KR101506698B1 - iron core winding assembly for transformer - Google Patents

Abstract

The present invention relates to a core winding assembly for transformer. The core winding assembly for transformer includes a winding unit in which a low voltage winding and a high voltage winding are stacked in order, and a core unit which is combined with the winding unit. The winding unit includes a winding bobbin which the low voltage winding to be wound on multi-layers and the high voltage winding to be wound on multi-layered in order. The core unit includes a core bobbin which winds a steel plate to form a magnetic circuit and the winding bobbin forms N (N is an integer) low voltage winding units having a stepped stack structure of which a cross section gets winder according to the stack height at which the low voltage winding is wound. Accordingly, the core unit can maximize the characteristic of smooth flow of flux since the core unit maintains a circular winding form, and can omit a separate manufacturing process for cutting artificially the edge of the low voltage winding to maintain the original shape of the core unit.

Description

Technical Field The present invention relates to an iron core winding assembly for transformer,

The present invention relates to an iron core winding assembly for a transformer, and more particularly, to an iron core winding assembly for a transformer capable of effectively reducing a weight and a volume of a coil by improving a shape structure of a winding portion and an iron core portion forming a magnetic circuit of a transformer .

Generally, a transformer is an inductive device that converts an AC electric arc voltage of the same frequency to one winding by an electromagnetic induction action, and is composed of at least two windings, one or more iron cores, and an insulating material.

In such a transformer, the conversion of the voltage means the conversion of the current at the same time, and the transformer is used to obtain the required voltage and current.

As shown in FIG. 1, the conventional iron core winding assembly for a transformer includes two winding portions 10 and 20 made of a primary coil (low-voltage winding) and a secondary coil (high-voltage winding) And an iron core portion (30) in which coils are wound with the portions (10, 20) in a binding state.

The coils wound on the winding units 10 and 20 and the iron core unit 30 share the entire output voltage so that each coil can have a good withstand voltage performance against the induced voltage. And so on.

However, since the iron core winding assembly for a transformer according to the related art has a structure in which the primary coil and the secondary coil forming the winding portions 10 and 20 have the same width and are laminated to each other, There is a limit in reducing the overall external size of the transformer owing to the volume occupied by both longitudinal corners of the coil, and the weight of the transformer is increased.

Further, when the iron core 30 is viewed from a plane, both side edges of the primary coil and the secondary coil form a track shape of a substantially rectangular structure in which the end face of the iron core 30 is not circular The short-circuit mechanical power was weakened.

Korean Registered Utility Model No. 0223839 (Mar. 3, 2001)

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and an object of the present invention is to provide a transformer for a transformer, which is capable of effectively reducing the weight and volume of a coil by improving a shape structure of a coil portion and an iron core portion, To provide a winding assembly.

In order to achieve the above object, a transformer comprising a winding portion in which a low-voltage winding and a high-voltage winding are sequentially stacked, and an iron core portion coupled with the winding portion, And an iron core bobbin for winding a steel plate forming a magnetic circuit, wherein the low-voltage winding is wound on a winding bobbin, and the low-voltage winding is wound around the winding bobbin, (N is an integer) number of low-voltage winding portions having a stepped surface lamination structure in which the cross-sectional area width gradually increases in accordance with the stack height.

The low-voltage winding section includes: a first low-voltage winding section wound nearest to the iron-core bobbin; a second low-voltage winding section having a channel-shaped accommodation space that is wider than the first low-voltage winding section; And a third low-voltage winding portion forming a wide channel-shaped accommodation space.

And a high-voltage winding support portion having an outwardly bent structure is additionally formed at the tip of the third low-voltage winding portion.

The low-voltage winding includes a first low-voltage winding layer positioned in the first low-voltage winding section and a second winding section wound around the first low-voltage winding layer, wherein a part of the circumferential surface outside the range of the first low- A second low-voltage winding layer wound around the second low-voltage winding layer in a state of being supported on the bottom surface of the low-voltage winding section; and a portion of a circumferential surface outside the second low- And a third low-voltage winding layer wound in a state of being supported on the bottom surface of the low-voltage winding section.

The winding bobbin is made of a metal material through which a current is passed, and a low-voltage inlet portion protruding outward is formed on one side of the winding bobbin.

And a cut-away portion having a penetrating structure for starting the winding of the low-voltage winding is formed at one point in the circumferential direction of the first low-voltage winding portion of the winding bobbin.

And the iron core bobbin is composed of a first iron core bobbin and a second iron core bobbin having a structure in which the winding bobbin is interposed and detached from each other.

According to the present invention having the above-described constitution, by constituting the winding bobbin having the low-voltage winding portion having the stepped-surface lamination structure in which the cross-sectional area width is gradually widened in accordance with the stack height at which the low-voltage winding is wound, So that it is possible to maximize the characteristic of smooth flow of the magnetic flux and to omit a separate machining operation for artificially cutting the edge of the low-voltage winding so as to maintain the circular shape of the iron core portion have.

In addition, the staircase winding structure by the winding bobbin can effectively reduce the cross-sectional area of the low-voltage winding, thereby greatly reducing the weight and size of the transformer and also reducing the material cost of the low-voltage winding.

In addition, since the iron core bobbin is divided into the first iron core bobbin and the second iron core bobbin having a structure in which the winding bobbins are interposed between the first and second iron core bobbins, the iron core bobbin can be easily advanced It is effective.

1 is a perspective view showing a structure of an iron core winding assembly for a transformer according to the related art.
2 is a perspective view illustrating an iron core winding assembly for a transformer according to an embodiment of the present invention.
3 is a perspective view showing a winding bobbin constituting an iron core winding assembly for a transformer according to an embodiment of the present invention.
Fig. 4 is a plan view of Fig. 3. Fig.
5 is a perspective view showing a process of winding a low-voltage winding on the winding bobbin of FIG.
6 is a top cross-sectional view of an iron core winding assembly for a transformer according to an embodiment of the present invention.
7 is a perspective view showing a coupling structure of an iron core bobbin constituting an iron core winding assembly for a transformer according to an embodiment of the present invention.
FIG. 8 is a perspective view illustrating a process in which an iron core coil is fixed to the iron core bobbin of FIG. 7;

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying FIGS. 2 to 8. FIG.

As shown in the drawing, the iron core winding assembly for a transformer according to the present invention includes a winding portion C in which a low-voltage winding C1 and a high-voltage winding C2 are sequentially stacked, and an iron core portion Wherein the winding section (C) comprises a winding bobbin (100) in which a low voltage winding (C1) wound in multiple layers and a high voltage winding (C2) wound in multiple layers are sequentially wound, I) includes an iron core bobbin 200 for winding a steel sheet forming a magnetic circuit.

First, the winding section C has a structure in which a low-voltage winding C1 and a high-voltage winding C2 are sequentially stacked, and the two parts are disposed at one side and the other side of the iron core section I, respectively.

The winding portion C according to the present invention is further comprised of a winding bobbin 100 capable of sequentially winding the low voltage winding C1 wound in multiple layers and the high voltage winding C2 wound in multiple layers .

In addition, the winding bobbin 100 is formed with N low-voltage winding portions 110 (N is an integer) having a stepped surface lamination structure in which the cross-sectional area width gradually increases in accordance with the stack height at which the low-voltage winding C1 is wound do.

That is, the winding bobbin 100 has a stepped shape in which the width of the low-voltage winding C1 is narrowed by the low-voltage winding portion 110, It is possible to maintain the winding shape and to maximize the smooth flow characteristics of the magnetic flux. In order to maintain the circular shape of the iron core part I, the edge of the low-voltage winding C1 is cut into an artificial step structure It is possible to omit a separate machining operation.

In addition, the stepped winding structure of the winding bobbin 100 can effectively reduce the cross-sectional area of the low-voltage winding C1, thereby greatly reducing the weight and size of the transformer and also reducing the material cost of the low- There is an effect that can be reduced.

3, the low-voltage winding unit 110 includes a first low-voltage winding unit 111 wound nearest to the iron-core bobbin 200 and a second low- A second low-voltage winding section 112 forming a wide channel-type accommodation space and a third low-voltage winding section 113 forming a channel-type accommodation space that is wider than the second low-voltage winding section 112.

In this case, the low-voltage winding section 110 is preferably formed in three configurations including the first, second, and third low-voltage winding sections 111, 112, and 113 as described above, but the present invention is not limited thereto. The low voltage winding section 110 can be manufactured in a plurality of configurations including only the first low voltage winding section 111 or the first and second low voltage winding sections 111 and 112, , And can be expanded to three or more configurations.

It is also possible to change the position of the windings of the low-voltage winding C1 and the high-voltage wire C2 to each other for an effective dot ratio as required.

In addition, a high-voltage winding support portion 114 having an outwardly bent structure is additionally formed at the tip of the third low-voltage winding portion 113.

That is, the high-voltage wire support 114 serves to stably support the high-voltage wire C2.

Also, the winding bobbin 100 according to the present invention is made of a metal material (aluminum, copper, or the like) through which a current is passed.

The reason why the winding bobbin 100 is made of a metal material is that the winding bobbin 100 itself serves as one turn (winding) of the low-voltage winding C1 so that the stack height of the low- Can be effectively lowered.

A low-voltage inlet 120 protruding outward is formed at one side of the winding bobbin 100 (see FIG. 3).

A cut-out portion 111a having a penetrating structure for starting the winding of the low-voltage winding C1 is formed at a point in the circumferential direction of the first low-voltage winding portion 111 of the winding bobbin 100. [

The winding section C1 is divided into a low voltage winding C1 and a high voltage winding C2 and the low voltage winding C1 and the high voltage winding C2 are sequentially wound in the circumferential direction of the winding bobbin 100, Thereby changing the voltage by the electromagnetic induction phenomenon.

6, the low-voltage winding C1 includes a first low-voltage winding layer C1 'positioned in the first low-voltage winding portion 111 and a second low-voltage winding layer C1' And a second low voltage winding layer C1 'wound in a wrapping state and wound in a state in which a part of a peripheral surface deviated from the region of the first low voltage winding layer (C1') is supported on the bottom surface of the second low voltage winding portion (112) And a part of the circumferential surface outside the region of the second low-voltage winding layer (C1 '') is wound around the third low-voltage winding section (113 '), And a third low-voltage winding layer (C1 '' ') wound in a state of being supported on the bottom surface.

That is, the low-voltage winding C1 has a stepped winding structure, and the surface area of the section from the first low-voltage winding layer C1 'to the third low-voltage winding layer C1' "gradually increases . Therefore, it is possible to omit many processes such as artificially cutting, forming, annealing, and assembling both side edges of the low-voltage winding C1, and it is possible to prevent the loss of coils discarded due to cutting, The winding type structure of the low voltage winding C1 without cutting particularly has an advantage that the amorphous structure can be manufactured at a low cost.

The iron core I is installed in a state of passing through between the two winding bobbins 100, and serves as a passage through which the magnetic flux generated by the electromagnetic induction phenomenon can flow.

In the iron core I according to the present invention, a circular iron core bobbin 200 for guiding the steel coil forming the magnetic circuit to be able to securely engage is formed.

The iron core bobbin 200 is composed of a first iron core bobbin 210 and a second iron core bobbin 220 having a structure in which the winding bobbin 100 is interposed therebetween.

The iron-core bobbin 200 of the prefabricated structure is preferably made of an insulating material made of synthetic resin.

5, the iron core bobbin 200 is rotated by the motor M and the driving roller R in a state where the first iron core bobbin 210 and the second iron core bobbin 220 are coupled to each other, The coil is held on the iron bobbin 200.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the invention. Therefore, the embodiments disclosed in the present invention are intended to illustrate rather than limit the scope of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of the claims should be construed as being included in the scope of the present invention.

C1: Low-voltage winding
C2: High-voltage winding
C: winding part
I: iron core part
100: winding bobbin
110: low voltage winding section
111: first low-voltage winding section
112: second low-voltage winding section
113: third low-voltage winding section
114: High-voltage winding support
120: Low pressure inlet
200: iron core bobbin
210: First iron core bobbin
220: Second iron core bobbin

Claims (7)

A transformer comprising a winding portion in which a low-voltage winding and a high-voltage winding are sequentially stacked, and an iron core portion which is engaged with the winding portion,
Wherein the winding section includes a winding bobbin in which a low-voltage winding wound in multiple layers and a high-voltage winding wound in multiple layers are sequentially wound,
Wherein the iron core portion includes an iron core bobbin for winding a steel plate forming a magnetic circuit,
(N is an integer) number of low-voltage winding portions having a stepped surface lamination structure in which the cross-sectional area width is sequentially widened in accordance with the stack height at which the low-voltage winding is wound,
Wherein the winding bobbin is made of a metallic material through which a current is passed, and a low-voltage inlet portion protruding outward is formed on one side of the winding bobbin.
The method according to claim 1,
The low-
A first low-voltage winding portion wound nearest to the iron-core bobbin,
A second low-voltage winding portion forming a channel-shaped accommodation space larger than the first low-voltage winding portion;
And a third low-voltage winding portion forming a channel-shaped accommodation space larger than the second low-voltage winding portion.
3. The method of claim 2,
And a high-voltage winding support portion having an outwardly bent structure is additionally formed at the tip of the third low-voltage winding portion.
3. The method of claim 2,
The low-
A first low-voltage winding layer positioned in the first low-voltage winding section,
A second low voltage winding layer wound in a state wrapping the first low voltage winding layer and wound in a state in which a part of a circumferential surface out of the range of the first low voltage winding layer region is supported on the bottom surface of the second low voltage winding section;
And a third low-voltage winding layer wound in a state of wrapping the second low-voltage winding layer, wherein a part of a circumferential surface outside the range of the second low-voltage winding layer region is wound on the bottom surface of the third low- A core wire winding assembly for a transformer.
delete 5. The method according to any one of claims 2 to 4,
Wherein a cut-away portion of a perforated structure for starting winding of the low-voltage winding is formed at a point in the circumferential direction of the first low-voltage winding portion of the winding bobbin.
5. The method according to any one of claims 1 to 4,
Wherein the iron core bobbin is composed of a first iron core bobbin and a second iron core bobbin having a structure in which the iron core bobbin is mutually detachably coupled with the winding bobbin therebetween.

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