EEE1VA100WR

Aluminum Electrolytic Capacitor

The EEE1VA100WR is a aluminum electrolytic capacitor from Panasonic. View the full EEE1VA100WR datasheet below including specifications and datasheet sections.

Manufacturer

Panasonic

Overview

Part: S series Type: Aluminum Electrolytic Capacitor

Description: Surface mount aluminum electrolytic capacitors with a rated voltage range of 4.0 V to 100 V, capacitance from 1 μF to 1500 μF, and an endurance of 2000 hours at 85 °C.

Operating Conditions:

Operating temperature: -40 °C to +85 °C
Rated voltage range: 4.0 V to 100 V
Endurance: 2000 h at +85 °C

Key Specs:

Capacitance range: 1 μF to 1500 μF
Capacitance tolerance: ±20 % (120 Hz / +20 °C)
Leakage current: I ≤ 0.01 CV or 3 μA, whichever is greater (2 minutes after reaching rated voltage, 20 °C)
Low temperature impedance ratio Z (-25 °C) / Z (+20 °C): 7 (for 4.0 V) to 2 (for 25 V, 35 V)
Low temperature impedance ratio Z (-40 °C) / Z (+20 °C): 15 (for 4.0 V) to 3 (for 35 V, 50 V)
Endurance capacitance change: Within ±20 % of the initial value (for 2000 h at +85 °C)
Endurance dissipation factor (tan δ): ≤ 200 % of the initial limit
Resistance to soldering heat capacitance change: Within ±10 % of the initial value

Features:

Endurance: 85 °C 2000 h
Vibration-proof product (30G guaranteed) is available upon request (ø8 ≤ )
AEC-Q200 compliant
RoHS compliant

Package:

Surface Mount Type
Size codes: B (ø4), C (ø5), D (ø6.3), D8 (ø6.3), E (ø8), F (ø8), G (ø10), H13 (ø12.5), J16 (ø16), K16 (ø18), K21 (ø18)

Features

Endurance : 85 °C 2000 h
Vibration-proof product (30G guaranteed) is available upon request. (ø8 ≤ )
AEC-Q200 compliant
RoHS compliant

Specifications	Specifications	Specifications	Specifications	Specifications	Specifications	Specifications	Specifications	Specifications	Specifications	Specifications
Category temp. range	-40 °C to +85 °C	-40 °C to +85 °C	-40 °C to +85 °C	-40 °C to +85 °C	-40 °C to +85 °C	-40 °C to +85 °C	-40 °C to +85 °C	-40 °C to +85 °C	-40 °C to +85 °C	-40 °C to +85 °C
Rated voltage range	4.0 V to 100 V	4.0 V to 100 V	4.0 V to 100 V	4.0 V to 100 V	4.0 V to 100 V	4.0 V to 100 V	4.0 V to 100 V	4.0 V to 100 V	4.0 V to 100 V	4.0 V to 100 V
Capacitance range	1 μF to 1500 μF	1 μF to 1500 μF	1 μF to 1500 μF	1 μF to 1500 μF	1 μF to 1500 μF	1 μF to 1500 μF	1 μF to 1500 μF	1 μF to 1500 μF	1 μF to 1500 μF	1 μF to 1500 μF
Capacitance tolerance	±20 %(120 Hz / +20 °C)	±20 %(120 Hz / +20 °C)	±20 %(120 Hz / +20 °C)	±20 %(120 Hz / +20 °C)	±20 %(120 Hz / +20 °C)	±20 %(120 Hz / +20 °C)	±20 %(120 Hz / +20 °C)	±20 %(120 Hz / +20 °C)	±20 %(120 Hz / +20 °C)	±20 %(120 Hz / +20 °C)
Leakage current	I ≤ 0.01 CV or 3 (μA), whichever is greater, 2 minutes after reaching rated voltage, 20 °C *CV = (Capacitance in μF) x (Rated voltage in V)	I ≤ 0.01 CV or 3 (μA), whichever is greater, 2 minutes after reaching rated voltage, 20 °C *CV = (Capacitance in μF) x (Rated voltage in V)	I ≤ 0.01 CV or 3 (μA), whichever is greater, 2 minutes after reaching rated voltage, 20 °C *CV = (Capacitance in μF) x (Rated voltage in V)	I ≤ 0.01 CV or 3 (μA), whichever is greater, 2 minutes after reaching rated voltage, 20 °C *CV = (Capacitance in μF) x (Rated voltage in V)	I ≤ 0.01 CV or 3 (μA), whichever is greater, 2 minutes after reaching rated voltage, 20 °C *CV = (Capacitance in μF) x (Rated voltage in V)	I ≤ 0.01 CV or 3 (μA), whichever is greater, 2 minutes after reaching rated voltage, 20 °C *CV = (Capacitance in μF) x (Rated voltage in V)	I ≤ 0.01 CV or 3 (μA), whichever is greater, 2 minutes after reaching rated voltage, 20 °C *CV = (Capacitance in μF) x (Rated voltage in V)	I ≤ 0.01 CV or 3 (μA), whichever is greater, 2 minutes after reaching rated voltage, 20 °C *CV = (Capacitance in μF) x (Rated voltage in V)	I ≤ 0.01 CV or 3 (μA), whichever is greater, 2 minutes after reaching rated voltage, 20 °C *CV = (Capacitance in μF) x (Rated voltage in V)	I ≤ 0.01 CV or 3 (μA), whichever is greater, 2 minutes after reaching rated voltage, 20 °C *CV = (Capacitance in μF) x (Rated voltage in V)
Dissipation factor (tan δ)	Please see the attached characteristics list	Please see the attached characteristics list	Please see the attached characteristics list	Please see the attached characteristics list	Please see the attached characteristics list	Please see the attached characteristics list	Please see the attached characteristics list	Please see the attached characteristics list	Please see the attached characteristics list	Please see the attached characteristics list
Characteristics at low temperature	Rated voltage (V)	4.0	6.3	10	25 16	35	50	63	100	(Impedance ratio at 120 Hz)
Characteristics at low temperature	Z (-25 °C) / Z (+20 °C)	7	4	3	2	2 2	2	3	3	(Impedance ratio at 120 Hz)
Characteristics at low temperature	Z (-40 °C) / Z (+20 °C)	15	8	6	4 4	3	3	4	4	(Impedance ratio at 120 Hz)
Endurance	at +85 °C ± 2 °C and then being stabilized at +20 °C, capacitors shall meet the following limits. After applying rated working voltage for 2000 h (Bi-polar:1000 h for each polarity)	at +85 °C ± 2 °C and then being stabilized at +20 °C, capacitors shall meet the following limits. After applying rated working voltage for 2000 h (Bi-polar:1000 h for each polarity)	at +85 °C ± 2 °C and then being stabilized at +20 °C, capacitors shall meet the following limits. After applying rated working voltage for 2000 h (Bi-polar:1000 h for each polarity)	at +85 °C ± 2 °C and then being stabilized at +20 °C, capacitors shall meet the following limits. After applying rated working voltage for 2000 h (Bi-polar:1000 h for each polarity)	at +85 °C ± 2 °C and then being stabilized at +20 °C, capacitors shall meet the following limits. After applying rated working voltage for 2000 h (Bi-polar:1000 h for each polarity)	at +85 °C ± 2 °C and then being stabilized at +20 °C, capacitors shall meet the following limits. After applying rated working voltage for 2000 h (Bi-polar:1000 h for each polarity)	at +85 °C ± 2 °C and then being stabilized at +20 °C, capacitors shall meet the following limits. After applying rated working voltage for 2000 h (Bi-polar:1000 h for each polarity)	at +85 °C ± 2 °C and then being stabilized at +20 °C, capacitors shall meet the following limits. After applying rated working voltage for 2000 h (Bi-polar:1000 h for each polarity)	at +85 °C ± 2 °C and then being stabilized at +20 °C, capacitors shall meet the following limits. After applying rated working voltage for 2000 h (Bi-polar:1000 h for each polarity)	at +85 °C ± 2 °C and then being stabilized at +20 °C, capacitors shall meet the following limits. After applying rated working voltage for 2000 h (Bi-polar:1000 h for each polarity)
Endurance	Capacitance change	Within ±20 %of the initial value	Within ±20 %of the initial value	Within ±20 %of the initial value	Within ±20 %of the initial value	Within ±20 %of the initial value	Within ±20 %of the initial value	Within ±20 %of the initial value	Within ±20 %of the initial value	Within ±20 %of the initial value
Endurance	Capacitance change	Size code	Size code	Size code	Size code	Rated voltage	Rated voltage	Rated voltage	Rated voltage	Capacitance change
Endurance	Capacitance change	B(ø4) to D, D8(ø6.3)	B(ø4) to D, D8(ø6.3)	B(ø4) to D, D8(ø6.3)	B(ø4) to D, D8(ø6.3)	4 V	4 V	4 V	4 V	1000 hours ±30%
Endurance	Capacitance change					6.3 V	6.3 V	6.3 V	6.3 V
Endurance	Capacitance change	≤ D(ø6.3) Miniature	≤ D(ø6.3) Miniature	≤ D(ø6.3) Miniature	≤ D(ø6.3) Miniature	≧ 10 V	≧ 10 V	≧ 10 V	≧ 10 V	1000 hours ±20%
Endurance	Dissipation factor (tan δ)	≤ 200 %of the initial limit	≤ 200 %of the initial limit	≤ 200 %of the initial limit	≤ 200 %of the initial limit	≤ 200 %of the initial limit	≤ 200 %of the initial limit	≤ 200 %of the initial limit	≤ 200 %of the initial limit	≤ 200 %of the initial limit
Endurance	Leakage current	Within the initial limit	Within the initial limit	Within the initial limit	Within the initial limit	Within the initial limit	Within the initial limit	Within the initial limit	Within the initial limit	Within the initial limit
Shelf life	After storage for 1000 h at +85 °C ± 2 °C with no voltage applied and then being stabilized at +20 °C, capacitors shall meet the limits specified in endurance. (Capacitors are left at room temperature and humidity for 2 hours after the test. Then, apply the rated voltage for 30min with a series protection resistance of 1000 Ω ± 10 Ω. Measure electrical characteristics after discharging the capacitor.)	After storage for 1000 h at +85 °C ± 2 °C with no voltage applied and then being stabilized at +20 °C, capacitors shall meet the limits specified in endurance. (Capacitors are left at room temperature and humidity for 2 hours after the test. Then, apply the rated voltage for 30min with a series protection resistance of 1000 Ω ± 10 Ω. Measure electrical characteristics after discharging the capacitor.)	After storage for 1000 h at +85 °C ± 2 °C with no voltage applied and then being stabilized at +20 °C, capacitors shall meet the limits specified in endurance. (Capacitors are left at room temperature and humidity for 2 hours after the test. Then, apply the rated voltage for 30min with a series protection resistance of 1000 Ω ± 10 Ω. Measure electrical characteristics after discharging the capacitor.)	After storage for 1000 h at +85 °C ± 2 °C with no voltage applied and then being stabilized at +20 °C, capacitors shall meet the limits specified in endurance. (Capacitors are left at room temperature and humidity for 2 hours after the test. Then, apply the rated voltage for 30min with a series protection resistance of 1000 Ω ± 10 Ω. Measure electrical characteristics after discharging the capacitor.)	After storage for 1000 h at +85 °C ± 2 °C with no voltage applied and then being stabilized at +20 °C, capacitors shall meet the limits specified in endurance. (Capacitors are left at room temperature and humidity for 2 hours after the test. Then, apply the rated voltage for 30min with a series protection resistance of 1000 Ω ± 10 Ω. Measure electrical characteristics after discharging the capacitor.)	After storage for 1000 h at +85 °C ± 2 °C with no voltage applied and then being stabilized at +20 °C, capacitors shall meet the limits specified in endurance. (Capacitors are left at room temperature and humidity for 2 hours after the test. Then, apply the rated voltage for 30min with a series protection resistance of 1000 Ω ± 10 Ω. Measure electrical characteristics after discharging the capacitor.)	After storage for 1000 h at +85 °C ± 2 °C with no voltage applied and then being stabilized at +20 °C, capacitors shall meet the limits specified in endurance. (Capacitors are left at room temperature and humidity for 2 hours after the test. Then, apply the rated voltage for 30min with a series protection resistance of 1000 Ω ± 10 Ω. Measure electrical characteristics after discharging the capacitor.)	After storage for 1000 h at +85 °C ± 2 °C with no voltage applied and then being stabilized at +20 °C, capacitors shall meet the limits specified in endurance. (Capacitors are left at room temperature and humidity for 2 hours after the test. Then, apply the rated voltage for 30min with a series protection resistance of 1000 Ω ± 10 Ω. Measure electrical characteristics after discharging the capacitor.)	After storage for 1000 h at +85 °C ± 2 °C with no voltage applied and then being stabilized at +20 °C, capacitors shall meet the limits specified in endurance. (Capacitors are left at room temperature and humidity for 2 hours after the test. Then, apply the rated voltage for 30min with a series protection resistance of 1000 Ω ± 10 Ω. Measure electrical characteristics after discharging the capacitor.)	After storage for 1000 h at +85 °C ± 2 °C with no voltage applied and then being stabilized at +20 °C, capacitors shall meet the limits specified in endurance. (Capacitors are left at room temperature and humidity for 2 hours after the test. Then, apply the rated voltage for 30min with a series protection resistance of 1000 Ω ± 10 Ω. Measure electrical characteristics after discharging the capacitor.)
Resistance to soldering heat	After reflow soldering and then being stabilized at +20 °C, capacitors shall meet the following limits.	After reflow soldering and then being stabilized at +20 °C, capacitors shall meet the following limits.	After reflow soldering and then being stabilized at +20 °C, capacitors shall meet the following limits.	After reflow soldering and then being stabilized at +20 °C, capacitors shall meet the following limits.	After reflow soldering and then being stabilized at +20 °C, capacitors shall meet the following limits.	After reflow soldering and then being stabilized at +20 °C, capacitors shall meet the following limits.	After reflow soldering and then being stabilized at +20 °C, capacitors shall meet the following limits.	After reflow soldering and then being stabilized at +20 °C, capacitors shall meet the following limits.	After reflow soldering and then being stabilized at +20 °C, capacitors shall meet the following limits.	After reflow soldering and then being stabilized at +20 °C, capacitors shall meet the following limits.
Resistance to soldering heat	Capacitance change	Within ±10 %of the initial value	Within ±10 %of the initial value	Within ±10 %of the initial value	Within ±10 %of the initial value	Within ±10 %of the initial value	Within ±10 %of the initial value	Within ±10 %of the initial value	Within ±10 %of the initial value	Within ±10 %of the initial value
Resistance to soldering heat	Dissipation factor (tan δ)	Within the initial limit	Within the initial limit	Within the initial limit	Within the initial limit	Within the initial limit	Within the initial limit	Within the initial limit	Within the initial limit	Within the initial limit
Resistance to soldering heat	Leakage current	Within the initial limit	Within the initial limit	Within the initial limit	Within the initial limit	Within the initial limit	Within the initial limit	Within the initial limit	Within the initial limit	Within the initial limit

Applications

■ Please be advised that this product and product specifications are subject to change without notice for improvement purposes. Therefore, please request and confirm the latest delivery specifications that explain the specifications in detail before the final design, or purchase or use of the product, regardless of the application. In addition, do not use this product in any way that deviates from the contents of the company's delivery specifications.
■ Unless otherwise specified in this catalog or the product specifications, this product is intended for use in general electronic equipment (AV products, home appliances, commercial equipment, office equipment, information and communication equipment, etc.).
When this product is used for the following special cases, the specification document suited to each application shall be signed/sealed (with Panasonic Industry and the user) in advance..These include applications requiring special quality and reliability, wherein their failures or malfunctions may directly threaten human life or cause harm to the human body (e.g.: space/aircraft equipment, transportation/traffic equipment, combustion equipment, medical equipment, disaster prevention/crime prevention equipment, safety equipment, etc.).

Related Variants

The following components are covered by the same datasheet.

Part Number	Manufacturer	Package
EEE1VA100NP	Panasonic	—
EEE1VA100SR	Panasonic	—

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