Conductive Polymer Hybrid Aluminum
Electrolytic Capacitors
● Endurance: 4000 h at 125 ℃ (High temperature / Long life)
● Low ESR and high ripple current (85 % over, Lower ESR than current V-TP)
● High-withstand voltage ( to 80 V), Low LC (0.01 CV or 3 μA)
● Equivalent to conductive polymer type aluminum electrolytic capacitor
(There are little characteristics change by temperature and frequency)
● Vibration-proof product is available upon request. New lineup of φ6.3 product. (φ6.3, φ8, φ10)
● AEC-Q200 compliant
● RoHS compliant
Example : 25 V 33 μF
[Standard]
Marking color : BLACK Unit:mm
[Vibration-proof product]
< Size code:D, D8 > < Size code:F, G >
High temperature lead-free reflow
ZC series
V type
Design and specifications are each subject to change without notice. Ask factory for the current technical specifications before purchase and/or use.
13-Dec-19
G
F
D8
D
Size code
0.70±0.2 5.3 1.3±0.2
10.0 10.5±0.3 10.3 12.0
0 to +0.15
3.5 1.2±0.2 4.6 0.70±0.2
2.2
0.35
+0.15
7.8
2.4
1.05±0.2
-0.20
0.70±0.2 6.9 1.3±0.2
-0.20
3.4 1.2±0.2 3.1 0.70±0.2
2.2 0.35
+0.15
1.1±0.2 3.3 1.05±0.2
10.0
0 to +0.15
R. voltage code
Unit:V
E
25
V
35
K
80
6.3 8.0±0.3 6.6 7.8
0 to +0.15
J
63
8.0 10.5±0.3 8.3
0 to +0.15
Unit:mm
H
50
φD
L
A, B
H
F
I
W
P
K
R
S
T
max.
1.1±0.2
3.3
6.3
6.1±0.3
6.6
2.4 0.65±0.1
0.65±0.1
G
10.0 10.2±0.3 10.3 12.0 3.5 0.90±0.2 4.6 0.70±0.2
+0.15
-0.20
F
8.0 10.2±0.3 8.3 10 3.4 0.90±0.2 3.1 0.70±0.2
D8
6.3 7.7±0.3 6.6 7.8 2.6 0.65±0.1 1.8 0.35
1.5 0.35
+0.15
-0.20
D
6.3
5.8±0.3
6.6
7.8
2.6
0.65±0.1
1.8
0.35
+0.15
-0.20
A, B
H
I
W
code
max.
5.3 6.5 2.2 0.65±0.15.0 5.8±0.3
Size
φD
L
Category temp. range
25 V to 63 V
25 V to 80 V
25 V to 50 V
Dissipation factor (tan δ)
Endurance 1
+125 ℃ ± 2 ℃, 4000 h, apply the rated ripple current without exceeding the rated voltage.
DC leakage current
Within the initial limit
DC leakage current
D
I ≦ 0.01 CV or 3 (μA) After 2 minutes (whichever is greater)
Please see the attached characteristics list
D8
F
G
–55 ℃ to +125 ℃
C
Dissipation factor (tan δ)
Capacitance change
Dissipation factor (tan δ)
ESR
10 μF to 33 μF
10 μF to 56 μF
22 μF to 100 μF
22 μF to 220 μF
33 μF to 330 μF
+125 ℃ ± 2 ℃, 3000 h, apply the rated ripple current without exceeding the rated voltage.
≦ 200 % of the initial limit
≦ 200 % of the initial limit
Within ±30% of the initial value
P
K
C
Capacitance change
Dissipation factor (tan δ)
Within ±30% of the initial value
≦ 200 % of the initial limit
≦ 300 % of the initial limit
Within the initial limit
Within ±10% of the initial value
Within the initial limit
≦ 200 % of the initial limit
Within the initial limit
≦ 200 % of the initial limit
+85 ℃ ± 2 ℃, 85 % to 90 %RH, 2000 h, rated voltage applied
DC leakage current
Marking
Dimensions (not to scale)
Resistance to
soldering heat
following limits.
DC leakage current
Within the initial limit
After reflow soldering and then being stabilized at +20 ℃, capacitors shall meet the
Surface Mount Type
Capacitance change
Capacitance change
Dissipation factor (tan δ)
ESR
Within ±30% of the initial value
Endurance 2
Shelf life
Damp heat (Load)
ESR
DC leakage current
Capacitance tolerance
Nominal cap.range
Rated voltage range
Specifications
Size code
Features
After storage for 1000 hours at +125 ℃ ± 2 ℃ with no voltage applied and then being
(With voltage treatment)
±20 % (120 Hz / +20 ℃)
stabilized at +20 ℃, capacitors shall meet the limits specified in endurance.
33
EZC
Negative polarity marking ()
Capacitance (μF)
Series identification
Rated voltage
Lot number
Pressure relief (φ10 ≦) ( ) Reference size
0.3 max.
H
L
φD±0.5
K
0.2
W
(I)
(P)
(I)
0.2
Supportive terminals ( ) Reference size
0.2
0.2
K
(I)
(I) (P)
W
(S)
R
T
φD±0.5
H
F
L
Supportive terminals ( ) Reference size
Pressure relief (φ10 ≦)
F
H
L
K
0.2
W
(I)
(P)
(I)
T
R
(S)
0.2
φD±0.5
Hybrid
Conductive Polymer Hybrid Aluminum Electrolytic Capacitors
Endurance 1 : 125 ℃ 4000 h
Endurance 2 : 125 ℃ 3000 h
*1: Ripple current (100 kHz / +125 ℃)
*2: ESR (100 kHz / +20 ℃)
*3: tan δ (120 Hz / +20 ℃)
◆ Please refer to the page of “Reflow profile” and “The taping dimensions.
◆ The dimensions of the vibration-proof products, please refer to the page of the mounting specification.
ZC series
13-Dec-19
Specification Part number Min.
packaging
q'ty
Taping
(pcs)
Case size
(mm)
Vibration-proof
product
Standard
Product
ESR*2
(mΩ) tan δ*3
L
Standard Vibration
-proof Endurance
2
Endurance
1
Ripple current *1
(mA rms)
0.08
EEHZC1K330P
EEHZC1K330V
500
47
10.0
10.2
10.5
G
1360
36
0.08
EEHZC1K470P
EEHZC1K470V
500
EEHZC1J820P
EEHZC1J820V
500
80
22
8.0
10.2
10.5
F
1050
45
0.08
EEHZC1K220P
EEHZC1K220V
500
33
10.0
10.2
10.5
G
1360
36
82
10.0
10.2
10.5
G
1400
30
0.08
500
68
10.0
10.2
10.5
G
1400
30
0.08
EEHZC1J680P
EEHZC1J680V
500
56
10.0
10.2
10.5
G
1400
30
0.08
EEHZC1J560P
EEHZC1J560V
500
47
8.0
10.2
10.5
F
1100
40
0.08
EEHZC1J470P
EEHZC1J470V
500
40
0.08
EEHZC1J330P
EEHZC1J330V
1000
22
6.3
7.7
8.0
D8
900
80
0.08
EEHZC1J220XP
EEHZC1J220XV
900
5.8
EEHZC1J100V
6.3
G
1600
28
0.10
EEHZC1H121P
EEHZC1H121V
500
63
10
6.1
D
700
120
0.08
EEHZC1J100P
33
8.0
10.2
10.5
F
1100
G
1600
28
0.10
EEHZC1H101P
EEHZC1H101V
500
30
0.10
F
1250
F
1250
30
0.10
EEHZC1H470P
EEHZC1H470V
500
EEHZC1H680P
EEHZC1H680V
500
750
80
0.10
EEHZC1H220P
EEHZC1H220V
1000
7.7
D8
1100
40
0.10
EEHZC1H330XP
EEHZC1H330XV
900
G
2000
2800
20
0.12
EEHZC1V271P
EEHZC1V271V
500
50
10
5.8
C
500
120
0.10
EEHZC1H100R
1000
22
6.3
5.8
6.1
D
EEHZC1V151P
EEHZC1V151V
500
220
10.2
G
2000
2800
20
0.12
EEHZC1V221P
EEHZC1V221V
500
F
1600
1900
10.5
EEHZC1V680XV
900
10.2
F
1600
1900
27
0.12
EEHZC1V101P
EEHZC1V101V
500
7.7
10.5
1000
47
D
900
60
0.12
EEHZC1V470P
EEHZC1V470V
1000
5.8
5.8
6.3
6.3
1000
22
C
550
100
0.12
EEHZC1V220R
1000
5.8
5.8
5.0
5.0
35
10
C
550
100
0.12
EEHZC1V100R
33
D
900
60
0.12
EEHZC1V330P
EEHZC1V330V
68
D8
1400
35
0.12
EEHZC1V680XP
G
2000
2900
20
0.14
EEHZC1E331P
EEHZC1E331V
500
10.2
EEHZC1E151P
EEHZC1E151V
500
220
F
1600
1900
27
0.14
EEHZC1E221P
EEHZC1E221V
500
10.2
10.2
1900
F
1600
EEHZC1E560P
EEHZC1E560V
1000
900
100
D8
1400
30
0.14
EEHZC1E101XP
EEHZC1E101XV
900
7.7
D8
1400
EEHZC1E680XP
EEHZC1E680XV
D
900
50
56
D
900
50
150 μF ≦ C
47 μF ≦ C < 150 μF
1.00
1.00
25
22
5.0
5.8
C
550
80
33
5.0
5.8
C
550
80
47
5.8
6.1
0.50
0.60
0.65
0.70
0.75
0.90
50 kHz ≦ f < 100 kHz
0.80
0.75
15 kHz ≦ f < 20 kHz
0.50
1.05
1.00
1.00
10 kHz ≦ f < 15 kHz
0.45
0.80
0.85
Characteristics list
Frequency correction factor for ripple current
500 kHz ≦ f
0.80
0.85
30 kHz ≦ f < 40 kHz
Frequency (f)
Frequency (f)
20 kHz ≦ f < 30 kHz
0.60
0.65
Correction
factor
C < 47 μF
Frequency (f)
Rated capacitance(C)
Rated capacitance(C)
150 μF ≦ C
100 kHz ≦ f < 500 kHz
0.85
0.80
47 μF ≦ C < 150 μF
0.45
0.40
Correction
factor
0.3
φ10xL10.2
Design and specifications are each subject to change without notice. Ask factory for the current technical specifications before purchase and/or use.
0.85
0.85
40 kHz ≦ f < 50 kHz
0.75
0.70
Size
ESR(Ω)
φ5xL5.8
φ6.3xL5.8
φ6.3xL7.7
φ8xL10.2
2
1.4
0.8
0.4
After endurance ESR (100 kHz, –40 °C)
Correction
factor
0.90
C < 47 μF
1.00
0.15
150 μF ≦ C
47 μF ≦ C < 150 μF
C < 47 μF
Frequency (f)
Correction
factor
1 kHz ≦ f < 2 kHz
0.30
Rated capacitance(C)
2 kHz ≦ f < 3 kHz
C < 47 μF
0.10
0.10
0.45
5.0
6.3
8.0
0.60
5 kHz ≦ f < 10 kHz
0.30
0.30
Rated capacitance(C)
150 μF ≦ C
0.25
0.25
300 Hz ≦ f < 500 Hz
0.25
0.20
200 Hz ≦ f < 300 Hz
0.15
0.15
100 Hz ≦ f < 200 Hz
47 μF ≦ C < 150 μF
3 kHz ≦ f < 5 kHz
0.20
500 Hz ≦ f < 1 kHz
0.40
0.55
6.3
10.2
68
150
8.0
100
150
8.0
330
8.0
120
10.5
10.5
10.5
10.5
10.5
33
47
68
100
10.2
10.2
10.2
270
10.0
10.0
8.0
10.5
10.2
10.2
10.0
10.0
0.14
0.14
0.14
30
0.14
27
0.14
27
0.12
0.14
EEHZC1E220R
1000
EEHZC1E330R
1000
EEHZC1E470P
EEHZC1E470V
1000
Rated
voltage
(V)
Size
code
Capacitance
(±20 %)
(μF) φD
6.1
6.1
8.0
6.3
6.3
6.3
6.3
8.0
8.0
10.0
10.5
10.5
10.5
5.8
7.7
6.1
8.0
8.0
■ If you want to use our products described in this online catalog for applications requiring
special qualities or reliability, or for applications where the failure or malfunction of the
products may directly jeopardize human life or potentially cause personal injury
(e.g. aircraft and aerospace equipment, traffic and transportation equipment, combustion
equipment, medical equipment, accident prevention, anti-crime equipment, and/or safety
equipment), it is necessary to verify whether the specifications of our products fit to such
applications. Please ensure that you will ask and check with our inquiry desk as to whether
the specifications of our products fit to such applications use before you use our products.
■ The quality and performance of our products as described in this online catalog only apply
to our products when used in isolation. Therefore, please ensure you evaluate and verify
our products under the specific circumstances in which our products are assembled in your
own products and in which our products will actually be used.
■ If you use our products in equipment that requires a high degree of reliability, regardless
of the application, it is recommended that you set up protection circuits and redundancy
circuits in order to ensure safety of your equipment.
■ The products and product specifications described in this online catalog are subject to
change for improvement without prior notice. Therefore, please be sure to request and
confirm the latest product specifications which explain the specifications of our products in
detail, before you finalize the design of your applications, purchase, or use our products.
■ The technical information in this online catalog provides examples of our products'
typical operations and application circuits. We do not guarantee the non-infringement of
third party's intellectual property rights and we do not grant any license, right, or interest
in our intellectual property.
■ If any of our products, product specifications and/or technical information in this online
catalog is to be exported or provided to non-residents, the laws and regulations of the
exporting country, especially with regard to security and export control, shall be observed.
■ The switchover date for compliance with the RoHS Directive/REACH Regulations varies
depending on the part number or series of our products.
■ When you use the inventory of our products for which it is unclear whether those products
are compliant with the RoHS Directive/REACH Regulation, please select "Sales Inquiry" in the
website inquiry form and contact us.
We do not take any responsibility for the use of our products outside the scope of the
specifications, descriptions, guidelines and precautions described in this online catalog.
13-Dec-19
Guidelines and precautions regarding the
technical information and use of our products
described in this online catalog.
<Regarding the Certificate of Compliance with
the EU RoHS Directive/REACH Regulations>
Notices / Items to be observed
■ Applicable laws and regulations
・This product complies with the RoHS Directive (Restriction of the use of certain hazardous substances in
electrical and electronic equipment (DIRECTIVE 2011/65/EU and(EU)2015/863)).
・ No Ozone Depleting Chemicals(ODC's), controlled under the Montreal Protocol Agreement, are used in
producing this product.
 We do not use PBBs or PBDEs as brominated flame retardants.
・ Export procedure which followed export related regulations, such as foreign exchange and a foreign trade
method, on the occasion of export of this product.
・ These products are not dangerous goods on the transportation as identified by UN(United Nations) numbers
or UN classification.
■ Limited applications
・ This capacitor is designed to be used for electronics circuits such as audio/visual equipment, home
appliances, computers and other office equipment, optical equipment, measuring equipment.
・ An advanced specification must be signed individually for high-reliability use that might threaten
 human life or property due to a malfunction of the capacitor.
■ Intellectual property rights and licenses
・ The technical information in this specification provides examples of our products' typical operations and application
circuits. We do not guarantee the non-infringement of third party's intellectual property rights and we do not grant
any license, right, or interest in our intellectual property.
■ For specification
・ This specification guarantees the quality and performance of the product as individual components.
The durability differs depending on the environment and the conditions of usage.
Before use, check and evaluate their compatibility with actual conditions when installed in the products.
When safety requirements cannot be satisfied in your technical examination, inform us immediately.
・ Do not use the products beyond the specifications described in this document.
■ Upon application to products where safety is regarded as important
Install the following systems for a failsafe design to ensure safety if these products are to be used in
equipment where a defect in these products may cause the loss of human life or other signification damage,
such as damage to vehicles (automobile, train, vessel), traffic lights, medical equipment, aerospace equipment,
electric heating appliances, combustion/ gas equipment, rotating rotating equipment, and disaster/crime
prevention equipment.
(1) The system is equipped with a protection circuit and protection device.
(2) The system is equipped with a redundant circuit or other system to prevent an unsafe status in the event
of a single fault.
■ Conditions of use
・ Before using the products, carefully check the effects on their quality and performance, and determined
 whether or not they can be used. These products are designed and manufactured for general-purpose and
 standard use in general electronic equipment. These products are not intended for use in the following special
 conditions.
(1) In liquid, such as Water, Oil, Chemicals, or Organic solvent.
(2) In direct sunlight, outdoors, or in dust.
(3) In vapor, such as dew condensation water of resistive element, or water leakage, salty air, or air with a
high concentration corrosive gas, such as Cl2, H2S, NH3, SO2, or NOx.
(4) In an environment where strong static electricity or electromagnetic waves exist.
(5) Mounting or placing heat-generating components or inflammables, such as vinyl-coated wires, near
these products.
(6) Sealing or coating of these products or a printed circuit board on which these products are mounted,
with resin and other material.
(7) Using resolvent, water or water-soluble cleaner for flux cleaning agent after soldering. (In particular,
when using water or a water-soluble cleaning agent, be careful not to leave water residues)
(8) Using in the atmosphere where strays acid or alkaline.
(9) Using in the atmosphere where there are excessive vibration and shock.
(10) Using in the atmosphere where there are low pressure or decompression.
・ Please arrange circuit design for preventing impulse or transitional voltage.
 Do not apply voltage, which exceeds the full rated voltage when the capacitors receive impulse voltage,
 instantaneous high voltage, high pulse voltage etc.
・ Our products there is a product are using an electrolyte solution. Therefore, misuse can result in rapid
 deterioration of characteristics and functions of each product. Electrolyte leakage damages printed circuit and
affects performance, characteristics, and functions of customer system.
Notices
Items to be observed
13-Dec-19
Conductive Polymer Hybrid Aluminum Electrolytic Capacitors
1. Circuit design
1.1 Operating temperature and frequency
Electrical characteristics of the capacitor are likely to change due to variation in temperature and/or frequency.
Circuit designers should take these changes into consideration.
(1) Effects of operating temperature on electrical parameters
At higher temperatures : leakage current and capacitance increase while equivalent series resistance
(ESR) decreases.
At lower temperatures : leakage current and capacitance decrease while equivalent series resistance
(ESR) increases.
(2) Effects of frequency on electrical parameters
At higher frequencies : capacitance and impedance decrease while tan d increases.
At lower frequencies : heat generated by ripple current will rise due to an increase in equivalent
series resistance (ESR).
1.2 Operating temperature and life expectancy
(1) Expected life is affected by operating temperature. Generally, each 10 °C reduction in temperature will
double the expected life. Use capacitors at the lowest possible temperature below the upper category
temperature.
(2) If operating temperatures exceed the upper category limit, rapid deterioration of electrical parameter
will occur and irreversible damage will result.
Check for the maximum capacitor operating temperatures including ambient temperature, internal
capacitor temperature rise due to ripple current, and the effects of radiated heat from power transistors,
IC's or resistors.
Avoid placing components, which could conduct heat to the capacitor from the back side of the circuit board.
(3) The formula for calculating expected life at lower operating temperatures is as follows ;
L2 = L1×2
L1:Guaranteed life (h) at temperature, T1
L2:Expected life (h) at temperature, T2
T1:Upper category temperature + temperature rise due to rated ripple current (℃)
T2:Actual operating temperature, ambient temperature + temperature rise due to ripple current (℃)
(4) Using the capacitor beyond the rated lifetime will result in short circuit, electrolyte leak, vent open, and large
  deterioration of characteristics. The lifetime cannot exceed 15 years due to aging of sealing rubber.
1.3 Load conditions to avoid
The following load conditions will cause rapid deterioration of capacitor’s electrical characteristics.
In addition, instantaneous heating and gas generation within the capacitor may cause an operation of pressure
relief vent, and that results in electrolyte leaks, explosion and/or fire ignition.
The leaked electrolyte is combustible and electrically conductive.
(1) Reverse voltage
DC capacitors have polarity. Therefore, do not apply the reverse voltage. Find the correct polarity before
insertion.
(2) Charge / Discharge applications
General purpose capacitors are not suitable for use in repeating charge/discharge applications. For such
applications, consult a sales representative with actual application condition. Rush current must not exceed
100 A.
(3) ON-OFF circuit
When using capacitors in circuit where ON-OFF switching is repeated more than 10,000 times a day, consult
a sales representative with actual application condition for an appropriate choice of capacitors.
(4) Over voltage
Do not apply a voltage exceeding the rated voltage. The rated surge voltage can be applied only for a short
time. Make sure that a sum of the DC voltage and the superimposed AC ripple voltage does not exceed the
rated voltage.
(5) Ripple current
Do not apply ripple currents exceeding the rated value.
Make sure that rated ripple currents superimposed on low DC bias voltages do not cause reverse voltage
conditions. Even if the current is below the rated ripple current, using the capacitor for longer than the
rated lifetime will cause ESR increase and internal generation of heat, which may eventually lead to vent open,
bulging of case/rubber, electrolyte leak, shot circuit, explosion, or ignition in the worst case.
  Application guidelines(Hybrid)
30-Sep-20
T1-T2
10
Conductive Polymer Hybrid Aluminum Electrolytic Capacitors
1.4 Using two or more capacitors in parallel
Because the hybrid aluminum electrolytic capacitors have very small impedance, various circuit board pattern of wiring
to each capacitor may cause unbalanced ripple current loads among the parallel capacitors. Careful wiring methods
can minimize the potential risk of an excessive ripple current concentrated to one capacitor.
The capacitors cannot be used in series.
1.5 Capacitor mounting considerations
(1) For double sided circuit boards, avoid wiring patterns passing between the mounted capacitor and the circuit
board. When a radial lead type capacitor is dipped into a solder bath, an excess solder may deposit under the
capacitor by capillary action, causing short circuit between anode and cathode terminals. Also, lead holes must
be placed with special care for radial lead type capacitors because laminate on capacitor’s surface may become
damaged during flow process.
(2) The pitch between circuit board holes should match the lead wire pitch of the radial lead type capacitors within
the specified tolerances. Unmatched pitch may cause an excessive stress on lead wires during the insertion process
and result in short/open circuit, increased leakage current, or electrolyte leak.
(3) Clearance for case mounted pressure relief (≧ φ10 mm)
Capacitors with case mounted pressure relief require sufficient clearance to allow for proper pressure relief
operation. The minimum clearance are dependent on capacitor diameters as follows.
* ≧φ10 mm : 2 mm minimum
(4) Wiring near the pressure relief (≧ φ10 mm)
Avoid locating high voltage or high current wiring or circuit board paths above the pressure relief.
Flammable, high temperature gas that exceeds 100 ℃ may be released which could dissolve the wire
insulation and ignite.
(5) Circuit board patterns under the capacitor
Avoid circuit board runs under the capacitor, as an electrical short can occur due to an electrolyte leakage.
(6) Resonant vibration after circuit board’s production may make a heavy load on the capacitor and cause rapid
change in characteristics and/or capacitor’s break.
1.6 Electrical isolation
Electrically isolate the capacitor’s case from cathode terminals, as well as circuit patterns.
1.7 Capacitor coating
The laminate coating is intended for marking and identification purposes and is not meant to electrically
insulate the capacitor.
2. Capacitor handling techniques
2.1 Considerations before using
(1) Capacitors have a finite life. Do not reuse or recycle capacitors from used equipment.
(2) Transient recovery voltage may be generated in the capacitor due to dielectric absorption.
If required, this voltage can be discharged with a resistor with a value of about 1 kΩ.
(3) Capacitors stored for a long period of time may exhibit an increase in leakage current.
This can be corrected by gradually applying rated voltage in series with a resistor of approximately 1 kΩ.
(4) If capacitors are dropped, they can be damaged mechanically or electrically. Avoid using dropped
capacitors.
(5) Dented or crushed capacitors should not be used.
The seal integrity can be damaged and loss of electrolyte/ shortened life can result.
2.2 Capacitor insertion
(1) Verify the correct capacitance and rated voltage of the capacitor.
(2) Verify the correct polarity of the capacitor before insertion.
(3) Verify the correct terminal dimension and land pattern size for surface mount type, or holes’ pitch for
radial lead type before mount to avoid short circuit, stress on terminals, and/or lack of terminal strength.
(4) Excessive mounting pressure can cause high leakage current, short circuit, or disconnection.
(5) When using a mounter for radial lead type, avoid cutter wear and acute angle of lead-bending with
respect to circuit board. That may create excessive stress and pull the lead to damage the capacitor.
2.3 Reflow soldering (for surface mount type)
(1) Surface-mount type capacitor are exclusively for reflow soldering.
 When reflow solder is used an ambient heat condition system such as the simultaneous use of infrared
 and hot-air is recommended.
(2) Observe proper soldering conditions (temperature, time, etc.). Do not exceed the specified limits.
If the peak temperature is high or if the heating time is long, it may cause deterioration of the electrical
characteristics and life characteristics.
Recommended soldering condition is a guideline for ensuring the basic characteristics of the components,
but not for the stable soldering conditions. Conditions for proper soldering should be set up according to
individual conditions.
 ✽ The Temperature on capacitor top shall be measured by using thermal couple that is fixed firmly by
epoxy glue.
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Conductive Polymer Hybrid Aluminum Electrolytic Capacitors
(3) In case of use in 2 times reflow, 2nd reflow must be done when the capacitor’s temperature return back
 to normal level.
(4) In our recommended reflow condition , the case discoloration and the case swelling might be slightly
 generated. But please acknowledge that these two phenomena do not influence the reliability of the product.
(5) The crack on top marking might be occurred by reflow heat stress.
 But please acknowledge that it does not influence the reliability of the product.
(6) VPS (Vapor Phase Soldering) reflow can cause significant characteristics change and/ or mounting failure
 due to deformation by acute temperature rise.
 VPS is acceptable provided that the process does not exceed recommended reflow profile and
 temperature rise is less than 3 ℃ / sec.  Please contact Panasonic for detailed conditions.
(7) The vibration-proof capacitors of size Φ6.3 has support terminals extending from the bottom side to the lead edge.
Then, make sure to find appropriate soldering conditions to form fillet on the support terminals if required for
appearance inspection. However, even if sufficient solder fillets are not observed, the reliability of vibration-proof
will not be lowered because the support terminals on the bottom side enhance the solder joint to PCB.
2.4 Flow soldering (for radial type)
(1) Radial lead type capacitors cannot apply to reflow soldering.
(2) Do not immerse the capacitor body into the solder bath as excessive internal pressure could result.
(3) Apply proper soldering conditions (temperature, time, etc.). Do not exceed the specified limits.
(4) Do not allow other parts or components to touch the capacitor during soldering.
(5) When mounting the radial type being touched to PCB, be sure to check the appearance of solder under the
sealing rubber, which does not have an airflow structure.
2.5 Manual soldering
(1) Observe temperature and time soldering specifications or do not exceed temperature of 350 °C for
3 seconds or less.
(2) If a soldered capacitor must be removed and reinserted, avoid excessive stress on the capacitor leads.
(3) Avoid physical contacts between the tip of the soldering iron and capacitors to prevent or capacitor failure.
(4) When bending lead wires of radial type capacitors to match the hole pitch on PCB, avoid applying excessive
stress to the capacitor body.
2.6 Capacitor handling after soldering
(1) Avoid moving the capacitor after soldering to prevent excessive stress on the lead wires where they enter
the seal. The capacitor may break from element portion due to a torque at outer rim, causing a large stress
to terminals.
(2) Do not use the capacitor as a handle when moving the circuit board assembly. The total weight of the
board would apply to element portion through terminals, and the capacitor may break.
(3) Avoid striking the capacitor after assembly to prevent failure due to excessive shock. The capacitor may
break due to excessive shock or load above specified range.
2.7 Circuit board cleaning
(1) Circuit boards can be immersed or ultrasonically cleaned using suitable cleaning solvents for up to
5 minutes and up to 60 °C maximum temperatures. The boards should be thoroughly rinsed and dried.
The use of ozone depleting cleaning agents is not recommended for the purpose of protecting our
environment.
【Target solvent】
Pine Alpha ST-100S, Aqua Cleaner 210SEP, Clean-thru 750H / 750L / 710M, Sunelec B-12,
Sunelec B-12, Cold Cleaner P3-375, Techno Cleaner 219, DK Be-clear CW-5790,
Telpene Cleaner EC-7R, Technocare FRW-17 / FRW-1 / FRV-1
(2) Avoid using the following solvent groups unless specifically allowed in the specification ;
(a) Halogenated based solvents
: may permeate the seal and cause internal corrosion.
Especially, 1-1-1 trichloroethane must not be used on any aluminum electrolytic capacitors.
(b) Alkaline based solvents : may dissolve and react to the aluminum case.
(c) Petroleum based solvents
: may deteriorate the sealing rubber
(d) Xylene : may deteriorate the sealing rubber
(e) Acetone
: may erase the markings on the capacitor top
(3) A thorough drying after cleaning is required to remove residual cleaning solvents that may be trapped
between the capacitor and the circuit board. Avoid drying temperatures, which exceed the upper category
temperature of the capacitor.
(4) Monitor the contamination levels of cleaning solvents during use in terms of electrical conductivity, pH, specific
gravity, and water content. Inside the capacitor may corrode with high density of chlorine. Control the flux
density in the cleaning agent to be less than 2 mass%.
(5) Depending on the cleaning method, the marking on a capacitor may be erased or blurred.
※ Please consult us if you are not certain about acceptable cleaning solvents or cleaning methods.
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Conductive Polymer Hybrid Aluminum Electrolytic Capacitors
2.8 Mounting adhesives and coating agents
When using mounting adhesives or coating agents to control humidity, avoid using materials containing
halogenated solvents.
Also, avoid the use of chloroprene based polymers.
Cure or dry out the coating agents thoroughly, and do not leave any solvents. Make sure to dry out cleaning agents
completely immediately after washing the circuit board if the capacitors are mounted afterward, so that the solvents
are not left under the capacitor body. Also, leave more than 1/3 of the sealing portion open, and do not cover that
portion with any adhesives or coating.
2.9 Fumigation
In exporting electronic appliances with aluminum electrolytic capacitors, in some cases fumigation treatment
using such halogen compound as methyl bromide is conducted for wooden boxes.
If such boxes are not dried well, the halogen left in the box is dispersed while transported and enters in the
capacitors inside.
This possibly causes electrical corrosion of the capacitors. Therefore, after performing fumigation and drying
make sure that no halogen is left.
Don’t perform fumigation treatment to the whole electronic appliances packed in a box.
2.10 Flux
If you use a halogen type (Chlorine type, Bromine type, etc.) high-activity flux, please use it after confirmation
in advance, as it may have an impact on performance and reliability of this product due to the residue of the flux.
3. Precautions for using capacitors
3.1 Environmental conditions
Capacitors should not be stored or used in the following environments.
(1) Exposure to temperatures above the upper category or below the lower category temperature of the capacitor.
(2) Direct contact with water, salt water, or oil.
(3) High humidity conditions where water could condense on the capacitor.
(4) Exposure to toxic gases such as hydrogen sulfide, sulfuric acid, nitric acid, chlorine, chlorine compound,
bromine, bromine compound or ammonia.
(5) Exposure to ozone, radiation, or ultraviolet rays.
(6) Vibration and shock conditions exceeding specified requirements.
Even within the specified requirements, a large vibration acceleration may be applied due to resonance,
so be sure to evaluate and confirm with the actual product.
3.2 Electrical precautions
(1) Avoid touching the terminals of a capacitor as a possible electric shock could result. The exposed
aluminum case is not insulated and could also cause electric shock if touched.
(2) Avoid short circuiting the area between the capacitor terminals with conductive materials including liquids
such as acids or alkaline solutions.
(3) A low-molecular-weight-shiroxane which is included in a silicon material shall causes abnormal electrical
characteristics.
4. Emergency procedures
(1) If the pressure relief of the capacitor operates, immediately turn off the equipment and disconnect from
the power source.
This will minimize an additional damage caused by the vaporizing electrolyte.
(2) Avoid contact with the escaping electrolyte gas, which can exceed 100 °C temperatures.
If electrolyte or gas enters the eye, immediately flush the eye with large amounts of water.
If electrolyte or gas is ingested by mouth, gargle with water.
If electrolyte contacts the skin, wash with soap and water.
5. Long term storage
(1) Leakage current of a capacitor tends to increase after a long-term storage due to dielectric dissolution,
and very high current may flow at the first voltage load. However, applying voltage will form the dielectric,
and the leakage current will decrease. Expiration date is 42 months from the outgoing inspection date.
Storage condition is to keep in room temperature (5 ℃ to 35 ℃) and humidity (45 % to 85 %) with no
direct sunshine.
(2) Environmental conditions
Do not store under condition outside the area described in the specification, and also under conditions
listed below.
(a) Exposure to temperatures above the upper category or below the lower category temperature of the
capacitor.
(b) Direct contact with water, salt water, or oil.
(c) High humidity conditions where water could condense on the capacitor.
(d) Exposure to toxic gases such as hydrogen sulfide, sulfuric acid, nitric acid, chlorine, Chlorine compound,
Bromine, Bromine compound or ammonia.
(e) Exposure to ozone, radiation, or ultraviolet rays.
(f) Vibration and shock conditions exceeding specified requirements.
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Conductive Polymer Hybrid Aluminum Electrolytic Capacitors
6. Capacitor disposal
When disposing capacitors, use one of the following methods.
(1) Incinerate after crushing the capacitor or puncturing the can wall (to prevent explosion due to internal
pressure rise).
(2) Dispose as solid waste.
NOTE : Local laws may have specific disposal requirements which must be followed.
■ AEC-Q200 compliant
The products are tested based on all or part of the test conditions and methods defined in AEC-Q200.
Please consult with Panasonic for the details of the product specification and specific evaluation test results,
etc., and please review and approve Panasonic's product specification before ordering.
✽ Intellectual property right
We, Panasonic Group are providing the product and service that customers can use without anxiety, and are
working positively on the protection of our products under intellectual property rights.
Representative patents relating to Conductive Polymer Hybrid Aluminum Electrolytic Capacitors are as follows:
US Patent No.7497879, No.7621970, No.9208954
JP Patent No.5360250
EP Patent No.1808875
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The precautions in using aluminum electrolytic capacitors follow the "Safety application
guide for the use in fixed aluminum electrolytic capacitors for electronic equipment",
RCR-2367D issued by JEITA in October 2017.
Please refer to the above application guide for details.