0199000019 Fair-Rite, 0199000019 Datasheet - Page 130

BEAD KIT, EMI SUPPRESSION

0199000019

Manufacturer Part Number

0199000019

Description

BEAD KIT, EMI SUPPRESSION

Manufacturer

Fair-Rite

Datasheet

1.0199000019.pdf (715 pages)

Specifications of 0199000019

Kit Contents

Contains 28 Different Beads In Three Suppression Materials, 73, 43 And 61.

Component Type

Shield Bead Kit

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Current page: 130 of 715
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Fair-Rite Products Corp.

Phone:

Introduction

If ferrite cores are used in the design of transformers, chokes or

filters, which are required to carry direct current, it is necessary

to predict the degree of inductance degradation caused by the

static field. When dc flows through the winding of a ferromagnetic

device, it tends to pre-magnetize the core and reduce its induc-

tance. The permeability of a ferrite material measured with

superimposed dc might increase slightly for very low values of

dc ampere-turns, but then it progressively decreases as the dc

field is increased and the core approaches saturation. This

permeability is referred to as the incremental permeability m

an air gap is introduced into the magnetic path of a core, the

reluctance is increased hence the inductance is decreased.

However, the core’s capacity for dc ampere-turns without a

degradation in inductance is significantly improved, albeit at the

expense of a lower effective permeability.

DC Bias in Gapped Cores

The use of graphs such as the Hanna* curves has simplified the

tedious trial and error methods often employed when designing

inductors with superimposed dc. A Hanna curve is created by

measuring the inductance vs. dc bias of various core sizes and

gap lengths of the same material grade. The measured data is

used to create curves such as those plotted in Figure 1 (this curve

is specific for a set of 9478015002 E cores). A line is drawn

connecting the individual curves through the point of tangency.

The graphs are then normalized by dividing the vertical scale of

Figure 1 by the effective core volume V

and the gap lengths by the effective path length

The individual curves, once normalized, overlay creating the

Hanna curve. Figure 2 is such a curve for Fair-Rite 78 material

and can be used for all core sets in that material.

The Effect of Direct Current on the

Inductance of a Ferrite Core

*Footnote:

The paper provided a method of calculating the air gap that will yield the maximum inductance for a given number of turns, with a specified amount of dc,

for a particular material.

Technical Information

130

(888) 324-7748

(888) FAIR RITE / (845) 895-2055 -

C.R. Hanna presented a paper “Design of Reactances and Transformers which Carry Direct Current” at the 1927 Winter Convention of AIEE.

e

and the horizontal scale

FAX:

l

(888) FERRITE / (845) 895-2629

e

(888 337-7483

of the core set.

D

. If

Figure 1

Design Example

For a typical output choke application, the designer knows a

number of design criteria such as the required inductance, the

direct current, alternating ripple current and allowable dc resis-

tance. He will also have requirements for core size, ambient

temperature an often a preference for a particular core geometry.

A

L

I

2

PO Box J, One Commercial Row, Wallkill, NY 12589-0288

10

10

10

10

10

-

-

-5

-6

-7

-8

-9

Product inductance factor and current squared vs.

DC current for a pair of 9478015002 E cores.

0.01

www.fair-rite.com

E-Mail: ferrites@fair-rite.com

Bias Current (A)

0.1

air gap

.000

.001

1

.003

.010

.020

.040

15th Edition

10

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