EP0275499A1 - Current-compensated choke coil for spark interference suppression - Google Patents

Abstract

Current-compensated choke coil for spark-interference suppression having a magnetic core (1), wound with at least two electrical windings, which has a high balanced inductance component for the attenuation of unbalanced and balanced interference currents, the individual windings (3) being guided in structures thereof located outside the interior of the core, in external cores (2) of high saturation magnetisation. <IMAGE>

Description

The invention relates to a current-compensated choke for radio interference suppression with a magnetic core 1 wound with at least two electrical windings, which has a high symmetrical inductance component for damping asymmetrical and symmetrical interference currents.

In radio interference suppression technology, a distinction is made between symmetrical and asymmetrical interferers. One speaks of mixed interference when both symmetrical and asymmetrical disturbances occur. The aim of any interference suppression technology is to reduce the line-based transmission of interference from a source of interference as well as to reduce the influence of an interference sink.

In the case of symmetrical interferers, unwanted interference currents flow just like the operating currents via one or more network conductors to the interference sink and back on one or more other network conductors to the interference source. The interference currents therefore flow in a counter-clock mode, which is why a symmetrical interference is also referred to as a push-pull interference.

Asymmetrical disturbances can occur in all electrical devices in which, in addition to the mains conductors through which the operating current flows, an earth line is connected to protect the users and the devices. Parasitic capacitances in the interference sink or the interference source also cause an interference current in the earth circuit. This current flows on all network conductors in the common mode between interference sink and source of interference, while it flows back over the network line in push-pull. The asymmetrical disturbance is therefore also called common mode disturbance.

Interference suppression circuits are used in mains conductors to dampen the interference currents. These are mostly low passports that allow operating currents to pass through unhindered, but have high impedance for high-frequency interference currents. Low-pass filters for high operating currents are usually made up of chokes and capacitors. The chokes used here can be divided into rod core chokes and current-compensated chokes.

Rod core chokes dampen common and push-pull interference currents equally well. Their large magnetic shear prevents the magnetic core from being saturated by the operating current. However, it is disadvantageous that rod core chokes become very voluminous for larger operating currents. With interference suppression filter circuits with only rod cores, a separate rod core choke must be provided for each live mains conductor. In three-phase radio interference suppression filters with neutral conductor, for example, four such large-volume rod core chokes would have to be accommodated.

A more advantageous solution is provided here by the current-compensated chokes, in which the magnetic fluxes in the core are compensated for by a special arrangement of the windings. The choke core can thereby be greatly reduced and the number of turns reduced. However, since the magnetic fluxes of the push-pull interference currents compensate in the same way as that of the operating currents, there is no effective damping in the case of symmetrical interference.

Nevertheless, there is the possibility of using current-compensated chokes even with mixed and symmetrical interferers, since complete compensation of the magnetic field caused by the operating current cannot be achieved even with very careful winding construction. In practice, stray fields always occur, which lead to leakage inductances, which then cause a symmetrical inductance component. In general, however, these leakage inductances are not sufficient to dampen the symmetrical interference component.

For this reason, attempts have already been made to reduce the leakage inductance of a current-compensated choke by means of additional ones on the outer part of the Throttle attached to increase ferromagnetic materials. However, the saturation properties of the chokes are reduced so much that they are less suitable for filter connection at high operating currents.

For damping tasks under high operating currents, current-compensated chokes are combined with smaller rod core chokes. In all cases, this approach is preferable to a circuit that only uses rod core chokes.

Nevertheless, all known solutions under high operating currents also lead to high power losses. The heat released in this way must be dissipated by design measures in order to protect heat-sensitive components, such as, for example, metallized capacitors, from overheating.

The object of the invention is to provide a current-compensated choke for radio interference suppression which, with a small space requirement, has a high symmetrical proportion of inductance even at high operating currents.

This object is achieved with a current-compensated choke of the type described at the outset in that the individual turns of the electrical windings in their structures lying outside the core interior are guided in outer cores with high saturation magnetization.

With this choke design, the stray inductance required for a high symmetrical inductance component is therefore not formed, as was previously the case, by strengthening the stray field, which is closed via the air and part of the core. Rather, a high symmetrical inductance component is built up in the individual windings of this current-compensated choke by concentrating the magnetic field of the individual turns, which is not closed in the core, in one or more separate outer cores.

The additional symmetrical inductance In this way, the share does not come at the expense of increasing the throttle resistance. Especially with high operating currents, the losses of an interference suppression circuit can be significantly reduced.

A particularly good saturation behavior of the symmetrical inductance component can be achieved if each individual turn is led through a separate outer core. At the same time, the saturation magnetization of the core can be improved without a significant increase in volume.

Further advantageous designs of the current-compensated choke are shown in the subclaims.

The invention is explained in more detail below using an exemplary embodiment.

The FIG shows a partially wound, current-compensated quadruple toroidal choke in a perspective view.

A plurality of ferrite toroidal cores 6 are assembled to form a cylindrical core 1, the cavity for receiving four identical windings is divided into four identical segments by an insulating cross 4. For a better overview, only one of the four windings is shown. This consists of an insulated copper press rope 5, which is wound in four individual turns 3 around the core 1 and is guided in the outer region of the core 1 through four outer cores 2 made of carbonyl iron.

Claims (10)

1. Current-compensated choke for radio interference suppression with a magnetic core (1) wound with at least two electrical windings, which has a high symmetrical inductance component for damping asymmetrical and symmetrical interference currents, characterized in that the individual turns (3) of the electrical windings in their outside of the core inner structures are guided in outer cores (2) with high saturation magnetization. 2. Current-compensated choke according to claim 1, characterized in that at least individual individual turns (3) of a winding in the outer region of the core (1) are guided by at least one outer core (2). 3. Current-compensated choke according to claim 2, characterized in that each individual turn (3) is guided by a separate outer core (2). 4. Current-compensated choke according to one of the preceding claims, characterized in that the core (1) consists of a closed toroidal core, E core or U core. 5. Current-compensated choke according to one of the preceding claims, characterized in that the core (1) consists of a tubular body which is composed of individual ferrite ring cores (6). 6. Current-compensated choke according to one of the preceding claims, characterized in that the outer cores (2) consist of tube or U cores. 7. Current-compensated choke according to claim 6, characterized in that the tube cores consist of carbonyl iron or powder iron. 8. Current-compensated choke according to claim 6, characterized in that the U-cores consist of a higher permeability ferrite material. 9. Current-compensated choke according to one of the preceding claims, characterized in that the individual turns (3) are made of electrically insulated copper press cable (5). 10. Current-compensated choke according to one of the preceding claims, characterized in that the individual windings (3) are constructed piece by piece from copper rods.

Images