DE4302271A1 - HV transformer for TV receiver - Google Patents

Abstract

The hv transformer has a core (1) made of two U-shaped halves (2,3). The limbs (2a,3a) of the core form a wedge-shaped air gap (5) since one half of the core (2) is slightly tilted w.r.t. the other half. The larger airgap (6) is created by the other two limbs (2b,3b) of the core.The larger air gap includes a high voltage winding of a non-magnetically active material (7) deformed under pressure. The primary winding (9) and the h.v. winding (10) of the coil body (8) lie above the limbs which form the wedge-shaped air gap. The ratio of the axial length (L) of the coil body to its outer dia. (D) is less than 1. The winding in the larger air gap is a twisted, non-isolated copper winding. The cross-section of the core limbs (2a,2b,3a,3b) is in the region of 10-20 mm.

Description

The invention is based on a high-voltage transformer for a television receiver according to the preamble of claim 1. With such a high-voltage transformer must under whose two conditions are met.

On the one hand, the inductance of the windings should be adjustable, to a desired tuning of the high voltage transformer to a defined, especially odd harmonic of the To guarantee line frequency. That is z. B. achieved by that at a joint between two legs of the two U- shaped core halves a deformable material such. B. lacquer, Lead balls or a twisted insulated enamelled copper wire is provided and the two core halves under Defor of the material are pressed together until the ge desired inductance value is reached. In this condition the core halves are then held together by a spring or glued together.

On the other hand, efforts are made to determine the magnetization characteristic of the Transformers, i.e. H. the dependence of the inductance of the Primary winding from that flowing through the primary winding Electricity, improve. In particular, there should be a strong top the inductance at low current avoided and the drop in Primary inductance shifted towards high currents and flatter be formed. To achieve such an improved Ma gnetierungskennlinie it is known (EP-PS 039485), one Air gap at the joint between two core halves wedge-shaped to train. Through such a so-called wedge gap the magnetic resistance of the respective magnetic flux dependent. This is because with a small magnetic Flow the lines of force initially only over the narrow areas of the Wedge gaps flow, but more with increasing magnetic flux and have to flow more over the large parts of the wedge gap. This is due to the fact that the ferrite material increases with increasing flow saturation in the narrowest part of the gap, the  effective air gap increases, the inductance decreases and the magnetic resistance increases. In this way, one more favorable dependence of that formed by the winding Inductance reached by the current flowing through.

To meet these two requirements, Fer knit cores with specially ground core legs or other constructive measures required.

The invention is based, for such an object High voltage transformer to create a construction that manages without specially ground cores and in a simple way the mentioned tuning of the inductance as well as the improvement the magnetization characteristic. This task will solved by the invention specified in claim 1. Advantage adhesive developments of the invention are in the subclaims specified.

The solution according to the invention has several advantages. Because that for the improvement of the magnetization characteristics never decisive wedge gap and the air gap for the L-tuning can be achieved by simply tilting the core halves, can use conventional U-shaped cores without special grinding be used. The relatively expensive grinding of cores, e.g. B. to form a beveled front edge on a core leg, is no longer necessary. The two required air gaps for the magnetization characteristic and the L adjustment result from al so free, so to speak. Generally one such transformer each have the larger air gap within of the bobbin carrying the windings, around that of a such air gap inevitably outgoing magnetic Keep stray field low and shield it. In the invention is deviated from this solution by the smaller, wedge-shaped air gap inside the bobbin and the larger one Air gap is outside the bobbin. Has this solution following purpose. If the smaller, wedge-shaped air gap lies within the bobbin, the coupling between the Primary winding of the high voltage winding compared to the case ver  improves the larger air gap within the bobbin lies. This improved coupling in turn results in desirable ter way a reduction in the internal resistance by the Transformer illustrated high voltage source. Because of the location of the larger air gap outside the coil body is indeed the stray magnetic field increased again. According to a continuation extension of the invention is this occurring increase in stray magnetic field due to an increased cross section of the counteracted the core thigh forming the larger air gap. For example, the diameter of the round core leg of previously around 15 mm to values in the order of 17-20 mm elevated. This takes advantage of the fact that the stray field is on an air gap essentially by the ratio of the width of the air gap to the cross section of the air gap forming Kernel is determined. This solution is therefore based on the Er knows that the increase in the stray field at the larger air gap by its location outside of the bobbin by a corresponding increase in the cross section of the core legs can be mastered sufficiently.

The invention is particularly advantageously applicable to a Transformer with a so-called short bobbin and ent short core legs and a relatively short window within the core. Such a transformer, in which the Ratio of the axial length of the coil body to the outside knife of the bobbin is significantly smaller than 1 various advantages regarding the coupling of upper waves of the high voltage winding in the primary winding and there with the deflection current. Such a transformer is closer wrote in the older patent application P 42 25 692. At the Application of the invention to such a transformer there is the following advantage. By tilting the at the core halves form those lying in the bobbin Halves of the core at a relatively shallow angle with each other. The means that the inside diameter of the bobbin is larger must be the diameter of the inside of the bobbin the core leg, so that thereby the usable for the ferrite Cross section becomes smaller, which in turn affects the coupling  adversely affects. If now a relatively short bobbin and accordingly core halves with relatively short legs this cross-sectional loss becomes relatively small held.

In the invention, so to speak, an advantageous Kom bination effect achieved in the sense of double utilization. By the tilting of the core halves against each other with the aim of one Air gap to accommodate a deformable material for the L- Matching results on the opposite A wedge-shaped gap is inevitable. This wedge The gap is not disadvantageous, but becomes an advantage In addition, as a so-called wedge gap for improvement used the magnetization characteristic.

The demand achieved in the transformer according to the invention total decrease in the inductance of the primary winding at higher Streaming has the following advantage:

Television receivers generally have a beam current limitation tongue. The beam current limitation does not react arbitrarily fast, but intentionally has a time constant of around 100 ms. This is necessary so that sudden bright spots in the picture not undesirably by the beam current limitation un be suppressed and impair the brilliance of the picture. E.g. when switching between different channels it can according to driving experience to a very high beam current up to 8-10 mA. come. This increase can e.g. B. last 10-40 ms not corrected by the beam current limitation. Such a high beam current causes a correspondingly high current the primary winding of the transformer. At such a high Current through the primary winding is in known transformers the inductance of the primary winding to values of 200 mH dropped, causing the high voltage to rise sharply and the Switching transistor of the line deflection circuit is at risk. By the invention is created here in the reserve Meaning that the inductance of the primary winding even at high Flow through the primary winding which has a beam current of 8-  10 mA correspond, still has sufficiently large values that a Prevent danger to the switching transistor. The improvement dependent on the course of the inductance of the primary winding current from the primary winding - the characteristic curve is similar more a triangle than a rectangle - is essential Chen due to the fact that in the Transforma invention the two core halves by one point and not by one Edge of the colliding core legs are tilted. With egg tilting around a point, touching the wedge gap forming core leg only at one point, the be written saturation, the desired course of the magneti characteristic curve, achieved faster than with a loading Stir the two core halves along one edge, as with a rectangular core cross section would be the case. At a punctiform contact with subsequent wedge gap takes place effective air gap with increasing current and increasing magneti the desired flow faster.

The invention is explained below with reference to the drawing. Show in it

Fig. 1 shows the structure of the high-voltage transformer according to the invention in a simplified representation

Fig. 2 curves to explain the improvement of the magnetic characteristic's rule.

Fig. 1 shows a ferrite core 1 with two U-shaped core halves 2 , 3 , the parallel legs 2 a, 2 b and 3 a, 3 b are each composed. In this case 2 is formed between the core's angles a and 3 a round cross-section, a first junction point and between the core legs 2 b and 3 b having a rectangular cross section, a second joint. The core halves 2 , 3 are flipped about the uppermost point 4 at the first joint between the core legs 2 a, 3 a. At the top of the core legs 2 a and 3 a there is a point 4, and no tilting edge, because the core leg 2 a and 3 a circular cross-section have, while the core limbs 2 b and 3 b typically have a rectangular cross section. This results in a wedge-shaped air gap 5 at the first joint, which brings about the described improvement in the magnetization characteristic of the transformer and the reduction in the internal resistance of the high-voltage source.

At the second joint between the core legs 2 b and 3 b there is a larger oblique air gap 6 . A twisted, uninsulated copper wire 7 is inserted into this air gap 6 . As indicated by the arrows P, the two core halves 2 , 3 are pressed together after the coil former 8 has been applied, as a result of which the twisted copper wire is deformed. During this pressing together, the inductance of the winding 9 is measured, which increases when the core halves 2 , 3 are compressed by the reduction in the width of the air gap 6 and thus the magnetic resistance. When the desired inductivity is reached, the compression process is ended and the core is locked in this position by gluing, by a surrounding clip or by the coil body 8 itself.

The core legs 2 a and 3 a carry the bobbin 8 , which carries the primary winding 9 and the high-voltage winding 10 designed as a chamber winding. The ratio L / D from the axial length L and the outer diameter D of the bobbin 8 is dimensioned significantly smaller than 1, whereby the advantages described above for the transformer can be achieved. Due to the short length of the core legs 2 a, 2 b, 3 a, 3 b, there is the following geometric advantage. It can be seen that the inner diameter of the coil carrier 8 must be larger by the amount x because of the tilting of the two core halves 2 , 3 than the diameter of the core legs. Due to the small length of the core window formed, i.e. the dimension in the direction of the core leg, this difference in diameter x remains relatively ge ring.

FIG. 2 shows the dependence of the inductance Lprim of the primary winding 9 on the current Iprim flowing through the primary winding 9 . The magnetization characteristic M1 applies to a known high-voltage transformer without the wedge-shaped air gap 5 described . The characteristic curve M1 already drops off undesirably at a medium current. This means that the inductance represented by the primary winding 9 drops to small values. The characteristic curve M2 applies to a known transformer, in which the two core halves are also tilted against one another, but the wedge gap 5 lies outside the coil former 8 and the larger air gap 6 lies inside the coil former 8 . The magnetization characteristic M3 never applies to the high-voltage transformer according to FIG. 1 and is achieved by the wedge-shaped air gap 5 . It can be seen that the characteristic curve M3 only descends towards higher currents in the desired manner. This means that the inductance formed by the primary winding 9 only drops in a desired manner at higher currents, and thus the modulation range is increased. The characteristic curve M3 additionally reduces the internal resistance of the high-voltage source shown. The reason for this advantageous reduction of the internal resistance of the high-voltage source shown is as follows: With increasing beam current in the picture tube, the direct current Iprim flowing through the primary winding 9 also becomes. greater. As a result, the inductance Lprim of the primary winding 9 according to FIG. 2 becomes smaller, which in turn makes the ramp-down time determined by the tuning shorter. However, a reduction in the ramp-down time means an increase in the amplitude of the ramp-back pulse and thus an increase in the high voltage obtained therefrom through transformations and rectification. This effect in the sense of increasing the high voltage with increasing beam current means practically a reduction in the internal resistance of the high voltage source formed by the transformer.

The solution shown here, namely tipping around point 4 within the winding with the characteristic curve M3, leads to another advantage in contrast to the known solution, namely tipping around an edge of the normally rectangular outer legs outside the winding: when tipping around point 4 , the smaller air gap is created inside the winding and thus less eddy current losses in the windings above the air gap than when the edge of the outer leg is tilted, and thus the larger air gap lies inside the winding.

Claims (5)

1. High-voltage transformer for a television receiver with a core ( 1 ) from two U-shaped core halves ( 2 , 3 ), which are assembled on two butt parts, characterized by the following features:

• a. The two core halves ( 2 , 3 ) are tilted against each other around the outer point ( 4 ) of the first joint, and the resultant wedge-shaped air gap ( 5 ) at the first joint between the core legs ( 2 a, 3 a) having a round cross section. serves to improve the magnetization characteristic of the transformer.
• b. The resulting larger air gap ( 6 ) at the second joint contains a magnetically inactive material ( 7 ) that can be deformed under pressure in order to tune the high-voltage winding.
• c. The primary winding ( 9 ) and the high-voltage winding ( 10 ) carrying bobbin ( 8 ) lies over the wedge-shaped air gap ( 5 ) forming core legs ( 2 a, 3 a).

2. Transformer according to claim 1, characterized in that the ratio of the axial length (L) to the outer diameter (D) of the coil body ( 8 ) is significantly smaller than 1. 3. Transformer according to claim 1, characterized in that the deformable material ( 7 ) is gebil det at the second joint by a twisted, non-insulated copper wire. 4. Transformer according to claim 1, characterized in that the cross section of the core legs ( 2 a, 2 b, 3 a, 3 b) dimensioned so large that the magnetic stray field produced at the larger air gap ( 6 ) does not exceed an admissible value . 5. Transformer according to claim 4, characterized in that the diameter of the core legs ( 2 a, 2 b, 3 a, 3 b) is in the order of 10-20 mm.