KR100787043B1 - Apparatus for capture particle of drill with baffle - Google Patents

Abstract

A power transformer for a portable welding apparatus is provided to maximize an air contact area by forming a wrinkle shape on a ferrite core as a single body, and forming an air passing hole. A power transformer for a portable welding apparatus includes a plurality of ferrite cores(20,21), membrane cooling plates(30,31), thin film dielectric insulating bodies(40 to 46), plane windings(50 to 53), and a pair of insulating bobbins(60,61). The ferrite core has an E-shape cross section to be coupled with the bottom and the top of a body(10). The membrane cooling plate is contacted to the inner surface of the ferrite core. The thin film dielectric insulating body is contacted to the membrane cooling plate, and has the shape of a corrugated cardboard. The plane winding is laminated between the thin film dielectric insulating bodies. The pair of insulating bobbins are coupled to receive the thin film dielectric insulating bodies and the plane winding, and are inserted to center parts(20a,21a) of the ferrite cores.

Description

Power transformer for portable welding device {APPARATUS FOR CAPTURE PARTICLE OF DRILL WITH BAFFLE}

1 is a perspective view for explaining a transformer of a portable welding device in the prior art,

2 is a perspective view of a power transformer for a portable welding device of the present invention;

Figure 3 is an exploded perspective view of the power transformer for portable welding device shown in Figure 2,

Figure 4 is a side view showing a part of the coupling relationship of the power transformer for portable welding device shown in FIG.

5 and 6 are perspective views for explaining an application example of the ferrite core shown in FIG.

           <Description of the symbols for the main parts of the drawings>

10: body 20, 21, 20c, 20d: ferrite core

30, 31: membrane cooling plate 40 ~ 46: thin film dielectric insulator

50 to 53: Flat winding 60, 61: Insulated bobbin

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to power transformers for portable welding devices, and more particularly, to planar power transformers, which are thin, low profile and excellent in cooling performance.

In general, low profile products are designed to be thin enough for slim systems, but as the thickness becomes thinner, the heat generation characteristics are relatively deteriorated.

Conventional ground-mounted inverter welding machine used for electric welding according to the prior art or a small welder with a shoulder strap uses a transformer with a high core and a relatively large volume and weight in the high voltage, high current supply environment. Such large layouts present many challenges in developing small or portable products that can be handheld and used.

Nevertheless, the present applicant connects the torch body case 3 to the back of the electrode holder 1 for easy welding at home or at the factory as shown in FIG. 1, and the electrode holder for holding the electrode 4. (1) and a hand held welding device having a holder lever, a handle 6 having a trigger 6, formed on the case 3, and a blower provided on the rear surface of the case 3.

However, the transformer 7 used in the portable welding apparatus of the prior art is a high frequency transformer using a simple ferrite core, which is simply reduced in size and weight, and is very disadvantageous in terms of heat generation, and thus the inverter circuit during operation inside the portable welding apparatus. It is often disadvantageous to cause overheating, causing an operation stop or circuit failure, or a welding operation cannot be performed several times.

In addition, the transformer 7 used in the prior art portable welding device is not a thin, low-profile product, which occupies a relatively large installation area, which makes it difficult to develop a battery-operated fully portable product. It is becoming.

Accordingly, an object of the present invention for solving the above-mentioned problems is to make the internal cooling space of the portable welding device thinly manufactured while preventing overheating by maximizing the natural cooling area by the air-cooled cooling structure to increase the forced cooling efficiency of the blower. The present invention aims to provide a power transformer for a portable welding device which can occupy less, and is more durable.

An object of the present invention as described above is a power transformer for a portable welding device having a low-profile compact body, each ferrite core having an English E-shaped cross-sectional shape so as to be mutually matched at the top and bottom of the body Wow; A membrane cooling plate in contact with the inner surface of the ferrite core; A corrugated thin film dielectric insulator in contact with the membrane cooling plate; A plane winding stacked between the thin film dielectric insulators; A pair of insulating bobbins, which are formed to seat the thin film dielectric insulator and the planar winding, and which are fitted on the center of the ferrite core; A cross-sectional shape through which air can pass is achieved by a power transformer for a portable welding device, characterized in that a plurality of layers are formed in an insertion space of the ferrite core.

In the description of the present invention, an air-cooled cooling structure is realized by a corrugated membrane cooling plate, a corrugated ceramic thin film dielectric insulator, and an insulation bobbin having a plurality of air through holes formed in a wall, or integrated into the ferrite core itself. It is preferably implemented by forming a corrugation or air passage.

Hereinafter, exemplary embodiments of the present invention will be described with reference to FIGS. 2 to 7.

First, Figure 2 is a perspective view of the power transformer for portable welding device of the present invention, Figure 3 is an exploded perspective view of the power transformer for portable welding device shown in FIG. In addition, Figure 4 is a side view showing a part of the coupling relationship of the power transformer for portable welding device shown in Figure 3, Figures 5 and 6 are perspective views for explaining the application example of the ferrite core shown in FIG.

As shown in FIG. 2, the power transformer for portable welding apparatus according to the present invention has a body 10 having an air-cooled cooling structure maximizing a natural cooling area so as to increase forced cooling efficiency by using external air supplied from a blower. Has

The body 10 of the present invention externally satisfies a low-profile to prevent overheating and occupy a small amount of internal installation space, so that the high temperature is generated in the portable welding device 9 near the inverter. Even if it is used for the above, malfunctions such as stopping operation due to heat generation are hardly caused.

As shown in FIG. 3, first and second ferrite cores 20 and 21 are arranged to be mutually formed at an upper portion and a lower portion of the body 10, and each has an E-shaped cross-sectional shape.

In the body 10, a plurality of membrane cooling plates 30 and 31 are stacked on inner surfaces of each of the first and second ferrite cores 20 and 21.

Meanwhile, the body 10 includes a plurality of first to seventh thin film dielectric insulators 40, 41, and 42 inserted up and down as if surrounding the centers 20a and 21a of the first and second ferrite cores 20 and 21. (43, 44, 45, 46) (thin dielectric insulator).

In addition, the body 10 has a plurality of first to fourth planar windings 50, 51, 52, and 53.

In addition, the body 10 is formed or mated to seat the thin film dielectric insulators 40 to 46 and the planar windings 50 to 53, so that the body 10 is positioned on the center portion 20a, of the first and second ferrite cores 20 and 21. It has a pair of first and second insulating bobbins 60 and 61 so as to fit in 21a).

The membrane cooling plates 30 and 31 have a cross-sectional shape through which air can pass, such as a wave shape, a wrinkle shape, a corrugation shape, and the like, and have a relatively large natural cooling area compared to a general plane.

The membrane cooling plates 30 and 31 are disposed in the insertion spaces 22, 23, 24 and 25 located at both sides of the first and second ferrite cores 20 and 21 on the centers 20a and 21a. The membrane cooling plates 30 and 31 are disposed between the inner surface of the first ferrite core 20 and the first thin film dielectric insulator 40, and the inner surface of the second ferrite core 21 and the seventh thin film dielectric insulator 46. It serves as a cooling means among the.

The first to seventh thin film dielectric insulators 40 to 46 also have a corrugated cardboard shape in which voids are repeatedly formed so as to secure a natural cooling area.

The first to seventh thin film dielectric insulators 40 to 46 are formed of a ceramic material, have high dielectric constant and insulation effect, maintain a thin film in shape, and have excellent cooling efficiency through repeated pores.

In addition, the plurality of first to fourth planar windings 50, 51, 52, and 53 are formed by winding a plurality of strands of coil wires in a rectangular shape inside the molded shell. The first to fourth planar windings 50, 51, 52, 53 have an input terminal or an output terminal.

The first planar winding 50 is laminated between the first thin film dielectric insulator 40 and the second thin film dielectric insulator 41, and the second planar winding 51 is formed of the first insulating bobbin 60 and the fourth thin film. The third planar winding 52 is laminated between the dielectric insulator 43, and the third planar winding 52 is laminated between the fourth thin film dielectric insulator 43 and the second insulating bobbin 61. The thin film dielectric insulator 45 and the seventh thin film dielectric insulator 46 are laminated.

The first and second insulating bobbins 60 and 61 are formed on the upper surfaces of the first and second insulating bobbins 60 and 61 so that the thin film dielectric insulators 40 to 46 and the flat windings 50 to 53 are stacked and placed therein. Mounting grooves are formed on the lower surface, respectively, and a plurality of protrusions and protrusion insertion grooves for interlocking the first and second insulating bobbins 60 and 61 are formed, and the first and second ferrite cores 20 and 21 are formed. Cores 63 and 64 are formed at the center of one side and the other side for the occlusion.

In particular, the first and second insulation bobbins 60 and 61 may include a plurality of air through holes 62 to allow air to flow into the inner spaces of the stacked thin film dielectric insulators 40 to 46. It is preferable to form in the walls of the insulation bobbins 60 and 61.

The body 10 of the present invention has a very good heat generation characteristics, and despite the thermal stress applied when used when exposed to high heat, such as a portable welding device, it can maintain excellent durability and reliable in the portable welding device It allows you to secure motion.

As shown in FIG. 4, the stacking relationship will be described in more detail based on the first ferrite core 20, and the stacking relationship is equally applied to the second ferrite core.

After each of the membrane cooling plates 30 is inserted into the insertion spaces 22 and 23 positioned on both sides of the center ferrite 20a of the first ferrite core 20, the pleats and pores of the membrane cooling plates 30 are increased. The first thin film dielectric insulator 40 is inserted to be arranged in a lateral direction to form a soft honeycomb shape. The first planar winding 50 is stacked below the first thin film dielectric insulator 40, and the second thin film dielectric insulator 41 and the third thin film dielectric insulator 42 are sequentially stacked thereunder.

When stacked in this way, since the cross-sectional shape through which air can pass is formed in a plurality of layers in the insertion spaces 22 and 23 of the first ferrite core 20, the outside supplied from a blower for portable welding apparatus (not shown) Air can be used to increase forced cooling efficiency.

In particular, the membrane cooling plate 30 is inserted in the place where it is in contact with the first ferrite core 20, it is possible to maximize the heat generation performance.

As shown in FIG. 5, in order to maximize heat generation performance, each of the pair of ferrite cores 20c may be integrally formed with the corrugated portion 26 on the inner surface of the insertion space thereof.

6, the pair of different ferrite cores 20d are preferably formed to maximize the air contact area by forming a plurality of air passage holes 27 in their core bodies.

Since the air passage hole 27 can be formed in any direction such as the width direction, the thickness direction, the longitudinal direction, and the like of the parate core 20d, the number or direction of the holes is not limited in the present invention.

The power transformer for portable welding apparatus of the present invention constructed as described above has an air cooling type cooling structure made of a corrugated membrane cooling plate, a corrugated ceramic thin film dielectric insulator, and an insulation bobbin having a plurality of air through holes formed in a wall. By providing a, it is possible to increase the forced cooling efficiency by maximizing the natural cooling area, there is an advantage to prevent overheating.

In addition, the power transformer for portable contacting apparatus of the present invention has the advantage of maximizing the air contact area by forming a pleated shape integrally with the ferrite core, or by forming an air passage hole.

In addition, the power transformer for portable welding device is applied to a portable welding device having a narrow internal installation space, and despite being manufactured thinly, the heat generating property is very good, so it can maintain excellent durability against thermal stress and reliability in the portable welding device. There is an advantage to secure the operation.

Claims (5)

In a power transformer for portable welding apparatus having a low-profile compact body (10), A plurality of ferrite cores 20, 21, 20c, and 20d each having an English E-shaped cross-sectional shape so as to be mutually joined at the upper and lower portions of the body 10; Membrane cooling plates (30, 31) in contact with inner surfaces of the ferrite cores (20, 21); Corrugated thin film dielectric insulators 40 to 46 in contact with the membrane cooling plates 30 and 31; Plane windings 50 to 53 stacked between the thin film dielectric insulators 40 to 46; A pair of insulating bobbins 60 are formed to seat the thin film dielectric insulators 40 to 46 and the flat windings 50 to 53, and are fitted to the center portions 20a and 21a of the ferrite cores 20 and 21. , 61); A power transformer for a portable welding device, characterized in that a cross section through which air can pass is formed in a plurality of layers in the insertion spaces (22, 23, 24, 25) of the ferrite cores (20, 21). The method of claim 1, The membrane cooling plate (30, 31) is a power transformer for portable welding device, characterized in that it has a cross-sectional shape through which air can pass, such as wavy, corrugated, corrugated shape. The method of claim 1, The insulating bobbins 60 and 61 have a plurality of air through-holes 62 so as to allow air to flow into the inner spaces of the thin film dielectric insulators 40 to 46. A power transformer for a portable welding device, which is formed on a wall. The method of claim 1, The ferrite core (20c) is a power transformer for a portable welding device, characterized in that the pleated portion 26 is formed integrally on the inner surface of the insertion space. The method of claim 1, The ferrite core (20d) is a power transformer for a portable welding device, characterized in that formed in the core body a plurality of air passage holes (27).

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