KR101998213B1 - Earthquake-proof mold transformer - Google Patents

Abstract

The present invention relates to an earthquake-proof mold transformer, comprising: a base frame (10); a lower frame (20); three coils (30a-30c); an upper frame (40); a side frame (60); a first buffering unit (50) for absorbing and buffering impact from earthquake by elastic force and restoring force of a plurality of elastic members (56) through horizontal vibration of the coils (30a-30c) and buffering members (51a-51c) when vibration of earthquake is in a horizontal direction; first and second horizontal movement units (70a, 70b) arranged on lower parts of the buffering members (51a, 51c) arranged on both sides, having a complementary structure, and absorbing and buffering impact in a horizontal direction from earthquake; and a vertical impact absorbing unit (80) arranged on a lower part of the buffering member (51b) arranged on the center among the buffering members (51a-51c), and absorbing impact in a vertical direction induced by vibration of earthquake. Thus, according to the present invention, it is possible to prevent impact and separation of coils when earthquake occurs, thereby preventing damage and failure of an earthquake-proof mold transformer.

Description

Earthquake-proof mold transformer

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an anti-vibration mold transformer, and more particularly, to an anti-vibration mold transformer having a structure capable of efficiently coping with an earthquake or similar external vibration.

Generally, the transformer should be firmly installed and fixed in such a way that it will not be shaken by external factors. In recent years, there has been a growing interest in transformers having a structure against earthquakes (i.e., earthquake-resistant structures) due to an increase in frequency of occurrence of earthquakes.

The mold transformer is a form of a dry type transformer in which a winding portion is hardened by epoxy resin and is insulated, and a specific voltage is converted into a voltage desired by the user. In addition, the mold transformer can provide advantages such as stability, low loss, and low noise due to its structural characteristics, and can provide excellent crack resistance and excellent insulation performance with less risk of explosion and fire.

A mold transformer having an earthquake-proof function is disclosed in Korean Patent Registration No. 10-1843721 (Patent Document 1).

Patent Document 1 discloses an upper and a lower frame disposed at the upper and lower portions of a plurality of coil assemblies, respectively; And a vibration attenuator which is detachably coupled to a lower portion of the lower frame and attenuates vibrations transmitted to the plurality of coil assemblies when an earthquake occurs, wherein the vibration attenuator includes a frame supporting unit in which the lower frame is disposed and supported; A base unit disposed at a lower portion of the frame supporting unit and having a lower end supported by the mounting surface; And a frame supporting unit which is disposed between the frame supporting unit and the base unit and connects the frame supporting unit and the base unit to each other so as to interact with the frame supporting unit and the base unit, An assembly body having an upper end portion formed with a first groove portion in a circumferential direction and a second groove portion formed at a center of the upper end portion; A single center ball rotatably coupled to a central region of the lower end of the assembly body; A plurality of side balls rotatably coupled to a lower end of the assembly body along a circumferential direction of the center ball; And a resilient shoe having a main body inserted into the second groove and a rod extending to the main body, the elastic shoe corresponding to a vertical component of the earthquake.

Patent Document 1 has a problem in that it can not solve the vibration transmitted to the coil assembly when an earthquake occurs, although the vibration damping assembly and the sub-shock absorber assembly correspond to the vibration of the vertical earthquake.

In addition, in Patent Document 1, since the balls of different sizes arranged at the lower part of the body of the vibration damping assembly for vibration differ in size of the ball when horizontally moved inside the base body, the center point of the vibration damping assembly is shifted, (I.e., when the vibration damping assembly is disposed at an inclined position, the balance is shifted, and the elastic member and the shock absorber connected in this state are also deformed, so that the overall balance of the mold transformer is out of balance ).

1): Korean Patent Registration No. 10-1843721

An object of the present invention is to solve the above-mentioned problems, and an object of the present invention is to provide a vibration damping mold capable of preventing displacement and damage of a coil as the displacement generated in a mold transformer is rapidly reduced by using a complementary shock absorbing / To provide a transformer.

Another object of the present invention is to provide an anti-vibration mold transformer capable of improving seismic efficiency by applying a structure suitable for an earthquake-proof.

It is still another object of the present invention to provide a vibration damping apparatus capable of coping with vibrations in a vertical direction and a horizontal direction instantly generated by an earthquake using a base frame, And an earthquake-resistant mold transformer capable of stably coping by secondarily absorbing / mitigating the vibration of the earthquake by the stepwise movement of the coil and the buffer member and the organic interaction using the vertical shock-absorbing unit.

An earthquake-resistant mold transformer of the present invention comprises: a base frame; A lower frame disposed above the base frame; Three coils disposed on the upper portion of the lower frame; An upper frame disposed on the upper portion of the coil and arranged in a line with a gap from the lower frame; A side frame disposed between the lower frame and the upper frame to interconnect the lower frame and the upper frame and having a pair of first blocks connected to the inner side with elastic members; Three cushioning members surrounding the three coils, a plurality of connecting members disposed on both sides of the cushioning member, a plurality of elastic members elastically connecting the connecting member and the connecting member, And an adjusting screw which is disposed on the inner side of the cushioning member and adjusts the elasticity of the elastic member by moving to the left and right. When the vibration of the earthquake is in the horizontal direction, the vibration in the horizontal direction of the coil and the cushioning member, A first shock absorber for absorbing and cushioning an impact from an earthquake by a restoring force; A body in the form of a rectangular parallelepiped body having an open top and surrounding the cushioning member disposed at the center of the cushioning member, four support members arranged at four corners of the body, and a support member connected between the two support members arranged in the longitudinal direction 1 and a second guide shaft, first and second moving members slidably coupled to the outer periphery of each of the guide shafts so as to be slidable in left and right directions, and a vertical frame connected to the first and second moving members and the auxiliary frame, A second cushioning unit having first and second ball joints rotatably supported by the first and second moving members along the first and second guide shafts; A rack having a rack gear meshed with the pinion; a guide block disposed in a slot disposed on one side of the rack; and a guide block disposed on one side First and second horizontally moving units having complementary structures with each other and absorbing and absorbing a horizontal impact from an earthquake, and a lever connected to the pinion and having the other end connected to the guide block; An I-shaped frame disposed at a lower portion of a cushioning member disposed at the center of the cushioning member; an elastic member disposed on both sides of the I-shaped frame and spaced apart from each other; And a vertical impact absorbing unit having dog rollers and absorbing vertical impact due to vibration of the earthquake.

When the coil and the buffer member move in the horizontal direction in the left and right directions due to the vibration of the earthquake in the horizontal direction, the coil and the buffer member are returned to their original positions by the elastic force and the restoring force of the elastic member, A pair of moving members slidably coupled to a pair of guide shafts and a pair of hinging members which are slidably coupled to the pair of guide shafts when vibration in a direction perpendicular to the horizontal direction or deviated directions is applied, The ball joints of the first and second shock absorbers act in complementary relationship to each other to absorb and mitigate the forward and backward shocks of the coil and the shock absorbing member. When vibration of the earthquake occurs simultaneously in the vertical direction and the horizontal direction, The horizontal vibration of the earthquake in the vertical direction and the vertical vibration of the earthquake using the arranged vertical shock absorbing unit, the first and second horizontal movement units, and the first and second shock absorber units simultaneously It can be absorbed and alleviated.

In addition, the base frame may have a plurality of arch portions spaced apart from each other to reduce seismic resistance at the outer periphery, a space portion may be formed at the center of the base portion in the longitudinal direction, and a buffer material made of a rubber material may be filled in the base portion except for the space portion.

Wherein the base frame includes a plurality of fixed plates disposed at intervals, a shaft coupled to the fixed plate, and an earthquake-proof buffer portion formed of an elastic member inserted into the shaft.

The lower frame is formed with a hollow portion on the inner side, a fixing block is disposed on both sides of the hollow portion, the fixing block is connected to the second block through an elastic member, At least one stopper for regulating the movement of the two blocks may be disposed.

The moving member is connected to a ball joint disposed in a vertical frame connected to the auxiliary frame, the ball joint including a ball housing and a ball stud, The ball stud of the joint can also be configured to be moved.

The ball stud of the ball joint may include a shaft, a ball stud ball formed on one side of the shaft, a connecting member formed on the other side of the shaft, And an elastic member fitted to the shaft.

The first block of the side frame may be connected to the second block disposed inside the lower frame by a tapered bar.

The anti-vibration mold transformer of the present invention rapidly reduces the displacement generated in the mold transformer by using the complementary shock absorbing / mitigating structure in the event of an earthquake, thereby preventing the coil from being separated and damaged. There is an advantage to be able to do.

The vibration-proof mold transformer of the present invention is adapted to cope with vibrations in the vertical direction and the horizontal vibration momentarily generated at the time of an earthquake using the base frame, and also to prevent vibrations in the first and second buffer units, , It is advantageous to perform stable coping by absorbing / mitigating the vibration of the earthquake by the stepwise movement of the coil and the buffer member and the organic interaction by using the vertical shock absorbing unit.

In addition, the vibration-proof mold transformer of the present invention has an advantage that seismic performance can be further improved as compared with a conventional earthquake-resistant mold transformer by applying a moving member and a ball joint to a cushioning unit arranged at the center.

1 is a schematic perspective view showing an anti-vibration mold transformer according to the present invention,
Fig. 2 is a partial longitudinal sectional view of the anti-vibration mold transformer shown in Fig. 1,
3 is a front view showing a structure of a shock absorbing unit according to the present invention,
4 is a plan view showing a structure in which the first and second buffer units according to the present invention are applied to three coils,
5 is a perspective view showing a vertical shock absorbing unit according to the present invention.

Hereinafter, an embodiment of an anti-vibration mold transformer of the present invention will be described with reference to the accompanying drawings.

FIG. 1 is a schematic perspective view showing an anti-vibration mold transformer according to the present invention, and FIG. 2 is a longitudinal partial sectional view of the anti-vibration mold transformer shown in FIG.

Referring to FIGS. 1 and 2, a mold transformer 100 of the present invention basically includes a base frame 10, lower and upper frames 20 and 40, and three coils 30a to 30c.

In the case of a three-phase transformer, the mold transformer 100 may include three coils 30a to 30c arranged in a line in the longitudinal direction of the core 42 forming the magnetic circuit. The mold transformer 100 is not limited thereto, and the number of the coils 30a-30c may be one or two, although not shown.

For example, the coils 30a to 30c may have a configuration in which the outer periphery of the winding portion is surrounded by buffer members 51a to 51c molded by an epoxy resin. On the front surface and the upper surface, A primary side and a secondary side terminal to which a secondary voltage is applied, and an interphase lead and a tap switching terminal for connecting the primary side terminal.

The base frame 10 is disposed in a portion where three coils 30a to 30c are provided on the ground, and is arranged in a rectangular shape or a parallel straight line shape. The base frame 10 is fixed to the paper surface G by fastening means not shown.

The lower frame 20 is first disposed on the upper portion of the base frame 10 and the lower frame 20 and the upper frame 40 are disposed on the lower and upper portions of the three coils 30a to 30c, ) On both sides.

The coils 30a-30c are disposed on the upper portion of the lower frame 20. [ That is, it is disposed between the lower frame 20 and the upper frame 40, and three of them are arranged here.

Further, between the plurality of coils 30a-30c and the lower frame 20 and between the plurality of coils 30a-30c and the upper frame 40, while maintaining the insulation distance of the plurality of coils 30a-30c, And may further include a spacer 45 for blocking the noise and vibration of the upper and lower frames 20 and 40 and fixing the positions of the lower and upper frames 20 and 40.

The mold transformer 100 of the present invention is provided with the first buffer unit 50, the first and second horizontal movement units 70a and 70b, the vertical shock absorption unit 80 and the second buffer unit 50a ), And the like.

First, the base frame 10 is disposed at a lower portion of a portion where a plurality of coils 30a to 30c are provided on the ground G, and is arranged in a rectangular shape or a parallel straight line shape. The base frame 10 has a plurality of arch portions 14 spaced apart from each other to reduce seismic resistance. Here, when a seismic wave is vertically incident when an earthquake occurs, a plurality of arch portions 14 are arranged in an arch shape so that a plane of a rectangular structure such as a cube or a rectangular parallelepiped is not divided into normal stress and shear stress, It is designed to be prepared for an earthquake.

A space 17 is formed in the center of the base frame 10 in the longitudinal direction and a buffer material 12 made of a rubber material is filled in the space except the space 17.

The base frame 10 is provided with a pair of vibration damping portions 16a and 16b on the left and right sides. Each of the vibration damping portions 16a and 16b includes a plurality of fixed plates 11 arranged at intervals, a shaft 13 coupled to the fixed plate 11, and elastic members 15 ). The vibration damping portions 16a and 16b are configured to absorb the vibration in the upward and downward directions when an earthquake occurs by using the elastic member 15 inserted in the shaft 13. [

Thus, the base frame 10 is configured to absorb vibration in the left, right, and upward and downward directions when an earthquake occurs.

The lower frame 20 is disposed on the upper portion of the base frame 10. The lower frame 20 has a hollow portion 21 formed therein and a fixing block 22 is disposed on both sides of the hollow portion 21.

The fixing block 22 of the lower frame 20 is connected to the second block 24 via the elastic member 23 and the second block 24 of the hollow portion 21, At least one stopper 25 for restricting the movement of the second block 24 is disposed on the rear side (left and right side in FIG. 2). It is preferable that the second block 24 is made of a rubber material and that the second block 24 is constructed to be able to ride over the stopper 25 when the vibration of the earthquake is severe. Here, the stopper 25 may be formed to have a predetermined size, but may have different sizes depending on the magnitude of an earthquake. Here, the second block 24 is interconnected by the first blocks 62a and 62b disposed on the side frame 60, which will be described later, and the inclined bar 66.

The fixed block 22, the elastic member 23, the second block 24, the stopper 25 and the inclined bar 66 absorb the longitudinal vibration applied to the side frame 60 of the mold transformer 100 / Cushioning.

As shown in FIGS. 2 to 4, the first cushioning unit 50 includes three cylindrical cushioning members 51a-51c surrounding the three coils 30a-30c, A plurality of elastic members 56 for elastically connecting the connecting member 54 and the connecting member 54 and a plurality of connecting members 54 disposed on both sides of the connecting member 54, And an adjusting screw 58 which is disposed on the inside of the elastic member 56 and adjusts the elasticity of the elastic member 56 by moving left and right.

The second cushioning unit 50a includes a pair of movable members 96a and 96b having a complementary symmetrical structure and ball joints 110a and 110b.

The cushioning member 51b disposed at the center of the cushioning members 51a-51c further includes a body 52 in the form of a rectangular parallelepiped having an open top.

4, the body 52 includes four support members 92a-92d disposed at four corners, and two support members 92a, 92b, 92c, 92d disposed in the longitudinal direction. The first and second guide shafts 94a and 94b are disposed between the guide shafts 94a and 94b and the first and second moving members 96a and 94b are slidable in the left and right directions on the outer circumference of the guide shafts 94a and 94b, 96b.

The first and second moving members 96a and 96b may include first and second ball joints 110a and 110b installed on a vertical frame 95 connected to the auxiliary frame 90, . The first and second ball joints 110a and 110b each include a ball housing 115 and a ball stud 125. As a result, The ball stud 125 of the first and second ball joints 110a and 110b is also rotated by the first and second moving members 96a and 96b along the first and second guide shafts 94a and 94b, Lt; / RTI >

The ball housing 115 includes a main body 112 and a ball 114 connected to the main body 112. The ball stud 125 includes a shaft 122, a ball stud ball 124 formed on one side of the shaft 122, a connecting member 126 formed on the other side of the shaft 122, And an elastic member 128 which is fitted in the elastic member 122.

Since the connecting member 126 of the ball stud 125 is configured and connected in the form of a bendable hinge, when the first and second moving members 96a and 96b are moved, the first and second moving members 96a and 96b You can freely move left and right. That is, since the first and second ball joints 110a and 110b are connected to the body 52 to adjust the movement of the body 52 in the left and right directions, the vibration due to the earthquake is transmitted to the coils 30a to 30c, The vibrations in the left and right directions of the earthquake can be secondarily reduced when they are applied to the three cylindrical buffer members 51a-51c and the body 52 surrounding the cylindrical buffer members 51a-51c and the body 52, respectively.

The side frames 60 disposed on both sides of the mold transformer 100 are arranged in a longitudinal direction between the lower frame 20 and the upper frame 40 so that the lower frame 20 and the upper frame 40 And first blocks 62a and 62b connected to the elastic member 56 on the inner side. Here, although the side frame 60 has a rectangular configuration, the side frame 60 can be changed in various forms depending on the structure of the lower and upper frames 20 and 40. [ The first blocks 62a and 62b of the side frame 60 are connected to each other by a second block 24 disposed inside the lower frame 20 and a tilt bar 66. [

Referring to FIG. 2, the first and second horizontal movement units 70a and 70b are installed below the cushioning members 51a and 51c disposed on both sides, respectively. The first and second horizontal movement units 70a and 70b have complementary symmetrical structures, .

The first and second horizontally moving units 70a and 70b have a complementary symmetrical structure, and the construction of the first horizontally moving unit 70a will be described in detail with reference to FIG.

As shown in FIG. 3, the first horizontal moving unit 70a of the present invention includes a guide bar 55 installed at a lower portion of the buffer members 51a and 51c; A pinion (72) disposed on the guide bar (55); A rack (74) having a rack gear (73) engaged with said pinion (72); A guide block 76 disposed in a slot 75 formed at one side of the rack 74; And a lever 78 connected to the pinion 72 at one side and to the guide block 76 at the other side. In addition, the first horizontal moving unit 70a is disposed on both sides of the sub frame 90.

The pinion 72 is rotatably fitted in a shaft (not shown) disposed at the center of the guide bar 55 and the lever 78 fixed to one side of the pinion 72 is rotatably supported by a pinion 72, And the guide block 76 is moved to the left and right in the slot 75.

The pinion 72 remains meshed with the rack 74 when an earthquake is not generated and moves to the left and right along the rack 74 in a predetermined direction when an earthquake occurs. The guide block 76 connected to the lever 78 connected to the pinion 72 moves left and right in the slot 75 when the pinion 72 is moved left and right along the rack 74 in the event of an earthquake .

In this way, the first and second horizontal movement units 70a and 70b can further reduce left and right vibration of the earthquake when an earthquake occurs. The first and second horizontal movement units 70a and 70b are arranged in the directions opposite to each other under the cushioning members 51a and 51c disposed on both sides of the cushioning members 51a and 51b, 51c in the same direction.

Hereinafter, the vertical shock absorbing unit according to the present invention will be described with reference to FIGS. 3 and 5. FIG.

3 and 5, the vertical shock absorbing unit 80 includes an I-shaped frame 82 disposed below the cushioning members 51a and 51c disposed at the center of the cushioning members 51a to 51c, ; An elastic member 84 disposed on both sides of the I-shaped frame 82 at intervals, respectively; And a plurality of rollers 86 disposed below the I-shaped frame 82 at intervals. The plurality of rollers 86 may be a plurality of rubber bearings. The vertical shock absorbing unit 80 is disposed in the recessed channel 88 disposed at the center of the auxiliary frame 90. Here, the recessed channel 88 is formed in order to match the heights of the vertical shock absorbing unit 80 and the first and second horizontal movement units 70a and 70b.

Since the elastic members 84 are disposed on both sides of the I-shaped frame 82, it is configured to absorb vibration in the upward and downward directions. Here, the I-shaped frame 82 is arranged in an I-shape below the shock absorber unit 80, but may also be configured as a cross-shaped frame (not shown) according to the demand of the user.

Hereinafter, an operation of the vibration-proof mold transformer of the present invention will be described.

The vibration damping mold transformer 100 of the present invention accommodates and supports the three coils 30a to 30c in a state in which there is no horizontal movement of the cylindrical buffer members 51a to 51c when an earthquake is not generated, The horizontal moving units 70a and 70b and the vertical shock absorbing unit 80 are disposed in the lower part of the coils 30a to 30c (i.e., the first and second horizontal moving units 70a and 70b are the pinions 72, The vertical shock absorbing unit 80 does not move with the plurality of rollers 86 while it is engaged with the rack gear 73 and is not moved.

First, the first and second shock absorber units 50 and 50a, the first and second horizontal movement units 70a and 70b and the vertical shock absorber unit 80 of the vibration-proof mold transformer 100 of the present invention will be described The base frame 10 and the lower frame 20 of the earthquake-resistant mold transformer 100 of the present invention will be described.

Since the base frame 10 is provided with a plurality of arch portions 14 on the outer periphery of the conventional frame (not shown) and a plurality of earthquake-proof buffer portions 16 are arranged on the inner side of the base frame 10, The left, right, and up and down vibrations are absorbed.

The lower frame 20 disposed on the upper portion of the base frame 10 has a hollow portion 21 formed therein and the hollow portion 21 is provided with a fixing block 22 with an elastic member 23 interposed therebetween And the second block 24 is connected to the first blocks 62a and 62b disposed on the side frame 60. Therefore, when the second block 24 is connected to the second block 24, The left and right vibrations are absorbed. Since the stopper 25 is disposed on the front and rear sides of the second block 24, the vibration of the earthquake is absorbed step by step. When the magnitude of the earthquake is high, the second block 24 is connected to the first blocks 62a and 62b by the inclined bar 66, so that vibration of the earthquake is added in the elastic region of the elastic member 23 .

The first and second shock absorber units 50 and 50a, the first and second horizontal movement units 70a and 70b and the vertical shock absorber unit 80 of the vibration-proof mold transformer 100 of the present invention are operated As follows.

First buffering unit 50 includes cushioning members 51a-51c formed on the outer circumference of coils 30a-30c in a cylindrical shape corresponding to (corresponding to) the number of three coils 30a-30c And a body 52 of a rectangular parallelepiped shape is further provided on the outer periphery of the cushioning member 51b disposed at the center. The cushioning members 51a-51c are connected to each other by an elastic member 56. When vibration is transmitted in the horizontal direction at the time of an earthquake, vibration is not directly transmitted to the coils 30a-30c, So that the elastic members 56 connected to each other absorb the vibration.

That is, when an earthquake occurs and horizontal vibration is transmitted, the elastic members 56 connected to the connecting members 54 disposed outside the buffering members 51a-51c elastically receive the coils 30a-30c housed therein Thereby preventing the coils 30a-30c from coming off and preventing the coils 30a-30c from being damaged.

When vibration of the earthquake can not be alleviated only by the elastic members 56 of the first cushioning unit 50, the first cushioning members 51a and 51c disposed on both sides of the three cushioning members 51a-51c And the second shock absorber unit 80 and the second shock absorber unit 50a of the second horizontal movement units 70a and 70b and the centrally located cushioning member 51b.

First, the first and second horizontally moving units 70a and 70b disposed below the cushioning members 51a and 51c disposed on both sides move in the movement direction of the earthquake corresponding to the horizontal vibration of the earthquake. Since the first and second horizontally moving units 70a and 70b are opposed to each other in a direction opposite to each other, they move while canceling the horizontal vibration of the earthquake. That is, since the pinions 72 and the racks 74 of the first and second horizontal movement units 70a and 70b are disposed in the directions in which the racks 74 face each other, the buffering members 51b disposed at the center, Is reduced. Although the first and second horizontally moving units 70a and 70b are arranged in the direction facing each other, they may be arranged in the same direction according to the demand of the user.

When the vibration in the horizontal direction of the earthquake can not be alleviated by only a plurality of elastic members 56 connecting the buffer members 51a-51c, the buffer members 51a-51c are disposed under the buffer members 51a-51c disposed on both sides The first and second horizontal movement units 70a and 70b are moved in the movement direction of the earthquake.

When the first cushioning unit 50 corresponds to the vibration of the earthquake and the first cushioning unit 50 can not cope with the vibration of the earthquake, the first and second horizontal movement units 70a and 70b move in the horizontal direction And further corresponds to the horizontal vibration of the earthquake. That is, when the pinions 72 of the first and second horizontal movement units 70a and 70b move along the rack gear 73 corresponding to the vibration of the earthquake, the lever 78 fixed to one side of the pinion 72, And the guide block 76 connected to the slot 75 also corresponds to the vibration of the earthquake.

The first and second horizontal movement units 70a and 70b of the cushioning members 51a and 51c disposed on both sides of the three coils 30a to 30c and the buffer members 51a to 51c are moved And the buffer member 51b disposed at the center absorbs / mitigates the vibration using the vertical shock absorber 80 when the vibration of the earthquake is vertical, and the second shock absorber 51b, when the vibration of the earthquake is horizontal, So that the vibration is absorbed / mitigated by the vibration member 50a.

When the vibration of the earthquake is in the vertical direction, the vertical shock absorbing unit 80 disposed below the cushioning member 51b disposed at the center of the cushioning members 51a to 51c is configured so that the plurality of rollers 86 are simply moved in a predetermined direction The vertical vibration is transmitted to the I-shaped frame 82 as it is. Here, part of the vertical vibration of the earthquake is absorbed / relaxed by the elastic member 56, but is almost transferred to the I-shaped frame 82. At this time, vertical vibration of the earthquake is alleviated by the elastic members 84 disposed on both sides of the I-shaped frame 82. Since the elastic member 84 is applied to the I-shaped frame 82, the vibration of the vertical earthquake can be sufficiently absorbed / relaxed.

When the vibration of the earthquake is in the horizontal direction, the cushioning member 51b disposed at the center of the second cushioning unit 50a is provided with a guide shaft (not shown) in the other direction (the other direction opposite to the direction in which the elastic member 56 is disposed) The moving members 96a and 96b are disposed on the moving members 96a and 94b and the ball joints 110a and 110b connected to the moving members 96a and 96b absorb and mitigate forward and backward impacts of the earthquake when the earthquake occurs.

When the moving members 96a and 96b are moved in a predetermined horizontal direction, the ball studs 125 of the ball joints 110a and 110b are also moved in a predetermined horizontal direction, Thereby absorbing / mitigating the horizontal vibration of the vehicle. At this time, since the elastic members 56 connected to both sides of the cushioning member 51b arranged at the center are balanced, the movement of the cushioning member 51b can be reduced by a predetermined displacement, Absorption / relaxation.

The three coils 30a-30c and the buffer members 51a-51c move in the horizontal direction of the other side when the ground surface is shaken in one horizontal direction according to the horizontal vibration of the earthquake as described above, and the buffer members 51a- A plurality of elastic members 56 connected to both ends of the elastic members 56a and 51c serve to return the elastic members 56 to their original positions by restoring force of the elastic members 56 while restraining the other lateral movement of the buffer members 51a-51c.

That is, if the horizontal movement of the coils 30a-30c and the buffer members 51a-51c occurs in the horizontal direction due to the horizontal vibration of the earthquake, the elastic members of the first buffer unit 50 While restricting the horizontal movement of the coils 30a-30c and the cushioning members 51a-51c to the original position by the elastic force and the restoring force, A pair of moving members 96a and 96b slidably coupled to a pair of guide shafts 94a and 94b of the second cushioning unit 50a and a hinge action The pair of ball joints 110a and 110b act in a complementary relationship with each other to secondarily absorb and relax the forward and backward impacts of the coils 30a to 30c and the buffer members 51a to 51c.

When the vibration of the earthquake occurs simultaneously in the vertical direction and the horizontal direction, the vertical shock absorbing unit 80 and the first and second shock absorbers 50 and 50a disposed at the lower portion of the buffer member 51b described above are used simultaneously Thereby absorbing / mitigating vertical and horizontal vibrations of the earthquake.

Therefore, the vibration-proof mold transformer 100 according to the present invention can be applied to the first and second cushioning units 50 and 50a, the first and second horizontal movement units 70a and 70b, and the vertical shock- It is possible to prevent various accidents such as damage and breakdown of the anti-earthquake-resistant mold transformer 100.

The earthquake-resistant mold transformer 100 according to the present invention can prevent the shaking of the ground when an earthquake occurs by using the arch portion 14 and the plurality of earthquake-proof buffer portions 16 disposed in the base frame 10, Vibration of the earthquake can be absorbed by the elastic member 23, the second block 24 and the tilting bar 66 disposed in the lower frame 20 Can be further mitigated.

In addition, the vibration-proof mold transformer 100 according to the present invention may be configured such that a displacement generated in a mold transformer when an earthquake occurs is referred to as a first and second shock absorber / mitigation structure 50, 50a, The mobile units 70a and 70b and the vertical shock absorbing unit 80 can sufficiently alleviate the vibration in the left and right direction as well as the vibration in the up and down direction before and after the earthquake when the earthquake occurs.

The earthquake-resistant mold transformer of the present invention can be widely applied to various types of power high voltage transformers.

10: base frame 12: cushioning material
14: Arch portion 16a, 16b: Seismic buffer portion
17: Space section 20: Lower frame
21: hollow part 22: fixed block
23: elastic member 24: second block
25: stopper 42: core
30a-30c: coil 40: upper frame
50, 50a: Buffer unit 52: Body
51a-51c: buffer member 54: connecting member
58: adjusting screw 66: inclined bar
60: side frames 62a, 62b:
70a, 70b: horizontal movement unit 72: pinion
74: Rack 75: Slot
76: guide block 78: lever
80: vertical impact relief unit 82: I-shaped frame
84: elastic member 86: roller
90: auxiliary frame 92a-92d: supporting member
94a, 94b: guide shafts 96a, 96b:
100: anti-vibration mold transformer 110a, 110b: ball joint
112: main body 114: ball
122: shaft 125: ball stud
126: connecting member 128: elastic member

Claims (7)

A base frame 10;
A lower frame 20 disposed on the upper portion of the base frame 10;
Three coils 30a-30c disposed on the upper portion of the lower frame 20;
An upper frame 40 disposed above the coils 30a to 30c and arranged in a line with the lower frame 20;
A pair of first and second frames 20 and 30 connected to each other in the longitudinal direction between the lower frame 20 and the upper frame 40 to interconnect the lower frame 20 and the upper frame 40, A side frame (60) having blocks (62a, 62b), respectively;
Three cylindrical buffer members 51a-51c surrounding the three coils 30a-30c, a plurality of connecting members 54 disposed on both sides of the buffer members 51a-51c, A plurality of elastic members 56 elastically connecting the connecting member 54 with the connecting member 54 and a plurality of elastic members 56 arranged inside the connecting member 54 and moving left and right to adjust the elasticity of the elastic member 56 The vibration of the coils 30a-30c and the cushioning members 51a-51c in the horizontal direction is transmitted to the elastic members 56 of the plurality of elastic members 56 when the vibration of the earthquake is horizontal, A first shock absorber (50) which absorbs and buffers an impact from an earthquake by means of an earthquake;
A body 52 in the form of a rectangular parallelepiped having an opening at its upper portion surrounding the cushioning member 51b disposed at the center of the cushioning members 51a to 51c and four supporting members 92a to 92d arranged at four corners of the body, First and second guide shafts 94a and 94b connected between the two support members 92a and 92b and 92c and 92d arranged in the longitudinal direction and first and second guide shafts 94a and 94b connected to the outer periphery of the respective guide shafts 94a and 94b And a vertical frame 95 connected to the first and second moving members 96a and 96b and the auxiliary frame 90. The first and second moving members 96a and 96b are slidably coupled to the first and second moving members 96a and 96b, The first and second ball joints 110a and 110b which are installed between the first and second moving members 96a and 96b so as to be pivotally moved as they move along the first and second guide shafts 94a and 94b, A second buffer unit (50a) having a first buffer unit (110a);
A pinion 72 disposed in a guide bar 55 disposed below the cushioning members 51a and 51c disposed on both sides of the cushioning members 51a to 51c and a rack gear A guide block 76 disposed at one side of the rack 74 and a guide block 76 disposed at one side of the rack 74 and having one side connected to the pinion 72 and the other side connected to the guide block 76, First and second horizontally moving units (70a, 70b) having a complementary structure with each other and absorbing and absorbing a horizontal impact from an earthquake;
An I-shaped frame 82 disposed at a lower portion of a cushioning member 51b disposed at the center of the cushioning members 51a-51c; and an elastic member disposed at both sides of the I- And a vertical shock absorbing unit 80 having a plurality of rollers 86 spaced below the I-shaped frame 82 to absorb a vertical impact due to the vibration of the earthquake, ≪ / RTI &
When the horizontal movement of the coils 30a-30c and the buffer members 51a-51c due to inertia occurs in the horizontal direction due to the vibration of the earthquake in the horizontal direction, the elasticity of the elastic members 56, The vibration in the direction orthogonal to the horizontal direction or the direction deviated in the horizontal direction is controlled while the movement of the coils 30a-30c and the buffer members 51a-51c in the horizontal direction is primarily controlled while returning to the position A pair of moving members 96a and 96b slidably coupled to a pair of guide shafts 94a and 94b and a pair of ball joints 110a and 110b acting as a hinge function in a complementary relationship with each other, 30a-30c and the shock absorbing members 51a-51c,
When the vibration of the earthquake occurs simultaneously in the vertical direction and the horizontal direction, the vertical shock absorbing unit 80, the first and second horizontal movement units 70a and 70b disposed at the lower portion of the buffer member 51b, And the second cushioning unit (50, 50a) are used simultaneously to absorb and alleviate vertical and horizontal vibrations of the earthquake.
The method according to claim 1,
The base frame 10 has a plurality of arch portions 14 spaced apart from each other to reduce earthquake resistance at the outer periphery of the base frame 10. A space portion 17 is formed at the center of the base portion 10 in the longitudinal direction, And a cushioning material (12) made of a rubber material is filled inside.
The method according to claim 1,
The base frame 10 includes a plurality of fixed plates 11 arranged at intervals, a shaft 13 coupled to the fixed plate 11, and a pair of elastic members 15 inserted in the shaft 13 (16a, 16b) of the earthquake-proof mold transformer are provided on the right and left sides.
The method according to claim 1,
A hollow block 21 is formed on the inner side of the lower frame 20 and a fixing block 22 is disposed on both sides of the hollow block 21. The fixing block 22 is provided with elastic members 23, At least one stopper 25 for restricting the movement of the second block 24 is disposed at the front and rear sides of the second block 24 of the hollow portion 21 Wherein said transformer is a transformer.
The method according to claim 1,
The moving members 96a and 96b are connected to ball joints 110a and 110b disposed in a vertical frame 95 connected to the auxiliary frame 90. The ball joints 110a and 110b are connected to the ball housing 115 And the ball joints 110a and 110b include ball studs 125a and 125b of the ball joints 110a and 110b as the moving members 96a and 96b move along the guide shaft 94, Wherein the transformer is movable in the vertical direction.
6. The method of claim 5,
The ball housing 115 of the ball joints 110a and 110b includes a main body 112 and a ball 114 connected to the main body 112. The ball stud 125 of the ball joints 110a and 110b A shaft 122 and a ball stud ball 124 formed on one side of the shaft 122 and a connecting member 126 formed on the other side of the shaft 122 and an elastic member 128 fitted to the shaft 122. [ Wherein the transformer is a transformer.
The method according to claim 1,
Wherein the first blocks 62a and 62b of the side frame 60 are connected to each other by a second block 24 disposed inside the lower frame 20 and a tapered bar 66. [ .

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