DE3017368A1 - LINE TRANSFORMER FOR A TELEVISION RECEIVER - Google Patents

Abstract

1. Line transformer for a television receiver having a primary winding bracket (5), a secondary winding (6) and two core parts (2, 3) which are placed together to provide an air gap, characterized in that the core parts (2, 3) are directly in contact, without air gap, over a limited part of their cross section and that an air gap (8), having a width which varies over the cross section, is provided over the remaining cross section.

Description

Licentia Patent-Verwaltungs-GmbH TheodDr-Stern-Kai 1, 6000 Frankfurt (Main) 70

Hanover, April 21, 1980 UE2-H Wp / vß H 80/31

Line transformer for a television receiver

A flyback transformer for a television receiver generally contains a primary winding, one that supplies the high voltage Secondary winding and a core which has an air gap in one core leg or in both core legs. This The air gap is generally formed by a plastic film inserted between two core parts. On the one hand, the flyback transformer supplies the flyback current for the deflection coils the picture tube and on the other hand via a high-voltage rectifier the high voltage for the picture tube. The high voltage source formed in this way has an internal resistance in the order of 2-3 MiDu. This internal resistance the high voltage source is undesirable because it increases with Beam current decreases the high voltage.

This decrease in high voltage has the following effects, among other things. When the beam current increases and the high voltage increases As the load decreases, the deflection sensitivity becomes less due to the lower speed of the electron beam larger in the deflection field, so that the image width increases in an undesirable manner as the beam current increases.

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To reduce this effect it is known in the way to switch on a series resistor of the operating current to the line output stage. This works as follows. When the jet stream increases, the high voltage drops and the image width increases undesirably, the current consumption of the line output stage also increases. This will make the voltage drop above that Resistance increased "and thus that of the line output stage effective operating voltage reduced. This reduction in the operating voltage causes a reduction in the deflection amplitude and thus counteracts the mentioned enlargement of the image width. Since over the mentioned series resistor, but the entire When the direct current of the line output stage flows, a undesirable power dissipation, so that this resistor must be dimensioned for a relatively high power, and therefore also is relatively expensive. Efforts are therefore made to save this resistance.

Although there are known circuits that counteract the high voltage Stabilize beam current change. These circuits are however generally relatively complex and require a large number of active and passive components. .

Since the internal resistance of the high-voltage source is essentially disturbing at higher beam currents, it would be advantageous if the internal resistance decreases as the beam current increases. However, this cannot be achieved without further ado. Rather, the internal resistance of the high-voltage source is generally approximately constant as a function of the beam current. This applies at least from 100 - I50 _/ ^ A beam current.

The invention is based on the object without the use of additional Components to train the flyback transformer so that the Internal resistance of the high voltage source with increasing beam current decreases.

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

It is generally known for transformers (DE-PS 733 ? 83) to provide air gaps, the width of which extends over the cross-section the core leg changes. However, this solution is not based on the task of a flyback transformer Internal resistance of the high voltage source with increasing beam current to reduce »Rather, there should be a flattened current-voltage characteristic through the special design of the air gap can be achieved in order to avoid damage, e.g. in the event of a short circuit to avoid a relay. In addition, the essential feature of the invention that the two core parts over a part of their cross-section collide directly without an air gap and thus on an insulating film that forms the air gap can be completely dispensed with.

The advantageous mode of action of the solution according to the invention can be explained as follows. With a low beam current, i.e. a low direct current through the primary winding, the premagnetization of the core is small. Hence there is only one small area of the core cross-section saturated. For this small area of the core cross-section there is a small air gap, starting from zero to small values, effective. As the beam current increases, the premagnetization also increases of the core, so that now a larger area of the core cross-section is saturated. This makes it magnetic effective air gap volume increased in a desired manner. One However, increasing the air gap volume reduces the effective inductance and thus the return length in the deflection circuit. Decreased However, return means increasing high voltage. The magnetically effective air gap volume is thus determined by the according to the invention formed air gap in a desired manner dependent on the beam current and adapts in a desired manner to the respectively effective beam current in such a way that through

UQ0U / Q3U

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Return shortening of the decrease in high voltage is counteracted. This in turn means a reduction in internal resistance. ". ■ - ■■ _.

The solution according to the invention is surprising Way achieved several advantages.

a) previously in the way of the operating current to the line output stage Resistance provided to compensate for the radiation-flow-dependent Image width can be smaller and thus cheaper or even omitted completely. This gets the there occurring power loss is reduced. .

b) So far, the realization of a defined pleasure gap constant width insulating inserts are used, which were glued between the two core legs. Since in the solution according to the invention, the air gap must be zero at one point can, so the two core legs meet directly, such deposits can be completely dispensed with. This results in a particular advantage in production, because the handling for inserting the intermediate layers and for gluing the same are omitted.

c) The fact that there is a real air gap that does not go through an intermediate layer is formed, this air gap can with completely filled with an adhesive such as Araldith will. This results in a good possibility for gluing the. two core parts. In addition, the tendency of the transformer to form sparks in the air gap is thereby different Charging of the two core parts considerably reduced during testing.

d) By reducing the internal resistance of the high voltage source In the sense of the task, a very good behavior of the beam current with horizontal white bars is achieved achieved, as will be explained in more detail with reference to the description.

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The invention is explained below with reference to the drawing using various exemplary embodiments. Therein FIG. 1 shows, in principle, the flyback transformer according to the invention, Figure "2 different configurations of the air gap, Figure 3 _o the case of a high internal resistance occurring at

Disturbance in a white bar and FIG. 4 measurement curves to explain the reduction achieved the internal resistance at high beam current.

Figure 1 shows the core 1 of a flyback transformer, which is composed of two U-shaped core parts 2, 3. The primary winding 5 and the high-voltage winding 6 are located on the core leg k . Below the primary winding 5, the two core parts 2, 3 collide directly without forming an air gap. This has the advantage that a particularly strong coupling between the windings 5, 6 is achieved in the desired manner and no intermediate layer is required to form an air gap. In the opposite core leg 7, the two core parts 2, 3 collide on the inner edge even without forming an air gap. The core part 3, however, is beveled at its front end, so that a wedge-shaped air gap 8 results there. Its width increases linearly from the value zero to the value d. The value d can be in the. Of the order of 0.25 to 1.0 mm. This wedge-shaped air gap 8 brings about the described advantageous properties of the line transformer, ie in particular the reduction of the internal resistance of the high-voltage source when the beam current increases.

In FIG. 2a, the two core parts 2, 3, which are rectangular in cross section, lie over the cuboid area of width a directly on top of each other without an air gap. This solution has the advantage that the core parts 2, 3 is guaranteed and an extremely sharp edge is avoided at the support point, which can easily break out of core parts can lead. Towards the right end, the width of the air gap a 8 increases in a wedge shape up to the final value d. These

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Solution has the advantage that only the core portion 3 needs to be inclined ground _t, while the front end of the core member 2 as in prior art cores is flush and vertically.

In .Fig. 2b, the core parts 2, 3 abut directly at the left end again on each other. However, the two front ends are ground evenly at an angle, so that the right end again Air gap with the maximum width d is created. This solution has the advantage that both core parts 2, 3 are identical and thus a total of only one part manufactured and kept in stock too needs to be. With a small beam current, i.e. a low direct current through the primary winding, the premagnetization of the core is small. Therefore it is only a small area of the core cross-section saturated. This area is through the Hatched core parts 17 indicated. This effect also lies in the other exemplary embodiments.

FIG. 2c shows a combination of the solutions according to FIG. 2a And 2b.

Figure 2d shows a further embodiment in which the two Core parts 2,3 are identical. The opening angle et of the gap 8 is on the order of 10 to 14.

In Fig. 2e the end of the rectangular cross-section having core part 3 has two rectangular * -shaped, flat surfaces 1 ^, 15 on two opposite edges, on which core part 2 (not shown) rests directly without an air gap, similar to FIG. 2c. Between the faces "14.15" is. formed the end of the core part 3 to a concave surface 16 which forms a section of a cylinder surface * Thus, a air gap is also formed with varying over the cross section ** width * The width a of the surfaces IVt ₁ IS is in the order of 1 mm and the radius of curvature r of the surface l6 in the order of .20 - 30 ram. The lower end of the set core part 2 can then be flat as in Fig. 2a *

130046 / 0. ^ 44

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This has the advantage that the core part 2 is easier to manufacture of the core part 3 also have a concave surface l6. This has the advantage that both core parts 2, 3 are then identical are and thus only a core part of a single variety has to be produced.

Figure 3 shows the deformation of a horizontal white bar In the picture shown, the internal resistance of the high-voltage source is too high, the one shown in full line White bar 9 lies in the upper half of the picture and extends ZoB. over 20 to 30 lines. Suppose that for the white bar 9 the maximum beam current is of the order of magnitude from 3,000 to 5,000 ^ A. Pa down the white bar 9 extends over a multitude of lines, the smoothing capacitor for the high voltage, which can be in the order of magnitude from 1,000 to 2,500 pF, the high voltage is not maintained for so long that the high voltage during the representation of the white bar 9 »from the top to the bottom. Edge in direction 10, decreases. However, a reduced high voltage causes an increase in the deflection sensitivity because the electron beams pass through the deflection field at a lower speed. This becomes the effective horizontal deflection amplitude i.e. the image width is enlarged. Also the sensitivity to distraction in the vertical direction is enlarged so that the vertical deflection in the lower area of the white bar 9 becomes too big. This results in the distorted white bar 11 shown in dashed lines with an increasing in direction 10 Image width and one due to the increased vertical deflection sensitivity reduced geometric width in the vertical direction. There is a dim effect due to the too high internal resistance due to the high voltage source and this internal resistance is reduced by the solution according to the invention also the distortion shown in FIG. 3 during playback of the white bar 9 is reduced.

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In Figure 4, the high voltage U _{H is shown} as a function of the beam current is for a practically tested embodiment. Curve 12 shows this dependency for a known flyback transformer which is tuned to the 9th harmonic of the return frequency of the return oscillation and has an air gap of constant width. It can be seen that the internal resistance of the high voltage source, ie the slope of curve 12, is approximately constant. This internal resistance has a disadvantageous effect in the manner described, particularly in the case of a high jet current. The curve 13 shows the dependence of the high voltage on the beam current when using the Er-. finding. It can be seen that for the same high voltage with zero beam current, the high voltage drops significantly less with increasing beam current and that, moreover, the internal resistance of the high voltage source, namely the slope of the curve with increasing beam current, decreases in a desired manner. The dependency of the high voltage on the beam current is therefore reduced compared to curve 12, particularly in the case of high beam currents> 1,000 yuA. As a result, among other things, the errors explained with reference to FIG. 3 are reduced when rendering on the screen.

In an exemplary embodiment that has been tried and tested in practice, the following values were used for the differential internal resistance Ri High voltage source measured:

Beam current is ΐ / χΑ IiARi by UyjJMOhm]
1 without invention 4Ri from U _H (MOhmJ
with invention 0 3 2.7 200 2.8 2.0 400 3.2 2.0 600 2.9 1.8 8οο 2.3 1.2 1,000 2.4 0.9

It can be seen that when applying the invention, so an air gap with different widths, without additional switching measures, the internal resistance of the high voltage source is reduced in the case of large jet currents.

136CU6 / 0H4

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Claims (1)

H 80/31 Claim e Flyback transformer for a television receiver with a primary winding, a secondary winding and two core parts, which are assembled to form an air gap, as marked by that the core parts (2,3) lie directly on top of one another over a small part of their cross-section without an air gap and over the rest of the cross-section an air gap (8) with a width that changes over the cross-section is provided _o 2ο transformer according to claim 1, characterized in that the core parts (2, 3) only lie directly on top of one another at one edge without an air gap (Fig. 2a-c). 3 = transformer according to claim 1, characterized in that the width of the air gap (8) increases in a wedge shape from the point where the core parts (2, 3) lie directly on top of one another. 4. Transformer according to claim 1, characterized in that the core parts (2,3) lie directly on top of one another over a cuboid surface without an air gap (Fig. 2a, c, e). ο Transformer according to claim 1, characterized in that the boundary surfaces of the air gap (8) are flat. 6ο transformer according to claim 1, characterized in that the air gap (8) is arranged in the core leg (7) which does not carry any coils. 7ο transformer according to claim 1, characterized in that the core leg (k) carrying the coils (5, 6) has no air gap. .ORIGINAL • - 2 - H 80/31 8. Trafρ according to claim 1, characterized in that in the case of a core composed of two U-shaped core parts (2,3), one leg of one of the core parts (3) is beveled at the end (Fig. 2a). 9. Transformer according to claim 1, characterized in that in the case of a core composed of two equally large U-shaped core parts (2,3), the two abutting core legs are equally beveled, in such a way that the two core parts (2,3) are identical. are. 10. Transformer according to claim 31, characterized in that the opening angle (oC) of the wedge-shaped air gap (8) is of the order of 10 to 14. . 11. Transformer according to claim 1, characterized in that the two core parts (2,3) on two opposite edges over a small, rectangular part (1 ^, 15) of their cross-sectional area lie directly on top of one another and the end of the core part (3) otherwise Area of the cross-sectional area is concave (Fig. 2e) * 12. Transformer according to claim 11, characterized in that the width (a) of the cross-sectional area is of the order of 1 mm. 13. Transformer according to claim 11, characterized in that the surface at the front end of the core part (3) has the shape of a section of a cylinder surface in the remaining area of the cross-sectional area. ■ ■ · · ΐΊ. Transformer according to claim 13, characterized in that the radius of curvature of the cylindrical surface is in the order of magnitude of 20-30 mm "(Fig. 2e).