KR100279272B1 - Thin Film Coil Structure of Flyback Transformer - Google Patents

Abstract

The present invention relates to a thin film coil structure of a flyback transformer, comprising: a first winding between a top thin film insulating film and a bottom thin film insulating film, the input exposed conductor portion and the output exposed conductor portion, each of which is a starting point, wound in a clockwise direction a plurality of times In a thin film coil structure of a flyback transformer including a pattern coil and a second pattern coil, the first pattern coil and the second pattern coil are connected to each other by a joint having a moderate width. Since the first pattern coil and the second pattern coil are connected to the input exposed conductor portion and the output exposed conductor portion, respectively, because the first pattern coil and the second pattern coil have a moderate width, Maintaining a stable characteristic of the coil has an excellent effect to maximize the efficiency in the flyback transformer.

Description

Flyback Transformer Thin Film Coil Structure

The present invention relates to a thin-film coil structure of a flyback transformer, and more particularly, the first pattern coil and the second pattern coil, and the input exposed conductor portion and the output exposed conductor portion are interconnected through a joint having a moderate width. The present invention relates to a thin film coil structure of a flyback transformer that can maintain high pressure stability in a flyback transformer.

In general, a flyback transformer refers to a single winding transformer for obtaining a high voltage for a water pipe using pulses generated during the return period of a horizontal deflection output in a television receiver, and is also called a horizontal output transformer.

Conventional flyback transformers as defined above can be used in a variety of applications, in particular, to generate a high voltage using a horizontal synchronization signal in a television receiver, it is also widely used in oscilloscopes and monitors.

The flyback transformer used for this purpose is composed of a primary winding and a secondary winding, and a core made of a magnetic material is usually configured to magnetically connect them, and the degree of boosting is caused by the ratio of the primary winding and the secondary winding. Is determined.

Here, the structure of the thin film coil according to the prior art used for the winding will be described with reference to FIG.

1 is a plan view including a graph for explaining a thin film coil structure of a flyback transformer according to the prior art.

The thin film coil structure of the flyback transformer according to the present invention is formed of polyimide or polyester and has a top surface insulating film 10 having a substantially rectangular shape, and the top surface insulating film 10. The input exposed conductor part (a) and the output exposed conductor part (b) which are exposed by locally peeling both ends of respectively, and the input exposure conductor part (a) and the output exposure conductor part (b) are respectively started as the starting point, toward the center. The upper thin film insulating film having the first pattern coil 20 and the second pattern coil 30 wound in the clockwise direction and the first pattern coil 20 and the second pattern coil 30 interposed therebetween ( The lower surface of 10) is made of a thin film insulating film (not shown) to be bonded by high frequency induction heating.

In this case, the input exposed conductor part (a) and the output exposed conductor part (b) may be connected to other parts more easily so that the first pattern coil 20 and the second pattern coil 30 may be connected. It will have an area larger than its diameter.

That is, the input exposed conductor part (a) and the output exposed conductor part (b) have a larger area than the first pattern coil 20 and the second pattern coil 30 having a narrow diameter as shown in FIG. It is formed in the shape which has.

However, the thin film coil structure of the flyback transformer according to the related art formed as described above may include the first pattern coil 20 and the first pattern coil 20 having a small diameter. Due to the shape having an area larger than that of the two pattern coils 30, as shown in the graph of FIG. 1, an increase in the amount of charge due to a sharp drop in the resistance value is suddenly increased, causing a temperature increase. This, in turn, has a major drawback that greatly reduces the high voltage regulation by changing the high frequency characteristics of the flyback transformer.

Accordingly, the present invention was created to solve the above-mentioned problems, and the object of the present invention is that the first pattern coil and the second pattern coil are connected to the input exposed conductor part and the output exposed conductor through a joint part having a gentle width. The present invention provides a thin film coil structure of a flyback transformer that can be connected to each part to maximize efficiency in a flyback transformer.

1 is a plan view including a graph for explaining the structure of a thin film coil of a flyback transformer according to the prior art.

Figure 2 is a plan view including a graph for explaining the thin film coil structure of the flyback transformer according to the present invention.

Figure 3 is an explanatory diagram showing an example of the change in the resistance value with respect to the cross-sectional area and length in order to explain the thin film coil structure of the flyback transformer according to the present invention.

* Explanation of symbols for main parts of the drawings

10: upper thin film insulating film 20: the first pattern coil

30: second pattern coil 40: joint

a: input exposed conductor part b: output exposed conductor part

The thin film coil structure of the flyback transformer according to the present invention for achieving the above object, the input exposed conductor portion and the output exposed conductor portion between the upper thin film insulating film and the lower thin film insulating film, respectively, as a starting point, a plurality of clockwise toward the center In the thin film coil structure of a flyback transformer including a first coil coil and a second coil coil wound, the first pattern coil and the second pattern coil are connected to the input exposed conductor by a joint having a moderate width. Connected to the negative and output exposed conductor parts respectively is a basic feature of the technical configuration.

Hereinafter, a preferred embodiment of the thin film coil structure of the flyback transformer according to the present invention will be described with reference to FIG. 2.

2 is a plan view including a graph for explaining the thin film coil structure of the flyback transformer according to the present invention.

The thin film coil structure of the flyback transformer according to the present invention may be formed of a polyimide or polyester system to locally peel off both ends of the upper thin film insulating film 10 having a substantially rectangular shape and the upper thin film insulating film 10, respectively. Winding the input exposure conductor portion (a) and the output exposure conductor portion (b), and the input exposure conductor portion (a) and the output exposure conductor portion (b), respectively, as a starting point, clockwise toward the center a plurality of turns The first pattern coil 20 and the second pattern coil 30, and the first pattern coil 20 and the second pattern coil 30 are interposed between the upper surface of the thin film insulating film 10 at a high frequency. Induction heating is made of a thin film insulating film to be bonded.

In this case, the first pattern coil 20 and the second pattern coil 30 are connected to the input exposed conductor part a and the output exposed conductor part b by a joint part 40 having a gentle width, respectively. It consists of the shape which becomes.

That is, the joint portion 40 includes a first pattern coil 20 and a second pattern coil 30 having a narrow diameter, an input exposed conductor portion a having a large area, and an output exposed conductor portion b. The first pattern coil 20 and the second pattern coil 30 have a shape that becomes wider as they approach the input exposed conductor part a and the output exposed conductor part b so as to be smoothly interconnected therebetween.

Here, the first pattern coil 20 and the second pattern coil 30 having narrow diameters of the input exposed conductor part a and the output exposed conductor part b having a large area by the joint part 40 are provided. By slowly connecting), as shown in the graph of FIG. 2, it can be seen that the fluctuation of the rising amount of the charge amount due to the gentle drop of the resistance value is not large, so that the stability of the high pressure can be maintained.

3 is an explanatory diagram showing an example of a change in resistance value with respect to a cross-sectional area and a length in order to explain the thin film coil structure of the flyback transformer according to the present invention.

As shown in FIG. 3, the resistance value of a material is inversely proportional to the cross-sectional area of the material and according to the principle proportional to the length, the input exposed conductor part a and the output exposed conductor part having a large area by the joint part 40. (b) is gently connected to the first pattern coil 20 and the second pattern coil 30 having a narrow diameter to prevent a sudden change in the cross-sectional area to minimize the instantaneous change in the resistance value This makes it possible to reduce the fluctuation in the amount of increase in charge due to the gentle drop of. That is, since the resistance value is inversely proportional to the amount of charge, a sudden decrease in the resistance value can lead to a sharp increase in the amount of charge. It can be seen that the joint portion 40 having a gentle area can solve this problem.

In other words, as shown in FIG. 3, the resistance R (Ω) of the material when the cross-sectional area is S (m ² ) and the length is l (m) can be obtained as R = ρ × ℓ / S, where It can be seen that ρ is the resistivity and the resistance R is inversely proportional to the cross-sectional area. Therefore, since the resistance value is sensitive to the cross-sectional area, and the sudden change in the cross-sectional area may cause a sudden change in the resistance value, the input exposed conductor portion a and the output exposed conductor having a large area by the joint portion 40 are thus caused. It may be a feature of the present application that the portion (b) is gently connected to the first pattern coil 20 and the second pattern coil 30 having a narrow diameter.

As described above, according to the thin film coil structure of the flyback transformer according to the present invention, the first pattern coil and the second pattern coil are connected to the input exposed conductor part and the output exposed conductor part, respectively, by a joint having a moderate width. By configuring the shape, there is an excellent effect of maximizing the efficiency of the flyback transformer by maintaining the stable characteristics of the coil.

Claims (1)

A flyback transformer comprising a first pattern coil and a second pattern coil wound multiple times in a clockwise direction toward the center between the upper thin film insulating film and the lower thin film insulating film, respectively, as the starting point. In the thin film coil structure, And the first pattern coil and the second pattern coil are connected to the input exposed conductor portion and the output exposed conductor portion, respectively, by a joint having a moderate width.

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