![]() ![]() Highlighted in the red box is the core’s effective length (ℓ e) this is an important value for calculating the peak flux density. ![]() The part number is E38/8/25, and two halves are needed to make a full core-set: The design we are using as the basis of this article is aiming for an inductance of about 1 mH, and the ferrite material that will be considered is a planar type made by Ferroxcube. Temperature drift causes inductance change and can alter how a tuned filter might perform.The upper operating frequency is limited due to other (eddy current) core losses.A magnetic flux density of 400 mT brings saturation losses. The magnetic field is constrained to the ferrite core, thus reducing interference with close-by components and circuits. ![]() The magnetic field is magnified, and we can make an inductor with fewer turns leading to reduced copper losses.Make sure this is the best material for your application before proceeding.Īdvantages of using a ferrite core inductor The stages are as follows: Stage 1īefore proceeding, the implications of the decision to use ferrite cores rather than any other material needs to be considered. The process involves a sequence of steps requiring the use of several data sheets and, should the ferrite core inductor design need to be gapped, some degree of iteration. In this article, I’m going to take you through the standard ferrite cores selection guide and design process used in applications such as a DC-to-DC converter or a power filter inductor.
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