppH03pX8G (Murata) 50Vdc 5600pF±5% 4.0×3.5 2.5 5.0 K1 M1
RHE5G1H682J1ppH03pX8G (Murata) 50Vdc 6800pF±5% 4.0×3.5 2.5 2.5 A2 DB
RHE5G1H682J1ppH03pX8G (Murata) 50Vdc 6800pF±5% 4.0×3.5 2.5 5.0 K1 M1
RHE5G1H822J1ppH03pX8G (Murata) 50Vdc 8200pF±5% 4.0×3.5 2.5 2.5 A2 DB
RHE5G1H822J1ppH03pX8G (Murata) 50Vdc 8200pF±5% 4.0×3.5 2.5 5.0 K1 M1
RHE5G1H103J1ppH03pX8G (Murata) 50Vdc 10000pF±5% 4.0×3.5 2.5 2.5 A2 DB
RHE5G1H103J1ppH03pX8G (Murata) 50Vdc 10000pF±5% 4.0×3.5 2.5 5.0 K1 M1
RHE5G2A101J0ppH03pX8G (Murata) 100Vdc 100pF±5% 3.6×3.5 2.5 2.5 A2 DB
RHE5G2A101J0ppH03pX8G (Murata) 100Vdc 100pF±5% 3.6×3.5 2.5 5.0 K1 M1
RHE5G2A121J0ppH03pX8G (Murata) 100Vdc 120pF±5% 3.6×3.5 2.5 2.5 A2 DB
RHE5G2A121J0ppH03pX8G (Murata) 100Vdc 120pF±5% 3.6×3.5 2.5 5.0 K1 M1
RHE5G2A151J0ppH03pX8G (Murata) 100Vdc 150pF±5% 3.6×3.5 2.5 2.5 A2 DB
Continued on the following page.
Temperature Compensating Type, X8G Characteristics
!Note • Please read rating and !CAUTION (for storage, operating, rating, soldering, mounting and handling) in this catalog to prevent smoking and/or burning, etc.
• This catalog has only typical specifications. Therefore, please approve our product specifications or transact the approval sheet for product specifications before ordering.
27
C49E.pdf
May 10,2018
2
Continued from the preceding page.
Part Number Temp.
Char.
Rated
Voltage Capacitance
Dimensions
LxW
(mm)
Dimension
T
(mm)
Lead Space
F
(mm)
Lead Style
Code
Bulk
Lead Style
Code
Taping
RHE5G2A151J0ppH03pX8G (Murata) 100Vdc 150pF±5% 3.6×3.5 2.5 5.0 K1 M1
RHE5G2A181J0ppH03pX8G (Murata) 100Vdc 180pF±5% 3.6×3.5 2.5 2.5 A2 DB
RHE5G2A181J0ppH03pX8G (Murata) 100Vdc 180pF±5% 3.6×3.5 2.5 5.0 K1 M1
RHE5G2A221J0ppH03pX8G (Murata) 100Vdc 220pF±5% 3.6×3.5 2.5 2.5 A2 DB
RHE5G2A221J0ppH03pX8G (Murata) 100Vdc 220pF±5% 3.6×3.5 2.5 5.0 K1 M1
RHE5G2A271J0ppH03pX8G (Murata) 100Vdc 270pF±5% 3.6×3.5 2.5 2.5 A2 DB
RHE5G2A271J0ppH03pX8G (Murata) 100Vdc 270pF±5% 3.6×3.5 2.5 5.0 K1 M1
RHE5G2A331J0ppH03pX8G (Murata) 100Vdc 330pF±5% 3.6×3.5 2.5 2.5 A2 DB
RHE5G2A331J0ppH03pX8G (Murata) 100Vdc 330pF±5% 3.6×3.5 2.5 5.0 K1 M1
RHE5G2A391J0ppH03pX8G (Murata) 100Vdc 390pF±5% 3.6×3.5 2.5 2.5 A2 DB
RHE5G2A391J0ppH03pX8G (Murata) 100Vdc 390pF±5% 3.6×3.5 2.5 5.0 K1 M1
RHE5G2A471J0ppH03pX8G (Murata) 100Vdc 470pF±5% 3.6×3.5 2.5 2.5 A2 DB
RHE5G2A471J0ppH03pX8G (Murata) 100Vdc 470pF±5% 3.6×3.5 2.5 5.0 K1 M1
RHE5G2A561J0ppH03pX8G (Murata) 100Vdc 560pF±5% 3.6×3.5 2.5 2.5 A2 DB
RHE5G2A561J0ppH03pX8G (Murata) 100Vdc 560pF±5% 3.6×3.5 2.5 5.0 K1 M1
RHE5G2A681J0ppH03pX8G (Murata) 100Vdc 680pF±5% 3.6×3.5 2.5 2.5 A2 DB
RHE5G2A681J0ppH03pX8G (Murata) 100Vdc 680pF±5% 3.6×3.5 2.5 5.0 K1 M1
RHE5G2A821J0ppH03pX8G (Murata) 100Vdc 820pF±5% 3.6×3.5 2.5 2.5 A2 DB
RHE5G2A821J0ppH03pX8G (Murata) 100Vdc 820pF±5% 3.6×3.5 2.5 5.0 K1 M1
RHE5G2A102J0ppH03pX8G (Murata) 100Vdc 1000pF±5% 3.6×3.5 2.5 2.5 A2 DB
RHE5G2A102J0ppH03pX8G (Murata) 100Vdc 1000pF±5% 3.6×3.5 2.5 5.0 K1 M1
RHE5G2A122J0ppH03pX8G (Murata) 100Vdc 1200pF±5% 3.6×3.5 2.5 2.5 A2 DB
RHE5G2A122J0ppH03pX8G (Murata) 100Vdc 1200pF±5% 3.6×3.5 2.5 5.0 K1 M1
RHE5G2A152J0ppH03pX8G (Murata) 100Vdc 1500pF±5% 3.6×3.5 2.5 2.5 A2 DB
RHE5G2A152J0ppH03pX8G (Murata) 100Vdc 1500pF±5% 3.6×3.5 2.5 5.0 K1 M1
RHE5G2A182J1ppH03pX8G (Murata) 100Vdc 1800pF±5% 4.0×3.5 2.5 2.5 A2 DB
RHE5G2A182J1ppH03pX8G (Murata) 100Vdc 1800pF±5% 4.0×3.5 2.5 5.0 K1 M1
RHE5G2A222J1ppH03pX8G (Murata) 100Vdc 2200pF±5% 4.0×3.5 2.5 2.5 A2 DB
RHE5G2A222J1ppH03pX8G (Murata) 100Vdc 2200pF±5% 4.0×3.5 2.5 5.0 K1 M1
RHE5G2A272J1ppH03pX8G (Murata) 100Vdc 2700pF±5% 4.0×3.5 2.5 2.5 A2 DB
RHE5G2A272J1ppH03pX8G (Murata) 100Vdc 2700pF±5% 4.0×3.5 2.5 5.0 K1 M1
RHE5G2A332J1ppH03pX8G (Murata) 100Vdc 3300pF±5% 4.0×3.5 2.5 2.5 A2 DB
RHE5G2A332J1ppH03pX8G (Murata) 100Vdc 3300pF±5% 4.0×3.5 2.5 5.0 K1 M1
Two blank columns are filled with the lead style code. Please refer to the 3 columns on the right for the appropriate code.
The last blank column is filled with the packaging code. (B: bulk, A: ammo pack)
Part Number Temp.
Char.
Rated
Voltage Capacitance
Dimensions
LxW
(mm)
Dimension
T
(mm)
Lead Space
F
(mm)
Lead Style
Code
Bulk
Lead Style
Code
Taping
RHEL81E104K0ppH03pX8L (Murata) 25Vdc 0.1µF±10% 3.6×3.5 2.5 2.5 A2 DB
RHEL81E104K0ppH03pX8L (Murata) 25Vdc 0.1µF±10% 3.6×3.5 2.5 5.0 K1 M1
RHEL81E154K0ppH03pX8L (Murata) 25Vdc 0.15µF±10% 3.6×3.5 2.5 2.5 A2 DB
RHEL81E154K0ppH03pX8L (Murata) 25Vdc 0.15µF±10% 3.6×3.5 2.5 5.0 K1 M1
RHEL81E224K0ppH03pX8L (Murata) 25Vdc 0.22µF±10% 3.6×3.5 2.5 2.5 A2 DB
RHEL81E224K0ppH03pX8L (Murata) 25Vdc 0.22µF±10% 3.6×3.5 2.5 5.0 K1 M1
RHEL81E334K1ppH03pX8L (Murata) 25Vdc 0.33µF±10% 4.0×3.5 2.5 2.5 A2 DB
RHEL81E334K1ppH03pX8L (Murata) 25Vdc 0.33µF±10% 4.0×3.5 2.5 5.0 K1 M1
RHEL81E474K1ppH03pX8L (Murata) 25Vdc 0.47µF±10% 4.0×3.5 2.5 2.5 A2 DB
RHEL81E474K1ppH03pX8L (Murata) 25Vdc 0.47µF±10% 4.0×3.5 2.5 5.0 K1 M1
RHEL81E684K1ppH03pX8L (Murata) 25Vdc 0.68µF±10% 4.0×3.5 2.5 2.5 A2 DB
RHEL81E684K1ppH03pX8L (Murata) 25Vdc 0.68µF±10% 4.0×3.5 2.5 5.0 K1 M1
RHEL81E105K1ppH03pX8L (Murata) 25Vdc 1.0µF±10% 4.0×3.5 2.5 2.5 A2 DB
RHEL81E105K1ppH03pX8L (Murata) 25Vdc 1.0µF±10% 4.0×3.5 2.5 5.0 K1 M1
RHEL81E155K2ppH03pX8L (Murata) 25Vdc 1.5µF±10% 5.5×4.0 3.15 2.5 A2 DB
RHEL81E155K2ppH03pX8L (Murata) 25Vdc 1.5µF±10% 5.5×4.0 3.15 5.0 K1 M1
RHEL81E225K2ppH03pX8L (Murata) 25Vdc 2.2µF±10% 5.5×4.0 3.15 2.5 A2 DB
Continued on the following page.
High Dielectric Constant Type, X8L Characteristics
!Note • Please read rating and !CAUTION (for storage, operating, rating, soldering, mounting and handling) in this catalog to prevent smoking and/or burning, etc.
• This catalog has only typical specifications. Therefore, please approve our product specifications or transact the approval sheet for product specifications before ordering.
28
C49E.pdf
May 10,2018
2
Continued from the preceding page.
Part Number Temp.
Char.
Rated
Voltage Capacitance
Dimensions
LxW
(mm)
Dimension
T
(mm)
Lead Space
F
(mm)
Lead Style
Code
Bulk
Lead Style
Code
Taping
RHEL81E225K2ppH03pX8L (Murata) 25Vdc 2.2µF±10% 5.5×4.0 3.15 5.0 K1 M1
RHEL81E335K2ppH03pX8L (Murata) 25Vdc 3.3µF±10% 5.5×4.0 3.15 2.5 A2 DB
RHEL81E335K2ppH03pX8L (Murata) 25Vdc 3.3µF±10% 5.5×4.0 3.15 5.0 K1 M1
RHEL81E475K2ppH03pX8L (Murata) 25Vdc 4.7µF±10% 5.5×4.0 3.15 2.5 A2 DB
RHEL81E475K2ppH03pX8L (Murata) 25Vdc 4.7µF±10% 5.5×4.0 3.15 5.0 K1 M1
RHEL81E106K3ppH03pX8L (Murata) 25Vdc 10µF±10% 5.5×5.0 4.0 2.5 A2 DB
RHEL81E106K3ppH03pX8L (Murata) 25Vdc 10µF±10% 5.5×5.0 4.0 5.0 K1 M1
RHEL81E226MWppH03p
X8L (Murata) 25Vdc 22µF±20% 5.5×7.5 4.0 5.0 K1 M1
RHEL81H221K0ppH03pX8L (Murata) 50Vdc 220pF±10% 3.6×3.5 2.5 2.5 A2 DB
RHEL81H221K0ppH03pX8L (Murata) 50Vdc 220pF±10% 3.6×3.5 2.5 5.0 K1 M1
RHEL81H331K0ppH03pX8L (Murata) 50Vdc 330pF±10% 3.6×3.5 2.5 2.5 A2 DB
RHEL81H331K0ppH03pX8L (Murata) 50Vdc 330pF±10% 3.6×3.5 2.5 5.0 K1 M1
RHEL81H471K0ppH03pX8L (Murata) 50Vdc 470pF±10% 3.6×3.5 2.5 2.5 A2 DB
RHEL81H471K0ppH03pX8L (Murata) 50Vdc 470pF±10% 3.6×3.5 2.5 5.0 K1 M1
RHEL81H681K0ppH03pX8L (Murata) 50Vdc 680pF±10% 3.6×3.5 2.5 2.5 A2 DB
RHEL81H681K0ppH03pX8L (Murata) 50Vdc 680pF±10% 3.6×3.5 2.5 5.0 K1 M1
RHEL81H102K0ppH03pX8L (Murata) 50Vdc 1000pF±10% 3.6×3.5 2.5 2.5 A2 DB
RHEL81H102K0ppH03pX8L (Murata) 50Vdc 1000pF±10% 3.6×3.5 2.5 5.0 K1 M1
RHEL81H152K0ppH03pX8L (Murata) 50Vdc 1500pF±10% 3.6×3.5 2.5 2.5 A2 DB
RHEL81H152K0ppH03pX8L (Murata) 50Vdc 1500pF±10% 3.6×3.5 2.5 5.0 K1 M1
RHEL81H222K0ppH03pX8L (Murata) 50Vdc 2200pF±10% 3.6×3.5 2.5 2.5 A2 DB
RHEL81H222K0ppH03pX8L (Murata) 50Vdc 2200pF±10% 3.6×3.5 2.5 5.0 K1 M1
RHEL81H332K0ppH03pX8L (Murata) 50Vdc 3300pF±10% 3.6×3.5 2.5 2.5 A2 DB
RHEL81H332K0ppH03pX8L (Murata) 50Vdc 3300pF±10% 3.6×3.5 2.5 5.0 K1 M1
RHEL81H472K0ppH03pX8L (Murata) 50Vdc 4700pF±10% 3.6×3.5 2.5 2.5 A2 DB
RHEL81H472K0ppH03pX8L (Murata) 50Vdc 4700pF±10% 3.6×3.5 2.5 5.0 K1 M1
RHEL81H682K0ppH03pX8L (Murata) 50Vdc 6800pF±10% 3.6×3.5 2.5 2.5 A2 DB
RHEL81H682K0ppH03pX8L (Murata) 50Vdc 6800pF±10% 3.6×3.5 2.5 5.0 K1 M1
RHEL81H103K0ppH03pX8L (Murata) 50Vdc 10000pF±10% 3.6×3.5 2.5 2.5 A2 DB
RHEL81H103K0ppH03pX8L (Murata) 50Vdc 10000pF±10% 3.6×3.5 2.5 5.0 K1 M1
RHEL81H153K0ppH03pX8L (Murata) 50Vdc 15000pF±10% 3.6×3.5 2.5 2.5 A2 DB
RHEL81H153K0ppH03pX8L (Murata) 50Vdc 15000pF±10% 3.6×3.5 2.5 5.0 K1 M1
RHEL81H223K0ppH03pX8L (Murata) 50Vdc 22000pF±10% 3.6×3.5 2.5 2.5 A2 DB
RHEL81H223K0ppH03pX8L (Murata) 50Vdc 22000pF±10% 3.6×3.5 2.5 5.0 K1 M1
RHEL81H333K0ppH03pX8L (Murata) 50Vdc 33000pF±10% 3.6×3.5 2.5 2.5 A2 DB
RHEL81H333K0ppH03pX8L (Murata) 50Vdc 33000pF±10% 3.6×3.5 2.5 5.0 K1 M1
RHEL81H473K0ppH03pX8L (Murata) 50Vdc 47000pF±10% 3.6×3.5 2.5 2.5 A2 DB
RHEL81H473K0ppH03pX8L (Murata) 50Vdc 47000pF±10% 3.6×3.5 2.5 5.0 K1 M1
RHEL81H683K0ppH03pX8L (Murata) 50Vdc 68000pF±10% 3.6×3.5 2.5 2.5 A2 DB
RHEL81H683K0ppH03pX8L (Murata) 50Vdc 68000pF±10% 3.6×3.5 2.5 5.0 K1 M1
RHEL81H104K0ppH03pX8L (Murata) 50Vdc 0.10µF±10% 3.6×3.5 2.5 2.5 A2 DB
RHEL81H104K0ppH03pX8L (Murata) 50Vdc 0.10µF±10% 3.6×3.5 2.5 5.0 K1 M1
RHEL81H154K1ppH03pX8L (Murata) 50Vdc 0.15µF±10% 4.0×3.5 2.5 2.5 A2 DB
RHEL81H154K1ppH03pX8L (Murata) 50Vdc 0.15µF±10% 4.0×3.5 2.5 5.0 K1 M1
RHEL81H224K1ppH03pX8L (Murata) 50Vdc 0.22µF±10% 4.0×3.5 2.5 2.5 A2 DB
RHEL81H224K1ppH03pX8L (Murata) 50Vdc 0.22µF±10% 4.0×3.5 2.5 5.0 K1 M1
RHEL81H334K1ppH03pX8L (Murata) 50Vdc 0.33µF±10% 4.0×3.5 2.5 2.5 A2 DB
RHEL81H334K1ppH03pX8L (Murata) 50Vdc 0.33µF±10% 4.0×3.5 2.5 5.0 K1 M1
RHEL81H474K2ppH03pX8L (Murata) 50Vdc 0.47µF±10% 5.5×4.0 3.15 2.5 A2 DB
RHEL81H474K2ppH03pX8L (Murata) 50Vdc 0.47µF±10% 5.5×4.0 3.15 5.0 K1 M1
RHEL81H684K2ppH03pX8L (Murata) 50Vdc 0.68µF±10% 5.5×4.0 3.15 2.5 A2 DB
RHEL81H684K2ppH03pX8L (Murata) 50Vdc 0.68µF±10% 5.5×4.0 3.15 5.0 K1 M1
RHEL81H105K2ppH03pX8L (Murata) 50Vdc 1.0µF±10% 5.5×4.0 3.15 2.5 A2 DB
RHEL81H105K2ppH03pX8L (Murata) 50Vdc 1.0µF±10% 5.5×4.0 3.15 5.0 K1 M1
RHEL81H155K2ppH03pX8L (Murata) 50Vdc 1.5µF±10% 5.5×4.0 3.15 2.5 A2 DB
RHEL81H155K2ppH03pX8L (Murata) 50Vdc 1.5µF±10% 5.5×4.0 3.15 5.0 K1 M1
RHEL81H225K2ppH03pX8L (Murata) 50Vdc 2.2µF±10% 5.5×4.0 3.15 2.5 A2 DB
Continued on the following page.
!Note • Please read rating and !CAUTION (for storage, operating, rating, soldering, mounting and handling) in this catalog to prevent smoking and/or burning, etc.
• This catalog has only typical specifications. Therefore, please approve our product specifications or transact the approval sheet for product specifications before ordering.
29
C49E.pdf
May 10,2018
2
Continued from the preceding page.
Part Number Temp.
Char.
Rated
Voltage Capacitance
Dimensions
LxW
(mm)
Dimension
T
(mm)
Lead Space
F
(mm)
Lead Style
Code
Bulk
Lead Style
Code
Taping
RHEL81H225K2ppH03pX8L (Murata) 50Vdc 2.2µF±10% 5.5×4.0 3.15 5.0 K1 M1
RHEL81H335K3ppH03pX8L (Murata) 50Vdc 3.3µF±10% 5.5×5.0 4.0 2.5 A2 DB
RHEL81H335K3ppH03pX8L (Murata) 50Vdc 3.3µF±10% 5.5×5.0 4.0 5.0 K1 M1
RHEL81H475K3ppH03pX8L (Murata) 50Vdc 4.7µF±10% 5.5×5.0 4.0 2.5 A2 DB
RHEL81H475K3ppH03pX8L (Murata) 50Vdc 4.7µF±10% 5.5×5.0 4.0 5.0 K1 M1
RHEL81H106MWppH03p
X8L (Murata) 50Vdc 10µF±20% 5.5×7.5 4.0 5.0 K1 M1
RHEL82A221K0ppH03pX8L (Murata) 100Vdc 220pF±10% 3.6×3.5 2.5 2.5 A2 DB
RHEL82A221K0ppH03pX8L (Murata) 100Vdc 220pF±10% 3.6×3.5 2.5 5.0 K1 M1
RHEL82A331K0ppH03pX8L (Murata) 100Vdc 330pF±10% 3.6×3.5 2.5 2.5 A2 DB
RHEL82A331K0ppH03pX8L (Murata) 100Vdc 330pF±10% 3.6×3.5 2.5 5.0 K1 M1
RHEL82A471K0ppH03pX8L (Murata) 100Vdc 470pF±10% 3.6×3.5 2.5 2.5 A2 DB
RHEL82A471K0ppH03pX8L (Murata) 100Vdc 470pF±10% 3.6×3.5 2.5 5.0 K1 M1
RHEL82A681K0ppH03pX8L (Murata) 100Vdc 680pF±10% 3.6×3.5 2.5 2.5 A2 DB
RHEL82A681K0ppH03pX8L (Murata) 100Vdc 680pF±10% 3.6×3.5 2.5 5.0 K1 M1
RHEL82A102K0ppH03pX8L (Murata) 100Vdc 1000pF±10% 3.6×3.5 2.5 2.5 A2 DB
RHEL82A102K0ppH03pX8L (Murata) 100Vdc 1000pF±10% 3.6×3.5 2.5 5.0 K1 M1
RHEL82A152K0ppH03pX8L (Murata) 100Vdc 1500pF±10% 3.6×3.5 2.5 2.5 A2 DB
RHEL82A152K0ppH03pX8L (Murata) 100Vdc 1500pF±10% 3.6×3.5 2.5 5.0 K1 M1
RHEL82A222K0ppH03pX8L (Murata) 100Vdc 2200pF±10% 3.6×3.5 2.5 2.5 A2 DB
RHEL82A222K0ppH03pX8L (Murata) 100Vdc 2200pF±10% 3.6×3.5 2.5 5.0 K1 M1
RHEL82A332K0ppH03pX8L (Murata) 100Vdc 3300pF±10% 3.6×3.5 2.5 2.5 A2 DB
RHEL82A332K0ppH03pX8L (Murata) 100Vdc 3300pF±10% 3.6×3.5 2.5 5.0 K1 M1
RHEL82A472K0ppH03pX8L (Murata) 100Vdc 4700pF±10% 3.6×3.5 2.5 2.5 A2 DB
RHEL82A472K0ppH03pX8L (Murata) 100Vdc 4700pF±10% 3.6×3.5 2.5 5.0 K1 M1
RHEL82A682K0ppH03pX8L (Murata) 100Vdc 6800pF±10% 3.6×3.5 2.5 2.5 A2 DB
RHEL82A682K0ppH03pX8L (Murata) 100Vdc 6800pF±10% 3.6×3.5 2.5 5.0 K1 M1
RHEL82A103K0ppH03pX8L (Murata) 100Vdc 10000pF±10% 3.6×3.5 2.5 2.5 A2 DB
RHEL82A103K0ppH03pX8L (Murata) 100Vdc 10000pF±10% 3.6×3.5 2.5 5.0 K1 M1
RHEL82A153K0ppH03pX8L (Murata) 100Vdc 15000pF±10% 3.6×3.5 2.5 2.5 A2 DB
RHEL82A153K0ppH03pX8L (Murata) 100Vdc 15000pF±10% 3.6×3.5 2.5 5.0 K1 M1
RHEL82A223K0ppH03pX8L (Murata) 100Vdc 22000pF±10% 3.6×3.5 2.5 2.5 A2 DB
RHEL82A223K0ppH03pX8L (Murata) 100Vdc 22000pF±10% 3.6×3.5 2.5 5.0 K1 M1
RHEL82A333K1ppH03pX8L (Murata) 100Vdc 33000pF±10% 4.0×3.5 2.5 2.5 A2 DB
RHEL82A333K1ppH03pX8L (Murata) 100Vdc 33000pF±10% 4.0×3.5 2.5 5.0 K1 M1
RHEL82A473K1ppH03pX8L (Murata) 100Vdc 47000pF±10% 4.0×3.5 2.5 2.5 A2 DB
RHEL82A473K1ppH03pX8L (Murata) 100Vdc 47000pF±10% 4.0×3.5 2.5 5.0 K1 M1
RHEL82A683K1ppH03pX8L (Murata) 100Vdc 68000pF±10% 4.0×3.5 2.5 2.5 A2 DB
RHEL82A683K1ppH03pX8L (Murata) 100Vdc 68000pF±10% 4.0×3.5 2.5 5.0 K1 M1
RHEL82A104K1ppH03pX8L (Murata) 100Vdc 0.10µF±10% 4.0×3.5 2.5 2.5 A2 DB
RHEL82A104K1ppH03pX8L (Murata) 100Vdc 0.10µF±10% 4.0×3.5 2.5 5.0 K1 M1
RHEL82A154K2ppH03pX8L (Murata) 100Vdc 0.15µF±10% 5.5×4.0 3.15 2.5 A2 DB
RHEL82A154K2ppH03pX8L (Murata) 100Vdc 0.15µF±10% 5.5×4.0 3.15 5.0 K1 M1
RHEL82A224K2ppH03pX8L (Murata) 100Vdc 0.22µF±10% 5.5×4.0 3.15 2.5 A2 DB
RHEL82A224K2ppH03pX8L (Murata) 100Vdc 0.22µF±10% 5.5×4.0 3.15 5.0 K1 M1
Two blank columns are filled with the lead style code. Please refer to the 3 columns on the right for the appropriate code.
The last blank column is filled with the packaging code. (B: bulk, A: ammo pack)
!Note • Please read rating and !CAUTION (for storage, operating, rating, soldering, mounting and handling) in this catalog to prevent smoking and/or burning, etc.
• This catalog has only typical specifications. Therefore, please approve our product specifications or transact the approval sheet for product specifications before ordering.
30
C49E.pdf
May 10,2018
2
Specifications and Test Methods
* “room condition” Temperature: 15 to 35°C, Relative humidity: 45 to 75%, Atmosphere pressure: 86 to 106kPa
Visual inspection9 Marking To be easily legible
Using calipers and micrometers8 Physical Dimension Within the specified dimensions
Visual inspection7 External Visual No defects or abnormalities
Apply 150% of the rated voltage for 1000±12h at 150±3°C.
Let sit for 24±2h at room condition*, then measure.
The charge/discharge current is less than 50mA.
F0#20#2+#,2
Apply test voltage for 60±5 min at test temperature.
Remove and let sit for 24±2h at room condition*.
(for Char. X8L)
6
Operational Life The measured and observed characteristics should satisfy the
specifications in the following table.
Appearance
No defects or abnormalities except color change of outer
coating
Capacitance
Change
Within ±3% or ±0.3pF
(Whichever is larger) Within ±12.5%
Q/D.F. Q >
= 350 0.04 max.
I.R. 1000MΩ or 50MΩ F μF min. (Whichever is smaller)
Apply the rated voltage and DC1.3+0.2/-0V (add 100kΩ resistor)
at 85±3°C and 80 to 85% humidity for 1000±12h.
Remove and let sit for 24±2h at room condition*, then measure.
The charge/discharge current is less than 50mA.
F0#20#2+#,2
Perform the heat treatment at 150+0/-10°C for 60±5min and
then let sit for 24±2h at room condition*. (for Char. X8L)
5
Biased Humidity The measured and observed characteristics should satisfy the
specifications in the following table.
Appearance
No defects or abnormalities
Capacitance
Change
Within ±5% or ±0.5pF
(Whichever is larger) Within ±12.5%
Q/D.F. Q >
= 200 0.05 max.
I.R. 500MΩ or 25MΩ F μF min. (Whichever is smaller)
Apply the 24h heat (25 to 65°C) and humidity (80 to 98%)
treatment shown below, 10 consecutive times.
Let sit for 24±2h at room condition*, then measure.
F0#20#2+#,2
Perform the heat treatment at 150+0/-10°C for 60±5min and
then let sit for 24±2h at room condition*. (for Char. X8L)
4
Moisture
Resistance
The measured and observed characteristics should satisfy the
specifications in the following table.
Appearance
No defects or abnormalities
Capacitance
Change
Within ±5% or ±0.5pF
(Whichever is larger) Within ±12.5%
Q/D.F. Q >
= 200 0.05 max.
I.R. 500MΩ or 25MΩ F μF min. (Whichever is smaller)
(°C)
70
65
60
55
50
45
40
35
30
25
20
15
10
5
0
-5
-10
Humidity
90-98%
Humidity
80-98%
Humidity
90-98%
Humidity
80-98%
Humidity
90-98%
+10
-2°C
Initial measurement
Temperature
One cycle = 24 hours
0123456789
1011 1213 1415 1617 1819 2021 2223 24
Hours
Perform the 1000 cycles according to the four heat treatments
listed in the following table. Let sit for 24±2h at room
condition*, then measure.
F0#20#2+#,2
Perform the heat treatment at 150+0/-10°C for 60±5min and
then let sit for 24±2h at room condition*. (for Char. X8L)
3
Temperature
Cycling
The measured and observed characteristics should satisfy the
specifications in the following table.
Appearance
No defects or abnormalities except color change of outer
coating
Capacitance
Change
Within ±5% or ±0.5pF
(Whichever is larger) Within ±12.5%
Q/D.F. Q >
= 350 0.05 max.
I.R. 1000MΩ or 50MΩ F μF min. (Whichever is smaller)
Sit the capacitor for 1000±12h at 150±3°C. Let sit for 24±2h at
room condition*, then measure.
F0#20#2+#,2
Perform the heat treatment at 150+0/-10°C for 60±5min and
then let sit for 24±2h at room condition*. (for Char. X8L)
2
High Temperature
Exposure (Storage)
The measured and observed characteristics should satisfy the
specifications in the following table.
Appearance
No defects or abnormalities
Q/D.F. Q >
= 350 0.04 max.
I.R. More than 1000MΩ or 50MΩ F μF (Whichever is smaller)
1
Pre-and Post-Stress
Electrical Test
No. AEC-Q200 Test Method
Specification
AEC-Q200 Test Item
Temperature Compensating Type
(Char. X8G)
High Dielectric Constant Type
(Char. X8L)
Capacitance
Change
Within ±3% or ±0.3pF
(Whichever is larger) Within ±12.5%
Step 1
-55+0/-3
15±3
2
Room Temp.
1
3
150+3/-0
15±3
4
Room Temp.
1
Temp. (°C)
Time (min)
Continued on the following page.
!Note • Please read rating and !CAUTION (for storage, operating, rating, soldering, mounting and handling) in this catalog to prevent smoking and/or burning, etc.
• This catalog has only typical specifications. Therefore, please approve our product specifications or transact the approval sheet for product specifications before ordering.
31
C49E.pdf
May 10,2018
2
Specifications and Test Methods
* “room condition” Temperature: 15 to 35°C, Relative humidity: 45 to 75%, Atmosphere pressure: 86 to 106kPa
Per AEC-Q200-002
15 ESD
Appearance
No defects or abnormalities
Capacitance
Within the specified tolerance
Q/D.F. Q >
= 1000 0.025 max.
I.R. More than 10000MΩ or 500MΩ F μF (Whichever is smaller)
Perform the 300 cycles according to the two heat treatments
listed in the following table (Maximum transfer time is 20s).
Let sit for 24±2h at room condition*, then measure.
F0#20#2+#,2
Perform the heat treatment at 150+0/-10°C for 60±5min and
then let sit for 24±2h at room condition*. (for Char. X8L)
14
Thermal Shock The measured and observed characteristics should satisfy the
specifications in the following table.
Appearance
No defects or abnormalities
Capacitance
Change
Within ±5% or ±0.5pF
(Whichever is larger) Within ±12.5%
Q/D.F. Q >
= 350 0.05 max.
I.R. 1000MΩ or 50MΩ F μF min. (Whichever is smaller)
Step 1
-55+0/-3
15±3
2
150+3/-0
15±3
Temp. (°C)
Time (min)
The lead wires should be immersed in the melted solder 1.5 to
2.0mm from the root of terminal at 260±5°C for 10±1s.
Pre-treatment
Capacitor should be stored at 150+0/-10°C for 1h, then place
at room temperature for 24±2h before initial measurement.
(For Char. X8L)
Post-treatment
Capacitor should be stored for 24±2h at room condition*.
13
-
1
Resistance to
Soldering Heat
(Non-Preheat)
The measured and observed characteristics should satisfy the
specifications in the following table.
Appearance
No defects or abnormalities
Capacitance
Change
Within ±2.5% or ±0.25pF
(Whichever is larger) Within ±7.5%
Dielectric
Strength
(Between
Terminals)
No defects
13
-
2
Resistance to
Soldering Heat
(On-Preheat)
The measured and observed characteristics should satisfy the
specifications in the following table.
Appearance
No defects or abnormalities
Capacitance
Change
Within ±2.5% or ±0.25pF
(Whichever is larger) Within ±7.5%
Dielectric
Strength
(Between
Terminals)
No defects
13
-
3
Resistance to
Soldering Heat
(Soldering
Iron Method)
The measured and observed characteristics should satisfy the
specifications in the following table.
Appearance
No defects or abnormalities
Capacitance
Change
Within ±2.5% or ±0.25pF
(Whichever is larger) Within ±7.5%
Dielectric
Strength
(Between
Terminals)
No defects
The capacitor should be subjected to a simple harmonic motion
having a total amplitude of 1.5mm, the frequency being varied
uniformly between the approximate limits of 10 and 2000Hz.
The frequency range, from 10 to 2000Hz and return to 10Hz,
should be traversed in approximately 20min. This motion
should be applied for 12 items in each 3 mutually perpendicular
directions (total of 36 times).
12 Vibration
Appearance
No defects or abnormalities
Capacitance
Within the specified tolerance
Q/D.F. Q >
= 1000 0.025 max.
Three shocks in each direction should be applied along 3
mutually perpendicular axes of the test specimen (18 shocks).
The specified test pulse should be Half-sine and should
have a duration: 0.5ms, peak value: 1500G and velocity
change: 4.7m/s.
11
Mechanical
Shock
Appearance
No defects or abnormalities
Capacitance
Within the specified tolerance
Q/D.F. Q >
= 1000 0.025 max.
Per MIL-STD-202 Method 215
Solvent 1: 1 part (by volume) of isopropyl alcohol
3 parts (by volume) of mineral spirits
Solvent 2: Terpene defluxer
Solvent 3: 42 parts (by volume) of water
1 part (by volume) of propylene glycol
monomethyl ether
1 part (by volume) of monoethanolamine
10
Resistance
to Solvents
Appearance
No defects or abnormalities
Capacitance
Within the specified tolerance
Q/D.F. Q >
= 1000 0.025 max.
I.R. More than 10000MΩ or 500MΩ F μF (Whichever is smaller)
No. AEC-Q200 Test Method
Specification
AEC-Q200 Test Item
Temperature Compensating Type
(Char. X8G)
High Dielectric Constant Type
(Char. X8L)
First the capacitor should be stored at 120+0/-5°C for 60+0/-5s.
Then, the lead wires should be immersed in the melted solder 1.5
to 2.0mm from the root of terminal at 260±5°C for 7.5+0/-1s.
Pre-treatment
Capacitor should be stored at 150+0/-10°C for 1h, then place
at room temperature for 24±2h before initial measurement. (For
Char. X8L)
Post-treatment
Capacitor should be stored for 24±2h at room condition*.
Test condition
Temperature of iron-tip: 350±10°C
Soldering time: 3.5±0.5s.
Soldering position
Straight Lead: 1.5 to 2.0mm from the root of terminal.
Crimp Lead: 1.5 to 2.0mm from the end of lead bend.
Pre-treatment
Capacitor should be stored at 150+0/-10°C for 1h, then place
at room temperature for 24±2h before initial measurement.
(For Char. X8L)
Post-treatment
Capacitor should be stored for 24±2h at room condition*.
Continued from the preceding page.
Continued on the following page.
!Note • Please read rating and !CAUTION (for storage, operating, rating, soldering, mounting and handling) in this catalog to prevent smoking and/or burning, etc.
• This catalog has only typical specifications. Therefore, please approve our product specifications or transact the approval sheet for product specifications before ordering.
32
C49E.pdf
May 10,2018
2
Specifications and Test Methods
The capacitance change should be measured after 5min at each
specified temperature step.
The temperature coefficient or the ranges of capacitance
change is determined using the capacitance measured in
step 3 as a reference.
F0#20#2+#,2
#0$-0+2&#&#220#2+#,22{zzGQ{z$-0z+',,"
2&#,*#21'2$-0|~|&20--+!-,"'2'-,?@
#0$-0+2&#','2'*+#130#+#,2@H$-0&0@J
19
Capacitance
Temperature
Characteristics
'2&',{
H#+.@,%#BQ2-{|J
'2&',{GQ~z
H#+.@,%#B{|2-{zJ
Step
{
2
3
4
5
Temperature (°C)
||
Q}
||
{z}
||
?]0--+!-,"'2'-,^#+.#0230#B{2-}A#*2'4#&3+'"'27B~2-A2+-1.&#0#.0#1130#B2-{z)
1',2&#q%30#Aq62&#!.!'2-0 -"7A
..*72&#$-0!#%0"3**72-#!&*#"
in the radial direction of the capacitor
3,2'*0#!&',%{z,"2&#,)##.2&#
$-0!#..*'#"$-0{z{1@
18 Terminal
Strength
Tensile
Strength #0+',2'-,,-22- # 0-)#,-0*--1#,#"
!&*#"5'0#1&-3*" #13 (#!2#"2-$-0!#-$|@,"2&#,
# #,2z22&#.-',2-$#%0#11',-,#"'0#!2'-,@!&5'0#'1
2&#,0#230,#"2-2&#-0'%',*.-1'2'-,," #,2z',2&#
opposite direction at the rate of one bend per 2 to 3s.
Bending
Strength #0+',2'-,,-22- # 0-)#,-0*--1#,#"
Visual inspection
17
Electrical
Charac-
terization
Appearance
-"#$#!21-0 ,-0+*'2'#1
&#!.!'2,!#AG@@1&-3*" #+#130#"2|22&#
$0#/3#,!7,"4-*2%#1&-5,',2&#2 *#@
Capacitance
Within the specified tolerance
&#',13*2'-,0#1'12,!#1&-3*" #+#130#"2|}5'2&
4-*2%#,-2#6!##"',%2&#02#"4-*2%#2,-0+*
2#+.#0230#,"&3+'"'27,"5'2&',|+',-$!&0%',%@
H&0%#G'1!&0%#!300#,2 <
= z+@J
Insulation
Resistance
(I.R.)
Room
Temperature
{zzzzΩ-0zzΩF£+',@
H&'!&#4#0'11+**#0J
&#!.!'2-01&-3*",-2 #"+%#"5&#,4-*2%#-$
}zz-$2&#02#"4-*2%#H$-0&0@J-04-*2%#-$
|z-$2&#02#"4-*2%#H$-0&0@J'1..*'#" #25##,
2&#2#0+',2'-,1$-0{2-1@
H&0%#G'1!&0%#!300#,2 <
= z+@J
Between
Terminals -"#$#!21-0 ,-0+*'2'#1
The capacitor is placed in a container
5'2&+#2* **1-${++"'+#2#01-
2&2#!&2#0+',*A1&-02Q!'0!3'2'1)#.2
..0-6'+2#*7|++$0-+2&# **1A,"
|z-$2&#02#"4-*2%#'1
'+.0#11#"$-0{2-1 #25##,
capacitor terminals and metal balls.
H&0%#G'1!&0%#!300#,2 <
= z+@J
Dielectric
Strength
Body
Insulation -"#$#!21-0 ,-0+*'2'#1
No. AEC-Q200 Test Method
Specification
AEC-Q200 Test Item
Temperature Compensating Type
(Char. X8G)
High Dielectric Constant Type
(Char. X8L)
Char.


Nominal Cap.
< {zzz.
>
= {zzz.
<
= {z£
> {z£
Frequency
{z@{8
{z@{)8
{z@{)8
{|z|~8
Voltage
z@2-H0@+@1@J
{z@|H0@+@1@J
{@zz@|H0@+@1@J
z@z@{H0@+@1@J
Q/D.F. >
= {zzz z@z|+6@
&#',13*2'-,0#1'12,!#1&-3*" #+#130#"2{z}5'2&
4-*2%#,-2#6!##"',%2&#02#"4-*2%#2,-0+*
2#+.#0230#,"&3+'"'27,"5'2&',|+',-$!&0%',%@
H&0%#G'1!&0%#!300#,2 <
= z+@J
High
Temperature
{zzΩ-0ΩF£ min.
H&'!&#4#0'11+**#0J
..0-6@|++
#2* **1
The terminal of a capacitor is dipped into a solution of ethanol
HQQ{z{J,"0-1',HQQz|JH|0-1',',5#'%&2
.0-.-2'-,J,"2&#,',2-+-*2#,1-*"#0HQQ}||J$-0
|z@1@, -2&!1#12&#"#.2&-$"'..',%'13.2- -32
{@2-|++$0-+2&#2#0+',* -"7@
#+.@-$1-*"#0B
|~#"0##-*"#0H,Q}@z%Qz@3J
|}z-0}32#!2'!-*"#0
16 Solderability #"5'0#1&-3*" #1-*"#0#"5'2&3,'$-0+!-2',%-,2&#6'*
"'0#!2'-,-4#0-$2&#!'0!3+$#0#,2'*"'0#!2'-,@
Char.
Temperature Coefficient
25 to {z

B
z}z..+G

Q55 to 25

B
z}zGQ|ppmG


-,2',3#"$0-+2&#.0#!#"',%.%#@
!Note • Please read rating and !CAUTION (for storage, operating, rating, soldering, mounting and handling) in this catalog to prevent smoking and/or burning, etc.
• This catalog has only typical specifications. Therefore, please approve our product specifications or transact the approval sheet for product specifications before ordering.
33
C49E.pdf
May 10,2018
2
Features
1. Small size and large capacitance
2. Low ESR and ESL suitable for high frequency
3. Applied maximum temperature up to 175°C or 200°C
Note: Maximum accumulative time is within 2000 hours.
4. Meet AEC-Q200, ISO7637-2 (surge test) requirement
5. Meet LF (Lead Free) and HF (Halogen Free)
6. Flow soldering and welding are available.
(Re-flow soldering is not available.)
7. If copper wire is necessary at welding process, copper
wire is available based on request.
L max.
W max.25.0 min.
F±0.8
1.5 max.
T max.
ød: 0.5±0.05
(in mm)
· Lead Wire: Solder Coated CP Wire
Dimension code: 0
Lead style code: A2
175°C/200°C Operation Leaded MLCC for Automotive
RHS Series (DC100V-DC500V)
Dimensions and
Lead Style Code
Dimensions (mm)
L W W1 T F d
0A2/0DG
0K1/0M2
1A2/1DG
1K1/1M2
2A2/2DG
2K1/2M1
0.5
0.5
0.5
0.5
0.5
0.5
2.5
5.0
2.5
5.0
2.5
5.0
-
6.0
-
5.0
-
6.0
3.5
3.5
3.5
3.5
4.0
4.0
3.8
3.8
4.0
4.0
5.5
5.5
See the individual
product specification
!Note • Please read rating and !CAUTION (for storage, operating, rating, soldering, mounting and handling) in this catalog to prevent smoking and/or burning, etc.
• This catalog has only typical specifications. Therefore, please approve our product specifications or transact the approval sheet for product specifications before ordering.
34
C49E.pdf
May 10,2018
3
L max.
W max.
W1 max.
25.0 min.
F±0.8
*
T max.
ød: 0.5±0.05
(in mm)
* Coating extension does not exceed the end of the lead bend.
· Lead Wire: Solder Coated CP Wire
Dimension code: 0
Lead style code: K1
L max.
W max.25.0 min.
F±0.8
1.5 max.
T max.
ød: 0.5±0.05
(in mm)
· Lead Wire: Solder Coated CP Wire
Dimension code: 1
Lead style code: A2
L max.
W max.
W1 max.
25.0 min.
F±0.8
*
T max.
ød: 0.5±0.05
(in mm)
* Coating extension does not exceed the end of the lead bend.
· Lead Wire: Solder Coated CP Wire
Dimension code: 1
Lead style code: K1
L max.
W max.25.0 min.
F±0.8
1.5 max.
T max.
ød: 0.5±0.05
(in mm)
· Lead Wire: Solder Coated CP Wire
Dimension code: 2
Lead style code: A2
L max.
W max.
W1 max.
25.0 min.
F±0.8
*
T max.
ød: 0.5±0.05
(in mm)
* Coating extension does not exceed the end of the lead bend.
· Lead Wire: Solder Coated CP Wire
Dimension code: 2
Lead style code: K1
Dimensions
Rated Voltage
When the product temperature exceeds 150°C, please use
this product within the voltage and temperature derated
conditions in the figure below.
Maximum operating temperature
200°C: Temp. Char. CCG and UNJ
175°C: Temp. Char. XAL and XAN
10
100
-75 -50 -25 0 25 50 75 100 125 150 175 200
Temperature (°C)
Rated Voltage (%)
50%
25%
Rated Voltage
Temp. Char.
Dimension Code
0
1
Temperature Characteristics
Nominal Capacitance
Capacitance Tolerance
Rated Voltage
Manufacturer's Identification
CCG XAL XAN UNJ
DC500VDC200V
Marked with 3 figures
Marked with code (CCG Char.: 4, UNJ Char.: 2, XAL Char.: 6, XAN Char.: 9)
Marked with code
Marked with code (DC100V: 1, DC200V: 6, DC500V: 9)
Apart is omitted (Please refer to the marking example.)
9
103K
2
101J
DC100V
4
101J
6
103K
2224
K19
M103
J62
M101
J92
M
Marked with
A part is omitted (Please refer to the marking example.)
M
Marking
Part Number Temp.
Char.
Rated
Voltage Capacitance
Dimensions
LxW
(mm)
Dimension
T
(mm)
Lead Space
F
(mm)
Lead Style
Code
Bulk
Lead Style
Code
Taping
RHS7G2A101J0ppH01pCCG (Murata) 100Vdc 100pF±5% 3.8×3.5 2.5 2.5 A2 DG
RHS7G2A101J0ppH01pCCG (Murata) 100Vdc 100pF±5% 3.8×3.5 2.5 5.0 K1 M2
RHS7G2A121J0ppH01pCCG (Murata) 100Vdc 120pF±5% 3.8×3.5 2.5 2.5 A2 DG
RHS7G2A121J0ppH01pCCG (Murata) 100Vdc 120pF±5% 3.8×3.5 2.5 5.0 K1 M2
RHS7G2A151J0ppH01pCCG (Murata) 100Vdc 150pF±5% 3.8×3.5 2.5 2.5 A2 DG
RHS7G2A151J0ppH01pCCG (Murata) 100Vdc 150pF±5% 3.8×3.5 2.5 5.0 K1 M2
RHS7G2A181J0ppH01pCCG (Murata) 100Vdc 180pF±5% 3.8×3.5 2.5 2.5 A2 DG
RHS7G2A181J0ppH01pCCG (Murata) 100Vdc 180pF±5% 3.8×3.5 2.5 5.0 K1 M2
RHS7G2A221J0ppH01pCCG (Murata) 100Vdc 220pF±5% 3.8×3.5 2.5 2.5 A2 DG
RHS7G2A221J0ppH01pCCG (Murata) 100Vdc 220pF±5% 3.8×3.5 2.5 5.0 K1 M2
RHS7G2A271J0ppH01pCCG (Murata) 100Vdc 270pF±5% 3.8×3.5 2.5 2.5 A2 DG
RHS7G2A271J0ppH01pCCG (Murata) 100Vdc 270pF±5% 3.8×3.5 2.5 5.0 K1 M2
Continued on the following page.
Temperature Compensating Type, CCG/UNJ Characteristics
!Note • Please read rating and !CAUTION (for storage, operating, rating, soldering, mounting and handling) in this catalog to prevent smoking and/or burning, etc.
• This catalog has only typical specifications. Therefore, please approve our product specifications or transact the approval sheet for product specifications before ordering.
35
C49E.pdf
May 10,2018
3
Part Number Temp.
Char.
Rated
Voltage Capacitance
Dimensions
LxW
(mm)
Dimension
T
(mm)
Lead Space
F
(mm)
Lead Style
Code
Bulk
Lead Style
Code
Taping
RHS7G2A331J0ppH01pCCG (Murata) 100Vdc 330pF±5% 3.8×3.5 2.5 2.5 A2 DG
RHS7G2A331J0ppH01pCCG (Murata) 100Vdc 330pF±5% 3.8×3.5 2.5 5.0 K1 M2
RHS7G2A391J0ppH01pCCG (Murata) 100Vdc 390pF±5% 3.8×3.5 2.5 2.5 A2 DG
RHS7G2A391J0ppH01pCCG (Murata) 100Vdc 390pF±5% 3.8×3.5 2.5 5.0 K1 M2
RHS7G2A471J0ppH01pCCG (Murata) 100Vdc 470pF±5% 3.8×3.5 2.5 2.5 A2 DG
RHS7G2A471J0ppH01pCCG (Murata) 100Vdc 470pF±5% 3.8×3.5 2.5 5.0 K1 M2
RHS7G2A561J0ppH01pCCG (Murata) 100Vdc 560pF±5% 3.8×3.5 2.5 2.5 A2 DG
RHS7G2A561J0ppH01pCCG (Murata) 100Vdc 560pF±5% 3.8×3.5 2.5 5.0 K1 M2
RHS7G2A681J0ppH01pCCG (Murata) 100Vdc 680pF±5% 3.8×3.5 2.5 2.5 A2 DG
RHS7G2A681J0ppH01pCCG (Murata) 100Vdc 680pF±5% 3.8×3.5 2.5 5.0 K1 M2
RHS7G2A821J0ppH01pCCG (Murata) 100Vdc 820pF±5% 3.8×3.5 2.5 2.5 A2 DG
RHS7G2A821J0ppH01pCCG (Murata) 100Vdc 820pF±5% 3.8×3.5 2.5 5.0 K1 M2
RHS7G2A102J0ppH01pCCG (Murata) 100Vdc 1000pF±5% 3.8×3.5 2.5 2.5 A2 DG
RHS7G2A102J0ppH01pCCG (Murata) 100Vdc 1000pF±5% 3.8×3.5 2.5 5.0 K1 M2
RHS7G2A152J0ppH01pCCG (Murata) 100Vdc 1500pF±5% 3.8×3.5 2.5 2.5 A2 DG
RHS7G2A152J0ppH01pCCG (Murata) 100Vdc 1500pF±5% 3.8×3.5 2.5 5.0 K1 M2
RHS7G2A222J1ppH01pCCG (Murata) 100Vdc 2200pF±5% 4.0×3.5 2.5 2.5 A2 DG
RHS7G2A222J1ppH01pCCG (Murata) 100Vdc 2200pF±5% 4.0×3.5 2.5 5.0 K1 M2
RHS7G2A272J1ppH01pCCG (Murata) 100Vdc 2700pF±5% 4.0×3.5 2.5 2.5 A2 DG
RHS7G2A272J1ppH01pCCG (Murata) 100Vdc 2700pF±5% 4.0×3.5 2.5 5.0 K1 M2
RHS7G2A332J1ppH01pCCG (Murata) 100Vdc 3300pF±5% 4.0×3.5 2.5 2.5 A2 DG
RHS7G2A332J1ppH01pCCG (Murata) 100Vdc 3300pF±5% 4.0×3.5 2.5 5.0 K1 M2
RHS7J2D101J1ppH01pUNJ (Murata) 200Vdc 100pF±5% 4.0×3.5 2.5 2.5 A2 DG
RHS7J2D101J1ppH01pUNJ (Murata) 200Vdc 100pF±5% 4.0×3.5 2.5 5.0 K1 M2
RHS7J2D151J1ppH01pUNJ (Murata) 200Vdc 150pF±5% 4.0×3.5 2.5 2.5 A2 DG
RHS7J2D151J1ppH01pUNJ (Murata) 200Vdc 150pF±5% 4.0×3.5 2.5 5.0 K1 M2
RHS7J2D221J1ppH01pUNJ (Murata) 200Vdc 220pF±5% 4.0×3.5 2.5 2.5 A2 DG
RHS7J2D221J1ppH01pUNJ (Murata) 200Vdc 220pF±5% 4.0×3.5 2.5 5.0 K1 M2
RHS7J2D331J1ppH01pUNJ (Murata) 200Vdc 330pF±5% 4.0×3.5 2.5 2.5 A2 DG
RHS7J2D331J1ppH01pUNJ (Murata) 200Vdc 330pF±5% 4.0×3.5 2.5 5.0 K1 M2
RHS7J2D471J1ppH01pUNJ (Murata) 200Vdc 470pF±5% 4.0×3.5 2.5 2.5 A2 DG
RHS7J2D471J1ppH01pUNJ (Murata) 200Vdc 470pF±5% 4.0×3.5 2.5 5.0 K1 M2
RHS7J2D681J1ppH01pUNJ (Murata) 200Vdc 680pF±5% 4.0×3.5 2.5 2.5 A2 DG
RHS7J2D681J1ppH01pUNJ (Murata) 200Vdc 680pF±5% 4.0×3.5 2.5 5.0 K1 M2
RHS7J2D102J1ppH01pUNJ (Murata) 200Vdc 1000pF±5% 4.0×3.5 2.5 2.5 A2 DG
RHS7J2D102J1ppH01pUNJ (Murata) 200Vdc 1000pF±5% 4.0×3.5 2.5 5.0 K1 M2
RHS7J2D152J1ppH01pUNJ (Murata) 200Vdc 1500pF±5% 4.0×3.5 2.5 2.5 A2 DG
RHS7J2D152J1ppH01pUNJ (Murata) 200Vdc 1500pF±5% 4.0×3.5 2.5 5.0 K1 M2
RHS7J2D222J1ppH01pUNJ (Murata) 200Vdc 2200pF±5% 4.0×3.5 2.5 2.5 A2 DG
RHS7J2D222J1ppH01pUNJ (Murata) 200Vdc 2200pF±5% 4.0×3.5 2.5 5.0 K1 M2
RHS7J2D332J1ppH01pUNJ (Murata) 200Vdc 3300pF±5% 4.0×3.5 2.5 2.5 A2 DG
RHS7J2D332J1ppH01pUNJ (Murata) 200Vdc 3300pF±5% 4.0×3.5 2.5 5.0 K1 M2
RHS7J2D472J1ppH01pUNJ (Murata) 200Vdc 4700pF±5% 4.0×3.5 2.5 2.5 A2 DG
RHS7J2D472J1ppH01pUNJ (Murata) 200Vdc 4700pF±5% 4.0×3.5 2.5 5.0 K1 M2
RHS7J2D682J2ppH01pUNJ (Murata) 200Vdc 6800pF±5% 5.5×4.0 3.15 2.5 A2 DG
RHS7J2D682J2ppH01pUNJ (Murata) 200Vdc 6800pF±5% 5.5×4.0 3.15 5.0 K1 M2
RHS7J2D103J2ppH01pUNJ (Murata) 200Vdc 10000pF±5% 5.5×4.0 3.15 2.5 A2 DG
RHS7J2D103J2ppH01pUNJ (Murata) 200Vdc 10000pF±5% 5.5×4.0 3.15 5.0 K1 M2
RHS7J2H101J2ppH01pUNJ (Murata) 500Vdc 100pF±5% 5.5×4.0 3.15 5.0 K1 M2
RHS7J2H151J2ppH01pUNJ (Murata) 500Vdc 150pF±5% 5.5×4.0 3.15 5.0 K1 M2
RHS7J2H221J2ppH01pUNJ (Murata) 500Vdc 220pF±5% 5.5×4.0 3.15 5.0 K1 M2
RHS7J2H331J2ppH01pUNJ (Murata) 500Vdc 330pF±5% 5.5×4.0 3.15 5.0 K1 M2
RHS7J2H471J2ppH01pUNJ (Murata) 500Vdc 470pF±5% 5.5×4.0 3.15 5.0 K1 M2
RHS7J2H681J2ppH01pUNJ (Murata) 500Vdc 680pF±5% 5.5×4.0 3.15 5.0 K1 M2
RHS7J2H102J2ppH01pUNJ (Murata) 500Vdc 1000pF±5% 5.5×4.0 3.15 5.0 K1 M2
RHS7J2H152J2ppH01pUNJ (Murata) 500Vdc 1500pF±5% 5.5×4.0 3.15 5.0 K1 M2
RHS7J2H222J2ppH01pUNJ (Murata) 500Vdc 2200pF±5% 5.5×4.0 3.15 5.0 K1 M2
Continued from the preceding page.
Continued on the following page.
!Note • Please read rating and !CAUTION (for storage, operating, rating, soldering, mounting and handling) in this catalog to prevent smoking and/or burning, etc.
• This catalog has only typical specifications. Therefore, please approve our product specifications or transact the approval sheet for product specifications before ordering.
36
C49E.pdf
May 10,2018
3
Part Number Temp.
Char.
Rated
Voltage Capacitance
Dimensions
LxW
(mm)
Dimension
T
(mm)
Lead Space
F
(mm)
Lead Style
Code
Bulk
Lead Style
Code
Taping
RHS7J2H332J2ppH01pUNJ (Murata) 500Vdc 3300pF±5% 5.5×4.0 3.15 5.0 K1 M2
RHS7J2H472J2ppH01pUNJ (Murata) 500Vdc 4700pF±5% 5.5×4.0 3.15 5.0 K1 M2
Continued from the preceding page.
Two blank columns are filled with the lead style code. Please refer to the 3 columns on the right for the appropriate code.
The last blank column is filled with the packaging code. (B: bulk, A: ammo pack)
Part Number Temp.
Char.
Rated
Voltage Capacitance
Dimensions
LxW
(mm)
Dimension
T
(mm)
Lead Space
F
(mm)
Lead Style
Code
Bulk
Lead Style
Code
Taping
RHSL12A472K0ppH01pXAL (Murata) 100Vdc 4700pF±10% 3.8×3.5 2.5 2.5 A2 DG
RHSL12A472K0ppH01pXAL (Murata) 100Vdc 4700pF±10% 3.8×3.5 2.5 5.0 K1 M2
RHSL12A682K0ppH01pXAL (Murata) 100Vdc 6800pF±10% 3.8×3.5 2.5 2.5 A2 DG
RHSL12A682K0ppH01pXAL (Murata) 100Vdc 6800pF±10% 3.8×3.5 2.5 5.0 K1 M2
RHSL12A103K0ppH01pXAL (Murata) 100Vdc 10000pF±10% 3.8×3.5 2.5 2.5 A2 DG
RHSL12A103K0ppH01pXAL (Murata) 100Vdc 10000pF±10% 3.8×3.5 2.5 5.0 K1 M2
RHSL12A153K0ppH01pXAL (Murata) 100Vdc 15000pF±10% 3.8×3.5 2.5 2.5 A2 DG
RHSL12A153K0ppH01pXAL (Murata) 100Vdc 15000pF±10% 3.8×3.5 2.5 5.0 K1 M2
RHSL12A223K0ppH01pXAL (Murata) 100Vdc 22000pF±10% 3.8×3.5 2.5 2.5 A2 DG
RHSL12A223K0ppH01pXAL (Murata) 100Vdc 22000pF±10% 3.8×3.5 2.5 5.0 K1 M2
RHSL12A333K0ppH01pXAL (Murata) 100Vdc 33000pF±10% 3.8×3.5 2.5 2.5 A2 DG
RHSL12A333K0ppH01pXAL (Murata) 100Vdc 33000pF±10% 3.8×3.5 2.5 5.0 K1 M2
RHSL12A473K0ppH01pXAL (Murata) 100Vdc 47000pF±10% 3.8×3.5 2.5 2.5 A2 DG
RHSL12A473K0ppH01pXAL (Murata) 100Vdc 47000pF±10% 3.8×3.5 2.5 5.0 K1 M2
RHSL12A683K0ppH01pXAL (Murata) 100Vdc 68000pF±10% 3.8×3.5 2.5 2.5 A2 DG
RHSL12A683K0ppH01pXAL (Murata) 100Vdc 68000pF±10% 3.8×3.5 2.5 5.0 K1 M2
RHSL12A104K0ppH01pXAL (Murata) 100Vdc 0.1µF±10% 3.8×3.5 2.5 2.5 A2 DG
RHSL12A104K0ppH01pXAL (Murata) 100Vdc 0.1µF±10% 3.8×3.5 2.5 5.0 K1 M2
RHSN12A472K0ppH01pXAN (Murata) 100Vdc 4700pF±10% 3.8×3.5 2.5 2.5 A2 DG
RHSN12A472K0ppH01pXAN (Murata) 100Vdc 4700pF±10% 3.8×3.5 2.5 5.0 K1 M2
RHSN12A682K0ppH01pXAN (Murata) 100Vdc 6800pF±10% 3.8×3.5 2.5 2.5 A2 DG
RHSN12A682K0ppH01pXAN (Murata) 100Vdc 6800pF±10% 3.8×3.5 2.5 5.0 K1 M2
RHSN12A103K0ppH01pXAN (Murata) 100Vdc 10000pF±10% 3.8×3.5 2.5 2.5 A2 DG
RHSN12A103K0ppH01pXAN (Murata) 100Vdc 10000pF±10% 3.8×3.5 2.5 5.0 K1 M2
RHSN12A153K0ppH01pXAN (Murata) 100Vdc 15000pF±10% 3.8×3.5 2.5 2.5 A2 DG
RHSN12A153K0ppH01pXAN (Murata) 100Vdc 15000pF±10% 3.8×3.5 2.5 5.0 K1 M2
RHSN12A223K0ppH01pXAN (Murata) 100Vdc 22000pF±10% 3.8×3.5 2.5 2.5 A2 DG
RHSN12A223K0ppH01pXAN (Murata) 100Vdc 22000pF±10% 3.8×3.5 2.5 5.0 K1 M2
RHSN12A333K1ppH01pXAN (Murata) 100Vdc 33000pF±10% 4.0×3.5 2.5 2.5 A2 DG
RHSN12A333K1ppH01pXAN (Murata) 100Vdc 33000pF±10% 4.0×3.5 2.5 5.0 K1 M2
RHSN12A473K1ppH01pXAN (Murata) 100Vdc 47000pF±10% 4.0×3.5 2.5 2.5 A2 DG
RHSN12A473K1ppH01pXAN (Murata) 100Vdc 47000pF±10% 4.0×3.5 2.5 5.0 K1 M2
RHSN12A683K1ppH01pXAN (Murata) 100Vdc 68000pF±10% 4.0×3.5 2.5 2.5 A2 DG
RHSN12A683K1ppH01pXAN (Murata) 100Vdc 68000pF±10% 4.0×3.5 2.5 5.0 K1 M2
RHSN12A104K1ppH01pXAN (Murata) 100Vdc 0.1µF±10% 4.0×3.5 2.5 2.5 A2 DG
RHSN12A104K1ppH01pXAN (Murata) 100Vdc 0.1µF±10% 4.0×3.5 2.5 5.0 K1 M2
RHSN12A154K2ppH01pXAN (Murata) 100Vdc 0.15µF±10% 5.5×4.0 3.15 2.5 A2 DG
RHSN12A154K2ppH01pXAN (Murata) 100Vdc 0.15µF±10% 5.5×4.0 3.15 5.0 K1 M2
RHSN12A224K2ppH01pXAN (Murata) 100Vdc 0.22µF±10% 5.5×4.0 3.15 2.5 A2 DG
RHSN12A224K2ppH01pXAN (Murata) 100Vdc 0.22µF±10% 5.5×4.0 3.15 5.0 K1 M2
High Dielectric Constant Type, XAL/XAN Characteristics
Two blank columns are filled with the lead style code. Please refer to the 3 columns on the right for the appropriate code.
The last blank column is filled with the packaging code. (B: bulk, A: ammo pack)
!Note • Please read rating and !CAUTION (for storage, operating, rating, soldering, mounting and handling) in this catalog to prevent smoking and/or burning, etc.
• This catalog has only typical specifications. Therefore, please approve our product specifications or transact the approval sheet for product specifications before ordering.
37
C49E.pdf
May 10,2018
3
Temperature Compensating Type Specifications and Test Methods
* “room condition” Temperature: 15 to 35°C, Relative humidity: 45 to 75%, Atmosphere pressure: 86 to 106kPa
Apply 25% of the rated voltage for 1000±12h at 200±5°C.
Let sit for 24±2h at room condition*, then measure
The charge/discharge current is less than 50mA.
6
Operational
Life
Appearance
No defects or abnormalities except color change of outer
coating
Capacitance
Change
Within ±3% or ±0.3pF (Whichever is larger)
QQ >
= 350
I.R. 1000MΩ min.
Three shocks in each direction should be applied along
3 mutually perpendicular axes of the test specimen (18 shocks).
The specified test pulse should be Half-sine and should have a
duration: 0.5ms, peak value: 1500G and velocity change:
4.7m/s.
11
Mechanical
Shock
Appearance
No defects or abnormalities
Capacitance
Within the specified tolerance
QQ >
= 1000
Per MIL-STD-202 Method 215
Solvent 1: 1 part (by volume) of isopropyl alcohol
3 parts (by volume) of mineral spirits
Solvent 2: Terpene defluxer
Solvent 3: 42 parts (by volume) of water
1part (by volume) of propylene glycol
monomethyl ether
1 part (by volume) of monoethanolamine
10
Resistance
to Solvents
Appearance
No defects or abnormalities
Capacitance
Within the specified tolerance
QQ >
= 1000
I.R. 10000MΩ min.
Visual inspection9 Marking To be easily legible
Using calipers and micrometers8 Physical Dimension Within the specified dimensions
Visual inspection7 External Visual No defects or abnormalities
Apply the rated voltage and DC1.3+0.2/-0 V (add 100kΩ resistor)
at 85±3°C and 80 to 85% humidity for 1000±12h.
Remove and let sit for 24±2h at room condition*, then measure.
The charge/discharge current is less than 50mA.
5Biased
Humidity
Appearance
No defects or abnormalities
Capacitance
Change
Within ±5% or ±0.5pF (Whichever is larger)
QQ >
= 200
I.R. 500MΩ min.
Apply the 24h heat (25 to 65°C) and humidity (80 to 98%)
treatment shown below, 10 consecutive times.
Let sit for 24±2h at room condition*, then measure.
4
Moisture
Resistance
Appearance
No defects or abnormalities
Capacitance
Change
Within ±5% or ±0.5pF (Whichever is larger)
QQ >
= 200
I.R. 500MΩ min.
Perform the 1000 cycles according to the four heat treatments
listed in the following table. Let sit for 24±2h at room condition*,
then measure.
3
Temperature
Cycling
Appearance
No defects or abnormalities except color change of outer
coating
Capacitance
Change
Within ±5% or ±0.5pF (Whichever is larger)
QQ >
= 350
I.R. 1000MΩ min.
Step 1
-55+0/-3
15±3
2
Room Temp.
1
3
125+3/-0
15±3
4
Room Temp.
1
Temp. (°C)
Time (min)
Sit the capacitor for 1000±12h at 200±5°C. Let sit for 24±2h at
room condition*, then measure.
2
High
Temperature
Exposure
(Storage)
Appearance
No defects or abnormalities except color change of outer
coating
Capacitance
Change
Within ±3% or ±0.3pF (Whichever is larger)
QQ >
= 350
I.R. 1000MΩ min.
1
Pre-and Post-Stress
Electrical Test
No. AEC-Q200 Test MethodSpecificationsAEC-Q200 Test Item
(°C)
70
65
60
55
50
45
40
35
30
25
20
15
10
5
0
-5
-10
Humidity
90-98%
Humidity
80-98%
Humidity
90-98%
Humidity
80-98%
Humidity
90-98%
+10
-2°C
Initial measurement
Temperature
One cycle = 24 hours
0123456789
1011 1213 1415 1617 1819 2021 2223 24
Hours
Continued on the following page.
!Note • Please read rating and !CAUTION (for storage, operating, rating, soldering, mounting and handling) in this catalog to prevent smoking and/or burning, etc.
• This catalog has only typical specifications. Therefore, please approve our product specifications or transact the approval sheet for product specifications before ordering.
38
C49E.pdf
May 10,2018
3
Temperature Compensating Type Specifications and Test Methods
Perform the 300 cycles according to the two heat treatments
listed in the following table (Maximum transfer time is 20s).
Let sit for 24±2h at room condition*, then measure.
14 Thermal
Shock
Appearance
No defects or abnormalities
Capacitance
Change
Within ±5% or ±0.5pF (Whichever is larger)
QQ >
= 350
I.R. 1000MΩ min.
Step 1
-55+0/-3
15±3
2
200+5/-0
15±3
Temp. (°C)
Time (min)
The lead wires should be immersed in the melted solder 1.5 to
2.0mm from the root of terminal at 260±5°C for 10±1s.
Post-treatment
Capacitor should be stored for 24±2h at room condition*.
13
-
1
Resistance to
Soldering Heat
(Non-Preheat)
Appearance
No defects or abnormalities
Capacitance
Change
Within ±2.5% or ±0.25pF (Whichever is larger)
Within ±2.5% or ±0.25pF (Whichever is larger)
Within ±2.5% or ±0.25pF (Whichever is larger)
Dielectric
Strength
(Between
Terminals)
No defects
First the capacitor should be stored at 120+0/-5°C for 60+0/-5s.
Then, the lead wires should be immersed in the melted solder
1.5 to 2.0mm from the root of terminal at 260±5°C for
7.5+0/-1s.
Post-treatment
Capacitor should be stored for 24±2h at room condition*.
13
-
2
Resistance to
Soldering Heat
(On-Preheat)
Appearance
No defects or abnormalities
Capacitance
Change
Dielectric
Strength
(Between
Terminals)
No defects
Test condition
Termperature of iron-tip: 350±10°C
Soldering time: 3.5±0.5s.
Soldering position
Straight Lead: 1.5 to 2.0mm from the root of terminal.
Crimp Lead: 1.5 to 2.0mm from the end of lead bend.
Post-treatment
Capacitor should be stored for 24±2h at room condition*.
13
-
3
Resistance to
Soldering Heat
(soldering
iron method)
Appearance
No defects or abnormalities
Capacitance
Change
Dielectric
Strength
(Between
Terminals)
No defects
The capacitor should be subjected to a simple harmonic motion
having a total amplitude of 1.5mm, the frequency being varied
uniformly between the approximate limits of 10 and 2000Hz.
The frequency range, from 10 to 2000Hz and return to 10Hz,
should be traversed in approximately 20min. This motion
should be applied for 12 items in each 3 mutually perpendicular
directions (total of 36 times).
12 Vibration
Appearance
No defects or abnormalities
Capacitance
Within the specified tolerance
QQ >
= 1000
No. AEC-Q200 Test MethodSpecificationsAEC-Q200 Test Item
Continued from the preceding page.
The terminal of a capacitor is dipped into a solution of ethanol
(JIS-K-8101) and rosin (JIS-K-5902) (25% rosin in weight
propotion) and then into molten solder (JIS-Z-3282) for 2±0.5s.
In both cases the depth of dipping is up to about 1.5 to 2mm
from the terminal body.
Temp. of solder:
245±5°C Lead Free Solder (Sn-3.0Ag-0.5Cu)
16 Solderability Lead wire should be soldered with uniform coating on the axial
direction over 95% of the circumferential direction.
Per AEC-Q200-002
15 ESD
Appearance
No defects or abnormalities
Capacitance
Within the specified tolerance
QQ >
= 1000
I.R. 10000MΩ min.
* “room condition” Temperature: 15 to 35°C, Relative humidity: 45 to 75%, Atmosphere pressure: 86 to 106kPa
Continued on the following page.
!Note • Please read rating and !CAUTION (for storage, operating, rating, soldering, mounting and handling) in this catalog to prevent smoking and/or burning, etc.
• This catalog has only typical specifications. Therefore, please approve our product specifications or transact the approval sheet for product specifications before ordering.
39
C49E.pdf
May 10,2018
3
Temperature Compensating Type Specifications and Test Methods
The capacitance change should be measured after 5min at
each specified temperature step.
The temperature coefficient is determind using the
capacitance measured in step 3 as a reference. When cycling
the temperature sequentially from step 1 through 5 (-55 to
+200°C) the capacitance should be within the specified
tolerance for the temperature coefficient.
The capacitance drift is caluculated by dividing the differences
betweeen the maximum and minimum measured values in the
step 1, 3 and 5 by the capacitance value in step 3.
19
Capacitance
Temperature
Characteristics
Step
1
2
3
4
5
Temperature (°C)
25±2
-55±3
25±2
200±5
25±2
Char. Temperature Coefficient
−55 to 25°C: 0+30/−72ppm/°C
25 to 125°C: 0±30ppm/°C
125 to 200°C: 0+72/−30ppm/°C
−55 to 25°C: −750+120/−347ppm/°C
25 to 125°C: −750±120ppm/°C
125 to 200°C: −750+347/−120ppm/°C
CCG
UNJ
Visual inspection
17
Electrical
Charac-
terization
Appearance
No defects or abnormalities
Rated Voltage Test Voltage
250% of the rated voltage
150% of the rated voltage
DC100V, DC200V
DC500V
As in the figure, fix the capacitor body, apply the force
gradually to each lead in the radial direction of the capacitor
until reaching 10N and then keep the force applied for 10±1s.
18 Terminal
Strength
Tensile
Strength
Termination not to be broken or loosened
Within the specified Tolerance
Each lead wire should be subjected to a force of 2.5N and then
be bent 90° at the point of egress in one direction. Each wire is
then returned to the original position and bent 90° in the
opposite direction at the rate of one bend per 2 to 3s.
Bending
Strength
F
The capacitance, Q should be measured at 25°C at the
frequency and voltage shown in the table.
Capacitance
Within the specified tolerance
QQ >
= 1000
The insulation resistance should be measured at 25±3°C with a
DC voltage not exceeding the rated voltage at normal
temperature and humidity and within 2min of charging.
(Charge/Discharge current <
= 50mA)
I.R.
Room Temperature 10000MΩ min.
The insulation resistance should be measured at 200±5°C with
a DC voltage not exceeding 25% of the rated voltage at normal
temperature and humidity and within 2min of charging.
(Charge/Discharge current <
= 50mA)
High Temperature 20MΩ min.
The capacitor should not be damaged when voltage in table is
applied between the terminations for 1 to 5s.
(Charge/Discharge current <
= 50mA.)
Between Terminals No defects or abnormalities
The capacitor is placed in a container with
metal balls of 1mm diameter so that each
terminal, short-circuit, is kept approximately
2mm from the balls as shown in the figure,
and voltage in table is impressed for 1 to 5s
between capacitor terminals and
metal balls.
(Charge/Discharge current <
= 50mA.)
Dielectric
Strength
Body Insulation No defects or abnormalities
Nominal Cap.
C < 1000pF
C >
= 1000pF
Frequency
1±0.1MHz
1±0.1kHz
Voltage
AC0.5 to 5V (r.m.s.)
AC1±0.2V (r.m.s.)
No. AEC-Q200 Test MethodSpecificationsAEC-Q200 Test Item
Rated Voltage Test Voltage
300% of the rated voltage
250% of the rated voltage
150% of the rated voltage
DC100V
DC200V
DC500V
Continued from the preceding page.
Approx. 2mm
Metal balls
!Note • Please read rating and !CAUTION (for storage, operating, rating, soldering, mounting and handling) in this catalog to prevent smoking and/or burning, etc.
• This catalog has only typical specifications. Therefore, please approve our product specifications or transact the approval sheet for product specifications before ordering.
40
C49E.pdf
May 10,2018
3
High Dielectric Constant Type Specifications and Test Methods
* “room condition” Temperature: 15 to 35°C, Relative humidity: 45 to 75%, Atmosphere pressure: 86 to 106kPa
Per MIL-STD-202 Method 215
Solvent 1: 1 part (by volume) of isopropyl alcohol
3 parts (by volume) of mineral spirits
Solvent 2: Terpene defluxer
Solvent 3: 42 parts (by volume) of water
1part (by volume) of propylene glycol
monomethyl ether
1 part (by volume) of monoethanolamine
10
Resistance
to Solvents
Appearance
No defects or abnormalities
Apply 50% of the rated voltage for 1000±12h at 175±5
°C
.
Let sit for 24±2h at room condition*, then measure.
The charge/discharge current is less than 50mA.
F0#20#2+#,2
Apply test voltage for 60±5min at test temperature.
Remove and let sit for 24±2h at room condition*.
6
Operational
Life
Apply the rated voltage and DC1.3+0.2/-0 V (add 100kΩ resistor)
at 85±3°C and 80 to 85% humidity for 1000±12h.
Remove and let sit for 24±2h at room condition*, then measure.
The charge/discharge current is less than 50mA.
F0#20#2+#,2
Perform the heat treatment at 150+0/-10°C for 1h and then let
sit for 24±2h at room condition*.
5Biased
Humidity
Appearance
No defects or abnormalities
Capacitance
Change
Within ±12.5%
D.F. Char. XAL: 0.075 max.
Char. XAN: 0.05 max.
I.R. 500MΩ or 25MΩ F μF min. (Whichever is smaller)
Apply the 24h heat (25 to 65°C) and humidity (80 to 98%)
treatment shown below, 10 consecutive times.
Let sit for 24±2h at room condition*, then measure.
F0#20#2+#,2
Perform the heat treatment at 150+0/-10°C for 1h and then
let sit for 24±2h at room condition*.
4
Moisture
Resistance
Appearance
No defects or abnormalities
Capacitance
Change
Within ±12.5%
D.F. Char. XAL: 0.075 max.
Char. XAN: 0.05 max.
I.R. 500MΩ or 25MΩ F μF min. (Whichever is smaller)
Perform the 1000 cycles according to the four heat treatments
listed in the following table. Let sit for 24±2h at room condition*,
then measure.
F0#20#2+#,2
Perform the heat treatment at 150+0/-10°C for 1h and
then let sit for 24±2h at room condition*.
3
Temperature
Cycling
Appearance
No defects or abnormalities except color change of outer
coating
Capacitance
Change
Within ±12.5%
D.F. Char. XAL: 0.075 max.
Char. XAN: 0.05 max.
I.R. 1000MΩ or 50MΩ F μF min. (Whichever is smaller)
Sit the capacitor for 1000±12h at 175±5°C. Let sit for 24±2h
at room condition*, then measure.
F0#20#2+#,2
Perform the heat treatment at 150+0/-10°C for 1h and then
let sit for 24±2h at room condition*.
2
High
Temperature
Exposure
(Storage)
Appearance
No defects or abnormalities except color change of outer
coating
Capacitance
Change
Within ±12.5%
D.F. Char. XAL: 0.075 max.
Char. XAN: 0.04 max.
I.R. 1000MΩ or 50MΩ F μF min. (Whichever is smaller)
1
Pre-and Post-Stress
Electrical Test
No. AEC-Q200 Test MethodSpecificationsAEC-Q200 Test Item
(°C)
70
65
60
55
50
45
40
35
30
25
20
15
10
5
0
-5
-10
Humidity
90-98%
Humidity
80-98%
Humidity
90-98%
Humidity
80-98%
Humidity
90-98%
+10
-2°C
Initial measurement
Temperature
One cycle = 24 hours
0123456789
1011 1213 1415 1617 1819 2021 2223 24
Hours
Step 1
-55+0/-3
15±3
2
Room Temp.
1
3
175+5/-0
15±3
4
Room Temp.
1
Temp. (°C)
Time (min)
Appearance
No defects or abnormalities except color change of outer
coating
Capacitance
Change
Within ±15%
D.F. Char. XAL: 0.075 max.
Char. XAN: 0.04 max.
I.R. 100MΩ or 5MΩ F μF min. (Whichever is smaller)
Capacitance
Within the specified tolerance
D.F. Char. XAL: 0.075 max.
Char. XAN: 0.025 max.
I.R. 10000MΩ or 500MΩ F μF min. (Whichever is smaller)
Visual inspection9 Marking To be easily legible
Using calipers and micrometers8 Physical Dimension Within the specified dimensions
Visual inspection7 External Visual No defects or abnormalities
Continued on the following page.
!Note • Please read rating and !CAUTION (for storage, operating, rating, soldering, mounting and handling) in this catalog to prevent smoking and/or burning, etc.
• This catalog has only typical specifications. Therefore, please approve our product specifications or transact the approval sheet for product specifications before ordering.
41
C49E.pdf
May 10,2018
3
High Dielectric Constant Type Specifications and Test Methods
The terminal of a capacitor is dipped into a solution of ethanol
(JIS-K-8101) and rosin (JIS-K-5902) (25% rosin in weight
propotion) and then into molten solder (JIS-Z-3282) for 2±0.5s.
In both cases the depth of dipping is up to about 1.5 to 2mm
from the terminal body.
Temp. of solder :
245±5°C Lead Free Solder (Sn-3.0Ag-0.5Cu)
16 Solderability Lead wire should be soldered with uniform coating on the axial
direction over 95% of the circumferential direction.
Per AEC-Q200-002
15 ESD
Appearance
No defects or abnormalities
Capacitance
Within the specified tolerance
D.F. Char. XAL: 0.075 max.
Char. XAN: 0.025 max.
I.R. 10000MΩ or 500MΩ F μF min. (Whichever is smaller)
Perform the 300 cycles according to the two heat treatments
listed in the following table (Maximum transfer time is 20s).
Let sit for 24±2h at room condition*, then measure.
F0#20#2+#,2
Perform the heat treatment at 150+0/-10°C for 1h and then
let sit for 24±2h at room condition*.
14 Thermal
Shock
Appearance
No defects or abnormalities
Capacitance
Change
Within ±12.5%
D.F. Char. XAL: 0.075 max.
Char. XAN: 0.05 max.
I.R. 1000MΩ or 50MΩ F μF min. (Whichever is smaller)
Step 1
-55+0/-3
15±3
2
175+5/-0
15±3
Temp. (°C)
Time (min)
Appearance
13
-
3
Resistance to
Soldering Heat
(Soldering
Iron Method)
No defects or abnormalities
Capacitance
Change
Within ±7.5%
Dielectric
Strength
(Between
Terminals)
No defects
Test condition
Termperature of iron-tip: 350±10°C
Soldering time: 3.5±0.5s
Soldering position
Straight Lead: 1.5 to 2.0mm from the root of terminal.
Crimp Lead: 1.5 to 2.0mm from the end of lead bend.
F0#20#2+#,2
Perform the heat treatment at 150+0/-10°C for 1h and then
let sit for 24±2h at room condition*.
F-12Q20#2+#,2
Capacitor should be stored for 24±2h at room condition*.
The lead wires should be immersed in the melted solder 1.5 to
2.0mm from the root of terminal at 260±5°C for 10±1s.
F0#20#2+#,2
Perform the heat treatment at 150+0/-10°C for 1h and then
let sit for 24±2h at room condition*.
F-12Q20#2+#,2
Capacitor should be stored for 24±2h at room condition*.
13
-
1
Resistance to
Soldering Heat
(Non-Preheat)
Appearance
Appearance
No defects or abnormalities
Capacitance
Change
Within ±7.5%
Dielectric
Strength
(Between
Terminals)
No defects
13
-
2
Resistance to
Soldering Heat
(On-Preheat)
No defects or abnormalities
Capacitance
Change
Within ±7.5%
Dielectric
Strength
(Between
Terminals)
No defects
The capacitor should be subjected to a simple harmonic motion
having a total amplitude of 1.5mm, the frequency being varied
uniformly between the approximate limits of 10 and 2000Hz.
The frequency range, from 10 to 2000Hz and return to 10Hz,
should be traversed in approximately 20min. This motion should
be applied for 12 items in each 3 mutually perpendicular
directions (total of 36 times).
12 Vibration
Appearance
No defects or abnormalities
Capacitance
Within the specified tolerance
D.F. Char. XAL: 0.075 max.
Char. XAN: 0.025 max.
Three shocks in each direction should be applied along 3
mutually perpendicular axes of the test specimen (18 shocks).
The specified test pulse should be Half-sine and should have a
duration: 0.5ms, peak value: 1500G and velocity change: 4.7m/s.
11
Mechanical
Shock
Appearance
No defects or abnormalities
Capacitance
Within the specified tolerance
D.F. Char. XAL: 0.075 max.
Char. XAN: 0.025 max.
No. AEC-Q200 Test MethodSpecificationsAEC-Q200 Test Item
First the capacitor should be stored at 120+0/-5°C for 60+0/-5s.
Then, the lead wires should be immersed in the melted solder
1.5 to 2.0mm from the root of terminal at 260±5°C for
7.5+0/-1s.
F0#20#2+#,2
Perform the heat treatment at 150+0/-10°C for 1h and then
let sit for 24±2h at room condition*.
F-12Q20#2+#,2
Capacitor should be stored for 24±2h at room condition*.
Continued from the preceding page.
* “room condition” Temperature: 15 to 35°C, Relative humidity: 45 to 75%, Atmosphere pressure: 86 to 106kPa
Continued on the following page.
!Note • Please read rating and !CAUTION (for storage, operating, rating, soldering, mounting and handling) in this catalog to prevent smoking and/or burning, etc.
• This catalog has only typical specifications. Therefore, please approve our product specifications or transact the approval sheet for product specifications before ordering.
42
C49E.pdf
May 10,2018
3
High Dielectric Constant Type Specifications and Test Methods
* “room condition” Temperature: 15 to 35°C, Relative humidity: 45 to 75%, Atmosphere pressure: 86 to 106kPa
The capacitance change should be measured after 5min at
each specified temperature step.
The ranges of capacitance change compared with the above
25°C value over the temperature ranges shown in the table
should be within the specified ranges.
F0#20#2+#,2
Perform the heat treatment at 150+0/-10°C for 1h and then
let sit for 24±2h at room condition*.
Perform the initial measurement.
19
Capacitance
Temperature
Characteristics
Step
1
2
3
4
5
Temperature (°C)
25±2
-55±3
25±2
175±5
25±2
As in the figure, fix the capacitor body, apply the force
gradually to each lead in the radial direction of the capacitor
until reaching 10N and then keep the force applied for 10±1s.
18 Terminal
Strength
Tensile
Strength
Termination not to be broken or loosened
Each lead wire should be subjected to a force of 2.5N and then
be bent 90° at the point of egress in one direction. Each wire is
then returned to the original position and bent 90° in the
opposite direction at the rate of one bend per 2 to 3s.
Bending
Strength
F
Visual inspection
17
Electrical
Charac-
terization
Appearance
No defects or abnormalities
The capacitance, D.F. should be measured at 25°C at the
frequency and voltage shown in the table.
Capacitance
Within the specified tolerance
D.F. Char. XAL: 0.075 max.
Char. XAN: 0.025 max.
I.R.
Room Temperature 10000MΩ or 500MΩ F μF min.
(Whichever is smaller)
Approx. 2mm
Metal balls
The capacitor should not be damaged when DC voltage of
250% of the rated voltage is applied between the terminations
for 1 to 5s.
(Charge/Discharge current <
= 50mA.)
Between Terminals No defects or abnormalities
The capacitor is placed in a container with
metal balls of 1mm diameter so that each
terminal, short-circuit, is kept approximately
2mm from the balls as shown in the figure,
and 250% of the rated DC voltage is
impressed for 1 to 5s between capacitor
terminals and metal balls.
(Charge/Discharge current <
= 50mA.)
Dielectric
Strength
Body Insulation No defects or abnormalities
Frequency
1±0.1kHz
Voltage
AC1±0.2V (r.m.s.)
No. AEC-Q200 Test MethodSpecificationsAEC-Q200 Test Item
Continued from the preceding page.
The insulation resistance should be measured at 25±3°C with a
DC voltage not exceeding the rated voltage at normal
temperature and humidity and within 2min of charging.
(Charge/Discharge current <
= 50mA)
High Temperature 10MΩ or 0.5MΩ F μF min.
(Whichever is smaller)
The insulation resistance should be measured at 175±5°C with
a DC voltage not exceeding 50% of the rated voltage at normal
temperature and humidity and within 2min of charging.
(Charge/Discharge current <
= 50mA)
Char. Capacitance Change
−55 to 150°C: Within ±15%
150 to 175°C: Within+15/−40%
−55 to 125°C: Within ±15%
125 to 175°C: Within+15/−60%
XAL
XAN
Within the specified Tolerance
!Note • Please read rating and !CAUTION (for storage, operating, rating, soldering, mounting and handling) in this catalog to prevent smoking and/or burning, etc.
• This catalog has only typical specifications. Therefore, please approve our product specifications or transact the approval sheet for product specifications before ordering.
43
C49E.pdf
May 10,2018
3
Features
1. Small size and large capacitance
2. Low ESR characteristics for high frequency
3. Meet LF (Lead Free) and HF (Halogen Free)
4. Flow soldering is available, but re-flow soldering
is not available.
Applications
General electronic equipment
(Do not use for automotive-related power train and
safety equipment.)
(in mm)
L max.
ød: 0.5±0.05
T max.
W max.25.0 min.
W1 max.
F±0.8
*
* Coating extension does not exceed the end of the lead bend.
· Lead Wire: Solder Coated CP Wire
Dimensions code: 0/1/2/3
Lead style code: P1
Leaded MLCC for General Purpose
RDE Series (DC25V-DC1kV)
Dimensions and
Lead Style Code
Dimensions (mm)
L W W1 T F d
0P1/0S1
0K1/0M1
1P1/1S1
1K1/1M1
2P1/2S1
2K1/2M1
3P1/3S1
3K1/3M1
4K1/4M1
5B1/5E1
UB1/UE1
WK1/WM1
0.5
0.5
0.5
0.5
0.5
0.5
0.5
0.5
0.5
0.5
0.5
0.5
2.5
5.0
2.5
5.0
2.5
5.0
2.5
5.0
5.0
5.0
5.0
5.0
6.0
6.0
5.0
5.0
6.0
6.0
7.5
7.5
8.0
-
-
10.0
3.5
3.5
3.5
3.5
4.0
4.0
5.0
5.0
5.5
7.5*
12.5*
7.5
5.0
4.0
5.0
4.5
5.5
5.5
5.5
5.5
7.5
7.5
7.7
5.5
See the individual
product specification
*DC630V, DC1kV: W+0.5mm
!Note • Please read rating and !CAUTION (for storage, operating, rating, soldering, mounting and handling) in this catalog to prevent smoking and/or burning, etc.
• This catalog has only typical specifications. Therefore, please approve our product specifications or transact the approval sheet for product specifications before ordering.
44
C49E.pdf
May 10,2018
4
(in mm)
* Coating extension does not exceed the end of the lead bend.
· Lead Wire: Solder Coated CP Wire
ød: 0.5±0.05
T max.L max.
W max.25.0 min.
W1 max.
F±0.8
*
Dimensions code: 0/1
Lead style code: K1
(in mm)
* Coating extension does not exceed the end of the lead bend.
· Lead Wire: Solder Coated CP Wire
ød: 0.5±0.05
T max.L max.
W max.25.0 min.
W1 max.
F±0.8
*
Dimensions code: 2/3/4
Lead style code: K1
(in mm)
T max.
L max.
ød: 0.5±0.05
W max.25.0 min.
1.5 max.
F±0.8
· Lead Wire: Solder Coated CP Wire
Dimensions code: 5
Lead style code: B1
(in mm)
L max.
2.0 max.
F±0.8
W max.
25.0 min.
T max.
· Lead Wire: Solder Coated CP Wire
ød: 0.5±0.05
Dimensions code: U
Lead style code: B1
(in mm)
* Coating extension does not exceed the end of the lead bend.
· Lead Wire: Solder Coated CP Wire
ød: 0.5±0.05
T max.L max.
W max.25.0 min.
W1 max.
F±0.8
*
Dimensions code: W
Lead style code: K1
Dimensions
3, 4, W
0
1
5, U
2
105
K1C
M
224K
104K
475
K2C
M
224K
226
K2C
M
105
K5C
M
224K
335
K5C
M
225
K1C
M
153
K7C
M
(X7R)
472
J7U
M
(U2J)
(X7R)
474
M7C
M
(U2J)
333
J7U
M
(X7R)
104
K7C
M
(U2J)
103
J7U
M
332
J7A
M
(C0G)
102
JAU
M
(U2J)
(X7R)
102
KAC
M
(X7R)
104
KAC
M
(U2J)
103
JAU
M
(X7R)
333
KAC
M
(U2J)
472
JAU
M
(C0G)
102
JAA
M
475
K5C
M
226
K5C
M
A
102J
563
J5A
M
A
102J
103
J1A
M
103
J4U
M
(U2J)
473
K4C
M
(X7R)
(X7R)
474
K4C
M
474
K9C
M
(X7R)
224
K4C
M
(U2J)
473
J4U
M
153
J4A
M
(C0G)
U
102J
(U2J)
102K
(X7R)
(X7R)
153
K9C
M
103K
(X7R)
(X7R)
104
K9C
M
(X7R)
Temperature
Characteristics
Nominal Capacitance
Capacitance Tolerance
Rated Voltage
Manufacturer's
Identification
Under 100pF: Actual value 100pF and over: Marked with 3 figures
Marked with code (C0G char.: A, X7S/X7R char.: C, U2J char.: U)
A part is omitted (Please refer to the marking example.)
Marked with code
A part is omitted (Please refer to the marking example.)
Marked with code (DC25V: 2, DC50V: 5, DC100V: 1, DC250V: 4, DC500V: 9, DC630V: 7, DC1kV: A)
A part is omitted (Please refer to the marking example.)
M
Marked with
A part is omitted (Please refer to the marking example.)
C0G
DC25V DC50V DC100V
DC250V DC500V DC630V
X7S X7R X7S X7R X7S X7R X7R, U2J, C0GC0G
DC1kV
Dimensions
Code
Rated
Voltage
Temp.
Char.
Marking
Part Number Temp.
Char.
Rated
Voltage Capacitance
Dimensions
LxW
(mm)
Dimension
T
(mm)
Lead Space
F
(mm)
Lead Style
Code
Bulk
Lead Style
Code
Taping
RDE5C1H1R0C0ppH03pC0G (EIA) 50Vdc 1.0pF±0.25pF 4.0×3.5 2.5 5.0 K1 M1
RDE5C1H1R0C0ppH03pC0G (EIA) 50Vdc 1.0pF±0.25pF 5.0×3.5 2.5 2.5 P1 S1
RDE5C1H2R0C0ppH03pC0G (EIA) 50Vdc 2.0pF±0.25pF 4.0×3.5 2.5 5.0 K1 M1
RDE5C1H2R0C0ppH03pC0G (EIA) 50Vdc 2.0pF±0.25pF 5.0×3.5 2.5 2.5 P1 S1
RDE5C1H3R0C0ppH03pC0G (EIA) 50Vdc 3.0pF±0.25pF 4.0×3.5 2.5 5.0 K1 M1
RDE5C1H3R0C0ppH03pC0G (EIA) 50Vdc 3.0pF±0.25pF 5.0×3.5 2.5 2.5 P1 S1
RDE5C1H4R0C0ppH03pC0G (EIA) 50Vdc 4.0pF±0.25pF 4.0×3.5 2.5 5.0 K1 M1
RDE5C1H4R0C0ppH03pC0G (EIA) 50Vdc 4.0pF±0.25pF 5.0×3.5 2.5 2.5 P1 S1
RDE5C1H5R0C0ppH03pC0G (EIA) 50Vdc 5.0pF±0.25pF 4.0×3.5 2.5 5.0 K1 M1
RDE5C1H5R0C0ppH03pC0G (EIA) 50Vdc 5.0pF±0.25pF 5.0×3.5 2.5 2.5 P1 S1
Continued on the following page.
Temperature Compensating Type, C0G/U2J Characteristics
!Note • Please read rating and !CAUTION (for storage, operating, rating, soldering, mounting and handling) in this catalog to prevent smoking and/or burning, etc.
• This catalog has only typical specifications. Therefore, please approve our product specifications or transact the approval sheet for product specifications before ordering.
45
C49E.pdf
May 10,2018
4
Continued from the preceding page.
Part Number Temp.
Char.
Rated
Voltage Capacitance
Dimensions
LxW
(mm)
Dimension
T
(mm)
Lead Space
F
(mm)
Lead Style
Code
Bulk
Lead Style
Code
Taping
RDE5C1H6R0D0ppH03pC0G (EIA) 50Vdc 6.0pF±0.5pF 4.0×3.5 2.5 5.0 K1 M1
RDE5C1H6R0D0ppH03pC0G (EIA) 50Vdc 6.0pF±0.5pF 5.0×3.5 2.5 2.5 P1 S1
RDE5C1H7R0D0ppH03pC0G (EIA) 50Vdc 7.0pF±0.5pF 4.0×3.5 2.5 5.0 K1 M1
RDE5C1H7R0D0ppH03pC0G (EIA) 50Vdc 7.0pF±0.5pF 5.0×3.5 2.5 2.5 P1 S1
RDE5C1H8R0D0ppH03pC0G (EIA) 50Vdc 8.0pF±0.5pF 4.0×3.5 2.5 5.0 K1 M1
RDE5C1H8R0D0ppH03pC0G (EIA) 50Vdc 8.0pF±0.5pF 5.0×3.5 2.5 2.5 P1 S1
RDE5C1H9R0D0ppH03pC0G (EIA) 50Vdc 9.0pF±0.5pF 4.0×3.5 2.5 5.0 K1 M1
RDE5C1H9R0D0ppH03pC0G (EIA) 50Vdc 9.0pF±0.5pF 5.0×3.5 2.5 2.5 P1 S1
RDE5C1H100J0ppH03pC0G (EIA) 50Vdc 10pF±5% 4.0×3.5 2.5 5.0 K1 M1
RDE5C1H100J0ppH03pC0G (EIA) 50Vdc 10pF±5% 5.0×3.5 2.5 2.5 P1 S1
RDE5C1H120J0ppH03pC0G (EIA) 50Vdc 12pF±5% 4.0×3.5 2.5 5.0 K1 M1
RDE5C1H120J0ppH03pC0G (EIA) 50Vdc 12pF±5% 5.0×3.5 2.5 2.5 P1 S1
RDE5C1H150J0ppH03pC0G (EIA) 50Vdc 15pF±5% 4.0×3.5 2.5 5.0 K1 M1
RDE5C1H150J0ppH03pC0G (EIA) 50Vdc 15pF±5% 5.0×3.5 2.5 2.5 P1 S1
RDE5C1H180J0ppH03pC0G (EIA) 50Vdc 18pF±5% 4.0×3.5 2.5 5.0 K1 M1
RDE5C1H180J0ppH03pC0G (EIA) 50Vdc 18pF±5% 5.0×3.5 2.5 2.5 P1 S1
RDE5C1H220J0ppH03pC0G (EIA) 50Vdc 22pF±5% 4.0×3.5 2.5 5.0 K1 M1
RDE5C1H220J0ppH03pC0G (EIA) 50Vdc 22pF±5% 5.0×3.5 2.5 2.5 P1 S1
RDE5C1H270J0ppH03pC0G (EIA) 50Vdc 27pF±5% 4.0×3.5 2.5 5.0 K1 M1
RDE5C1H270J0ppH03pC0G (EIA) 50Vdc 27pF±5% 5.0×3.5 2.5 2.5 P1 S1
RDE5C1H330J0ppH03pC0G (EIA) 50Vdc 33pF±5% 4.0×3.5 2.5 5.0 K1 M1
RDE5C1H330J0ppH03pC0G (EIA) 50Vdc 33pF±5% 5.0×3.5 2.5 2.5 P1 S1
RDE5C1H390J0ppH03pC0G (EIA) 50Vdc 39pF±5% 4.0×3.5 2.5 5.0 K1 M1
RDE5C1H390J0ppH03pC0G (EIA) 50Vdc 39pF±5% 5.0×3.5 2.5 2.5 P1 S1
RDE5C1H470J0ppH03pC0G (EIA) 50Vdc 47pF±5% 4.0×3.5 2.5 5.0 K1 M1
RDE5C1H470J0ppH03pC0G (EIA) 50Vdc 47pF±5% 5.0×3.5 2.5 2.5 P1 S1
RDE5C1H560J0ppH03pC0G (EIA) 50Vdc 56pF±5% 4.0×3.5 2.5 5.0 K1 M1
RDE5C1H560J0ppH03pC0G (EIA) 50Vdc 56pF±5% 5.0×3.5 2.5 2.5 P1 S1
RDE5C1H680J0ppH03pC0G (EIA) 50Vdc 68pF±5% 4.0×3.5 2.5 5.0 K1 M1
RDE5C1H680J0ppH03pC0G (EIA) 50Vdc 68pF±5% 5.0×3.5 2.5 2.5 P1 S1
RDE5C1H820J0ppH03pC0G (EIA) 50Vdc 82pF±5% 4.0×3.5 2.5 5.0 K1 M1
RDE5C1H820J0ppH03pC0G (EIA) 50Vdc 82pF±5% 5.0×3.5 2.5 2.5 P1 S1
RDE5C1H101J0ppH03pC0G (EIA) 50Vdc 100pF±5% 4.0×3.5 2.5 5.0 K1 M1
RDE5C1H101J0ppH03pC0G (EIA) 50Vdc 100pF±5% 5.0×3.5 2.5 2.5 P1