Murata DE2B3E2102KA3 Safety standard recognized ceramic capacitor Datasheet

o Part Numbering
Safety Standard Recognized Ceramic Capacitors
(Part Number)
DE
2
E3
KH 102 M
N3
A
q
w
e
r
u
i o
t
y
yCapacitance Tolerance
qProduct ID
Code
Product ID
High Voltage (250V - 6.3kV) /
Safety Standard Recognized Ceramic Capacitors
DE
wSeries Category
Code
1
2
J
Outline
Contents
Safety Standard
Recognized
IEC60384-14 Class X1, Y1
AC250V
(r.m.s.)
T5%
K
T10%
M
T20%
Z
W80%, Y20%
uLead Style
IEC60384-14 Class X1, Y2
"Products which are based on
the Electrical Appliance and
Material Safety Law of Japan"
In case of Electrical Appliance and Material Safety Law of Japan, first
three digits (qProduct ID and wSeries Category) express "Series
Name".
In case of Safety Recognized Capacitors, first three digits express
product code. The following fourth figure expresses recognized type
shown in rSafety Standard Recognized Type column.
Lead
Style
Code
eTemperature Characteristics
Dimensions (mm)
Lead
Spacing
A2
A4
Cap.Change
or Temp. Coeff.
B3
B
T10%
E3
E
W20%,Y55%
F3
F
W30%,Y80%
1X
SL
Temperature
Range
10
5
Vertical
Crimp
Short
B3
W350 to Y1000ppm/D W20 to W85D
Code
Pitch of
Components
7.5
ø0.6T0.05
10
10
ø0.6W0.1, Y0.05
C3
7.5
ø0.6T0.05
D3
Straight Short
7.5
ø0.6T0.05
5
N3
Vertical
Crimp
Taping
N4
N5
Straight Taping
P3
7.5
Y
ø0.6W0.1,Y0.05
Straight Long
N7
rRated Voltage/Safety Standard Recognized Type
ø0.6T0.05
10
B2
N2
Y25 to W85D
7.5
A5
B5
Temperature
Characteristics
Lead Diameter
5
Vertical
Crimp
Long
A3
B4
Code
Capacitance Tolerance
J
Y
Y
Y
12.7
ø0.6T0.05
10
15
25.4
10
ø0.6W0.1, Y0.05
25.4
7.5
ø0.6T0.05
30
7.5
ø0.6T0.05
15
Rated Voltage
iPackaging
E2
AC250V
KH
X1, Y2; AC250V, (Safety Standard Recognized Type KH)
Code
Packaging
KY
X1, Y2; AC250V, (Safety Standard Recognized Type KY)
A
Ammo Pack
KX
X1, Y1; AC250V, (Safety Standard Recognized Type KX)
B
Bulk
tCapacitance
oIndividual Specification
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 which 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.
In case part number cannot be identified without "Individual
Specification", it is added at the end of part number. Expreseed
by three figures.
Taping Specifications
12.7mm pitch / lead spacing 5mm taping
Vertical crimp type
(Lead Code : N2)
∆S
P2
P
∆S
D
e
P2
P
25.4mm pitch / lead spacing 10.0mm taping
Vertical crimp type
(Lead Code : N4, N5)
R
Item
∗
∗
3.0 max.
4.0 max.
H0
Lead Code
N5
Lead Code
P3
t2
t1
øD0
N5
Code
N2
N3
P3
N7
Pitch of component
P
12.7
15.0
15.0
30.0
25.4
Pitch of sprocket hole
P0
12.7±0.3
15.0±0.3
15.0±0.3
15.0±0.3
12.7±0.3
Lead spacing
F
5.0 +0.8
–0.2
7.5±1.0
7.5±1.0
7.5±1.0
10.0±1.0
Length from hole center to component center
P2
6.35±1.3
7.5±1.5
7.5±1.5
7.5±1.5
—
Length from hole center to lead
P1
3.85±0.7
3.75±1.0
3.75±1.0
3.75±1.0
7.7±1.5
Body diameter
D
Deviation along tape, left or right
∆S
Carrier tape width
W
Position of sprocket hold
W1
Lead distance between reference
H0
and bottom planes
H
Protrusion length
øD0
Lead diameter
ød
N4
See the individual product specifications
0±1.0
0±2.0
18.0±0.5
9.0±0.5
18.0 +2.0
–0
18.0 +2.0
–0
–
20.0 +1.5
–1.0
–
r
Diameter of sprocket hole
–
+0.5 to -1.0
4.0±0.1
0.6 +0.1
–0.05
0.6±0.05
Total tape thickness
t1
0.6±0.3
Total thickness, tape and lead wire
t2
1.5 max.
Body thickness
T
See the individual product specifications
Portion to cut in case of defect
L
11.0 +0
–1.0
Hold down tape width
W0
11.5 min.
Hold down tape position
W2
Coating extension on lead
W
∗
W
W1
L
F
W0 W2
H0
ød
øD0
R
H0
Lead Code
N2, N3, N4, N7
∗
e
D
O ∆h2
∆h1
T max.
Marked side
∆S
P
P0
W1
e
P0
P1
W0 W2
H0
ød
F
L
W
P1
øD0
R
P0
H
W1
W0
L
W2
ød
F
∆S
D
e
P1
W
30mm pitch / lead spacing 7.5mm taping
Vertical crimp type
(Lead Code : N7)
∆S
D
W2
W0
L
W1
L
P
øD0
R
P0
15mm pitch / lead spacing 7.5mm taping
Straight type
(Lead Code : P3)
P2
ød
F
øD0
R
P0
P1
W
ød
F
W 0 W2
H0
P1
H0
W1
D
P
e
P2
15mm pitch / lead spacing 7.5mm taping
Vertical crimp type
(Lead Code : N3)
e
Deviation across tape, front
∆h1
Deviation across tape, rear
∆h2
1.5±1.5
Up to the end of crimp
1.0 max.
3.0 max.
Up to the end of crimp
2.0 max.
(in mm)
Continued on the following page.
Continued from the preceding page.
Packaging Styles
Bulk
Taping
Polyethylene Bag
Ammo Pack
Minimum Quantity (Order in Sets Only)
[Bulk] 1,000 pcs.
[Taping]
Lead Code
(pcs.)
Type KY
Type KH
Type KX
DEJ Series
1,000
–
–
1,500
900
900
–
1,000
N7
–
400
–
–
N4, N5
–
–
500
–
N2
N3, P3
Minimum Order Quantity
[Bulk] 3,000 pcs.
(pcs.)
[Taping]
Lead Code
Type KY
Type KH
Type KX
DEJ Series
N2
3,000
–
–
3,000
N3, P3
2,700
2,700
–
3,000
N7
–
2,000
–
–
N4, N5
–
2,000
–
–
“Minimum Quantity” means the numbers of units of each delivery or order.
The quantity should be an integral multiple of the “minimum quantity”.
(In case of bulk packaging, minimum quantities differ from packing quantities in a
bulk bag.)
1. Operating Voltage
When DC-rated capacitors are to be used in AC or ripple
current circuits, be sure to maintain the Vp-p value of the
applied voltage or the Vo-p which contains DC bias within
the rated voltage range.
When the voltage is applied to the circuit, starting or
stopping may generate irregular voltage for a transit
period because of resonance or switching. Be sure to
use a capacitor with a rated voltage range that includes
these irregular voltages.
Voltage
Positional
Measurement
DC Voltage
V0-p
DC+AC Voltage
V0-p
AC Voltage
Vp-p
Pulse Voltage (1)
Vp-p
Pulse Voltage (2)
Vp-p
2. Operating Temperature and Self-generated Heat
(Apply to B/E/F Char.)
Keep the surface temperature of a capacitor below the
upper limit of its rated operating temperature range. Be
sure to take into account the heat generated by the
capacitor itself. When the capacitor is used in a highfrequency current, pulse current or similar current, it may
have self-generated heat due to dielectric loss. Applied
voltage load should be such that self-generated heat is
within 20°C under the condition where the capacitor is
subjected at an atmosphere temperature of 25°C. When
measuring, use a thermocouple of small thermal
capacity-K of ø0.1mm under conditions where the
capacitor is not affected by radiant heat from other
components or wind from surroundings. Excessive heat
may lead to deterioration of the capacitor's characteristics
and reliability. (Never attempt to perform measurement
with the cooling fan running. Otherwise, accurate
measurement cannot be ensured.)
3. Test condition for withstanding Voltage
(1) Test Equipment
Test equipment for AC withstanding voltage should be
used with the performance of the wave similar to
50/60Hz sine wave.
If the distorted sine wave or overload exceeding the
specified voltage value is applied, a defect may be
caused.
Continued on the following page.
Continued from the preceding page.
(2) Voltage Applied Method
When the withstanding voltage is applied, capacitor's
lead or terminal should be firmly connected to the output
of the withstanding voltage test equipment, and then the
voltage should be raised from near zero to the test
voltage.
If the test voltage without the raise from near zero voltage
would be applied directly to capacitor, test voltage should
be applied with the *zero cross. At the end of the test
time, the test voltage should be reduced to near zero,
and then capacitor's lead or terminal should be taken off
the output of the withstanding voltage test equipment.
If the test voltage without the raise from near zero voltage
would be applied directly to capacitor, the surge voltage
may arise, and therefore, a defect may be caused.
*ZERO CROSS is the point where voltage sine wave
passes 0V. See figure at right.
4. Fail-Safe
When capacitor would be broken, failure may result in a
short circuit. Be sure to provide an appropriate fail-safe
function like a fuse on your product if failure would result
in an electric shock, fire or fuming.
Failure to follow the above cautions may result, worst
case, in a short circuit and cause fuming or partial
dispersion when the product is used.
Voltage sine wave
0V
zero cross
Specifications and Test Methods
Apply to Type KY/KH/KX
Operating Temperature Range : -25 to +125°C (-25 to +85°C in case of the standard of UL)
No.
1
Specifications
Item
Appearance and Dimensions
No marked defect on appearance form and
dimensions are within specified range.
The capacitor should be visually inspected.
2
Marking
To be easily legible
3
Capacitance
Within specified tolerance
4
Dissipation Factor (D.F.)
Q
Char.
B, E
F
SL
5
Insulation Resistance (I.R.)
Testing Method
The capacitor should be visually inspected for evidence of
defect.
Dimensions should be measured with slide calipers.
Specifications
D.F.V2.5%
D.F.V5.0%
QU400+20C*1(CF30pF)
QU1000
(CU30pF)
The capacitance, dissipation factor and Q should be measured
at 20˚C with 1±0.1kHz (char. SL : 1±0.1MHz) and AC5V
(r.m.s.) max.
The insulation resistance should be measured with
DC500±50V within 60±5 sec. of charging.
The voltage should be applied to the capacitor through a
resistor of 1MΩ.
10000MΩ min.
The capacitor should not be damaged when test voltages of
Table 1 are applied between the lead wires for 60 sec.
<Table.1>
Type
Between Lead
No failure
Wires
KY
KH
KX
6
First, the terminals of the capacitor
should be connected together. Then,
as shown in figure at right, a metal
foil should be closely wrapped around
Metal
the body of the capacitor to the
about
Foil
distance of about 3 to 4mm from
3 to 4mm
each terminal.
Metal
Then, the capacitor should be inserted
Balls
into a container filled with metal balls
of about 1mm diameter. Finally, AC
voltage of Table 2 is applied for 60 sec. between the capacitor
lead wires and metal balls.
Dielectric
Strength
Body
Insulation
Test Voltage
In case of lead spacing F=5mm AC2000V (r.m.s.)
In case of lead spacing F=7.5mm AC2600V (r.m.s.)
AC2600V (r.m.s.)
AC4000V (r.m.s.)
No failure
<Table.2>
Type
KY
KH
KX
7
Temperature Characteristics
Capacitance Change
Char.
B
Within ±10%
E
Within +20
-55%
F
Within +30
-80%
Temperature characteristic guarantee is -25 to +85°C
Char.
SL
Temperature Coefficient
+350 to -1000ppm/°C
Temperature characteristic guarantee is +20 to +85°C
8
Solderability of Leads
Lead wire should be soldered with uniform coating
on the axial direction over 3/4 of the circumferential
direction.
Test Voltage
AC2600V (r.m.s.)
AC2600V (r.m.s.)
AC4000V (r.m.s.)
The capacitance measurement should be made at each step
specified in Table 3.
<Table.3>
Step
1
2
3
4
5
Temperature (ºC)
20±2
-25±2
20±2
85±2
20±2
The lead wire of a capacitor should be dipped into molten
solder for 2±0.5 sec.
The depth of immersion is up to about 1.5 to 2.0mm from the
root of lead wires.
Temp. of solder: Lead Free Solder (Sn-3Ag-0.5Cu) 245±5°C
H63 Eutectic Solder 235±5°C
*1 "C" expresses nominal capacitance value (pF).
Continued on the following page.
Specifications and Test Methods
Continued from the preceding page.
No.
9
10
11
Specifications
Item
Soldering
Effect
(Non-Preheat)
Appearance
No marked defect
Capacitance
Change
Within ±10%
I.R.
1000MΩ min.
Dielectric
Strength
Per Item 6
Appearance
No marked defect
Capacitance
Change
Within ±10%
I.R.
1000MΩ min.
Dielectric
Strength
Per Item 6
Appearance
No marked defect
Capacitance
Within the specified tolerance
Soldering
Effect
(On-Preheat)
Vibration
Resistance
D.F.
Q
Char.
B, E
F
SL
12
Humidity
(Under
Steady
State)
Appearance
No marked defect
Capacitance
Change
Char.
B
E, F
SL
Capacitance Change
Within ±10%
Within ±15%
Within ± 5%
Char.
B, E
F
Specifications
D.F.V5.0%
D.F.V7.5%
QU275+5/2C*1(CF30pF)
QU350
(CU30pF)
D.F.
Q
SL
13
Humidity
Loading
Specifications
D.F.V2.5%
D.F.V5.0%
QU400+20C*1(CF30pF)
QU1000
(CU30pF)
I.R.
3000MΩ min.
Dielectric
Strength
Per Item 6
Appearance
No marked defect
Capacitance
Change
Char.
B
E, F
SL
Capacitance Change
Within ±10%
Within ±15%
Within ± 5%
Char.
B, E
F
Specifications
D.F.V5.0%
D.F.V7.5%
QU275+5/2C*1(CF30pF)
QU350
(CU30pF)
D.F.
Q
SL
I.R.
3000MΩ min.
Dielectric
Strength
Per Item 6
Testing Method
As shown in figure, the lead wires
, Capacitor
should be immersed in solder of Thermal
Screen,
,
350±10°C or 260±5°C up to 1.5
,
,
1.5
,,,,,,,,,,
,
,,,,,,
to 2.0mm from the root of terminal
,,,,,,,,,,
,,,,
,
to 2.0mm
,
, Molten
for 3.5±0.5 sec. (10±1 sec. for
,,,
260±5°C).
Solder
Pre-treatment:
Capacitor should be stored at 85±2°C for 1 hr., then placed at
∗2
room condition for 24±2 hrs. before initial measurements.
Post-treatment:
Capacitor should be stored for 1 to 2 hrs. at ∗2room condition.
First the capacitor should be
, Capacitor
Thermal
stored at 120+0/-5°C for
Screen,
,
60+0/-5 sec.
,
,
1.5
,,,,,,,,,,
,
,,,,,,
Then, as in figure, the lead wires
,,,,,,,,,,
,,,,
,
to 2.0mm
,
,
should be immersed solder of
,,,Molten
260+0/-5°C up to 1.5 to 2.0mm
Solder
from the root of terminal for
7.5+0/-1 sec.
Pre-treatment:
Capacitor should be stored at 85±2°C for 1 hr., then placed at
∗2
room condition for 24±2 hrs. before initial measurements.
Post-treatment:
Capacitor should be stored for 1 to 2 hrs. at ∗2room condition.
The capacitor should be firmly soldered to the supporting lead
wire and vibrated at a frequency range of 10 to 55Hz, 1.5mm in
total amplitude, with about a 1 minute rate of vibration change
from 10Hz to 55Hz and back to 10Hz.
Apply for a total of 6 hrs., 2 hrs. each in 3 mutually
perpendicular directions.
Set the capacitor for 500±12 hrs. at 40±2°C in 90 to 95%
relative humidity.
Post-treatment:
Capacitor should be stored for 1 to 2 hrs. at ∗2room condition.
Apply the rated voltage for 500±12 hrs. at 40±2°C in 90 to 95%
relative humidity.
Post-treatment:
Capacitor should be stored for 1 to 2 hrs. at ∗2room condition.
*1 "C" expresses nominal capacitance value (pF).
*2 "room condition" Temperature: 15 to 35°C, Relative humidity: 45 to 75%, Atmospheric pressure: 86 to 106kPa
Continued on the following page.
Specifications and Test Methods
Continued from the preceding page.
No.
Specifications
Item
Appearance
No marked defect
Capacitance
Change
Within ±20%
I.R.
3000MΩ min.
Testing Method
Impulse Voltage
Each individual capacitor should be subjected to a 5kV (Type
KX: 8kV) impulses for three times. After the capacitors are
applied to life test.
100 (%)
90
Front time (T1) =1.2µs=1.67T
Time to half-value (T2) =50µs
50
30
0
14
t
T
T1
Life
T2
Dielectric
Strength
Apply a voltage of Table 4 for 1000 hrs. at 125+2/-0°C, and
relative humidity of 50% max.
Per Item 6
<Table.4>
Applied Voltage
AC425V (r.m.s.), except that once each hour the voltage
is increased to AC1000V (r.m.s.) for 0.1 sec.
Post-treatment:
Capacitor should be stored for 1 to 2 hrs. at ∗2room condition.
The capacitor should be subjected to applied flame for 15 sec.
and then removed for 15 sec. until 5 cycles are completed.
The capacitor flame discontinues as follows.
Cycle
1 to 4
5
Flame Test
Time (sec.)
30 max.
60 max.
7
12
38
20°
15
Capacitor
Flame
76
(in mm)
Gas Burner: Inside Dia. 9.5
Tensile
16
Robustness
of
Terminations
Lead wire should not be cut off. Capacitor should
not be broken.
As shown in the figure at right, fix the body
of the capacitor and apply a tensile weight
gradually to each lead wire in the radial
direction of the capacitor up to 10N and keep
it for 10±1 sec.
W
Each lead wire should be subjected to 5N weight and then a
90° bend, at the point of egress, in one direction, return to
original position, and then apply a 90° bend in the opposite
direction at the rate of one bend in 2 to 3 sec.
Bending
The capacitor should be individually wrapped in at least one but
not more than two complete layers of cheese-cloth. The
capacitor should be subjected to 20 discharges. The interval
between successive discharges should be 5 sec. The UAC
should be maintained for 2 min. after the last discharge.
F
S1
Tr
S2
C1
UAC
L1
C2
L3
R
L2
C3
Cx
Ct
Ut
L4
Oscilloscope
17
Active Flammability
The cheese-cloth should not be on fire.
C1,2
L1 to 4
Ct
Cx
F
: 1µF±10%
C3
: 0.033µF±5% 10kV
: 1.5mH±20% 16A Rod core choke
: 3µF±5% 10kV
R
: 100Ω±2%
: Capacitor under test
UAC
: UR±5%
: Fuse, Rated 10A
UR
: Rated Voltage
Ut
: Voltage applied to Ct
Ux
5kV
time
*1 "C" expresses nominal capacitance value (pF).
*2 "room condition" Temperature: 15 to 35°C, Relative humidity: 45 to 75%, Atmospheric pressure: 86 to 106kPa
Continued on the following page.
Specifications and Test Methods
Continued from the preceding page.
No.
Passive Flammability
The burning time should not exceed 30 sec.
The tissue paper should not ignite.
Testing Method
The capacitor under test should be held in the flame in the
position which best promotes burning. Each specimen should
only be exposed once to the flame. Time of exposure to flame:
30 sec.
Length of flame : 12±1mm
Gas burner
: Length 35mm min.
Inside Dia. 0.5±0.1mm
Outside Dia. 0.9mm max.
Gas
: Butane gas Purity 95% min.
Test Specimen
200T5mm
About 8mm
18
Specifications
Item
45°
Tissue
About 10mm Thick Board
19
Temperature
and
Immersion
Cycle
Appearance
No marked defect
Capacitance
Change
Char.
B
E, F
SL
Capacitance Change
Within ±10%
Within ±20%
Within ± 5%
Char.
B, E
F
Specifications
D.F.V5.0%
D.F.V7.5%
QU275+5/2C*1(CF30pF)
QU350
(CU30pF)
D.F.
Q
SL
I.R.
Dielectric
Strength
3000MΩ min.
Per Item 6
The capacitor should be subjected to 5 temperature cycles,
then consecutively to 2 immersion cycles.
<Temperature Cycle>
Step
1
2
3
4
Temperature (ºC)
-25+0/-3
Room temp.
125+3/-0
Room temp.
Time (min.)
30
3
30
3
Cycle time: 5 cycle
<Immersion Cycle>
Step
Temperature (ºC)
Time
(min.)
1
65+5/-0
15
2
0±3
15
Immersion
Water
Clean
water
Salt
water
Cycle time: 2 cycle
Pre-treatment:
Capacitor should be stored at 85±2˚C for 1 hr., then placed at
∗2
room condition for 24±2 hrs.
Post-treatment:
Capacitor should be stored for 24±2 hrs. at ∗2room condition.
*1 "C" expresses nominal capacitance value (pF).
*2 "room condition" Temperature: 15 to 35°C, Relative humidity: 45 to 75%, Atmospheric pressure: 86 to 106kPa
Type KY/KH/KX are recognized by UL1414 6th edition and CSA E384-14.
"Discharge Test" that was compulsory in previous safety standards(*) is not specified in new safety standards. (* UL1414 5th edition and CSA C22.2 No.1)
Therefore the description of "Discharge Test" is deleted in this catalog.
Type KX (B char.)
Type KX (E char.)
AC voltage : 60Hz
Temperature : 25°C
AC voltage : 60Hz
Temperature : 25°C
6.0
A5B
1.0
71K
KX4
Leakage current [mA(r.m.s.)]
Leakage current [mA(r.m.s.)]
1.2
B3
DE1
0.8
0.6
B3
D E1
0.4
KX2
DE1B3K
0.2
A5B
21K
X101KA
5B
A01
A5B
72M
KX4
3
E
DE1
5.0
4.0
3.0
5BA01
X222MA
DE1E3K
2.0
BA01
DE1E3KX102MA5
1.0
0.0
0.0
0
1000
2000
AC voltage [V(r.m.s.)]
3000
4000
0
1000
2000
AC voltage [V(r.m.s.)]
3000
4000
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