KR101631182B1 - Transformer for high space factor - Google Patents

Abstract

The present invention relates to a transformer with a high space factor. The transformer comprises: an iron core part; a winding part composed of a primary coil and a secondary coil; and a winding bobbin interposed between the iron core part and the winding part. The primary coil is a rectangular copper wire extending by a certain length with a predetermined thickness and is wound in a direction such that upper and lower surfaces are perpendicular to the winding bobbin with respect to a lengthwise direction, to increase a space factor with respect to the iron core part, wherein the primary coil is composed of a group of multiple ring-shaped coils that are wound continuously in the lengthwise direction of the winding bobbin with the number of turns restricted to one. Accordingly, a contact area can be reduced greatly compared with the winding area of a traditional iron core part, thereby greatly increasing a space factor with respect to the iron core part. Therefore, the efficiency of the transformer can be increased further compared with a transformer with identical specifications.

Description

[0001] TRANSFORMER FOR HIGH SPACE FACTOR [0002]

The present invention relates to a high-ratio transformer, and more particularly, to a high-ratio transformer capable of easily winding a coil, having excellent workability, and greatly improving a winding dot rate with respect to an iron core.

Generally, a transformer is an inductive device that changes the value of an AC voltage or an electric current by using an electromagnetic induction action. The transformer 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.

1, the winding assembly includes two winding portions 10 and 20 made of a primary coil 3a and a secondary winding 3b and a high-voltage winding, An iron core portion 30 bound to the two winding portions 10 and 20 and a winding bobbin 11 interposed between the winding portions 10 and 20 and the iron core portion 30.

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.

In addition, the winding units 10 and 20 select the most effective conductor type in consideration of the transformer capacity, the current, and the voltage.

That is, the conductor shape applied to the primary coil 3a of the winding part is made of a square copper wire, and the secondary coil 3b is generally formed in the form of a round wire.

Each time the winding is performed once on the iron core 30, the winding portions 10 and 20 are wound in the same winding number for the purpose of insulation.

Therefore, in the transformer according to the related art, each time the winding portions 10 and 20 are wound once with respect to the iron core portion 30, the interlayer sheet 5 must also perform the winding operation once, There is a problem that it takes much time.

In addition, in the case of the rectangular copper wire of the primary coil 3a, since the longitudinal extending surface is closely attached to the bobbin 11 for stable grounding, the higher the ground area of the rectangular copper wire is, The loss factor of the transformer is widened and the efficiency of the transformer is lowered.

Further, as the capacity, current, and voltage of the transformer increase, the number of windings of the winding sections 10, 20 increases, and accordingly, the amount of the winding work is increased proportionally, and as the number of windings of the winding section increases, If a winding failure such as a twist or a twist occurs, there was a cumbersome inconvenience that the winding portion should be loosened and rewound again.

That is, when the winding portion is left untwisted or twisted, the high voltage is leaked to the outside due to the electrical short circuit when the high voltage is stepped up, resulting in a functional damage to the product, thereby lowering the reliability of the product.

Korean Patent Registration No. 10-0740437 (2007.07.11) Structure of transformer and winding method of winding coil for transformer

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above-described problems of the conventional art, and it is an object of the present invention to provide a coin- So as to prevent occurrence of staggering or kinking.

In order to achieve the above object, a high-frequency transformer according to the present invention is a transformer including an iron core, a winding portion composed of a primary coil and a secondary coil, and a winding bobbin interposed between the iron core portion and the winding portion, Wherein the primary coil is a rectangular copper wire having a predetermined thickness and extending to a predetermined length so that winding is performed in a direction perpendicular to the winding bobbin in the vertical direction about the longitudinal direction so as to increase the drop rate with respect to the iron core portion, Wherein the primary coil is constituted by a plurality of groups of annular coils which are limited to one turn and are continuously wound along the longitudinal direction of the winding bobbin.

The annular coil group is manufactured in various sizes with different widths in the longitudinal direction according to the capacity, current, and voltage value of the transformer.

Wherein an interlayer insulating paper is interposed between each square copper wire forming the annular coil group and the interlayer insulating paper is formed in the same shape as the rectangular copper wire.

And radiating grooves are formed on an upper surface or a lower surface of the rectangular copper wire in the longitudinal direction to increase the heat radiating effect.

And the heat dissipation groove is formed to extend from one end of the rectangular copper wire to a vicinity of the other end.

The length of the upper and lower surfaces is longer than the length of both end portions of the thickness surface when viewed from the cross-sectional direction of the rectangular copper wire.

And the iron core portion is formed by stacking infinite iron core members having the same thickness.

And the width of at least some sections of the iron core members gradually decreases from the center to the outer side when viewed from the cross section.

According to the present invention having the above-described structure, since one end portion of the thickness side of the square copper wire is wound along the circumferential direction of the iron core portion so that the square copper wire can be positioned in the direction perpendicular to the iron core portion, The contact area can be greatly reduced as compared with the area of the iron core winding, and as a result, the winding load ratio with respect to the iron core portion can be greatly increased, and the efficiency of the transformer and the comparative transformer of the same standard can be further improved.

In addition, the increase of the dot rate of the rectangular copper wire has the effect of greatly improving the short-circuit mechanical power as the winding density is high.

In addition, since the primary coil is limited to one turn, it is easy to perform winding work and is not only inexpensive to perform, but also can prevent winding defects such as staggering or twisting due to an increase in the number of windings It is effective.

In addition, since the primary coil is wound without a separate conductor coating, it is advantageous in cost reduction as well as heat radiation effect.

1 is a cross-sectional view showing a transformer configuration according to the prior art.
2 is a cross-sectional view illustrating a high-ratio transformer according to an embodiment of the present invention.
3 is a cross-sectional view showing the shape of the iron core portion of Fig.
Fig. 4 is a front view showing the primary coil of Fig. 2. Fig.
5 is a partially enlarged view of Fig.
Figure 6 is a schematic diagram illustrating various embodiments of the primary coil of Figure 2;
FIG. 7 is a cross-sectional view in which a heat dissipating groove is additionally formed with respect to the primary coil of FIG. 2. FIG.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to FIGS. 2 to 7 attached hereto.

As shown in the drawing, the high-ratio transformer according to the present invention includes a winding unit 200 including an iron core 100, a primary coil 210 wound around the iron core 100, and a secondary coil 220, And a winding bobbin 300 interposed between the iron core unit 100 and the winding unit 200.

First, the iron core unit 100 is a component that is bound together with a winding unit 200 and a winding bobbin 300, which will be described later, and serves as a passage through which a magnetic flux generated by the electromagnetic induction phenomenon can flow.

In addition, a separate iron core bobbin (not shown) may be additionally provided to the iron core 100 so that the steel coil forming the magnetic circuit can be securely held.

Of course, the iron core 100 may vary in size and shape (angular, elliptical, circular) depending on the size and capacity of the transformer.

Particularly, when the iron core part 100 is made into an elliptical shape ('onshore track' structure) or a circular shape, an infinite number having the same thickness (A) so as to greatly improve a drop rate with respect to the winding bobbin 300 The widths B of at least some sections of the iron core members 101 are gradually decreased with increasing distance from the central portion as viewed from the cross section of the core members 101 (See FIG. 3).

The winding unit 200 has a structure in which windings are formed along the circumferential direction of the iron core unit 100 and the primary coil 210 and the secondary coil 220 are sequentially wound. 200 are disposed at one side and the other side of the iron core unit 100, respectively.

The primary coil 210 is a low-voltage winding and the secondary coil 220 is a high-voltage winding.

The primary coil 210 according to the present invention is formed of a flat copper wire having a predetermined thickness and extending to a predetermined length.

That is, the primary coil 210 has a rectangular cross-sectional structure in which the coil is not circular in cross section. When viewed from the cross-sectional direction, the length of the upper and lower surfaces 210a is longer than the length of both ends 210b .

Specifically, the primary coil 210 is made of a square copper wire having a rectangular shape, and the secondary coil 200 is made of a circular coil.

Particularly, the primary coil 210 according to the present invention is wound around the winding bobbin 300 in a direction perpendicular to the winding bobbin 300 so that the upper and lower surfaces 210a of the primary coil 210 are centered in the longitudinal direction, do.

This is because the upper and lower surfaces 210a are not wound in the direction (vertical direction) facing the iron core part 100 about the longitudinal direction of the rectangular copper wire as in the prior art but the rectangular copper wire is wound around the iron core part 100 The one end portion 210b of the thickness side of the square copper wire can be greatly reduced in the area of the winding in which the winding is made along the circumferential direction of the iron core portion 100 so that the iron core portion 100 ), It is possible to further improve the efficiency of the transformer compared to the transformer of the same standard.

Particularly, the primary coil 210 according to the present invention includes a plurality of annular coil groups 200a, which are limited to one turn and are continuously wound along the longitudinal direction of the winding bobbin 300.

That is, since the primary winding 210 has a simpler and simpler winding operation of the coil than the conventional configuration in which the winding is performed by the number of turns as in the conventional art, the time required for winding the primary winding 210 There is an effect that can be reduced.

The annular coil group 200a having such a configuration is fabricated in various sizes having different widths L1, L2 and L3 in accordance with the capacity, current, and voltage of the transformer (see FIG. 5).

On the other hand, between the respective rectangular copper lines constituting the annular coil group 200a, the interlayer insulating paper 230 is interposed therebetween since it is electrically insulated.

Here, the interlayer insulating paper 230 is formed in the same shape as the rectangular copper wire.

In addition, in the case of the primary coil 210 according to the present invention, winding is performed on the winding bobbin directly without constructing a separate conductor covering body, which is advantageous in cost reduction as well as heat radiation effect. .

In addition, a heat radiating groove 211 for enhancing a heat radiation effect may be additionally formed on the upper surface or the lower surface 210a about the longitudinal direction of the rectangular copper wire.

In this case, it is preferable that the heat dissipation groove 211 is formed to extend from one end to the vicinity of the other end of the rectangular copper wire, but it is not limited to this, but may be formed in various shapes and structures.

The winding bobbin 300 is interposed between the iron core part 100 and the winding part 200 so that the primary winding 210 and the secondary winding 220 can be sequentially wound. .

Since the winding bobbin 300 is a well-known technique, its detailed configuration and operation will not be described.

According to the present invention configured as described above, since one end of the thickness-wise plane of the rectangular copper wire is wound along the circumferential direction of the iron core portion so that the square copper wire can be positioned in a direction perpendicular to the iron core portion 100, The contact area can be greatly reduced as compared with the area of the iron core winding, and as a result, the winding load ratio with respect to the iron core portion can be greatly increased, and the efficiency of the transformer and the comparative transformer of the same standard can be further improved.

In addition, the increase of the dot rate of the rectangular copper wire has the effect of greatly improving the short-circuit mechanical power as the winding density is high.

In addition, since the primary coil 210 is limited to one turn, it is easy to perform the winding operation and is not only inexpensive, but also prevents the occurrence of winding defects such as stagger or twist due to an increase in the number of windings There is an effect that can be done.

In addition, since the primary coil 210 is wound without a separate conductor coating, it is advantageous in cost reduction as well as heat radiation effect.

100: iron core part 200: winding part
210: primary coil 220: secondary coil
200a: annular coil group 300: winding bobbin
230: Interlayer insulation paper

Claims (8)

And a winding bobbin interposed between the iron core part and the winding part, wherein the winding bobbin is made up of an iron core part, a primary coil and a secondary coil,
Wherein the primary coil is a rectangular copper wire having a predetermined thickness and extending to a predetermined length so that winding is performed in a direction perpendicular to the winding bobbin in the vertical direction about the longitudinal direction so as to increase the drop rate with respect to the iron core portion, Wherein the primary coil is composed of a plurality of groups of annular coils which are limited to one turn and are continuously wound along the longitudinal direction of the winding bobbin.
The method according to claim 1,
Wherein the annular coil group is fabricated in various sizes having different widths in the longitudinal direction according to the capacity, current, and voltage value of the transformer.
The method according to claim 1,
Characterized in that an interlayer insulating paper is interposed between each square copper wire forming the annular coil group and the interlayer insulating paper is formed in the same shape as the square copper wire.
4. The method according to any one of claims 1 to 3,
Wherein a heat dissipating groove is formed on an upper surface or a lower surface of the rectangular copper wire in the longitudinal direction to increase the heat dissipation effect.
5. The method of claim 4,
Wherein the heat dissipation groove is elongated from one end to the vicinity of the other end of the rectangular copper wire.
4. The method according to any one of claims 1 to 3,
Wherein the length of the upper and lower surfaces is longer than the length of both end portions of the thickness side when viewed from the cross-sectional direction of the rectangular copper wire.
4. The method according to any one of claims 1 to 3,
Wherein the iron core portion is formed by stacking infinite iron core members having the same thickness.
8. The method of claim 7,
Wherein a width of at least some sections of the iron core members gradually decreases with increasing distance from the central part when viewed from a transverse section of the iron core members.

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