KR200474299Y1 - Mold transformer - Google Patents

Abstract

The present invention relates to a mold transformer for lowering the temperature of a low-voltage winding by using a cooling duct, wherein the mold transformer of the present invention includes at least one vertical direction provided between upper and lower horizontal bars, A core comprising a leg of the body; A low-voltage coil surrounding the legs; A high-voltage coil surrounding the outer periphery of the low-voltage coil; And a cooling duct mounted between the horizontal bar and the low-pressure coil for introducing outside air between the leg and the low-pressure coil.

Description

Mold transformer {MOLD TRANSFORMER}

The present invention relates to a mold transformer, and more particularly, to a mold transformer structure in which the temperature of a low-voltage winding is cooled down by using a cooling duct.

The mold transformer is a solid insulation type transformer that encloses the windings with epoxy resin. It contains an inorganic filler such as silica in epoxy resin or basic material such as glass fiber to prevent environmental pollution, and has fire resistance and self-extinguishing And it is widely used in subway, underground shopping mall, and so on. Especially, it does not cause gas generation during curing, has less mechanical shrinkage and mechanical stability, and has excellent chemical resistance and water resistance heat resistance. Even if it is left for a long time, damage of transformer is small and winding is molded in high vacuum. Also have strong resistance. Therefore, it is suitable for use in a part where stable voltage supply is required, for example, in a public building, a subway, a hospital, or the like.

1 is a front view of a conventional mold transformer. As shown in Fig. 1, there is provided a core including at least one vertical leg 1b provided between upper and lower horizontal bars (bar 1a, 1c) in the horizontal direction constituting a magnetic circuit . That is, the core has a ladder shape as a whole, and has a plurality of vertical legs 1b between the upper horizontal bar 1a and the lower horizontal bar 1c. The legs are wound around a low-voltage coil and a high-voltage coil to form an electric circuit. And a base 5 for supporting the upper frame 3, the lower frame 4, and the lower frame on the back side thereof is provided with a structure for fixedly supporting the core and the winding portion.

On the other hand, a terminal of the mold transformer is provided with a primary terminal 7 provided in the winding section and a secondary terminal 6 provided in the upper frame. In addition, an interphase lead 9 for connecting the primary terminal 7 to the winding portion is provided, and the torsion ring portion 8 is provided on the surface of the winding portion.

Figures 2 and 3 illustrate the coupling of the core with the winding. As shown in Fig. 2, the low-voltage coil 2a and the high-voltage coil 2b are respectively wound on the concentric axis in succession to the legs 1b extending vertically in the upper horizontal bar 1a of the core. 3 is a cross-sectional view of point A in the winding section of Fig.

Generally, the core of the temperature rise of the transformer is the core. The low-voltage coil adjacent to the core is over-heated during operation due to convection, radiation and self-winding temperatures with the core. Such a mold transformer generally performs heat exchange with the surrounding by natural convection and cools it.

As shown in Fig. 3, the gap between the leg 1b of the core and the low-voltage coil is too narrow. Therefore, when cooling is performed by natural convection, it is not easy for outside air to enter between the core and the low-pressure coil. Accordingly, stagnation of the air flow occurs between the leg 1b of the core and the low-voltage coil, and the temperature of the entire transformer rises due to heat generation of the core, heat generation of the low-voltage coil, and heat generation of the high- As a result, the temperature of both the core, the low-voltage coil, and the high-voltage coil is further increased. In order to solve this problem, a fan may be installed to perform forced circulation. However, since the air can not smoothly enter between the core and the low-voltage coil, the efficiency of the fan is poor.

The present invention is intended to solve the above problems.

It is an object of the present invention to provide a mold transformer in which the cooling efficiency of a transformer is improved by guiding the air flow smoothly between the core and the low-voltage coil.

The present invention has the following structure in order to solve the above problems.

The mold transformer of the present invention includes a core including at least one vertical directional leg provided between upper and lower horizontal bars in a horizontal direction; A low-voltage coil surrounding the legs; A high-voltage coil surrounding the outer periphery of the low-voltage coil; And a cooling duct mounted between the horizontal bar and the low-pressure coil for introducing outside air between the leg and the low-pressure coil.

The cooling duct is characterized in that a pressure difference is generated between the both ends so that the cross-sectional area of the side end portion in contact with the low-pressure coil is larger than the cross-sectional area of the side end portion in contact with the horizontal bar.

Further, the cooling duct is mounted between the lower horizontal bar and the lower end of the low-pressure coil, and at least one of the cooling ducts is mounted on the legs of the core.

Further, the cooling duct is made of an insulator.

The present invention has the following effects with the above-described configuration.

The mold transformer of the present invention uses an insulator to mount a cooling duct on the bottom of the core so that the cross-sectional area of the upper portion is larger than the cross-sectional area of the lower portion, thereby guiding the flow of air smoothly between the core and the low- .

1 is a front view of a conventional mold transformer;
Figure 2 is a plan view of the mold transformer of Figure 1;
3 is a cross-sectional view of part A of the mold transformer of Fig.
4 is a front view of the mold transformer of the present invention.
5 is a schematic view of a cooling duct used in a mold transformer of the present invention;

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, a detailed description thereof will be omitted in the description of the portions known in the general construction.

Fig. 4 shows a front view of a mold transformer of the present invention, and Fig. 5 shows a schematic view of a cooling duct used in a mold transformer of the present invention.

4, the mold transformer according to the present invention includes a core including at least one vertical directional leg 10b provided between upper and lower horizontal bars (bar, 10a, 10c) in the horizontal direction, Pressure coil 20b surrounding the outer periphery of the low-pressure coil, and a cooling duct 20b mounted between the horizontal bar and the low-pressure coil for introducing outside air between the legs and the low- (100).

The core is formed by laminating a silicon steel sheet and includes at least one vertical directional leg 10b provided between a horizontal upper bar 10a and a lower horizontal bar 10c constituting a magnetic circuit . That is, the core has a ladder shape as a whole.

The low-voltage coil 20a and the high-voltage coil 20b are respectively wound on the concentric axis in succession to the legs 10b extending vertically in the upper horizontal bar 10a of the core. These low-voltage coils and high-voltage coils are insulated by being wrapped with epoxy resin. That is, they are each molded with an epoxy resin.

As shown in FIG. 4, the upper frame 30, the lower frame 40, and a base 50 for supporting the lower frame 40 and the lower frame are provided with a structure for fixing the core, the low-voltage coil, and the high-voltage coil.

On the other hand, a terminal of the mold transformer is provided with a primary terminal 70 provided on the outer surface of the high-voltage coil and a secondary terminal (not shown) provided on the upper frame. In addition, an interphase lead for connecting the primary terminal 70 to the winding portion is provided, and the torsion ring portion 80 is provided on the surface of the winding portion. The tapped ring portion 80 is a device for setting the primary winding to a required load voltage by adjusting the taps when the load voltage of the secondary winding is high or low, and switches the power after the power supply is turned off.

The cooling duct 100 is composed of an insulator and is mounted between the lower horizontal bar 10c and the lower end of the low pressure coil 20a as shown in Figure 4 and is mounted on at least one of the legs 10b of the core . That is, the cooling duct 100 is mounted on the lower side of each leg 10b in Fig. 4, and the upper side of the cooling duct is in contact with the lower end of the low-pressure coil.

5, the cooling duct 100 is configured such that the cross-sectional area 121 of the side end portion 120 in contact with the low-voltage coil is larger than the cross-sectional area 111 of the side end portion 110 in contact with the horizontal bar. Whereby a pressure difference is generated between the both end portions so that the outside air is guided by the pressure difference between the leg and the low-pressure coil. That is, outside air is induced between the inner side surface of the low-voltage coil surrounding the legs and the legs to rise. Thereby, the outside air has a flow rising from the lower portion of the leg to the upper portion, and absorbs heat to cool the core.

On the other hand, more preferably, a fan may be installed to induce a stronger flow.

The mold transformer of the present invention uses an insulator to mount a cooling duct on the bottom of the core so that the cross-sectional area of the upper portion is larger than the cross-sectional area of the lower portion, thereby guiding the flow of air smoothly between the core and the low- .

While the preferred embodiments of the present invention have been described with reference to the accompanying drawings, it should be understood that the scope of the present invention should not be construed as being limited to those embodiments and / or drawings, . It should be clearly understood that improvements, changes, and modifications obvious to those skilled in the art are included within the scope of the present invention as set forth in the appended claims.

10: core (10a: upper horizontal bar, 10b: leg, 10c: lower horizontal bar)
20a: Low-voltage coil 20b: High-voltage coil
30: upper frame 40: lower frame
50: Base 70: Primary terminal
80: tapped portion 100: cooling duct
110: sectional area of the lower side end portion 111: 110 of the cooling duct
120: sectional area of the upper side end portion 121: 120 of the cooling duct

Claims (4)

A core including at least one vertical leg provided between upper and lower horizontal bars in a horizontal direction;
A low-voltage coil surrounding the legs;
A high-voltage coil surrounding the outer periphery of the low-voltage coil; And
And a cooling duct mounted between the lower horizontal bar and the lower end of the low-pressure coil for introducing outside air between the leg and the low-pressure coil,
Wherein a cross sectional area of a side end portion of the cooling duct contacting the low-voltage coil is larger than a cross-sectional area of a side end portion contacting the horizontal bar, so that a pressure difference is generated between the both end portions. delete The method according to claim 1,
Wherein the cooling duct is mounted on at least one leg of the core. The method according to claim 1 or 3,
Wherein the cooling duct is an insulator.

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