EP0459570A1 - Inductance or transformer, particularly for switching mode current supply device - Google Patents

Abstract

2.1. The invention relates to an inductor or a transformer having a ferrite core, especially for pulsed power supply devices. It is intended to specifiy a ferrite core whose inductance behaviour can be varied in a simple and cost-effective manner such that the ferrite core has, in particular, the characteristics of a ferrite annular core with a stepped air gap. 2.2. It is proposed that the ferrite core (1) be constructed as a core having a plurality of holes, having at least one air gap (2), in particular a double-holed core. 2.3. Pulsed power supply devices. <IMAGE>

Description

The invention relates to a choke or a transformer with a ferrite core provided with at least one winding.

One area of application for ferrite cores is power supply technology. Ferrite cores are used in particular for storage chokes or storage transformers in clocked power supply devices.

In the article "Ferrite for Modern Technologies" in Siemens Components 27, 1989, Issue 3, pages 94 to 97, by Dr. Erich Röß, describes how the magnetic properties of a ferrite core can be adjusted using an air gap. Thus, inductance profiles can be generated through an air gap. have low inductance values for small currents and low inductance values for high modulation. This can be achieved, for example, by using a stepped air gap. By introducing a stepped air gap, for example in the case of a ferrite ring core, an inductance curve arises which is composed of the inductance curve of a first ring core without an air gap and that of a second ring core with an air gap. The introduction of a stepped air gap with a defined depth, however, requires a high degree of precision in production.

The invention has for its object to provide a device of the type mentioned, the ferrite core can be produced in a simple and inexpensive manner is, the inductance profile in particular has the properties of a ferrite ring core with a stepped air gap.

This object is achieved in a device of the type mentioned at the outset in that the ferrite core is designed as a multi-hole core having at least one air gap, in particular as a double-hole core.

In contrast to a ferrite core, for example a ring core, the air gap of a ferrite core formed in this way can be sawn in or cut in without this requiring any particular precision. In this case, in particular in the case of a double-hole core with a continuous air gap, the same inductance curve is achieved as in the case of a ring core with a stepped air gap, without the need to introduce a stepped air gap with a precisely defined depth. With such an inductance curve, the saturation of the ferrite core can be shifted towards higher magnetization currents, for example.

By introducing further air gaps, which can also have a residual web, i.e. can be designed as a stepped air gap, the inductance profile of the ferrite core can be influenced in a targeted manner.

Because at least one air gap has an insert made of permanent magnetic material, a maximum of the inductance is achieved, for example, at high magnetizing currents.

The invention is explained in more detail below on the basis of the exemplary embodiments illustrated in the figures.

1 shows an embodiment of a ferrite core designed as a double-hole core.

2 shows the course of the inductance of different ferrite cores as a function of their magnetizing current.

1 schematically shows an exemplary embodiment of a ferrite core 1 designed as a double-hole core. The double-hole core 1 has an air gap 2, which can be introduced into the double-hole core in a simple manner by sawing or milling. The air gap can also be pressed in another way, for example already during the manufacture of the ferrite core, before sintering. In contrast to the production of a stepped air gap, it is only necessary in the continuous air gap shown in FIG. 1 to cut the air gap laterally continuously. The result of this is that a double-hole core designed in this way can be produced simply and inexpensively, in particular in the case of large quantities. If a winding 3 is arranged around the double-hole core 1 in a known manner, an inductance profile results for the double-hole core 1, which is composed of an inductance profile of a ring core 1a without an air gap and the inductance profile of a ring core 1b with a continuous air gap. The overall behavior of the inductance profile of the double-hole core with an air gap thus corresponds to a ring core with a stepped air gap, without the complex manufacturing process or the precision in the production of a stepped air gap being necessary. As a further advantage over a toroidal core with a stepped air gap, the double-hole core 1 offers a relatively large cross section with a small base area, which makes a small number of turns necessary. When using a double-hole core shown in FIG. 1 in a clocked power supply device effective shielding of neighboring components can be achieved by attaching a simple shielding cap. By introducing additional air gaps into the double-hole core 1, the inductance profile of the double-hole core can be influenced in a targeted manner. One way to change the inductance curve is to fill the air gap 2 with a permanent magnetic material. As a result, in such a double-hole core provided with windings, the inductance maximum is shifted, for example toward higher magnetizing currents.

2 shows the basic courses 4, 5, 6, 7 of the inductance L of different ferrite cores designed as double-hole cores as a function of their magnetization current I. As a comparison curve, curve 4 shows the inductance profile of a double-hole core without an air gap. The inductance profile 4 corresponds to that of a ferrite core designed as a single-hole core (toroidal core), ie the inductance profile 4 of a double-hole core without an air gap shows a high inductance L at low magnetization currents I, but this decreases sharply with increasing magnetization current due to the saturation of the coil core. Curve 5 shows the inductance curve of a double-hole core in accordance with the exemplary embodiment shown in FIG. 1, ie a core half has an air gap. The inductance remains constant after a maximum at low magnetization currents I over a wide range and only shows a decrease in the inductance at higher magnetization currents I, ie the saturation is shifted towards higher magnetization currents I compared to curve 4. This corresponds to the inductance profile of a ferrite core with a stepped air gap designed as a ring core. Curve 6 shows the inductance curve of a double-hole core, in which both core halves 1a, 1b (Fig. 1) each have an air gap. This corresponds to the inductance curve of a ferrite core with a continuous air gap. Curve 7 shows the inductance curve of a double-hole core, in which one core half (FIG. 1) has an air gap, into which an insert made of permanent magnetic material is introduced. Such an inductance curve 7 has a maximum inductance L at high magnetization currents I. The combination of air gap and permanent magnetic insert thus enables a high inductance L of a storage choke or a transformer at high magnetization currents I.

Claims (4)

Choke or transformer with a ferrite core provided with at least one winding,
characterized by
that the ferrite core (1) is designed as a multi-hole core having at least one air gap (2), in particular as a double-hole core. Device according to claim 1,
characterized by
that the air gap (2) is introduced perpendicular to the hole axis of the ferrite core (1). Device according to one of claims 1 or 2,
characterized by
that at least one air gap (2) has an insert made of permanent magnetic material. Ferrite core suitable for use in a device according to any one of claims 1 to 3.

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