NL8201850A - TRANSFORMER. - Google Patents

Description

1 st EHN 10,341 1 N.V. Philips' Glow-bulb factories in Eindhoven

Transformer

The invention relates to a transformer comprising a ferromagnetic core with at least two parallel yoke-connected legs, at least one of which has a transformer winding arranged to be magnetically coupled to the core.

Such a transformer is known, for example, from DE Offenle-gungsschrift 21 03 112. Such transformers are used, for example, as a power transformer in electronic circuits. Often it is advantageous that, in addition to the transformer, an astra coil or a filter is required, for instance to eliminate undesired interference voltages that occur in the mains voltages. The construction and also the price of a coil or a filter are comparable to that of a transformer, so that installing them increases the cost price.

The object of the invention is to provide a transformer of the type mentioned in the preamble, which makes the expensive separate production of a coil or filter to be combined with it superfluous.

To this end, the transformer according to the invention is characterized in that at least one further winding is arranged on the core such that it is not magnetically coupled to the transformer winding. The further winding can act as an independent coil independently of the windings of the transformer. Because it does not need its own core and coil kbker, it can be added to the transformer at a very low cost. A filter can be manufactured in a very simple manner by attaching at least one capacitor galvanically connected to the further winding to the transformer.

The invention will now be explained in more detail with reference to the drawing. Herein is:

Figure 1 shows a side view of an exemplary embodiment of a transformer according to the invention and Figure 2 shows a circuit diagram in which the exemplary embodiment shown in Figure 1 is applied.

8201850 # · \ ν 'ΕΗΝ 10.341 2

The transformer shown in figure 1 comprises a core made of ferromagnetic material (for example iron or ferrite) with two parallel legs 1 which are connected to each other by yokes 3, so that an annular whole is obtained, which forms a closed magnetic circuit in which, if desired, an air gap (not shown) may be included. An insulating coil sleeve 5 with a primary winding 7 is arranged around one of the legs 1 (the right leg in Figure 1) and an insulating coil sleeve 9 with a secondary winding 11 on the other leg.

An insulating plate is attached to the coil sleeves 5, 9, which carries connecting pins 15, 16 *. The primary and secondary windings 7, 11 are covered with an insulating foil over which a further winding 17 is provided. This further winding 17 consists of windings which run around both legs 1 of the core. The connecting wires of the primary winding 7 are bonded to the connecting pins 15 and those of the secondary winding 11 and the further winding 17 to the connecting pins 16, for example by soldering.

When an alternating current is passed through the primary winding 7, it generates a magnetic flux cp in the core, which follows a closed path through the core. This flux is directed at a certain moment, for example, according to arrows 19. This flux is contained by the turns of the secondary winding 11, so that a voltage is induced in this winding. In other words, the primary and secondary windings are both magnetically coupled to the core and magnetically coupled through the core.

The turns of the further winding 17, on the other hand, extend around both legs 1 of the core and thus comprise the opposite, equally large fluxes in both legs. The net flux contained by these windings is therefore equal to zero, so that the further winding 17 is not magnetically coupled to the primary or the secondary winding. The same result would be achieved if the turns of the further winding 17 were not to run around both legs 1 but around both yokes 3. After all, the fluxes in these two yokes are the same size and directed in opposite directions. If the core contains more than two legs (for example, three), the turns of the further winding must include all legs for the net flux within these wins to be zero. It makes no difference whether the primary and secondary windings 7, 11 are each mounted on their own leg 1 as in the example described, or together on a single leg or split and distributed among the available legs. If desired, the 8201850 * t »*> * PHN 10.341 3 the primary and secondary windings can also be replaced by a single transformer winding which combines the functions of belde (autotransformer).

The further winding 17 is connected on the one hand to an end of the secondary winding 11 and on the other hand to a capacitor 21 which is further connected to the other end of the secondary winding. The capacitor 21 is attached to the transformer in that its lead wires are soldered to two of the lead pins 16.

It will be clear that for the further winding 17 no material is required other than the wire from which it is made. The core with the transformer windings 1, 11 wrapped with insulating foil thereon, which carrier for the further winding 17, is an element of the transformer, as is the connecting plate 13, and thus has no influence on the price of the further winding.

Figure 2 shows an example of a circuit diagram in which the transformer according to Figure 1 is applied. In Figure 2, the same reference numerals as in Figure 1 are used, as far as applicable. The primary winding 7 can be connected to the mains via the connecting pins 15. The further winding 17, together with the capacitor 21, forms an LC filter which purifies the voltage supplied by the secondary winding 11 from disturbances before it is fed via the connecting pins 16 to a device 23. If desired, further components, such as spring positions In the same manner as capacitor 21 is added to the filter.

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Claims (4)

9 EHN 10.34T 4 CONCLUSIONS. A transformer comprising a ferramagretic core with at least two parallel yoke-connected legs on at least one of which a transformer winding is arranged to be magnetically coupled to the core, characterized in that at least g a further winding (17) is mounted on the core so that it is not magnetically coupled to the transformer winding (7, 11). Transformer according to claim 1, characterized in that the further winding (17 consists of turns which extend around all the legs (1) of the core. Transformer according to claim 1, characterized in that the further winding (17) consists of windings extending around all the yokes (3) of the core. Transformer according to any one of claims 1 to 3, characterized in that at least one capacitor (21) galvanically connected to the further winding (17) is attached to the transformer to form a filter. 20 25 30 35 8201850