DIMENSIONS: mm
25.0 min.
3.0 max.
D max.
Tinned
copper wire
DE04-05–#24
DE06-16–#22
Vertical Crimp:
1kV 4.0, 2kV 5.0,
3kV 6.0,
6kV 7.0
L.S.
TYPE LEADS TEMP. CHAR. CAPACITANCE TOL. VOLTAGE
DE04 05 – B 101 K 1K
CAPACITOR LEAD SPACING LEAD/ TEMPERATURE CHARACTERISTICS CAPACITANCE CAPACITANCE VOLTAGE
TYPE AND 05 = 5 TAPING Class I: Per standard EIA specifications. VALUE TOLERANCE Identified by a
SIZE 07 = 7.5 CODE Class II & III: 3-digit code J = ±5% one-digit number
10 = 10 See TEMPERATURE RANGE: –25°C to +85°C K = ±10%
following MAX. CAP. CHANGE OVER TEMP. RANGE: Z = +80, –20%
page B = ±10%
E = +20, –55%
F = +30, –80%
LEADED CAPACITORS, NETW ORKS & HV CAPACITORS
MEDIUM VOLTAGE CAPACITORS
1kV to 6kVDC E.I.A. CLASS II & III DE Series
80 CG01-J
PART NUMBERING SYSTEM
TYPICAL TEMPERATURE CHARACTERISTICS
Non-Vertical Crimp:
DE0507/DE0607 type
and rated voltage
6.3kV type
–1 Lead Code
d
5 ± 1.0
B
E
F
F
E
B
–40 –20 0 20 40 60 80 100 120
Temp. °C
Cap. Change %
60
40
20
0
–20
–40
–60
–80
MARKING*
*Three-digit capacitance code for values of 100pF and larger.
SL and F have no temperature characteristic marking.
DE04, 05, 06 DE07, 08, 09
DE10 & Larger
101
2KV 681K
3KV
B
472K
1KV
00
00:Date
Code
LEADED CAPACITORS, NETW ORKS & HV CAPACITORS
MEDIUM VOLTAGE CAPACITORS
1kV to 6kVDC E.I.A. CLASS II & III DE Series
CG01-J 81
: Lead Configuration/Lead Code
Straight Straight Double Taping*
†
Long Short Crimp
Part Number Nominal Max. Lead Rated
(: optional lead Capacitance Body Spacing Voltage
code shown (pF) Diameter F (mm) (kVDC)
Lead Spacing Lead Spacing Lead Spacing
at the right) D (mm)
F: 5.0 F: 7.5 F: 7.5
Pitch of Pitch of Pitch of
Component Component Component
P: 12.7 P: 15.0 P: 30.0
DE0405B101K1K 100
DE0405B151K1K 150 4.5
DE0405B221K1K 220
DE0405B331K1K 330
DE0505B471K1K 470 5 5.0 –979 —
DE0605B681K1K 680 61 –69 —
DE0605B102K1K 1000
DE0805B152K1K 1500 8
DE0905B222K1K 2200 9
DE1005B332K1K 3300 10
DE1207B472K1K 4700 12 7.5 — –486
DE1507B682K1K 6800 15 –610 –477
DE0405B101K2K 100
DE0405B151K2K 150 4.5
DE0405B221K2K 220
DE0505B331K2K 330 5 —
DE0605B471K2K 470 6 5.0 No Code –1 —–979 —
DE0705B681K2K 680 7 2
DE0805B102K2K 1000 8
DE0905B152K2K 1500 9
DE1005B222K2K 2200 10
DE1207B332K2K 3300 12 7.5 –486
DE1507B472K2K 4700 15 –610 — –477
DE0507B101K3K 100
DE0507B151K3K 150 5
DE0507B221K3K 220
DE0607B331K3K 330 6
DE0707B471K3K 470 7 7.5 3.15 –620 –486 —
DE0807B681K3K 680 8
DE0907B102K3K 1000 9
DE1107B152K3K 1500 11 —
DE1307B222K3K 2200 13
DE1507B332K3K 3300 15 –610 –477
DE0910B101K6K 100
DE0910B151K6K 150 9
DE0910B221K6K 220 No Code —
DE0910B331K6K 330 10.0 6.3 Bulk Only —— —
DE1010B471K6K 470 10
DE1110B681K6K 680 11
DE1310B102K6K 1000 13
B CHARACTERISTIC (Similar to EIA Temperature Characteristic Y5P)
DE0505E102Z1K 1000 5
DE0705E222Z1K 2200 7 5.0 1–69 –979 —
DE0905E472Z1K 4700 9
DE1307E103Z1K 10000 13 7.5 –620 — –486 —
DE0605E102Z2K 1000 6
DE0805E222Z2K 2200 8 5.0 2No Code –1 — –979 —
DE1105E472Z2K 4700 11
DE1607E103Z2K 10000 16 7.5 –610 –477
DE0707E102Z3K 1000 7
DE1007E222Z3K 2200 10 7.5 3.15 –620 —–486
DE1307E472Z3K 4700 13 —
DE1110E102Z6K 1000 11 10.0 6.3 Bulk Only — — —
DE1510E222Z6K 2200 15
E CHARACTERISTIC (Similar to EIA Temperature Characteristic Y5U)
: Lead Configuration/Lead Code
Straight Long Straight Short Double Crimp Taping*
†
Part Number Nominal Max. Lead Rated
(: optional lead Capacitance Body Spacing Voltage
code shown (pF) Diameter F (mm) (kVDC)
Lead Spacing Lead Spacing
at the right) D (mm)
F: 5.0 F: 7.5
Pitch of Pitch of
Component Component
P: 12.7 P: 15.0
DE0605F222Z1K 2200 6
DE0705F472Z1K 4700 7 5.0 1 –69
DE1005F103Z1K 10000 10 –979 —
DE0505F102Z2K 1000 5 No Code –1
DE0705F222Z2K 2200 7 5.0 2—
DE0905F472Z2K 4700 9
DE1207F103Z2K 10000 12 7.5 — –486
F CHARACTERISTIC (Similar to EIA Temperature Characteristic Y5V)
All “No Code” bulk versions standard through authorized Murata Electronics Distributors.
†
See page 96 for specifications.
*900 pcs. for KH type
*900 pcs. for KH type
LEADED CAPACITORS
NETWORKS, AND
HV CAPACITORS
LEADED CAPACITORS, NETW ORKS & HV CAPACITORS
MEDIUM VOLTAGE CAPACITORS
1kV to 6kVDC E.I.A.CLASS II&III–
SPECIFICATIONS & TEST METHODS
DE Series
82 CG01-J
Item Specification Test Method
Temperature Compensating High Dielectric Constant
1 Operating Temperature Range –25 to +85°C –25 to +85°C —
2 Capacitance Within the specified tolerance. Within the specified
tolerance.
3Q
Dissipation Factor (D.F.)
4 Insulation Between 10000M ohms min. 10000M ohms min.
Resistance (I.R.) lead wires
5 Dielectric Between No failure. No failure.
Strength lead wires
Body No failure. No failure.
Insulation
6 Temperature Characteristic
7 Vibration Appearance No marked defect. No marked defect.
Resistance Capacitance Within the specified tolerance. Within the specified
Change tolerance.
Q.
D.F.
8 Soldering Appearance No marked defect. No marked defect.
Effect Capacitance
Change
Dielectric Pass the item No. 5. Pass the item No. 5.
Strength
(between
lead wires)
9 Humidity Appearance No marked defect. No marked defect.
(Under Capacitance
Steady State) Change
Q.
D.F.
I.R. 1000M ohms min. 1000M ohms min.
10 Humidity Appearance No marked defect. No marked defect.
Loading Capacitance
Change
Q.
D.F.
I.R. 500M ohms min. 500M ohms min.
11 Life Appearance No marked defect. No marked defect.
Capacitance
Change
Q.
D.F.
I.R. 2000M ohms min. 2000M ohms min.
12 Strength of Pull Lead wire shall not cut off.
Lead Capacitor shall not be broken.
Bending
13 Solderability of Leads Lead wire shall be soldered with uniform coating on the axial
direction over
3
/
4
of the circumferential direction.
1“C” expresses nominal capacitance value (pF). 2“room condition” temperature: 15 to 35°C; humidity: 45 to 75%; atmospheric pressure: 860 to 1060hPa.
The capacitance shall be measured at 20°C with 1 ± 0.2kHz
(SL: 1 ± 0.2MHz) and 5V(r.m.s.) max.
Same condition as capacitance.
The insulation resistance shall be measured with 500 ± 50VDC within
60 ± 5 sec. of charging.
The capacitors shall not be damaged when DC voltage of 200% of the
rated voltage is applied between the lead wires for 1 to 5 sec.
(Charge/discharge current ≤50mA)
The capacitance measurement shall be made at each step specified in
table. Capacitance change from the value of step 3 shall not exceed the
limit specified.
The capacitor shall firmly be soldered to the supporting lead wire and
vibration which is 10 to 55Hz in the vibration frequency range, 1.5mm
in total amplitude, and about 1 minute in the rate of vibration change
from 10Hz to 55Hz and back to 10Hz is applied for a total of 6 hours;
2 hours each in 3 mutually perpendicular directions.
The lead wire shall be immersed into the melted solder of 350 ± 10°C
(body of 5 and under: 270 ± 5°C) up to about 1.5 to 2mm from the
main body for 3.5 ± 0.5 sec. (body of 5 and under: 5 ± 0.5 sec.).
Pre-treatment
Capacitor shall be stored at 85 ± 2°C for 1 hour, then placed at room
condition
2
for 24 ± 2 hours before initial measurements (B, E, F).
Post-treatment
Capacitor shall be stored for 1 to 2 hours at room condition
2
(SL).
Capacitor shall be stored for 24 ± 2 hours at room condition
2
(B, E, F).
Set the capacitor for 500
+24
–0
hours at 40 ± 2°C in 90 to 95% humidity.
Pre-treatment
Capacitor shall be stored at 85 ± 2°C for 1 hour, then placed at room
condition
2
for 24 ± 2 hours before initial measurements (B, E, F).
Post-treatment
Capacitor shall be stored for 1 to 2 hours at room condition
2
.
Apply the rated voltage for 500
+24
–0
hours at 40 ± 2°C in 90 to 95%
humidity. (Charge/discharge current ≤50mA).
Pre-treatment
Capacitor shall be stored at 85 ± 2°C for 1 hour, then placed at room
condition
2
for 24 ± 2 hours before initial measurements (B, E, F).
Post-treatment
Capacitor shall be stored for 1 to 2 hours at room condition
2
(SL).
Capacitor shall be stored at 85 ± 2°C for 1 hour, then placed at room
condition
2
for 24 ± 2 hours (B, E, F).
Apply a DC voltage of 150% of the rated voltage for 1000
+48
–0
hours at
85 ± 2°C. (Charge/discharge current ≤50mA).
Pre-treatment
Capacitor shall be stored at 85 ± 2°C for 1 hour, then placed at room
condition
2
for 24 ± 2 hours before initial measurements (B, E, F).
Post-treatment
Capacitor shall be stored for 1 to 2 hours at room condition
2
(SL).
Capacitor shall be stored at 85 ± 2°C for 1 hour, then placed at room
condition
2
for 24 ± 2 hours (B, E, F).
As in figure, fix the body of capacitor, apply a tensile weight
gradually to each lead wire in the radial direction of capacitor
up to 10N (1.0kgf) 5N (0.51kgf) for lead diameter 0.5, and
keep it for 10 ± 1 sec.
Each lead wire shall be subjected to 5N (0.51kgf) 2.5N (0.25kgf) for lead
diameter 0.5 weight and then a 90° bend, at the point of egress, in one
direction, return to original position, and then a 90° bend in the opposite
direction at the rate of one bend in 2 to 3 seconds.
The lead wire of a capacitor shall be dipped into a methanol solution of
25wt% rosin and then into molten solder of 235 ± 5°C for 2 ± 0.5
seconds. In both cases the depth of dipping is up to about 1.5 to 2mm
from the root of lead wires.
Pre-treatment
Capacitor shall be stored at 85 ± 2°C for 1 hour, then placed at room
condition
2
for 24 ± 2 hours before initial measurements (B, E, F).
The capacitor is placed in the container with metal
balls of diameter 1mm so that each lead wire, short-
circuited, is kept approximately 2mm off the balls as
shown in the figure, and DC voltage of 1.3kV is
applied for 1 to 5 sec. between capacitor lead wires
and small metals. (Charge/discharge current ≤50mA).
SL C ≥30pF: Q ≥1000
C < 30pF: Q ≥400 + 20C
1
SL C ≥30pF: Q ≥1000
C < 30pF: Q ≥400 + 20C
1
B, E D.F. ≤2.5%
FD.F. ≤5.0%
B, E D.F. ≤2.5%
FD.F. ≤5.0%
SL C ≥30pF: Q ≥350
C < 30pF: Q ≥275 +
5
/
2
C
1
B, E D.F. ≤5.0%
FD.F. ≤7.5%
SL within ±2.5% Bwithin ±5%
Ewithin ±15%
Fwithin ±20%
SL within ±5% Bwithin ±10%
Ewithin ±20%
Fwithin ±30%
SL C ≥30pF: Q ≥200
C < 30pF: Q ≥100+
10
/
3
C
1
B, E D.F. ≤5.0%
FD.F. ≤7.5%
SL within ±7.5% Bwithin ±10%
Ewithin ±20%
Fwithin ±30%
SL C ≥30pF: Q ≥350
C < 30pF: Q ≥275 +
5
/
2
C
1
B, E D.F. ≤4.0%
FD.F. ≤7.5%
SL within ±3% Bwithin ±10%
Ewithin ±20%
Fwithin ±30%
T.C. Temp. Coefficient
SL +350 to –1000ppm/°C T.C. Cap. Change
Bwithin ±10%
Ewithin
+20
–55
%
Fwithin
+30
–80
%Char. Step 1 2 3 4 5
SL — — 20 ±2°C 85 ±2°C 20 ±2°C
B, E, F 20 ± 2°C –25 ± 3°C 20 ± 2°C 85 ± 2°C 20 ± 2°C
Approx. 2mm
Metal balls
W
DIMENSIONS: mm
25.0 min.
3.0 max.
D max.
Tinned
copper wire
DE04-05–#24
DE06-16–#22
Vertical Crimp:
1kV 4.0, 2kV 5.0,
3kV 6.0,
6kV 7.0
L.S.
LEADED CAPACITORS, NETW ORKS & HV CAPACITORS
HIGH TEMPERATURE CAPACITORS
250V to 3kVDC E.I.A. CLASS I & II DE Series
CG01-J 83
PART NUMBERING SYSTEM
TYPICAL TEMPERATURE VS.
CAPACITANCE CHANGE
Non-Vertical Crimp:
In case of Murata type:
DE0507, DE0607 and rated
voltage 6.3kV
–1 Lead Code
d
5 ± 1.0
MARKING*
*Working Voltage not marked for 500V. Three-digit capacitance
code for values 100pF and higher.
TYPICAL AC/DC BREAKDOWN VOLTAGE
HR
102
DE04, 05, 06
HRSL
221J
2KV
00
00: Date
Code
DE10 & Larger
HR R
102K
1KV
DE07, 08, 09
TYPE LEADS TEMP. CHAR. CAPACITANCE TOL. VOLTAGE
DE04 05 – SL 120 J 1K
CAPACITOR LEAD SPACING
LEAD/
TEMPERATURE CAPACITANCE VALUE CAPACITANCE VOLTAGE
TYPE AND 05 = 5 TAPING CODE CHARACTERISTICS Expressed in picofarads and TOLERANCE Identified by a
SIZE 07 = 7.5 See following –25°C to +125°C identified by a three-digit D= ±0.5pF one, two or three
10 = 10 pages MAX. CAP. CHANGE number. First two digits J = ±5% (SL only) digit number.
OVER TEMP. RANGE represent significant figures. K = ±10%
SL = +350–1000ppm/°C Last digit specifies the number
of zeros to follow. –25°C to +85°C +85°C to +125°C
R = ±15% +15, –30%
C = ±20% +15, –30%
SL
CR
–40 –20 0 20 40 60 80 100 120
Temperature (°C)
Capacitance Change (%)
+15
0
–15
–30
123 456 78 9101112
Breakdown Voltage (kV)
: DC Breakdown Voltage : AC Breakdown Voltage
DE1007 SL 121J 3K
DE1005 SL 221J 2K
DE1005 SL 331J 1K
DE1910 R 272K 3K
DE2110 R 472K 2K
DE1707 R 472K 1K
DE51-4 C 472K 500
DE512 R 103K 250
LEADED CAPACITORS
NETWORKS, AND
HV CAPACITORS
LEADED CAPACITORS, NETW ORKS & HV CAPACITORS
HIGH TEMPERATURE CAPACITORS
250V to 3kVDC E.I.A. CLASS I & II DE Series
84 CG01-J
: Lead Configuration/Lead Code
Straight Straight Double Taping*
†
Long Short Crimp
Part Number Nominal Max. Lead Rated
(: optional lead Capacitance Body Spacing Voltage
code shown (pF) Diameter F (mm) (kVDC)
Lead Spacing Lead Spacing Lead Spacing
at the right) D (mm)
F: 5.0 F: 7.5 F: 7.5
Pitch of Pitch of Pitch of
Component Component Component
P: 12.7 P: 15.0 P: 30.0
DE0405SL100D1K 10
DE0405SL120J1K 12
DE0405SL150J1K 15
DE0405SL180J1K 18
DE0405SL220J1K 22 4.5
DE0405SL270J1K 27
DE0405SL330J1K 33
DE0405SL390J1K 39
DE0405SL470J1K 47
DE0505SL560J1K 56 5
DE0505SL680J1K 68 5.0 1–69 –979 —
DE0605SL820J1K 82
DE0605SL101J1K 100 6
DE0605SL121J1K 120
DE0705SL151J1K 150 7
DE0705SL181J1K 180
DE0805SL221J1K 220 8
DE0905SL271J1K 270 9
DE1005SL331J1K 330 10
DE1005SL391J1K 390
DE1105SL471J1K 470 11 —
DE1207SL561J1K 560 12 7.5 –1 –620 — –486
DE0405SL100D2K 10
DE0405SL120J2K 12
DE0405SL150J2K 15
DE0405SL180J2K 18 4.5
DE0405SL220J2K 22
DE0405SL270J2K 27
DE0405SL330J2K 33
DE0505SL390J2K 39 5
DE0605SL470J2K 47 5.0 –69 –979 —
DE0605SL560J2K 56 6
DE0605SL680J2K 68 2No Code
DE0705SL820J2K 82 7
DE0705SL101J2K 100
DE0805SL121J2K 120 8
DE0805SL151J2K 150
DE0905SL181J2K 180 9
DE1005SL221J2K 220 10
DE1107SL271J2K 270 11
DE1207SL331J2K 330 12 –486
DE1307SL391J2K 390 13 7.5 –620
DE1407SL471J2K 470 14 — –477
DE1507SL561J2K 560 15
DE0507SL100D3K 10
DE0507SL120J3K 12
DE0507SL150J3K 15 5
DE0507SL180J3K 18
DE0507SL220J3K 22
DE0607SL270J3K 27
DE0607SL330J3K 33 6
DE0607SL390J3K 39 —
DE0707SL470J3K 47 7–486 —
DE0707SL560J3K 56 7.5 3.15 ——
DE0807SL680J3K 68 8
DE0807SL820J3K 82
DE0907SL101J3K 100 9
DE1007SL121J3K 120 10
DE1107SL151J3K 150 11
DE1107SL181J3K 180
DE1207SL221J3K 220 12
DE1407SL271J3K 270 14
DE1507SL331J3K 330 15 — –477
DE1607SL391J3K 390 16
SL CHARACTERISTIC
: Lead Configuration/Lead Code
Straight Long Straight Short Double Crimp Taping*
†
Part Number Nominal Max. Lead Rated
(: optional lead Capacitance Body Spacing Voltage
code shown (pF) Diameter F (mm) (VDC)
Lead Spacing
at the right) D (mm)
F: 5.0
Pitch of Component
P: 12.7
DE506R221K250 220
DE506R331K250 330
DE506R471K250 470 6
DE506R681K250 680
DE506R102K250 1000
DE507R152K250 1500 7 5.0 250 No Code –1 –69 –979
DE508R222K250 2200 8
DE509R332K250 3300 9
DE510R472K250 4700 10
DE512R682K250 6800 12
DE512R103K250 10000
R CHARACTERISTIC (250V)
All “No Code” bulk versions standard through authorized Murata Electronics Distributors.
†
See page 96 for specifications. *900 pcs. for KH type
*900 pcs. for KH type
LEADED CAPACITORS, NETW ORKS & HV CAPACITORS
HIGH TEMPERATURE CAPACITORS
250V to 3kVDC E.I.A. CLASS I & II DE Series
CG01-J 85
: Lead Configuration/Lead Code
Straight Straight Double Taping*
†
Long Short Crimp
Part Number Nominal Max. Lead Rated
(: optional lead Capacitance Body Spacing Voltage
code shown (pF) Diameter F (mm) (kVDC)
Lead Spacing Lead Spacing Lead Spacing
at the right) D (mm)
F: 5.0 F: 7.5 F: 7.5
Pitch of Pitch of Pitch of
Component Component Component
P: 12.7 P: 15.0 P: 30.0
DE0705R221K1K 220
DE0705R331K1K 330 7
DE0705R471K1K 470 5.0 –69 –979 —
DE0805R681K1K 680 8 —
DE0905R102K1K 1000 9 1
DE1105R152K1K 1500 11
DE1310R222K1K 2200 13 –486
DE1510R332K1K 3300 15 10.0 –610 — — –477
DE1710R472K1K 4700 17
DE0707R221K2K 220 7
DE0707R271K2K 270
DE0807R331K2K 330 8
DE0807R391K2K 390 –1
DE0907R471K2K 470 9
DE0907R561K2K 560 —
DE1007R681K2K 680 10 7.5 –620 –486
DE1107R821K2K 820 11
DE1207R102K2K 1000 2
DE1207R122K2K 1200 12
DE1207R152K2K 1500
DE1407R182K2K 1800 14 No Code
DE1507R222K2K 2200 15 –477
DE1707R272K2K 2700 17
DE1910R332K2K 3300 19
DE2010R392K2K 3900 20 10.0 –810 —
DE2110R472K2K 4700 21 —
DE0707R151K3K 150
DE0707R181K3K 180 7
DE0707R221K3K 220
DE0707R271K3K 270 —
DE0807R331K3K 330 8
DE0907R391K3K 390 9 –486
DE1007R471K3K 470 10
DE1007R561K3K 560 7.5 3.15 — —
DE1107R681K3K 680 11
DE1207R821K3K 820 12
DE1307R102K3K 1000 13
DE1407R122K3K 1200 14
DE1507R152K3K 1500 15 –477
DE1607R182K3K 1800 16 —
DE1707R222K3K 2200 17
DE1910R272K3K 2700 19 10.0 —
R CHARACTERISTIC (1 to 3.15kV)
: Lead Configuration/Lead Code
Straight Long Straight Short Double Crimp Taping*
†
Part Number Nominal Max. Lead Rated
(: optional lead Capacitance Body Spacing Voltage
code shown (pF) Diameter F (mm) (VDC)
Lead Spacing
at the right) D (mm)
F: 5.0
Pitch of Component
P: 12.7
DE50-6C331K500 330 6
DE50-6C471K500 470
DE50-7C681K500 680 7
DE50-8C102K500 1000 8 5.0 500 No Code –1 –69 –979
DE50-9C152K500 1500 9
DE51-0C222K500 2200 10
DE51-2C332K500 3300 12
DE51-4C472K500 4700 14 10.0 –610 —
C CHARACTERISTIC *900 pcs. for KH type
†
See page 96 for specifications. *900 pcs. for KH type
LEADED CAPACITORS
NETWORKS, AND
HV CAPACITORS
LEADED CAPACITORS, NETW ORKS & HV CAPACITORS
HIGH TEMPERATURE CAPACITORS
250Vto 3kVDCE.I.A.CLASSI& II–
SPECIFICATIONS & TEST METHODS
DE Series
86 CG01-J
Item Specification Test Method
1 Operating Temperature Range –25 to +125°C —
2 Capacitance Within the specified tolerance.
3Q C ≥30pF: Q ≥1000 D.F. ≤0.4% (R [250V])
Dissipation Factor (D.F.) C < 30pF: Q ≥400 + 20C
1
(SL) D.F. ≤0.2% (R [1 to 3.15kV])
D.F. ≤0.3% (C)
4 Insulation Between 10000M ohms min. 1000M ohms min.
Resistance (I.R.) lead wires (SL, R [1 to 3.15kV], C) (R [250V])
5 Dielectric Between No failure.
Strength lead wires
Body No failure.
Insulation
6 Temperature Characteristic
7 Temperature Appearance No marked defect. No marked defect.
Cycling Capacitance Within ±5% (SL) Within ±10% (R, C)
Change
QC ≥30pF: Q ≥350 D.F. ≤0.4% (R, C)
D.F. C < 30pF: Q ≥275 +
5
/
2
C
1
(SL)
I.R. 1000M ohms min.
Dielectric Pass the item No. 5.
Strength
(between
lead wires)
8 Vibration Appearance No marked defect.
Resistance Capacitance Within the specified tolerance.
Change
Q. C ≥30pF: Q ≥1000 D.F. ≤0.4% (R [250V])
D.F. C < 30pF: Q ≥400 + 20C
1
(SL) D.F. ≤0.2% (R [1 to 3.15kV])
D.F. ≤0.3% (C)
9 Soldering Appearance No marked defect.
Effect Capacitance Within ±2.5% (SL) Within ±10% (R, C)
Change
Dielectric Pass the item No. 5.
Strength
(between
lead wires)
10 Humidity Appearance No marked defect.
(Under Capacitance Within ±5% (SL) Within ±10% (R, C)
Steady State) Change
QC ≥30pF: Q ≥350 D.F. ≤0.4% (R, C)
D.F. C < 30pF: Q ≥275 +
5
/
2
C
1
(SL)
I.R. 1000M ohms min.
11 Life Appearance No marked defect.
Capacitance Within ±3% (SL) Within ±10% (R, C)
Change
QC ≥30pF: Q ≥350 D.F. ≤0.4% (R, C)
D.F. C < 30pF: Q ≥275 +
5
/
2
C
1
(SL)
I.R. 2000M ohms min. 1000M ohms min.
(SL, R [1 to 3.15kV], C) (R [250V])
12 Strength Pull Lead wire shall not cut off.
of Lead Capacitor shall not be broken.
Bending
13 Solderability of Leads Lead wire shall be soldered with uniform coating on the axial
direction over
3
/
4
of the circumferential direction.
1“C” expresses nominal capacitance value (pF). 2“room condition” temperature: 15 to 35°C; humidity: 45 to 75%; atmospheric pressure: 860 to 1060hPa.
3The measurement of I.R. will be held in 12 to 24 hours after Life test.
The capacitance shall be measured at 20°C with 1 ± 0.2kHz
(SL: 1 ± 0.2MHz) and 5V(r.m.s.) max.
Same condition as capacitance.
The insulation resistance shall be measured with 500 ± 50VDC
(R [250V]: 100 ± 15V) within 60 ± 5 sec. of charging.
The capacitors shall not be damaged when DC voltage of 200% of the rated
voltage (in case of rated voltage: 1 to 3.15kV) or DC voltage of 250% of the rated
voltage (in case of rated voltage: 250V, 500V) is applied between the lead wires
for 1 to 5 sec. (Charge/discharge current ≤50mA)
The capacitance measurement shall be made at each step specified in table.
Capacitance change from the value of step 3 shall not exceed the limit specified.
The capacitor shall firmly be soldered to the supporting lead wire and vibration
which is 10 to 55Hz in the vibration frequency range, 1.5mm in total amplitude,
and about 1 minute in the rate of vibration change from 10Hz to 55Hz and back
to 10Hz is applied for a total of 6 hours; 2 hours each in 3 mutually
perpendicular directions.
The capacitor shall be introduced into the test chamber, and shall be exposed to
the temperature conditions of steps 1 to 4 as shown in table at 5 cycles.
The lead wire shall be immersed into the melted solder of 350 ± 10°C up to
about 1.5 to 2mm from the main body for 3.5 ± 0.5 sec. and the specified items
shall be measured after leaving for 24 ± 2 hours.
Pre-treatment: Capacitor shall be stored at 125 ± 3°C for 1 hour, then placed at
room condition
2
for 24 ± 2 hours before initial measurements (R, C).
Post-treatment: Capacitor shall be stored for 1 to 2 hours at room condition
2
(SL). Capacitor shall be stored for 24 ± 2 hours at room condition
2
(R, C).
Measurement Order: Dielectric Strength ➞Pre-treatment ➞Capacitance ➞
Soldering Effect test ➞Post-treatment ➞Capacitance, Dielectric Strength
(R [250V]).
Apply a DC voltage of 200% of the rated voltage (in case of rated voltage: 250V,
500V) or DC voltage of 150% of the rated voltage (in case of rated voltage:
1 to 3.15kV) for 1000
+48
–0
hours at 125 ± 2°C.
Pre-treatment: Capacitor shall be stored at 125 ± 3°C for 1 hour, then placed at
room condition
2
for 24 ± 2 hours before initial measurements (R, C).
Post-treatment: Capacitor shall be stored for 1 to 2 hours at room condition
2
(SL). Capacitor shall be stored at 125 ± 3°C for 1 hour, then placed at room
condition
2
for 24 ± 2 hours (R, C).
Measurement Order: I.R. ➞Pre-treatment ➞Capacitance, D.F. ➞Life test ➞
I.R.
3
➞Post-treatment ➞Capacitance, D.F. (R [250V]).
(Charge/discharge current ≤50mA).
Set the capacitor for 500
+24
–0
hours at 40 ± 2°C in 90 to 95% humidity.
Pre-treatment: Capacitor shall be stored at 125 ± 3°C for 1 hour, then placed at
room condition
2
for 24 ± 2 hours before initial measurements (R, C).
Post-treatment: Capacitor shall be stored for 1 to 2 hours at room condition
2
.
Measurement Order: I.R. ➞Pre-treatment ➞Capacitance, D.F. ➞Humidity test
➞Post-treatment ➞Capacitance, D.F., I.R. (R [250V]).
(Charge/discharge current ≤50mA).
As in figure, fix the body of capacitor, apply a tensile weight gradually
to each lead wire in the radial direction of capacitor up to 10N
(1.0kgf) and keep it for 10 ± 1 sec.
Each lead wire shall be subjected to 5N (0.51kgf) weight and then a 90° bend, at
the point of egress, in one direction, return to original position, and then a 90°
bend in the opposite direction at the rate of one bend in 2 to 3 seconds.
The lead wire of a capacitor shall be dipped into a methanol solution of 25wt%
rosin and then into molten solder of 235 ± 5°C for 2 ± 0.5 seconds. In both
cases the depth of dipping is up to about 1.5 to 2mm from the root of lead wires.
Pre-treatment: Capacitor shall be stored at 125 ± 3°C for 1 hour, then placed at
room condition
2
for 24 ± 2 hours before initial measurements (R, C).
Pre-treatment: Capacitor shall be stored at 125 ± 3°C for 1 hour, then placed at
room condition
2
for 24 ± 2 hours before initial measurements (R, C).
Post-treatment: Capacitor shall be stored for 1 to 2 hours at room condition
2
(SL). Capacitor shall be stored for 24 ± 2 hours at room condition
2
(R, C).
Measurement Order: I.R., Dielectric Strength ➞Pre-treatment ➞Capacitance,
D.F. ➞Temp. Cycling test ➞Post-treatment ➞Capacitance, D.F., I.R., Dielectric
Strength (R [250V]).
The capacitor is placed in the container with metal balls of
diameter 1mm so that each lead wire, short-circuited, is kept
approximately 2mm off the balls as shown in the figure, and
AC voltage of 1250V is applied for 1 to 5 sec. between
capacitor lead wires and small metals.
(Charge/discharge current ≤50mA)
T.C. Temp. Coefficient
SL +350 to –1000ppm/°C Temp. Cap. Change
Range CR
–25 to within within
+85°C ±20% ±15%
+85 to within
+15
–30
%
+125°C
Char. Step 1 2 3 4 5
SL — — 20 ± 2°C 85±2°C/125±2°C 20 ± 2°C
C, R 20 ± 2°C –25 ± 3°C 20 ± 2°C 85±2°C/125±2°C 20 ± 2°C
Step Temp. (°C) Time (min.) Step Temp. (°C) Time (min.)
1–25 ± 3 30 ± 3 3+125 ± 3 30 ± 3
2room temp. 3 max. 4room temp. 3 max.
Approx. 2mm
Metal balls
W
