D223M39Z5UH65J5R [VISHAY]
CAP CER 0.022UF 100V Z5U RADIAL;型号: | D223M39Z5UH65J5R |
厂家: | VISHAY |
描述: | CAP CER 0.022UF 100V Z5U RADIAL |
文件: | 总18页 (文件大小:381K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
General Information
Vishay BCcomponents
www.vishay.com
Ceramic Disc, RFI and Safety Capacitors
IN ACCORDANCE WITH IEC RECOMMENDATIONS CERAMIC CAPACITORS ARE SUBDIVIDED
INTO TWO CLASSES:
• CERAMIC CLASS 1 or low-K capacitors are mainly manufactured of titanium dioxide or magnesium silicate
• CERAMIC CLASS 2 or high-K capacitors contain mostly alkaline titanates
• Material categorization: for definitions of compliance please see www.vishay.com/doc?99912
MAIN FEATURES
CLASS 1
CLASS 2
For temperature compensation of frequency
discriminating circuits and filters, coupling and
decoupling in high-frequency circuits where low
losses and narrow capacitance tolerances are
demanded. As RFI and safety capacitors.
As coupling and decoupling capacitors for such
application where higher losses and a reduced
capacitance stability are required.
APPLICATION
As RFI and safety capacitors
High stability of capacitance. Low dissipation
factor up to higher frequencies. Defined
temperature coefficient of capacitance, positive
or negative, linear and reversible. High insulation
resistance. No voltage dependence. High
long-term stability of electrical values.
PROPERTIES
Temperature dependence
capacitance
High capacitance values with small dimensions.
Non-linear dependence of capacitance on
temperature.
DC VOLTAGE
Capacitance dependence
None
Increasing with
DISSIPATION FACTOR TAN
Max. 0.15 % (typical)
Max. 3.5 % (typical)
INSULATION RESISTANCE
10 G
1 G
< 10 pF: 0.25 pF, 0.5 pF, 1 pF
10 pF: 2 %, 5 %, 10 %, 20 %
CAPACITANCE TOLERANCES
RATED VOLTAGE
10 %, 20 %, (ꢀ 80/- 20) %
Up to 6 kVDC
Up to 6 kVDC
STANDARDS AND SPECIFICATIONS
GENERAL STANDARDS
IEC 60062
Marking codes for resistors and capacitors
IEC 60068
Basic environmental testing procedures
SPECIAL STANDARDS FOR CERAMIC CAPACITORS
EN 130600 and IEC 60384-8
EN 130700 and IEC 60384-9
STANDARD FOR SPECIAL APPLICATION PURPOSES
CSA C22.2
Fixed capacitors of ceramic dielectric, class 1
Fixed capacitors of ceramic dielectric, class 2
EN 132400
IEC 60065
RFI - and safety capacitors
IEC 60384-14.3
UL60384-14
VDE 0560, part 2’5.70 and VDE 0860/8.81
Revision: 31-Jul-15
Document Number: 28536
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MEASURING AND TESTING CONDITIONS
CLASS 1
CLASS 2
C 100 pF
C 1000 pF
1 kHz, 1 VRMS to 5 VRMS
C < 1000 pF
1 kHz, 1.0 VRMS 0.2 VRMS
C < 100 pF
CAPACITANCE AND DISSIPATION FACTOR
1 MHz, 1 VRMS to 5 VRMS
Rated voltage < 100 V:
1 MHz, 1.0 VRMS 0.2 VRMS
measuring voltage = (10 1) V
measuring voltage = (100 15) V
measuring voltage = (500 50) V
60 s 5 s
100 V to < 500 V:
500 V:
Measuring time:
INSULATION RESISTANCE TEMPERATURE
DEPENDENCE CAPACITANCE
Rated voltage 500 V:
> 500 V:
Test voltage = 2.5 x UR
measuring voltage = 1.5 x UR
2 s
DIELECTRIC STRENGTH
Measuring time:
Notes
•
•
Climatic test conditions: temperature 20 °C to 25 °C
Relative humidity 50 % to 70 %
NOMINAL VALUE SERIES ACCORDING TO IEC 60063
E6 ( 2ꢀ ꢁ TOLERANCE)
E12 ( 1ꢀ ꢁ TOLERANCE)
E24 ( ꢂ ꢁ TOLERANCE)
100
100
-
100
110
120
130
150
160
180
200
220
240
270
300
330
360
390
430
470
510
560
620
680
750
820
910
-
-
120
-
-
150
150
-
-
-
180
-
-
220
220
-
-
-
270
-
-
330
330
-
-
-
390
-
-
470
470
-
-
-
560
-
-
680
680
-
-
-
-
820
-
Note
•
E6 values preferred
Revision: 31-Jul-15
Document Number: 28536
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CAPACITANCE CODING SYSTEM
CODE
p33
CAPACITANCE VALUE
0.33 pF
3p3
3.3 pF
33p
33 pF
330p
n33
330 pF
CAPACITANCE VALUE
330 pF (0.33 nF)
3300 pF (3.3 nF)
33 000 pF (33 nF)
330 000 pF (330 nF)
0.33 μF
3n3
33n
330n
μ33
3μ3
3.3 μF
C-TOLERANCE
< 1ꢀ pF (pF)
C-TOLERANCE
1ꢀ pF (ꢁ)
CODE LETTER
C
0.25
-
D
0.5
0.5
G
-
-
-
-
-
2
CAPACITANCE TOLERANCE
J
5
10
K
M
20
Z
ꢀ 80/- 20
RATED VOLTAGE
CLEAR TEXT
CLASS 1
CLASS 2
NP0 (C0G)
N750 (U2J)
SL0
X7R
Y5P
Z5U
Z5V
Y5V
Y5U
CERAMIC DIELECTRIC
S3N
Note
The actual markings are given in detail on the respective datasheet.
•
PRODUCTION CODE ACCORDING TO IEC 60062
• The production code is indicated with a 4 FIGURE CODE (YEAR/WEEK)
• The 1st two figures indicate the year and the second two figures indicate the week.
Examples:
18th Week 1998 = 9818
50th Week 1999 = 9950
32nd Week 2000 = 0032
41st Week 2001 = 0141
27th Week 2002 = 0227
22nd Week 2003 = 0322
15th Week 2004 = 0415
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Document Number: 28536
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MARKING OF THE TEMPERATURE CHARACTERISTIC OF CAPACITANCE FOR CLASS 2 CERAMIC
CAPACITORS
According to EN 13ꢀ7ꢀꢀ or IEC 6ꢀ384-9
2
D
3
Marking for class 2
ceramic capacitor
Admissible capacitance change
related to 20 °C over the
Temperature range:
upper and lower
entire temperature range
temperature limits in °C
DC VOLTAGE
CODE
TEMPERATURE
CODE
LETTER
RANGE
FIGURE
WITHOUT
10 %
WITH
ꢀ 10 %/- 15 %
ꢀ 20 %/- 30 %
B
C
D
E
F
-55 to ꢀ125
-55 to ꢀ85
-40 to ꢀ85
-25 to ꢀ85
-10 to ꢀ85
1
2
3
4
5
20 %
ꢀ 20 %/- 30 % ꢀ 20 %/- 40 %
ꢀ 22 %/ - 56 % ꢀ 22 %/- 70 %
ꢀ 30 %/- 80 % ꢀ 30 %/- 90 %
15 %
15 %
ꢀ 15 %/- 40 %
ꢀ 15 %/- 25 %
R
X
According to EIA Standard RS 198
Y
ꢂ
S
Lower category temperature
Upper category temperature
Admissible capacitance change
related to 25 °C over the
entire temperature range
TEMPERATURE
-55 °C
CODE LETTER
TEMPERATURE
ꢀ45 °C
CODE FIGURE
CHANGE
1 %
CODE LETTER
X
Y
Z
2
4
5
6
7
A
B
C
D
E
F
-30 °C
ꢀ65 °C
1.5 %
ꢀ10 °C
ꢀ85 °C
2.2 %
ꢀ105 °C
3.3 %
ꢀ125 °C
4.7 %
7.5 %
10 %
P
R
S
T
15 %
22 %
ꢀ 22 %/- 33 %
ꢀ 22 %/- 56 %
ꢀ 22 %/- 82 %
U
V
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CLASS 1 CERAMIC TYPE
TEMPERATURE COEFFICIENT OF THE CAPACITANCE FOR CLASS 1 CERAMIC CAPACITORS
C = capacitance change
C
C
= temperature coefficient in 10-6/°C
= temperature change in °C
-------
% = 100 x x
5
4
50
40
3
2
30
20
1
10
N750 (U2J)
NP0 (C0G)
0
NP0 (C0G)
0
N750 (U2J)
-1
-2
-10
-20
-3
-4
-5
-30
-40
-50
-55 -40 -20
0
20 40 60 80 100 120
85
-55 -40 -20
0
20 40 60 80 100 120
85
υ u (°C)
υ u (°C)
1000
60
40
350
0
20
SL0
0
S3N
-1000
-20
-40
-60
-2000
-60 -40 -20
0
20 40 60 80 100 120 140 160
Temperature (°C)
-55 -40 -20
0
10 25 45 65 85 105125 150
Temperature (°C)
VOLTAGE DEPENDENCE OF CAPACITANCE
None
FREQUENCY DEPENDENCE OF CAPACITANCE
Max. -2 % at 10 MHz
DISSIPATION FACTOR
• For values greater than 50 pF: see datasheet
• For lower values the dissipation factor is calculated according to the type of ceramic (rated temperature coefficient) under
consideration of the capacitance acc. to EN 130600.
• The dissipation factor as well as the measuring method to be agreed between manufacturer and user for values lower than
5 pF.
Revision: 31-Jul-15
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CLASS 2 CERAMIC TYPE
Ceramic Dielectric: YꢂP
Ceramic Dielectric: X7R
Typical % Capacitance Change at 25 °C
Typical % Capacitance Change at 25 °C
20
15
10
5
10
5
Y5P
0
X7R
-5
0
-5
-10
-15
-20
-10
-15
-20
-15
-35
-55 -35 -15
5
25
Temperature °C
45
65
85
5
25
45
65
85
105 125
Temperature °C
Ceramic Dielectric: ZꢂU/ZꢂV
Ceramic Dielectric: XꢂF
Typical % Capacitance Change at 25 °C
Typical % Capacitance Change at 25 °C
10
0
6.5
4.5
-10
Z5U
-20
X5F
-30
2.5
-40
0.5
- 50
- 60
- 70
- 80
- 90
-1.5
-3.5
-5.5
Z5V
-15
-35
-55
-35
-15
5
25
45
65
85
5
25
45
65
85
Temperature °C
Temperature °C
Ceramic Dielectric: YꢂV
Ceramic Dielectric: YꢂU
Typical % Capacitance Change at 25 °C
Y5V
Typical % Capacitance Change at 25 °C
Y5U
10
0
10
0
-10
-10
-20
-30
-40
-50
-60
-20
-30
-40
-50
-60
-70
-80
-90
-40 -30 -20 -10
0
10 20 30 40 50 60 70 80 90
Temperature °C
-40 -30 -20 -10
0
10 20 30 40 50 60 70 80 90
Temperature °C
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CAPACITANCE “AGING” OF CERAMIC CAPACITORS
Following the final heat treatment, all class 2 ceramic capacitors reduce their capacitance value. According to logarithmic law,
this is due to their special crystalline construction. This change is called “aging”. If the capacitors are heat treated (for example
when soldering), the capacitance increases again to a higher value deaging, and the aging process begins again.
Note
•
The level of this deaging is dependent on the temperature and the duration of the heat; an almost complete deaging is achieved at 150 °C
in one hour. These conditions also form the basis for reference measurements when testing. The capacitance change per time decade
(aging constant) differs for the various types of ceramic, but typical values can be taken from the equations below.
t1, t2 = measuring time point (h)
C11, C12 = capacitance values for the times t1, t2
k = aging constant (%)
100 x C11 - C12
-----------------------------------------------
k =
C11 x log10t2/t1
C12 = C11 x 1 - k/100 x log10t2/t1
REFERENCE MEASUREMENT
Due to aging, it is necessary to quote an age for reference measurements which can be related to the capacitance with fixed
tolerance. According to EN 130700, this time period is 1000 h.
In order to avoid the influence of aging, it is important to deage the capacitors before stress-testing. The following procedure is
adopted (see also EN 130700):
Deaging at 125 °C, 1 h
Storage for 24 h at normal climate temperature
Initial measurement
Stress
Deaging at 125 °C, 1 h
Storage for 24 h at normal climate temperature
Final measurement
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COMPONENT CLIMATIC CATEGORY
4ꢀ/ꢀ8ꢂ/21
1st SET
2nd SET
3rd SET
Minimum ambient temperature
Maximum ambient temperature
Number of days
of operation (test cold)
of operation (dry heat test)
(steady test state)
The large number of possible combinations of tests and
severities may be reduced by the selection of a few standard
groupings according to IEC 60068-1.
Category examples according to IEC 60068-1
25/085/04
25/085/21
40/085/21
55/125/21
First set: two digits denoting the minimum ambient
temperature of operation (cold test).
65
55
40
25
10
00
05
-65 °C
-55 °C
-40 °C
-25 °C
-10 °C
0 °C
ꢀ5 °C
Second set: three digits denoting the maximum ambient
temperature (dry heat test).
155
125
110
090
085
080
075
070
065
060
055
ꢀ155 °C
ꢀ125 °C
ꢀ110 °C
ꢀ90 °C
ꢀ85 °C
ꢀ80 °C
ꢀ75 °C
ꢀ70 °C
ꢀ65 °C
ꢀ60 °C
ꢀ55 °C
Third set: two digits denoting the number of days of the
damp heat steady state test (Ca).
56
21
10
04
56 days
21 days
10 days
4 days
The component is not required
to be exposed to damp heat
56 days
00
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STORAGE
The capacitors must not be stored in a corrosive atmosphere, where sulphide or chloride gas, acid, alkali or salt are present.
Exposure of the components to moisture, should be avoided. The solderability of the leads is not affected by storage of up to
24 months (temperature ꢀ10 °C to ꢀ40 °C, relative humidity up to 60 % RH). Class 2 ceramic dielectric capacitors are also
subject to aging see previous page.
SOLDERING
SOLDERING SPECIFICATIONS
Soldering test for capacitors with wire leads: (according to IEC 60068-2-20, solder bath method)
SOLDERABILITY
(235 5) °C
(2 0.5) s
RESISTANCE TO SOLDERING HEAT
Soldering temperature
Soldering duration
(260 5) °C
(10 1) s
5 mm
Distance from component body
2 mm
SOLDERING RECOMMENDATIONS
Soldering of the component should be achieved using a Sn96.5/Ag3.0/Cu0.5, a Sn60/40 type or a silver-bearing Sn type solder.
Ceramic capacitors are very sensitive to rapid changes in temperature (Thermal shock) therefore the solder heat resistance
specification (see above table) should not be exceeded. Subjecting the capacitor to excessive heating may result in thermal
shocks that can crack the ceramic body. Similarly, excessive heating can cause the internal solder junction to melt.
CLEANING
The components should be cleaned immediately following the soldering operation with vapor degreasers.
SOLVENT RESISTANCE
The coating and marking of the capacitors are resistant to the following test method:
IEC 60068-2-45 (method XA)
MOUNTING
We do not recommend modifying the lead terminals, e.g. bending or cropping. This action could break the coating or crack the
ceramic insert. If however, the lead must be modified in any way, we recommend support of the lead with a clamping fixture
next to the coating.
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AQL/FIT VALUES/SUPPLIED QUALITY
AQL ꢀ.1 for the Sum of the Electric Main Faults
• C-tolerance > 1.5 x tolerance limit
• DF > 1.5 x catalog value
• RIS < catalog value
• Inadequate dielectric breakdown
• Interruption
AQL ꢀ.2ꢂ for the Sum of the Mechanical Main Faults
• Marking wrong or missing
• Dimensions out of tolerance
• Coating failure
• Lead space out of tolerance
• Poor solderability of leads
• Wrong lead length
AQL ꢀ.6ꢂ for Secondary Faults
• Coating extension out of tolerance
• Marking incomplete
• Tape dimensions out of tolerance
• Testing in accordance to IEC 60410
Notes
The following agreements are possible on request:
•
•
•
•
Lower AQL values
Confirmed initial random sampling test with appropriate report
Report on production test findings
Agreement on ppm concept
RELIABILITY
By careful control of the manufacturing process stages, the quality of the product is maintained at the highest possible level.
To obtain data on the reliability of our ceramic capacitors, many long-term tests under increased temperature and voltage
conditions have been carried out in our laboratories.
Based on the results of these tests, the following can be stated:
Reference conditions: ambient temperature: (40 2) °C
relative humidity: 90 % to 95 %
electrical stress: 0 V rated voltage (UR), RFI safety cap 100 % UR
Failure criteria:
Failure tests:
short circuit (R 1 G) or short circuit (R 3 G RFI safety caps)
class 1 capacitors: l = 500 FIT
class 2 capacitors: l = 500 FIT
By derating the voltage load, greatly increased reliability can be predicted.
Temperature, up to the maximum category temperature, is not believed to significantly affect the reliability.
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PRODUCTION FLOWCHART
QC 1
Pressing discs
Sinter process (firing)
QC 2
PC 1
PC 2
Screen printing of both electrodes
Firing of electrodes
PC 3
PC 4
Sorting in tolerance classes if necessary
QC 3
Forming and soldering leads
Aligning for coating process
Epoxy or phenol resin coating
Hardening resin coat
PC 5
PC 6
Marking
100 % test
C-value
Dissipation factor
Voltage test
PC 7
Visual inspection
QC 4
PC 8, 9
Cutting leads for bulk packaging or taping
Packaging
QC 5
PC = Production control
QC = Quality control
Delivery
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STANDARD LEAD CONFIGURATIONS
L = straight leads
K = outside crimp kinked leads
J = inside crimp kinked leads
D
D
D
Tangent
Tangent
Tangent
line
line
line
SH
SH
DR
F
F
F
V = inline kinked leads
D
T
D = diameter
F = lead spacing
SH = seated height
T = thickness
L = lead length
DR = run down
SH
F
L
Ø d
NON-STANDARD LEAD STYLES AVAILABLE ON REQUEST
T = double crimp leads
D
T
SH
L
F
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PACKAGING RADIAL TAPE AND AMMOPACK
ꢂ.ꢀ mm LEAD SPACING
12.7 mm FEED HOLE PITCH
7.ꢂ mm LEAD SPACING
1ꢂ.ꢀ mm FEED HOLE PITCH
DESCRIPTION
CODE
Body dimension
Feed hole diameter
Wire lead diameter
Lead end protrusion
Lead spacing
D
D0
d
11.0 max.
14.0 max.
4.0 0.2
4.0 0.2
0.6 0.05
0.6 0.05
1.0 max.
e
1.0 max.
F
5.0 ꢀ 0.6/- 0.4
7.5 ꢀ 0.6/- 0.4
Height to seating plane
H0
H0
20.0 0.5
20.0 0.5
(for straight leads)
Height to seating plane
(for kinked leads)
16.0 0.5
32.0 max.
16.0 0.5
40.0 max.
Top of component height
Body inclination
H1
h
L
0
1.0
0
1.0
Rejected component cut height
Component pitch
11.0 max.
12.7 1.0
12.7 0.3
3.85 0.7
6.35 1.3
1.0 max.
11.0 max.
15.0 1.0
15.0 0.3
3.75 0.7
7.5 1.5
p
Feed hole pitch
P0
P1
P2
P
t
Feed hole off alignment
Plane deviation
1.0 max.
Overall tape thickness
Overall tape and lead thickness
Carrier tape width
0.9 max.
0.9 max.
t1
1.5 max.
1.5 max.
W
W0
W1
W2
18.0 ꢀ 1.0/- 0.5
5.0 min.
18.0 ꢀ 1.0/- 0.5
5.0 min.
Adhesive tape width
Feed hole height off alignment
Adhesive tape margin
Reference drawing
9.0 ꢀ 0.75/- 0.5
3.0 max.
9.0 ꢀ 0.75/- 0.5
3.0 max.
Fig. 1
Fig. 1
PACKAGING RADIAL TAPE AND AMMOPACK
7.ꢂ mm LEAD SPACING
1ꢀ.ꢀ mm LEAD SPACING
DESCRIPTION
CODE
12.7 mm FEED HOLE PITCH
1ꢂ.ꢀ mm FEED HOLE PITCH
2ꢂ.4 mm COMPONENT PITCH 2ꢂ.4 mm COMPONENT PITCH
Body dimension
Feed hole diameter
Wire lead diameter
Lead end protrusion
Lead spacing
D
D0
d
22.0 max.
4.0 0.2
22.0 max.
4.0 0.2
0.6 0.05
1.0 max.
0.8 0.05
e
1.0 max.
F
7.5 ꢀ 0.6/- 0.4
10.0 ꢀ 0.6/- 0.4
Height to seating plane
H0
H0
20.0 0.5
20.0 0.5
(for straight leads)
Height to seating plane
(for kinked leads)
16.0 0.5
43.0 max.
16.0 0.5
43.0 max.
Top of component height
Body inclination
H1
h
L
0
1.0
0
1.0
Rejected component cut height
Component pitch
11.0 max.
25.4 1.0
12.7 0.3
8.9 0.7
11.0 max.
25.4 1.0
12.7 0.3
8.9 0.7
p
Feed hole pitch
P0
P1
P2
P
t
Feed hole off alignment
12.7 1.5
1.0 max.
12.7 1.5
1.0 max.
Plane deviation
Overall tape thickness
Overall tape and lead thickness
Carrier tape width
0.9 max.
0.9 max.
t1
1.5 max.
1.7 max.
W
W0
W1
W2
18.0 ꢀ 1.0/- 0.5
5.0 min.
18.0 ꢀ 1.0/- 0.5
5.0 min.
Adhesive tape width
Feed hole height off alignment
Adhesive tape margin
Reference drawing
9.0 ꢀ 0.75/- 0.5
3.0 max.
9.0 ꢀ 0.75/- 0.5
3.0 max.
Fig. 2
Fig. 2
Revision: 31-Jul-15
Document Number: 28536
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PACKAGING VERSIONS
Reel Packaging
Ammo Packaging
direction of unreeling
Ø 16
1
340 max.
350 max.
60 max.
340 max.
55 max.
P2
ΔP
T
P
Δh
D
Δh
ΔP
P
Δh
Δh
P2
ΔP
ΔP
H1
H0
W2
W1
H1
F
Ø d
W2
W1
W0
L
W
H0
W0
A
W
A
e
P1
F
P0
D0
e
Ø d
F
P0
P1
D0
t
t1
t
Direction of unreeling
Detail A
t1
Detail A
Fig. 1 - Illustration for component pitch 12.7 mm and 15.0 mm
Feed hole pitch 12.7 mm and 15.0 mm
(12.7 mm for F = 5.0 mm and 6.4 mm; 15 mm for F = 7.5 mm)
Fig. 2 - Illustration for component pitch 25.4 mm
Feed hole pitch 12.7 mm
(for F = 7.5 mm, 10.0 mm and 12.5 mm)
Revision: 31-Jul-15
Document Number: 28536
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CLEAR TEXT ORDERING CODE
D
471
K
2ꢀ
YꢂP
8 9 10
L
6
3
13
J
ꢂ
R
16
1
2 3 4
5
6 7
11
12
14
15
Product Capacitance Capacitance
Type Tolerance
Size
Temperature
Rated
Lead
Packaging/
Lead
Style
Lead
Spacing Compliant
RoHS-
Code Characteristic Voltage Diameter Lead Length
D = general The first two C = 0.25 pF Please Please see the F = 50 V
6 =
3 = bulk
30 mm
Please see
“lead
2 =
type with digits are the D = 0.5 pF
see
“size
code”
table
temperature H = 100 V 0.6 mm
coefficient L = 500 V 0.05 mm
2.5 mm
phenolic
significant
figures of
G = 2 %
J = 5 %
5.0 mm configurations”
resin coat
curve of
N = 1 kV
5 =
5.0 mm
capacitance K = 10 %
and the last M = 20 %
ceramic type P = 2 kV
R = 3 kV
5 = bulk
5.0 mm
0.8 mm
8 =
0.8 mm
0.05 mm
S = general
type with
epoxy resin
coat
digit is a
multiplier as
follows:
0 = x 1
1 = x 10
2 = x 100
3 = x 1000
4 = x 10 000
9 = x 0.1
Z = ꢀ 80 %/
- 20 %
U = 6 kV
6 =
6.4 mm
S = X1/Y2
300 V (AC)
T = tape
and reel
7 =
7.5 mm
F = low
dissipation
type
Q = X1/Y1
500 V (AC)
U =
ammopack
0 =
10.0 mm
For VY1:
G = X1/Y1
500 V (AC)
HF
VY1 =
safety
recognized
with epoxy
resin coat
X =
12.5 mm
For VY1*C:
C = X1/Y1
500 V (AC)
HF,
VY2 =
safety
recognized
with epoxy
resin coat
compact
size
For VY2:
G = X1/Y2
300 V (AC)
HF
H = HV
disc X7R
Note
•
HF = RoHS-compliant and halogen-free.
LABELING
Each reel is provided with a label showing the following details:
Manufacturer, capacitance, tolerance, batch number, quantity of components, rated voltage and dielectric. On special request
other designations can be shown. For example:
Revision: 31-Jul-15
Document Number: 28536
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SMALLEST PACKAGING QUANTITIES (SPQ)
STANDARD PACKAGING SPEC.
BOX
PRODUCT
FAMILY (D)
LEAD SPACE
(F)
PACKAGING
SIZE CODE
WORKING VOLTAGE
SPQ
DIMENSIONS
(W)
(PCS)
L x W x H (mm)
20 to 25
29 to 39
43 to 47
53 to 75
84 to 96
39 to 49
53 to 75
20 to 25
29 to 39
43 to 47
53 to 59
63 to 84
96
1000
1000
1000
500
All (except 6 kV)
Disc cap;
long lead;
(L 25.4 mm)
All
245 x 120 x 65
250
500
6 kV
250
5000
3000
2000
1000
500
Bulk
Disc cap;
short lead;
(L 10 mm)
All
All
245 x 120 x 65
250
20 to 33
39 to 47
53 to 59
63 to 75
84
3000
2000
1000
500
Safety disc;
short lead;
(L 10 mm)
All
All
245 x 120 x 65
250
< 500 VDC
500 WV 2000 VDC
3000 VDC
2500
2000
1000
1000
500
6.4 mm
47
Disc cap
Safety disc
Disc cap
7.5 mm
6.4 mm
7.5 mm
Tape and reel
All
All
370 x 370 x 60
53
500
53
59
All
1000
500
7.5 mm
> 7.5 mm
500
< 500 VDC
2000
2000
1500
1500
1500
1000
1000
750
335 x 240 x 50
335 x 290 x 50
360 x 330 x 55
335 x 290 x 50
500 WV < 2000 VDC
2000 VDC and 3000 VDC
6.4 mm
47
7.5 mm
6.4 mm
7.5 mm
All
All
Ammopack
53
53
59
All
7.5 mm
Safety disc
360 x 330 x 55
> 7.5 mm
750
Revision: 31-Jul-15
Document Number: 28536
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THIS DOCUMENT IS SUBJECT TO CHANGE WITHOUT NOTICE. THE PRODUCTS DESCRIBED HEREIN AND THIS DOCUMENT
ARE SUBJECT TO SPECIFIC DISCLAIMERS, SET FORTH AT www.vishay.com/doc?91000
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SIZE CODE
SIZE CODE (CTC)
DISC DIAMETER (OUTPUT)
5.0 mm max.
20
25
29
31
33
35
39
41
43
47
49
51
53
59
61
65
69
75
84
93
96
6.5 mm max.
7.5 mm max.
8.0 mm max.
8.5 mm max.
8.9 mm max.
10.0 mm max.
10.5 mm max.
11.0 mm max.
12.0 mm max.
12.5 mm max.
13.0 mm max.
13.5 mm max.
15.0 mm max.
15.5 mm max.
16.5 mm max.
17.5 mm max.
19.0 mm max.
21.5 mm max.
23.6 mm max.
24.5 mm max.
MEASUREMENT
On the basis of the center of the product, measure the thickness with vernier caliper along every direction. Calipering position
refers to the figure below. The maximum value is the thickness value.
D max.
T
Vernier Caliper position
for the thickness measurement
Vernier Caliper position
for the diameter measurement
Revision: 31-Jul-15
Document Number: 28536
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ARE SUBJECT TO SPECIFIC DISCLAIMERS, SET FORTH AT www.vishay.com/doc?91000
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CAUTION
1. OPERATING VOLTAGE AND FREQUENCY CHARACTERISTIC
When sinusiodal or ripple voltage applied to DC ceramic disc capacitors, be sure to maintain the peak-to-peak value or the peak
value of the sum of both AC ꢀ DC within the rated voltage.
When start or stop applying the voltage, resonance may generate irregular voltage.
When rectangular or pulse wave voltage is applied to DC ceramic disc capacitors, the self-heating generated by the capacitor
is higher than the sinusoidal application with the same frequency. The allowable voltage rating for the rectangular or pulse wave
corresponds approximately with the allowable voltage of a sinusoidal wave with the double fundamental frequency.
The allowable voltage varies, depending on the voltage and the waveform.
Diagrams of the limiting values are available for each capacitor series on request.
VOLTAGE
DC
DC + AC
AC
Waveform
figure
Vp-p
V0-p
V0-p
0
0
0
2. OPERATING TEMPERATURE AND SELF-GENERATED HEAT
The surface temperature of the capacitors must not exceed the upper limit of its rated operating temperature.
During operation in a high-frequency circuit or a pulse signal circuit, the capacitor itself generate heat due to dielectric losses.
Applied voltage should be the load such as self-generated heat is within 20 °C on the condition of environmental temperature
25 °C.
Note, that excessive heat may lead to deterioration of the capacitor’s characteristics.
Revision: 31-Jul-15
Document Number: 28536
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THIS DOCUMENT IS SUBJECT TO CHANGE WITHOUT NOTICE. THE PRODUCTS DESCRIBED HEREIN AND THIS DOCUMENT
ARE SUBJECT TO SPECIFIC DISCLAIMERS, SET FORTH AT www.vishay.com/doc?91000
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