Datasheet

ManualsBrandsVISHAY ManualsCapacitorsElectrolytic capacitor Axial lead 2200 µF 63 V 20 % (Ø x L) 21 mm x 38 mm 1 pc(s)

Document Number: 28325 For technical questions contact: alumin

umcaps2@vishay.com www.vishay.com

Revision: 10-Nov-03 9

021 ASM

Aluminum Capacitors

Axial Standard Miniature

Vishay BCcomponents

IMPEDANCE (Z)

10 10

f (Hz)

( )

Ω

Curve 1: 330 µF, 63 V.

Curve 2: 470 µF, 63 V.

Curve 3: 680 µF, 40 V.

Curve 4: 1000 µF, 25 and 40 V.

Curve 5: 1500 µF, 16 and 25 V.

Curve 6: 2200 µF, 10 and 16 V.

Curve 7: 3300 µF, 10 V.

Fig.16 Typical impedance as a function of frequency.

Case ∅D × L = 12.5 × 30 mm.

amb

= 40 °C.

10 10

f (Hz)

( )

Ω

Curve 1: 330 µF, 63 V.

Curve 2: 470 µF, 63 V.

Curve 3: 680 µF, 40 V.

Curve 4: 1000 µF, 25 and 40 V.

Curve 5: 1500 µF, 16 and 25 V.

Curve 6: 2200 µF, 10 and 16 V.

Curve 7: 3300 µF, 10 V.

Fig.17 Typical impedance as a function of frequency.

Case ∅D × L = 12.5 × 30 mm.

amb

= 20 °C.

10 10

f (Hz)

( )

Ω

Curve 1: 1000 µF, 63 V.

Curve 2: 2200 µF, 40 V.

Curve 3: 3300 µF, 25 V.

Curve 4: 4700 µF, 16 V.

Curve 5: 6800 µF, 10 V.

Fig.18 Typical impedance as a function of frequency.

Case ∅D × L = 18 × 30 mm.

amb

= 40 °C.

10 10

f (Hz)

( )

Ω

Curve 1: 1000 µF, 63 V.

Curve 2: 2200 µF, 40 V.

Curve 3: 3300 µF, 25 V.

Curve 4: 4700 µF, 16 V.

Curve 5: 6800 µF, 10 V.

Fig.19 Typical impedance as a function of frequency.

Case ∅D × L = 18 × 30 mm.

amb

= 20 °C.