Unit of Measure
Items
KXJ Series 470 Microfarad (µF) Capacitance Miniature Aluminum Electrolytic Capacitor

KXJ Series 470 Microfarad (?F) Capacitance Miniature Aluminum Electrolytic Capacitor
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KXJ Series 47 Microfarad (µF) Capacitance Miniature Aluminum Electrolytic Capacitor

KXJ Series 47 Microfarad (?F) Capacitance Miniature Aluminum Electrolytic Capacitor
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KXJ Series 120 Microfarad (µF) Capacitance Miniature Aluminum Electrolytic Capacitor

KXJ Series 120 Microfarad (?F) Capacitance Miniature Aluminum Electrolytic Capacitor
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KXJ Series 220 Microfarad (µF) Capacitance Miniature Aluminum Electrolytic Capacitor

KXJ Series 220 Microfarad (?F) Capacitance Miniature Aluminum Electrolytic Capacitor
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KXJ Series 150 Microfarad (µF) Capacitance Miniature Aluminum Electrolytic Capacitor

KXJ Series 150 Microfarad (?F) Capacitance Miniature Aluminum Electrolytic Capacitor
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Manufacturer Stock N/A {0} N/A {0} N/A {0} N/A {0} N/A {0}
Description N/A
  • Downsized and Longer life from current KXG series
  • For electronic ballast circuits and other long life applications
  • Non solvent resistant type
  • AEC-Q200 compliant
N/A
  • Downsized and Longer life from current KXG series
  • For electronic ballast circuits and other long life applications
  • Non solvent resistant type
  • AEC-Q200 compliant
N/A
  • Downsized and Longer life from current KXG series
  • For electronic ballast circuits and other long life applications
  • Non solvent resistant type
  • AEC-Q200 compliant
N/A
  • Downsized and Longer life from current KXG series
  • For electronic ballast circuits and other long life applications
  • Non solvent resistant type
N/A
  • Downsized and Longer life from current KXG series
  • For electronic ballast circuits and other long life applications
  • Non solvent resistant type
  • AEC-Q200 compliant
Brands N/A Nippon Chemi-Con
Manufacturer N/A United Chemi-Con
Series N/A KXJ
Working Direct Current (DC) Voltage N/A 160 V N/A 200 V N/A 400 V N/A 400 V N/A 450 V
Capacitance N/A 470 µF N/A 47 µF N/A 120 µF N/A 220 µF N/A 150 µF
Capacitance Tolerance (±) at 120 Hertz (Hz) Frequency, 20 Degree Celsius (ºC) Temperature N/A 20 %
Diameter (D) N/A 18 mm N/A 10 mm N/A 18 mm N/A 18 mm N/A 18 mm
Maximum Diameter (D) N/A 18.5 mm N/A 10.5 mm N/A 18.5 mm N/A 18.5 mm N/A 18.5 mm
Dimension L N/A 31.5 mm N/A 20 mm N/A 31.5 mm N/A 50 mm N/A 50 mm
Maximum Dimension L N/A 33 mm N/A 21.5 mm N/A 33 mm N/A 51.5 mm N/A 51.5 mm
Diameter (d) N/A 0.8 mm N/A 0.6 mm N/A 0.8 mm N/A 0.8 mm N/A 0.8 mm
Dimension F N/A 7.5 mm N/A 5 mm N/A 7.5 mm N/A 7.5 mm N/A 7.5 mm
Dissipation Factor (Tan δ) N/A 0.20 N/A 0.20 N/A 0.24 N/A 0.24 N/A 0.24
Rated Ripple Current at 105 Degree Celsius (ºC) Temperature, 120 Hertz (Hz) Frequency N/A 1660 mArms N/A 290 mArms N/A 840 mArms N/A 1220 mArms N/A 1060 mArms
Temperature Range N/A -40 to +105 ºC
Leakage Current at 20 Degree Celsius (ºC) Temperature After 1 Minute N/A I=0.04CV+100
Where, I : Max. leakage current (µA), C : Nominal capacitance (µF), V : Rated voltage (V)
Leakage Current at 20 Degree Celsius (ºC) Temperature After 5 Minutes N/A I=0.02CV+25
Where, I : Max. leakage current (µA), C : Nominal capacitance (µF), V : Rated voltage (V)
Maximum Impedance Ratio Low Temperature Characteristics at 120 Hertz (Hz) Frequency N/A Z(-25 ºC)/Z(+20 ºC) = 3
Z(-40 ºC)/Z(+20 ºC) = 6
N/A Z(-25 ºC)/Z(+20 ºC) = 3
Z(-40 ºC)/Z(+20 ºC) = 6
N/A Z(-25 ºC)/Z(+20 ºC) = 5
Z(-40 ºC)/Z(+20 ºC) = 6
N/A Z(-25 ºC)/Z(+20 ºC) = 5
Z(-40 ºC)/Z(+20 ºC) = 6
N/A Z(-25 ºC)/Z(+20 ºC) = 6
Rated Ripple Current Multipliers at 120 Hertz (Hz) Frequency N/A 1
Rated Ripple Current Multipliers at 1 Kilohertz (kHz) Frequency N/A 1.67 N/A 1.75 N/A 1.67 N/A 1.67 N/A 1.67
Rated Ripple Current Multipliers at 10 Kilohertz (kHz) Frequency N/A 2.05 N/A 2.25 N/A 2.05 N/A 2.05 N/A 2.05
Rated Ripple Current Multipliers at 100 Kilohertz (kHz) Frequency N/A 2.25 N/A 2.50 N/A 2.25 N/A 2.25 N/A 2.25
Note for Rated Ripple Current Multipliers N/A The deterioration of aluminum electrolytic capacitors accelerates their life due to the internal heating produced by ripple current. N/A The deterioration of aluminum electrolytic capacitors accelerates their life due to the internal heating produced by ripple current. N/A The deterioration of aluminum electrolytic capacitors accelerates their life due to the internal heating produced by ripple current. N/A The endurance of capacitors is reduced with internal heating produced by ripple current at the rate of halving the lifetime with every 5 ºC rise. When long life performance is required in actual use, the rms ripple current has to be reduced. N/A The deterioration of aluminum electrolytic capacitors accelerates their life due to the internal heating produced by ripple current.
Industry Standards N/A Restriction of Hazardous Substances (RoHS) 2 Compliant N/A Restriction of Hazardous Substances (RoHS) 2 Compliant N/A Restriction of Hazardous Substances (RoHS) 2 Compliant N/A Restriction of Hazardous Substances (RoHS) 2 Compliant N/A Restriction of Hazardous Substances (RoHS) Compliant
Endurance N/A The following specifications shall be satisfied when the capacitors are restored to 20 ºC after subjected to DC voltage with the rated ripple current is applied (the peak voltage shall not exceed the rated voltage) for the specified time at 105 ºC.

Time: 12,000 hours
Capacitance change: ≤ ±20% of the initial value
D.F. (tan δ): ≤ 200% of the initial value
Leakage current: ≤ The initial specified value
N/A The following specifications shall be satisfied when the capacitors are restored to 20 ºC after subjected to DC voltage with the rated ripple current is applied (the peak voltage shall not exceed the rated voltage) for the specified time at 105 ºC.

Time: 10,000 hours
Capacitance change: ≤ ±20% of the initial value
D.F. (tan δ): ≤ 200% of the initial value
Leakage current: ≤ The initial specified value
N/A The following specifications shall be satisfied when the capacitors are restored to 20 ºC after subjected to DC voltage with the rated ripple current is applied (the peak voltage shall not exceed the rated voltage) for the specified time at 105 ºC.

Time: 12,000 hours
Capacitance change: ≤ ±20% of the initial value
D.F. (tan δ): ≤ 200% of the initial value
Leakage current: ≤ The initial specified value
N/A The following specifications shall be satisfied when the capacitors are restored to 20 ºC after subjected to DC voltage with the rated ripple current is applied for 12,000 hours (10,000 hours for 20L max.) at 105 ºC.

Capacitance change: ≤ ±20% of the initial value
D.F. (tan δ): ≤ 200% of the initial value
Leakage current: ≤ The initial specified value
N/A The following specifications shall be satisfied when the capacitors are restored to 20 ºC after subjected to DC voltage with the rated ripple current is applied (the peak voltage shall not exceed the rated voltage) for the specified time at 105 ºC.

Time: 12,000 hours
Capacitance change: ≤ ±20% of the initial value
D.F. (tan δ): ≤ 200% of the initial value
Leakage current: ≤ The initial specified value
Shelf Life N/A The following specifications shall be satisfied when the capacitors are restored to 20 ºC after exposing them for 1,000 hours at 105 ºC without voltage applied. Before the measurement, the capacitor shall be preconditioned by applying voltage according to Item 4.1 of JIS C 5101-4.

Capacitance change: ≤ ±20% of the initial value
D.F. (tan δ): ≤ 200% of the initial value
Leakage current: ≤ 500% of the initial value
Note N/A Product specifications are subject to change without notice. Request our product specifications before purchase and/or use. Please use our products based on the information contained in product specifications.