Type AXLH -40 ºC to +150 ºC
High Temperature Axial Leaded Aluminum Electrolytic Capacitors
High Performance Axial Leaded Aluminum Electrolyic Capacitors
Highlights
470 to 4700 µF
Capacitance Tolerance (100 Hz/+20 ºC)
-10/+30%
Rated Voltage
25, 40, 63 Vdc
Operating Temperature
-40 ºC to +150 ºC
Leakage Current (at 20°C)
I = 0.003 CV +4.0 µA; after 5 minutes at rated voltage
I = leakage current in µAmps
C = rated capacitance in µF
V = rated DC Working voltage in Volts
Standard
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Frequency (Hz)
100
300
Ripple Current Correction Factor
0.35
0.57
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Ripple Current vs. Frequency Correction Factors
Shelf Life
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Capacitance Range (100 Hz/+20 ºC)
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Specifications
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- 150 °C Operating Temperature
- Up to 28 Amps RMS Continuous Ripple Current
- Capacitance Range: 470 µF to 4700 µF
- High Vibration Resistance
- Very Long Shelf Life
- Low Leakage Current
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Type AXLH capacitors are a new generation of high performance
aluminum electrolytic capacitors rated up to 2000 hours at 150 ºC.
They are designed for applications that place high demands on a
capacitor. The capacitor’s outstanding features include low ESR, low
leakage current, a long shelf life and a high ripple current capability.
1000 5000
0.8
1
100 kHz
1.04
(+105 ºC/0 Vdc): 5000 hours
(+40 ºC/0 Vdc): 10 years
IEC 60384-4 long life grade 40/125/56
RoHS Compliant
222
P
025
E
D
Capacitance
Capacitance Tolerance
Voltage Code
Case Dia.Code
Length Code
222 = 2200 µF
P = -10/+30%
025 = 25 Vdc
E = 20 mm
D = 27 mm
LE
T
AXLH
E
Part Numbering System
Case
040 = 40 Vdc
H = 35 mm
063 = 63 Vdc
L = 43 mm
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CDM Cornell Dubilier • 140 Technology Place • Liberty, SC 29657 • Phone: (864)843-2277 • Fax: (864)843-3800
Type AXLH -40 ºC to +150 ºC
High Temperature Axial Leaded Aluminum Electrolytic Capacitors
Load Life Test
∆C
Capacitance will be within ±15% of the initial value
Clamp the case to the test fixture.
Frequency range is 10 - 2000 Hz. Amplitude of 1.5mm or 20 g
acceleration.
Duration of test is 22 hours in each of three directions.
After the test, measure the capacitance at +20°C.
∆C
Capacitance change from the initial measurement must not exceed 5%.
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Test
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Vibration Test
No electrolyte leakage or other visible damage. The markings will be
legible.
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Appearance
H
ESR will be less than 2 times the initial value
The leakage current will be within the specified value
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ESR
DCL
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Test
Mount the capacitor on a heat sink with a low thermal resistance path.
Apply the maximum rated voltage for 2000 hrs at +150°C with the
+150°C maximum ripple current applied to the capacitor. After the
test, measure the capacitance, ESR, and DCL at +20°C.
Test
Subject the capacitor to 1000 surge voltage cycles at +150°C. For each
cycle, apply 1.15 times the rated voltage for 30 seconds followed by no
voltage for 5 min. and 30 seconds. The time constant for charging is 0.1
seconds. After one to two hours, measure the capacitance and esr.
∆C
Capacitance change from the initial measurement must not exceed 15%.
ESR
The ESR will be < 2x initial value.
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Surge Voltage Test
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Appearance No electrolyte leakage or other visible damage.
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Appearance No electrolyte leakage or other visible damage.
Storage at Low Temperature Test
Test
Subject the capacitor to 72 hours at -55°C. After 16 hours at room
temperature, measure the capacitance and DCL.
∆C
Capacitance change from the initial measurement must not exceed 10%.
DCL
Leakage current will meet the initial specification.
Appearance
No electrolyte leakage or other visible damage. The markings are to be
legible.
Test
Subject the capacitor to 1 million charge/discharge cycles at +20°C. For
each cycle, apply the rated voltage for 0.5 seconds using a 0.1 second
charge/discharge time constant. After the test, the following will apply;
∆C
Capacitance will be within ±10% of the initial value.
Appearance No electrolyte leakage or other visible damage.
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Charge and Discharge Test
CDM Cornell Dubilier • 140 Technology Place • Liberty, SC 29657 • Phone: (864)843-2277 • Fax: (864)843-3800
Type AXLH -40 ºC to +150 ºC
High Temperature Axial Leaded Aluminum Electrolytic Capacitors
Ratings
(µF)
(%)
2200
-10/+30
Cornell Dubilier
Part Number
25
AXLH222P025ED
Case
Size
DxL
Rated
Maximum
Max. ESR
Max. ESR
Ripple Current Ripple Current
100 Hz/+20°C 100 kHz/+20°C
≥ 5kHz/+125°C ≥ 5kHz/+125°C
(mm)
(mΩ)
(mΩ)
(A)
20 x 27
50
25
7.1
(A)
9.1
3300
-10/+30
25
AXLH332P025EH
20 x 35
34
17
8.9
4700
-10/+30
25
AXLH472P025EL
20 x 43
25
13
10.3
1500
-10/+30
40
AXLH152P040ED
20 x 27
57
22
7.3
9.3
2200
-10/+30
40
AXLH222P040EH
20 x 35
41
17
8.9
11.2
2700
-10/+30
40
AXLH272P040EL
20 x 43
32
13
63
AXLH471P063ED
20 x 27
125
32
63
AXLH681P063EH
20 x 35
87
23
900
-10/+30
63
AXLH901P063EL
20 x 43
67
18
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-10/+30
-10/+30
10.1
12.8
5.5
7.0
6.9
8.7
8.1
10.2
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Outline Drawings & Dimensions Table
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470
680
11.3
13.1
Dimensions in mm
Size Code
Approximate Weight
(grams)
D
L
d
LL
± 0.5
±1
± 0.03
±2
ED
20
26.5
1
40
13
EH
20
34.5
1
40
20
EL
20
42.5
1
40
24
Note: Bend leads at least 3.5 mm from the case.
CDM Cornell Dubilier • 140 Technology Place • Liberty, SC 29657 • Phone: (864)843-2277 • Fax: (864)843-3800
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Capacitance
Tolerance
H
Rated
Capacitance
100Hz/+20°C
Type AXLH -40 ºC to +150 ºC
High Temperature Axial Leaded Aluminum Electrolytic Capacitors
R
Cornell Dubilier
Part Number
AXLH222P025ED
10.6
22.2
14
6.3
AXLH332P025EH
7.8
25.8
16.3
7.3
AXLH472P025EL
6.4
28.5
18
AXLH152P040ED
10
22.8
14.4
AXLH222P040EH
7.9
25.7
16.2
6.7
27.9
17.6
17.5
17.3
10.9
AXLH681P063EH
13
20
AXLH901P063EL
10.6
22.2
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AXLH272P040EL
AXLH471P063ED
≥ 5 kHz/+150°C
(A)
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≥ 5 kHz/+140°C
(A)
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≥ 5 kHz/+125°C
(A)
H
Maximum Ripple Current *
Max.
ESR 5-100 kHz
125-150°C
(mΩ)
6.5
7.3
7.9
4.9
12.7
5.7
14
6.3
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Heat-Sinked Ratings
Marking
Description
-- CDM ++
Logo, Polarity Marks
AXLH222P025ED
CDE Part Number
2200 uF 25VDC
Capacitance, Rated Voltage (VDC)
160603
Date Code (Year, Week), Batch Number
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Capacitor Markings
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* When the capacitor is mounted to a heat-sink using low thermal resistance path.
CDM Cornell Dubilier • 140 Technology Place • Liberty, SC 29657 • Phone: (864)843-2277 • Fax: (864)843-3800
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Notice and Disclaimer: All product drawings, descriptions, specifications, statements, information and data
(collectively, the “Information”) in this datasheet or other publication are subject to change. The customer
is responsible for checking, confirming and verifying the extent to which the Information contained in this
datasheet or other publication is applicable to an order at the time the order is placed. All Information given
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the suitability for a specific customer application, use, storage, transportation, or operating environment.
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