Datasheet

2© KEMET Electronics Corporation • KEMET Tower • One East Broward Boulevard LF0036_SSHB10H • 3/4/2019

Fort Lauderdale, FL 33301 USA • 954-766-2800 • www.kemet.com

AC Line Filters – Dual Mode SSHB Coils, 10H Series, High Impedance Type

Magnetic Permeability of Ferrite Material

Inordertoachieveecientnoisereduction,itisimportanttoselectthematerialaccordingtothetargetfrequencyband.

Depending on its magnetic permeability, a particular ferrite material will be effective in a certain frequency band. A

schematic representation of the relationship between the magnetic permeability of each material and the corresponding

effective band range is shown in Figure 1.

Materials with higher magnetic permeability are effective in the lower frequency range, while those with lower magnetic

permeability are effective in the higher frequency range. Thus, Mn-Zn products are mainly used for reducing conduction

noise, while Ni-Zn products are commonly used for radiation noise countermeasures.

The effective frequency range varies depending on core shape, size, and number of windings. This frequency dependence

ofthemagneticpermeabilityasshowninthegureservesforreferencepurposesonly.Itshouldbetestedontheactual

device to determine its effectiveness.

S18H, S15H, 10H, 7H, 5H, 1400L, and 700L are KEMET’s proprietary ferrite material names. Other materials are available

upon request.

Figure 1 - Relationship between the magnetic permeability of each material and its effective frequency range

10 kHz

10,000

20,000

100 kHz 1 MHz 10 MHz 100 MHz 1 GHz

Effective Frequency Range

Magnetic Permeability

Ni-Zn Series

1400L

700L

S18H

S15H

10H

Mn-Zn Series

Lower magnetic permeability:

Higher noise suppression effect

in the higher frequency range

Higher magnetic permeability:

Higher noise suppression effect

in the lower frequency range