EP0071008A1

EP0071008A1 - Line transformer, in particular a transformer for a television receiver

Info

Publication number: EP0071008A1
Application number: EP82105090A
Authority: EP
Inventors: Gerhard Napp; Ulrich Dipl.-Ing. Bieringer; Heinz Kreismer; Walter Dipl.-Ing. Goseberg
Original assignee: Licentia Patent Verwaltungs GmbH; Telefunken Fernseh und Rundfunk GmbH
Current assignee: Sentenza Di Nullita' Emessa Dal Tribunale telefunk
Priority date: 1981-07-25
Filing date: 1982-06-10
Publication date: 1983-02-09
Also published as: DE3129381A1; AU8575582A; BR8204309A; US4500833A; NZ201175A; DE3266164D1; HK13691A; JPH048928B2; DE3129381C2; JPS5830111A; SG46891G; EP0071008B1

Abstract

Schaltnetzteil-Transformator, insbesondere für einen Fernsehempfänger. Primärwicklung (1) und Sekundärwicklung (2) sind in mehrere Teilwicklungen aufgeteilt, die in verschiedenen Kammern (10) eines kammerförmigen Spulenkörpers (9) liegen. Die Kammern der Gruppe für die Primärwicklung (P) und der Gruppe für die Sekundärwicklung (S) sind ineinander geschachtelt. Durch diese Lösung werden die geforderte Spannungsfestigkeit zwischen Primärwicklung (P) und Sekundärwicklung (S) und eine geringe Streuinduktivität dieser Wicklungen erreicht.Switching power supply transformer, in particular for a television receiver. The primary winding (1) and secondary winding (2) are divided into several partial windings, which are located in different chambers (10) of a chamber-shaped coil former (9). The chambers of the group for the primary winding (P) and the group for the secondary winding (S) are nested. This solution achieves the required dielectric strength between primary winding (P) and secondary winding (S) and a low leakage inductance of these windings.

Description

1. Switching power supply transformer, in particular for a television receiver with a power output between 40 and 150 watts, with a primary winding and a secondary winding, characterized by the following features:

a) primary winding (1) and secondary winding (2) are divided into several partial windings (la-lc; 2a-2b).

b) The partial windings of the primary winding (1) lie in a first group and the partial windings of the secondary winding (2) in a second group of chambers (10) of a chamber bobbin (9).

c) The chambers (10) of the two groups are nested.
2. Transformer according to claim 1, characterized in that the total number of chambers (10) is approximately 6.
3. Transformer according to claim 1, characterized in that the chamber width of the narrowest chambers is approximately 1 mm.
4. Transformer according to claim 1, characterized in that the chamber widths of the 6 chambers are different.
5. Transformer according to claim 1, characterized in that the width of all 6 chambers to achieve a flat and optimally coupled transformer is only about 20 mm.
6. Transformer according to claim 1, characterized in that in five successive chambers (10) alternately a third of the primary winding (1) and half of the secondary winding (2) are arranged to generate the main operating voltage U1.
7. Transformer according to claim 1, characterized in that an additional secondary winding (7) for generating a further operating voltage is also divided into a plurality of partial windings (7a-7c) which are in the chambers (10) of the second group.
8. Transformer according to claim 7, characterized in that the partial windings (7a-7c) of the additional secondary winding (7) under the partial windings of the secondary winding (2): are.
9. Transformer according to claim 7, characterized in that the additional secondary winding (7) is used to generate an operating voltage for a consumer (sound output stage) with fluctuating current consumption.
10. Transformer according to claim 1 or 7, characterized in that the partial windings (7a-7c) are connected in parallel.
11. Transformer according to claim 1, characterized in that the partial windings (1a-1c) are connected in series.
12. Transformer according to claim 1, characterized in that further primary auxiliary windings (3, 4) in an approximately in the middle of the coil former (9) lying chamber (10) of the first group over the partial winding (1b) of the primary winding (1) are arranged.
13. Transformer according to claim 1, characterized in that all the chambers (10) of the two groups are wound with wire of only one diameter.

Claims

In telecommunications equipment, especially television receivers, it is known to effect the desired electrical isolation from the network by means of so-called switched-mode power supply transformers. Switching power supply transformers of this type are considerably smaller and lighter than a mains transformer operating at 50 Hz for the same power, because they operate at a substantially higher frequency of approximately 20-30 KHz. Such a switched-mode power supply transformer (hereinafter referred to as SMPS transformer) generally contains a primary side with the primary winding serving as the working winding for the switch, as well as additional auxiliary windings and a secondary side with the secondary winding for generating the essential operating voltage and, if appropriate, further additional windings for generating further ones Operating voltages of different sizes and polarities. The secondary side and primary side are insulated from each other in accordance with the VDE regulations and have the required dielectric strength so that touching live parts on the secondary side remains safe.

Another requirement for such an SMPS transformer is that the leakage inductance of at least the primary winding and the secondary winding is as small as possible. If the leakage inductance is too high, transient processes can occur during switching operation, which do not guarantee optimal switching operation of the switching transistor on the primary side and endanger this transistor by excessive power consumption. In addition, an increased leakage inductance undesirably increases the internal resistance of the voltage sources for the individual operating voltages.

It is known to design the windings for such transformers as a layer winding. Layer coils of this type, however, contain feathered film intermediate layers between the windings and, after completion, generally require the winding or the complete transformer to be cast in order to ensure VDE safety. An application as chamber winding in television sets is currently not taking place because of the problems listed below. A chamber winding would have in particular. the advantage that it could be wrapped more easily and efficiently with automatic machines. When using a chamber winding on a switching power supply, the desired insulation between the primary side and the secondary side would initially be achieved by two chambers, one of which is filled only with windings on the primary side and the other only with windings on the secondary side. With such an arrangement, however, there would be a slight coupling between the primary side and the secondary side and thus an undesirably high leakage inductance. If, on the other hand, the number of chambers is chosen to be significantly larger, the transformer becomes more expensive and unnecessarily large. A larger core is also required. So far, no SMPS transformer with chamber winding technology has been presented in a television set.

The invention is based, an SMPS transformer the task to create in chamber winding technology, which enables a rational automatic winding process, ie can be wound with only one type of wire, has a spatially narrow and flat construction, which has the required insulation between the primary and secondary sides and low leakage inductances. The transformer should not be potted or soaked and still not generate any annoying noises during operation. Without any mechanical aids, the transformer should only be held on its connecting nails in the printed circuit board by soldering.

This object is achieved by the invention described in claim 1. Advantageous developments of the invention are described in the subclaims.

The fact that the individual windings or partial windings on the primary side are only in chambers of the first group and the windings or partial windings on the secondary side are only in chambers of the second group, i.e. the primary side and secondary side are divided into separate chambers, the necessary dielectric strength between the primary side and secondary side ensured. The division of the windings into several chambers and the nested arrangement of the chambers from the primary side and the secondary side achieve the desired fixed coupling between the primary side and the secondary side and thus the desired low leakage inductance on the primary side and the secondary side. It has been shown that a total number of chambers in the order of 6 represents an economically advantageous solution. With a smaller number of chambers, the coupling between the primary side and the secondary side becomes less. With a higher number of chambers, however, either the individual chambers become too small or the entire transmitter and in particular the core become too large.

An embodiment of the invention is explained with reference to the drawing. Show in it 1 shows the circuit diagram of a transformer for the switching power supply and

Figure 2 shows the division of the individual windings into different chambers.

Figure 1 shows a transformer intended for a switched-mode power supply with the primary side P and the secondary side S, which, while maintaining the necessary dielectric strength of e.g. 10,000 V are electrically isolated from each other. The primary side contains the primary winding 1, which is a working winding in the collector circuit of the switching transistor switched at approximately 20-30 KHz. The primary winding 1 is divided into three sub-windings 1a, 1b and 1c, which are connected in series. The beginning of the partial winding la and the end of the partial winding 1c are switched into the collector circuit of the switching transistor, while the taps between the partial windings 1a and 1b are not used, but only form bases for connecting the connections of the partial windings. The primary side P also contains an additional winding 3 for feeding the feedback path with which the primary side is designed as a self-oscillating circuit. In addition, the primary side P contains an additional winding 4 for regulating the point of use of the switching transistor in order to stabilize the amplitude of the output voltages on the secondary side S.

The secondary side S initially contains the secondary winding 2, from which the main operating voltage U1 is obtained via a rectifier circuit. The secondary winding 2 is divided into two partial windings 2a and 2b connected in series. The secondary winding S also contains an additional winding 5 for generating an operating voltage for the video amplifier and a further winding 6 for generating the operating voltage for the vertical deflection stage. In addition, an additional winding 7 is provided, from which the operation after rectification voltage for the sound stage is obtained. The winding 7 consists of three partial windings 7a, 7b, 7c, which are connected in parallel. The sound amplifier has a strongly fluctuating current consumption between 50 mA and 1,000 mA, which changes the load on the secondary side S. This change in load can cause an undesirable change in the operating voltage U1, which also influences the line deflection amplitude. This undesirable dependency can be reduced in that the coupling between the winding 7 and the winding 4 for the control is dimensioned larger than the coupling between the winding 2 and the winding 4. This solution is described in more detail in DE-OS 27 49 847 This increased coupling between the windings 7 and 4 is achieved in the present case by the three windings 7a, 7b, 7c connected in parallel. Another winding 8 is used after rectification to generate a negative operating voltage of -30 V.

FIG. 2 shows the coil former 9 for the individual windings in FIG. 1, which has a total of six chambers 10. One third of the primary winding 1 is divided into the first, third and fifth chamber in the form of the partial windings 1a, 1b, 1c. The secondary winding 2 is divided in half in the form of the partial windings 2a, 2b into the second and fourth chambers. The three partial windings 7a, 7b, 7c of the winding 7 for the audio output stage are divided into the second, fourth and sixth chambers. It can be seen that only alternate windings or partial windings of the primary side P or the secondary side S are located in the chambers. The shown nesting of the windings, i.e. the alternating arrangement of windings of the primary side and the secondary side in successive chambers ensures the desired close coupling between the primary side P and the secondary side S. The arrangement of the windings 3, 4 approximately in the middle of the coil former 9 above the partial winding 1b ensures the desired tight Coupling the windings 3, 4 with the other windings.

In a practical example, the individual windings had the following number of turns.