KR101889337B1 - Molded Transformer - Google Patents

Abstract

The present invention provides a mold transformer which comprises: a plurality of base frames arranged in parallel on an installation surface; a pair of lower frames arranged in parallel to interconnect upper surfaces of the base frames; at least one winding unit provided on the lower frame; a pair of upper frames arranged to face the lower frame in an upper part of the winding unit; a connection frame for connecting each end unit on both sides of the base frame; and a reinforcement frame for connecting an end unit of the connection frame and the upper frame.

Description

[0001] Molded Transformer [

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a mold transformer, and more particularly, to a mold transformer capable of preventing a secondary accident by stably earthquake-proof, anti-vibration or seismic isolation against an external force such as an earthquake.

Generally, a transformer is a device that changes the value of an AC voltage or current by using electromagnetic induction phenomenon. It is also called a transformer and is usually used to convert a voltage to a required value.

The basic structure is divided into a primary winding and a secondary winding by winding a coil on both sides of the iron core. The iron core is used as a path of magnetic flux. When an AC power source is connected to the primary winding, current flows, and an alternating magnetic flux ). Since this magnetic flux is linked to the secondary winding and alternately changes in accordance with the frequency of the alternating current, a voltage is generated in the secondary winding, and the voltage can be controlled according to the primary and secondary coil .

Here, a transformer in which a winding portion of a coil wound around an iron core is molded by epoxy resin is referred to as a dry-type transformer. The dry-type transformer uses flame-retardant epoxy instead of insulating oil, Since it is simple and light in structure, it is installed in various fields such as building, apartment, subway, ship and it is coated with epoxy resin, so it can prevent corrosion from moisture and dust, .

The dry-type mold transformer includes a coil assembly molded by an epoxy resin in a state where a high-voltage coil and a low-voltage coil are separated from each other and having a predetermined space inside, a plurality of stacked silicon pieces stacked in such a manner that they are exposed upwardly and downwardly through the respective coil assemblies A steel plate, and an upper frame and a lower frame which press the silicon steel plates exposed upward and downward, respectively.

Further, a spacer is provided between the upper and lower frames and the coil assembly to block the noise and vibration of the structure while maintaining an insulation distance, and the spacer serves to fix the positions of the upper and lower frames supporting the silicon steel sheet.

Further, a support base for supporting the entire dry-type mold transformer is provided on the bottom surface of the lower frame by supporting the lower frame.

The dry-type transformer is provided with a primary side terminal to which a primary voltage is applied and a secondary side terminal to which a secondary voltage is applied. The primary side terminals are connected by an inter-phase lead for connection, And a tap switching terminal for changing the tap voltage is provided.

However, since the above-mentioned dry-type mold transformer is structured such that the upper and lower frames, which respectively support the upper and lower portions of the silicon steel sheet, are not elastically supported, when the vertical vibration and the horizontal vibration are generated by earthquake- Which has a fatal problem.

In this case, since the upper spacer supporting the upper frame is fixed to the upper end of the coil assembly only by the tightening bolts that are screwed to the upper frame, the vibration is generated and released from the coil assembly while flowing together with the upper frame.

In addition, since a separate structure for elastically supporting the overall load of the dry-type mold transformer is not provided, when the vertical and lateral vibrations are generated by an external force, the coupling relationship between the respective structures is changed and functions are lost, There is concern that there is.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and it is an object of the present invention to provide a base frame, A pair of lower frames arranged side by side to connect the upper surfaces of the base frames to each other; At least one winding part provided on the lower frame; A pair of upper frames disposed on the upper portion of the winding portion so as to face the lower frame; And a reinforcement frame connecting the upper frame and the end portions of the connection frame, wherein the connection frame connects both ends of the base frame to each other.

According to an aspect of the present invention, there is provided a base frame comprising: a base frame arranged in parallel on a mounting surface; A pair of lower frames arranged side by side to connect the upper surfaces of the base frames to each other; At least one winding part provided on the lower frame; A pair of upper frames disposed on the upper portion of the winding portion so as to face the lower frame; And a reinforcing frame connecting the upper frame and the end portions of the connection frame, wherein the connection frame connects both ends of the base frame.

The mold transformer may further include an extension frame interposed between the upper frame and the reinforcing frame.

The extended frame may connect a pair of the upper frame and a pair of the reinforcing frames at the same time.

The extended frame may be coupled to one side of an upper surface or a lower surface of the upper frame, and may be coupled to a side surface of the reinforcing frame.

The extension frame includes a bottom surface coupled to an upper surface or a lower surface of the upper frame, a first side plate bent in a vertical direction from the bottom surface and coupled to the reinforcing frame on the back side, And a second side plate coupled to the end portion.

Wherein the reinforcing frame includes a first coupling plate having one end coupled to the first side plate and extending in the coupling frame direction, and a second coupling unit having a second end integrally bent from the first coupling plate, Plate.

Wherein the connection frame includes a first connection plate fixed on the base frame and a second connection plate integrally bent from the first connection plate and coupled to the second connection plate at both ends, The plate and the second connecting plate may be bent at least at an angle of at least a right angle.

The mold transformer may further include an auxiliary frame coupled to connect the lower ends of the first connecting plate and the lower frame to each other.

The auxiliary frame may have a longer length than the extended frame.

The reinforcing frame may connect the connection frame from the upper frame in a vertical direction or an oblique direction.

And each of the winding portions and the base frame may be arranged to face each other with respect to the lower frame.

According to the mold transformer of the present invention,

First, a spacer having an improved shape between the winding part and the upper frame and between the winding part and the lower frame is provided, so that transmission of vibration can be reduced and firmly supported,

Secondly, the shape of the elongate frame, the reinforcing frame, and the connecting frame can be improved,

Third, the assembled state of the upper and lower frames and the winding part can be more firmly supported through the elongate frame, the reinforcing frame, and the connection frame,

Fourth, the joining structure of the elongate frame, the reinforcing frame, the connecting frame, and the auxiliary frame is improved, and the position of the base frame is improved so that the stiffness can be increased while supporting the mold transformer more stably.

1 is a front perspective view showing a mold transformer according to an embodiment of the present invention.
2 is a rear perspective view showing a rear surface of the mold transformer shown in Fig.
3 is a front view showing a front view of the mold transformer shown in Fig.
4 is a side view showing a side view of the mold transformer shown in Fig.
Fig. 5 is a rear view showing the rear surface of the mold transformer shown in Fig. 2; Fig.
6 is a partial cross-sectional view showing a spacer of the mold transformer shown in Fig.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. It should be noted that the drawings denoted by the same reference numerals in the drawings denote the same reference numerals whenever possible, in other drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. And certain features shown in the drawings are to be enlarged or reduced or simplified for ease of explanation, and the drawings and their components are not necessarily drawn to scale. However, those skilled in the art will readily understand these details.

As is well known, a high voltage transformer for electric power is constituted in a power system and receives an electric voltage from a power plant and plays an important role of transmitting electric power to a customer through a step-up and a depressurization. In particular, the transformer must be rigidly mounted and fixed so that it is not shaken by external factors for stable operation, and this fixed condition must be maintained. For example, since the number of recent earthquakes has been increasing, interest in designing and structure for earthquake (hereinafter referred to as "earthquake-proof structure") is increasing. A mold transformer is a form of a dry type transformer in which a winding portion is cured by resin (for example, epoxy or the like) to insulate the specific voltage to a voltage desired by a user.

Fig. 1 is a front perspective view showing a mold transformer according to an embodiment of the present invention, Fig. 2 is a rear perspective view showing a rear surface of the mold transformer shown in Fig. 1, Fig. 3 is a front view of the mold transformer shown in Fig. Fig. 4 is a side view showing a side surface of the mold transformer shown in Fig. 1, and Fig. 5 is a rear view showing a rear surface of the mold transformer shown in Fig.

1 to 5, a mold transformer 100 according to an embodiment of the present invention includes a base frame 110, a lower frame 120, a winding part 130, an upper frame 140, A reinforcing frame 160, an elongate frame 170, an auxiliary frame 180, and a spacer 190. The connecting frame 150, the reinforcing frame 160,

A plurality of the base frames 110 are provided side by side on the mounting surface to provide a function of supporting the mold transformer 100. More preferably, the base frame 110 is provided corresponding to the number of the winding portions 130.

The lower frames 120 are vertically arranged at the upper part of the base frame 110 and are arranged so as to be spaced apart from each other.

The winding part 130 is fixed on the lower frame 120 and a lower spacer 190 'is interposed between the winding part 130 and the lower frame 120.

An upper frame 140 is disposed in parallel with the lower frame 120 on the upper portion of the winding portion 130 to firmly fix upper and lower portions of the winding portion 130, respectively.

Of course, the upper spacer 190 is also interposed between the upper part of the winding part 130 and the upper frame 140.

Here, the upper frame 140 and the lower frame 120 are made of a material having a high mechanical strength and a low deformation, which is a kind of beam and has one end section in a shape of 'C' or 'H' .

The winding unit 130 and the base frame 110 are arranged to face each other with respect to the lower frame 120. This can distribute the center of gravity uniformly, thereby reducing the transmission of the vibration due to the external force, and also preventing the concentration of cracks or damage in a part of the reduced vibration transmitted uniformly.

Between the upper frame 140 and the lower frame 120, the upper and lower portions of the winding part 130 are fixed via the spacers 190 and 190 '. Therefore, when an external force is generated, it is feared that the winding part 130 may be broken due to separation or deformation of the spacers 190 and 190 '. Therefore, the extension frame 150 A reinforcing frame 160, and a connection frame 170 are provided.

First, the extension frame 150 is coupled to the upper frame 140 where the pairs are arranged side by side. At this time, the extended frame 150 includes a bottom surface 151 coupled to an upper surface or a lower surface of the upper frame 140, a first side plate 151 bent in a vertical direction from the bottom surface 151 and coupled to the back surface of the reinforcing frame 160, And a second side plate 153 coupled to both ends of the bottom surface 151 and the first side plate 152. As shown in Fig. The first side plate 152 connects the pair of reinforcing frames 160 and 160 'and the second side plate 153 connects the pair of the upper frames 140, The bottom plate 151 and the first side plate 152 are connected to reinforce the rigidity of the elongated frame 150. Since the extension frame 150 configured as described above extends in the upper direction of the upper frame 140, it can function to firmly support the upper frame 140 in the vertical direction. In other words, assuming that the upper frame 140, the winding part 130 and the lower frame 120 are one unit U, the extended frame 150 fixes the upper part of the unit U to provide a strong supporting force .

The reinforcing frame 160 connects the extension frame 150 and the connection frame 170. The reinforcing frame 160 includes a first coupling plate 161 having one end coupled to the rear surface of the first side plate 152 and a second coupling plate 161 having one end bent integrally from the first coupling plate 161, And a second coupling plate 162 coupled thereto. Accordingly, the extension frame 150 and the connection frame 170 can be connected to each other to form a structure that firmly fixes the unit U so as to surround the outside of the unit U. At this time, the reinforcing frame 160 connects the connection frame 170 from the extension frame 150 in the vertical direction or diagonally.

The connection frame 170 includes a first connection plate 171 fixed on the base frame 110 and a second connection plate 171 integrally bent from the first connection plate 171 and joined to the second connection plate 162 at both ends thereof. 2 connecting plate 172. [ At this time, it is preferable that the first connection plate 171 and the second connection plate 172 are bent at an angle of at least a right angle. 4, when the extension frame 150 is shorter than the length of the base frame 110, the reinforcing frame 160 is inclined downwardly. At this time, the second connection plate 172 is connected to the first connection The reinforcing frame 160 can be coupled so as to be inclined in the oblique direction only when bent from the plate 171 at an obtuse angle. Although not shown in the drawings, the extending frame 150 may have a coupling structure with a length shorter than or equal to the length of the base frame 110.

Although not shown in the drawing, the pair of reinforcing frames 160 and 160 'may include reinforcing members (not shown) connecting the reinforcing frames 160 and 160'. The reinforcing member may connect one or a plurality of the reinforcing frames 160 and 160 'to increase the rigidity between the reinforcing frame 160 and another adjacent reinforcing frame 160'. At this time, the reinforcing member may be coupled horizontally or diagonally between the reinforcing frames 160 and 160 ', and may be biased to any one of the central portion and the upper and lower portions of the reinforcing frames 160 and 160' It may be arranged closely. When a plurality of reinforcement members are coupled, the position, number, or arrangement / engagement relationship of the reinforcement members can be variously arranged in a set pattern according to the reinforcement position. Therefore, the reinforcing member can be stiffened in the portion where the rigidity is relatively weak between the reinforcing frames 160 and 160 ', or has an effect of minimizing the transmission of external force.

And an auxiliary frame 180 coupled to the connection frame 170 and the lower frame 120 to connect the connection frame 170 and the lower frame 120 to each other.

The auxiliary frame 180 is arranged to face side by side with the elongate frame 150 and is coupled to the bottom to connect the ends of the pair of lower frames 120 at the ends of the pair of first connecting plates 171. 4, the extension frame 150, the pair of reinforcement frames 160 and the auxiliary frame 180 are coupled to each other so as to have a substantially trapezoidal shape at a side surface thereof.

Also, the extension frame 150, the reinforcement frame 160, the connection frame 170, the auxiliary frame 180, and the reinforcement member can be fastened through fasteners so as to be detachable from each other, It can be realized as an integral structure.

Also, an isolating pad (not shown) is provided between the base frame 110 and the lower frame 120. It may be provided not only between the base frame 110 and the lower frame 120 but also between the lower frame 120 and the winding part 130.

The seismic pad is composed of a plurality of lead pads stacked in a plate shape. Therefore, when an external force is applied to the base frame 110, the laminated lead pads are slipped with respect to each other, thereby providing an effect of segregating the lower frame 120.

The seismic pad may further include a plurality of lead pads stacked in a plate form and a rubber or synthetic resin pad alternately stacked between the lead pads.

Therefore, the anti-vibration pads prevent the external force in the horizontal direction while the lead pads are slipped with respect to each other. Since the rubber or synthetic resin pad has a predetermined elasticity, it induces the restoration of the lead pad and absorbs the impact in the vertical direction, There is an effect that can be minimized.

6 is a partial cross-sectional view showing a spacer of the mold transformer shown in Fig.

Referring to FIG. 6, the mold transformer 100 includes a spacer 190 disposed between the winding part 130 and the upper frame 140, or between the winding part 130 and the lower frame 120.

The spacer 190 has a primary coil portion supporting region 191 and a secondary coil portion supporting region 192 for independently supporting the primary coil portion 131 and the secondary coil portion 132 separated from each other And includes support pads 193 that are in contact with the coil portions for each support region.

The spacer 190 also includes a connecting portion 194 interposed between the primary coil portion 131 and the secondary coil portion 132 to connect the upper and lower spacers 190 of the coil portion 130 to each other .

The connection portion 194 is interposed between the primary coil portion supporting region 191 and the secondary coil portion supporting region 192 and extends in the direction of the connecting portion 194 of the opposite spacer 190 or the spacer 190. The connecting portions 194 may extend or come into contact with each other in the directions opposite to each other at the connecting portions 194 on both sides and may be connected to the connecting portions 194 on either side of the opposing connecting portions 194 on both sides facing each other. The connection portion 194 may be extended only in the direction of the connection portion 194.

The connecting portion 194 can be firmly fixed to the upper frame 140 and the lower frame 120 at the upper portion and the lower portion of the winding portion 130 and the primary coil portion 131 and the secondary coil portion 132 ) Can be stably maintained.

Here, the connection portion 194 extends from the spacer 190 disposed on the upper portion of the winding portion 130 to the spacer 190 'disposed on the lower side, or the spacer 190 disposed on the upper portion of the winding portion 130 And may be configured to extend in the same length at the spacer 190 'disposed at the lower portion and to be connected to each other at a central portion inside the winding portion 130.

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, And the like. Accordingly, such modifications are deemed to be within the scope of the present invention, and the scope of the present invention should be determined by the following claims.

100: Mold transformer
110: base frame
120: Lower frame
130:
140: upper frame
150: Extension frame
160, 160 ': reinforcing frame
170: connection frame
180: Auxiliary frame
190, 190 ': Spacer

Claims (11)

A plurality of base frames disposed side by side on an installation surface;
A pair of lower frames arranged side by side to connect the upper surfaces of the base frames to each other;
At least one winding part provided on the lower frame;
A pair of upper frames disposed on the upper portion of the winding portion so as to face the lower frame;
A connection frame for connecting both side ends of the base frame;
A reinforcing frame connecting the upper frame and the end of the connection frame,
And an extension frame interposed between the upper frame and the reinforcing frame,
The extension frame includes a bottom surface coupled to an upper surface or a lower surface of the upper frame, a first side plate bent in a vertical direction from the bottom surface and coupled to the reinforcing frame on the back side, And a second side plate coupled to the end,
Wherein the reinforcing frame comprises a first coupling plate having one end coupled to the first side plate and extending in the coupling frame direction and a second coupling plate having a second end integrally bent from the first coupling plate, / RTI >
Wherein the connecting frame includes a first connecting plate fixed on the base frame and a second connecting plate integrally bent from the first connecting plate and coupled to the second connecting plate at both ends, And the second connecting plate are bent at least at an angle of at least a right angle. delete The method according to claim 1,
The extension frame
And a pair of the upper frame and a pair of the reinforcing frames are connected at the same time. The method according to claim 1,
The extension frame
Wherein one side is coupled to an upper surface or a lower surface of the upper frame, and is coupled to a side surface of the reinforcing frame. delete delete delete The method according to claim 1,
Further comprising an auxiliary frame coupled to connect the lower ends of the first connecting plate and the lower frame to each other. The method of claim 8,
Wherein the auxiliary frame is longer than the elongate frame. The method of claim 9,
The reinforcing frame
And connecting the connection frame from the upper frame in a vertical direction or an oblique direction. The method according to claim 1,
And each of the winding portions and the base frame is disposed to face each other with respect to the lower frame.

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