KR102032339B1 - Earthquake-proof mold transformer - Google Patents

Abstract

The present invention relates to a seismic mold transformer, capable of preventing damage and failure of a seismic transformer, which comprises: a base frame (10); first and second plates (20, 30); three coils (35a to 35c); an upper frame (80); a pair of longitudinal sidewalls (90a, 90b); a pair of widthwise sidewalls (95a, 95b); first to third lower end buffer units (40a to 40c); first and second middle buffer units (70a, 70b); first and second upper end buffer units (140a, 140b); third and fourth upper end buffer units (110a, 110b); and three elastic members (42).

Description

Earthquake-proof mold transformer

The present invention relates to an earthquake resistant mold transformer, and more particularly, to an earthquake resistant mold transformer having a structure capable of efficiently coping with an earthquake or similar external vibration.

In general, the transformer should be firmly installed and maintained so that there is no vibration caused by external factors. Recently, the number of earthquakes has increased, and interest in transformers having a structure for earthquakes (that is, a seismic structure) has increased.

A mold transformer is a type of dry transformer insulated by curing the winding part with an epoxy resin, and converts a specific voltage into a voltage desired by a user. In addition, the molded transformer may provide advantages such as stability, low loss, and low noise due to its structural features, and may also provide excellent cracking resistance and excellent insulation performance with less risk of explosion and fire.

A mold transformer having a seismic function is disclosed in Korean Patent Publication No. 10-1937612 (Patent Document 1).

Patent document 1, the first and second lower frames provided in parallel with each other on the upper portion of the support frame provided on the bottom surface; First and second upper frames provided in parallel with the first and second lower frames, respectively; A core part fixedly supported between the first and second lower frames and the first and second upper frames and having a coil molded with a resin; A vibration damping unit connected to the first and second upper frames and having a rotating frictional force and having a rotatable rotating plate; First pulleys respectively installed on upper ends of the first upper frames; Second pulleys respectively installed on upper ends of the second upper frames; A first wire having one side connected to the support frame, connected along the first pulley, and the other side connected to the rotating plate; A second wire having one side connected to the support frame, the second wire connected to the second pulley, and the other side connected to the rotating plate; First and second stoppers for coupling the support frame and the first and second lower frames to maintain a predetermined constant distance from each other; And a rubber pad positioned between the support frame and the first and second lower frames and between the first and second lower frames and the first and second stoppers, the rubber pad having elastic force in a rubber material. And a fixed frame connected between the ends of the first and second upper frames and formed vertically downward in the center and having a rotating shaft and a friction pad provided on the rotating shaft in contact with the rotating plate, wherein the rotating plate includes the rotating shaft. It is configured to be rotatably coupled to.

Patent document 1 has a fixed frame having a rotating shaft and a vibration damping unit having a friction pad, but the wire is twisted when the earthquake or vibration is directly applied to the support frame, thereby causing a problem that the pulley cannot perform its original function. .

In addition, Patent Document 1, although only a plurality of pulleys and wires can partially cope with the seismic or external vibration in the vertical direction, there is a component that can not respond to the seismic or external vibration in the horizontal direction has a problem that can not be solved have.

1): Korea Patent Publication No. 10-1937612

An object of the present invention is to solve the above problems, to provide a seismic mold transformer that can prevent the separation or breakage of the coil by reducing the displacement generated in the mold transformer during the earthquake.

Another object of the present invention is to provide a seismic mold transformer capable of absorbing and cushioning shocks from earthquakes three-dimensionally at the lower, middle, and upper ends of three coils, respectively.

Another object of the present invention to provide a structure suitable for earthquake, earthquake resistance to provide an earthquake-resistant mold transformer that can improve the earthquake and seismic efficiency.

Still another object of the present invention is to cope with vibration primarily by using a shock absorbing member against vertical and horizontal vibrations generated momentarily during an earthquake or earthquake, and the first and second lower shock absorbing units, first and second The present invention provides a seismic mold transformer that can stably maintain a seismic transformer by applying a suspension buffer unit and first to fourth upper buffer units to cope with vibration.

The seismic mold transformer of the present invention includes a base frame; A first plate installed on the base frame; Second plates spaced apart from each other above the first plate; Three coils arranged at intervals in the longitudinal direction on the second plate; An upper frame disposed on top of the three coils to support the coils, the upper frame each having a rack having rack gears adjacent to both sides of a central coil located at the center of the three coils; A pair of longitudinal sidewalls disposed vertically at intervals on both sides along the three coils; A pair of widthwise sidewalls connected to both ends of the first and second plates, the upper frame and the pair of longitudinal sidewalls, respectively and installed in a vertical direction; The first to third bottom buffers are disposed to correspond to the lower portions of the three coils at intervals between the first and second plates, respectively, to absorb and cushion vertical and horizontal shocks caused by the vibration of the earthquake. A unit; A first body surrounding a central coil positioned in the center of the three coils and having a first connection portion disposed on both sides thereof, and spaced on both sides of the first body, and a second connection portion disposed on one side and a third on the other side. A pair of second bodies having a connection portion disposed therebetween, a pair of bellows disposed between the first body and the pair of second bodies each having an elastic member inside, and one side thereof is connected to a third connection portion of the second body, The other side is provided with a pair of connecting members connected to a pair of widthwise side walls, and when the horizontal vibration is applied to the interruption of the coil by the earthquake, the elastic force and the restoring force of the pair of bellows having an elastic member inward from the earthquake. First and second stop buffer units for absorbing and buffering the impact of the shock absorber; Four supports each disposed at 90 ° intervals with respect to the coils disposed on both sides of the three coils, the four supports being adjacent to the coils, the four shafts each connected to the four supports and having elastic members, and Four connection members connected to the other end and provided on the pair of widthwise sidewalls and the pair of longitudinal sidewalls, respectively, and four cushioning members made of rubber material and installed inside the support, are provided on top of the three coils. When the longitudinal or widthwise vibration is applied by the earthquake, each of the four support body is arranged at intervals with the coil so as to surround a portion of the coil disposed on both sides to prevent the horizontal movement or fluctuation of the coil 2 top buffer unit; Pinions, which are engaged with rack gears disposed on both sides of the upper frame, respectively, corresponding to the central coils located in the center of the three coils, and the pivot portion is pivotable to the pivot portion where the front end is connected to the pinion and the rear end is provided on the longitudinal side wall. And a third pin which has a arm fixed by a hinge pin, and the pinion is engaged with the rack gear of the rack when the longitudinal vibration is applied to the upper ends of the three coils by an earthquake. And a fourth upper shock absorbing unit, wherein the first to third lower shock absorbing units include: three lower EL guides arranged to be movable in a longitudinal direction along a lower EL rail provided in a length direction on a lower side of the first lower shock absorbing unit; And three upper ELs respectively installed to be movable in the width direction along the three upper EL rails installed in the width direction on the second plate. A three cylindrical housing having an upper end and an upper end and installed at the three lower L guides, and elastically supported within the housing, the lower end of the rod being connected to the support block, and the upper end of the rod extending out of the housing. And three movable bodies respectively connected to the lower portions of the three upper LM guides, and three elastic members respectively accommodated in the housing to elastically support the support block, and the lower, middle and upper ends of the three coils It is characterized by absorbing and cushioning the impact from the earthquake in three dimensions, respectively.

Both ends of the three upper RAM rails are respectively fitted and fixed to three through holes formed in the width direction of the second plate, and portions except for both ends of the upper RAM rail are between the second plate and the upper RAM rail. Since the gap is formed, the upper LM guide installed on the upper LM rail may be installed to be movable in the width direction along the upper LM rail.

In addition, the seismic mold transformer according to the present invention is a four-side fixed block disposed inside the base frame, four support blocks arranged at intervals on the outer peripheral surface of the fixed block, and one side is connected to the support block The other side may further include a pair of shock absorbing members made up of four beams disposed on the base frame, the outer peripheral surface of the fixed block and the plurality of support blocks, and four buffer members made of rubber material.

The connection member disposed on the pair of widthwise sidewalls is fitted by a hinge pin to the pivot part disposed on the pair of widthwise sidewalls, and the connection member disposed on the pair of longitudinal sidewalls is disposed at a lower portion of the pivot portion where the arm is installed. It can be fitted by a hinge pin to the arranged pivot portion.

In addition, a first connecting portion disposed on both sides of the first body of the first and second stop buffer unit and the second connecting portion disposed on one side of the second body are each provided with a receiving portion, and the third connecting portion of the second body. May be connected to the pair of widthwise sidewalls by a connecting member.

Furthermore, a pair of bellows of the first and second stop buffer units are fitted on both sides, and a lower shaft is fitted between the first body and the pair of second bodies, and the bellows is disposed in the shaft. It can be interconnected with the connecting member. The pair of connecting members of the first and second stop buffer units may have a shaft disposed in the center and fastening plates disposed at both sides thereof, and an elastic member may be fitted to the shaft.

The seismic mold transformer of the present invention has the advantage of preventing damage and failure of the seismic transformer because it can prevent the separation of the coil by reducing the displacement generated in the mold transformer during the earthquake, seismic occurrence.

In the present invention, the lower, middle and upper ends of the three coils can absorb and cushion the shock from the earthquake in three dimensions.

The seismic mold transformer of the present invention primarily deals with vibration by using a shock absorbing member against vertical and horizontal vibrations generated momentarily during an earthquake or earthquake, and also includes first and second lower shock absorbing units, first and second. By applying the interruption buffer unit, the first to fourth upper buffer unit, there is an advantage that it can stably maintain the seismic transformer by coping with the secondary vibration.

In addition, the seismic mold transformer of the present invention has the advantage of improving the seismic performance compared to the conventional seismic mold transformer by applying a pair of bellows having an elastic member inside the first and second interruption buffer units disposed in the center. .

1 is a schematic perspective view showing the overall structure of an earthquake resistant mold transformer according to the present invention;
2 is a longitudinal sectional view of the seismic mold transformer shown in FIG.
3 is a plan view showing a shock absorbing member according to the present invention;
Figures 4a to 4c is a longitudinal cross-sectional view showing the first to third lower buffer unit according to the present invention, respectively, a plan view showing the arrangement of the upper rail and the upper guide rails installed on the second plate, the upper lam installed on the second plate Cross section of rail and upper LM guide,
Figure 5 is a longitudinal cross-sectional view showing a first and a second stop buffer unit according to the present invention,
Figure 6 is a schematic plan view showing the structure of the first to fourth upper buffer unit according to the present invention.

Hereinafter, an embodiment of an earthquake resistant mold transformer of the present invention will be described with reference to the accompanying drawings.

As illustrated in FIGS. 1 and 2, the seismic mold transformer 100 of the present invention includes a base frame 10, first and second plates 20 and 30, three coils 35a to 35c, The upper frame 80, a pair of longitudinal sidewalls 90a and 90b, a pair of widthwise sidewalls 95a and 95b, first to third lower buffer units 40a-40c, first and first It is composed of two stop buffer units (70a, 70b), the first and second top buffer unit (140a, 140b), and the third and fourth top buffer unit (110a, 110b).

The seismic mold transformer 100 is a three-phase mold transformer in which the core 25 and three coils 35a-35c are arranged at a predetermined interval in a line in the longitudinal direction of the core 25.

The coils 35a to 35c may have, for example, a form in which the outer circumference of the winding part is surrounded by a buffer member (not shown) molded by epoxy resin, and the front and top surfaces have a primary voltage for the coil. Primary and secondary terminals to which a secondary voltage is applied, and an interphase lead for connecting the primary terminal, a tap-changing terminal, and the like may be installed.

In the present invention, at least one shock absorbing unit 15a, 15b is installed on the base frame 10 so as to absorb / buffer vibrations and shocks in the horizontal direction and the up / down direction of the left and right sides during the earthquake. First to third lower buffer units 40a-40c, first and second stop buffer units 70a and 70b, and first and third ends of the three coils 35a to 35c, respectively. The second upper buffer units 140a and 140b and the third and fourth upper buffer units 110a and 110b are installed and organically coupled to each other.

First, as shown in FIGS. 1 to 3, the base frame 10 is configured in at least one or more quadrangular shapes, and a mold transformer earthquake-resistant from an external shock such as an earthquake or earthquake may be formed inside the base frame 10. At least one shock absorbing unit (15a, 15b) for primarily mitigating the impact applied to the 100 may be installed.

The shock absorbing units 15a and 15b are for buffering / mitigating the shock of the earthquake-resistant mold transformer 100 by vibration in the horizontal direction (X direction and Y direction) when an earthquake or earthquake occurs. One may be applied to the inner side, or the base frame 10 may be divided into two, and one may be applied to the inner side thereof. Here, the impact buffer unit (15a, 15b), as shown in Figure 3, divided the base frame 10 into two rectangular forms, and applied to each one by one shown as an example.

As illustrated in FIG. 3, the pair of shock absorbing units 15a and 15b have four support blocks disposed at intervals on the fixed block 2 and the outer circumferential surface of the fixed block 2, respectively. Four beams 6 connected to the block 4, one side of which is connected to the support block 4, and the other side of which is connected to an edge of the base frame 10, and an outer circumferential surface of the fixed block 2 and four supports. It is arranged between the blocks (4) and may be composed of four buffer material (8) made of a rubber material.

The fixing block 2 may have a quadrangular shape, in particular, a rhombus shape (or a cube shape), and the fixing block 2 may include fastening members (bolts and nuts, etc.) not illustrated with the first plate 20 described later. It is fixed by). Here, the fixed block 2 is shown as an example of a rhombus, but may be configured in a rectangular or polygonal form of various forms according to the user's request. In addition, the shape or arrangement position of the support block 4 may be changed and applied in various forms according to the shape of the fixed block 2. Although the first plate 20 is illustrated as being disposed above the fixed block 2 as an example, it may be installed on the support block 4 of the shock absorbing unit (15a, 15b) according to the user's request.

The support block 4 is configured to support the fixed block 2 and has a triangular shape, and is configured to support the outer circumferential surface (or outer circumferential wall) of the fixed block 2. The buffer material 8 may be formed by forming a channel (not shown) between the fixed block 2 and the support block 4 and inserting the channel into the channel, and according to a user's request, It is fixed to one side is coupled in close contact with the fixed block (2).

Preferably, the fixed block 2 is disposed at a predetermined height difference slightly higher than that of the support block 4 or the base frame 10 (that is, the fixed block 2 is a reinforcement that is a reference to other members. Since it is a member, it is preferable to comprise in convex uneven | corrugated form).

The beam 6 is connected between the edge of the support block 4 and the base frame 10 to support the support block 4, but the beam 6 may be further provided to provide a damper function. May be applied to an elastic member (not shown).

As shown in FIGS. 1 and 2, the first plate 20 is disposed in the longitudinal direction (X direction) on the upper portion of the base frame 10, and one lower EL rail 22 is in the same direction (length). Direction).

The second plate 30 is disposed in the longitudinal direction (X direction) on the upper portion of the base frame 10, and three coils 32a-are spaced apart from the three rails 32 by the second plate 30. Corresponding to 35c), it is disposed below the coil in the width direction (Y direction). Here, the second plate 30 is disposed parallel to the first plate 20. In addition, three coils 35a to 35c are disposed on the second plate 30 at intervals in the longitudinal direction. Lower portions of the three coils 35a to 35c are connected to and installed at the three L guides 34 to be described later.

As shown in FIGS. 1, 2, and 4, the first to third lower shock absorbing units 40a-40c according to the present invention are provided to correspond to the lower ends of the three coils 35a to 35c, respectively.

The three first to third lower shock absorbing units 40a-40c are disposed between the first plate 20 and the second plate 30, respectively, in the X and Y directions of the earthquake or earthquake (ie, the horizontal direction). And three lower L guides 24 arranged to be movable in the longitudinal direction (X direction) along the lower L rail 22 positioned on the first plate 20 so as to cushion the vibrations or shocks thereof. Connected to each other, and an upper side of each of the three L guides 34 disposed to be movable in the width direction (Y direction) along the three L rails 32 installed in the width direction (Y direction) on the second plate 30; It is connected.

In this case, the combination of the lower LM rail 22 and the lower LM guide 24, and the combination of the LM rail 32 and the LM guide 34 may be a combination of the LM guides which are movably installed on the well known rail. In the present invention, only the electromagnetic control is applied, and it is used as a linear movement mechanism in which the LM guide is movable in the longitudinal direction along the LM rail using only a mechanical mechanism.

As shown in FIGS. 4A to 4C, both ends of the three L rails 32 are fitted into and fixed to three through holes 30a formed to be elongated in the width direction in the second plate 30, respectively. The portions excluding both ends of the LM rail 32 have a predetermined gap formed between the second plate 30 and the LM rail 32 so that the LM guide 34 installed on the LM rail 32 is the LM rail 32. Along the width direction (Y direction) is provided so that a flow is possible.

In addition, the first to third lower shock absorbing units 40a-40c may each have an upper portion open and a lower portion installed at the lower L guide 24 so as to correspond to vibrations or shocks in the Z direction of an earthquake or earthquake. The cylindrical housing 44 and the elastic support is received in the housing 44, the lower end of the rod 46 is connected to the support block 41 and the upper end of the rod 46 is extended to the outside of the housing 44 It consists of a movable body 47 connected to the lower portion of the LM guide 34 and an elastic member 42 accommodated in the housing 44 to elastically support the support block 41. In addition, the inlet of the housing 44 is provided with a stepped portion 43 for restricting the separation of the support block 41.

On the other hand, the first and second stop buffer unit (70a, 70b) according to the present invention, as shown in Figures 2 and 5, are installed corresponding to the interruption of the three coils (35a-35c), respectively.

The first and second stop buffer units 70a and 70b accommodate and support a lower portion of the coil 35b positioned at the center of the three coils 35a to 35c, and the first connection portion 52 is provided at both sides thereof. The body 54 and the lower portions of the coils 35a and 35c located on both sides of the three coils 35a to 35c are accommodated and supported, and a second connection portion 62 is provided at one side and a third connection portion 64 at the other side. ) Is provided between a pair of second body (58a, 58b), and between the first body (54) and the second body (58a, 58b), respectively, a pair of having an elastic member (55) inside Bellows 56a and 56b and a pair of connecting members 60a and 60b connected to one side of the third connecting portion 64 and the other side to a pair of widthwise side walls 95a and 95b are provided.

The first and second stop buffer units (70a, 70b) through the multi-stage buffering action due to the collision between the coils (35a-35c) due to the vibration in the X direction (that is, the longitudinal direction) when an earthquake or earthquake occurs To avoid collisions.

Receiving portions 52a and 62a are formed between the first connecting portion 52 disposed on both sides of the first body 54 and the second connecting portion 62 disposed on one side of the second bodies 58a and 58b, respectively. The third connecting portion 64 of the second bodies 58a and 58b is connected to the pair of widthwise sidewalls 95a and 95b via the pair of connecting members 60a and 60b. The receiving portions 52a and 62a are configured to be coupled to the fitting portions 57a and 57b disposed at both sides of the bellows 56a and 56b.

Bellows 56a and 56b of the first and second suspension buffer units 70a and 70b have fitting portions 57a and 57b respectively formed at both sides thereof, and a shaft 61 is formed at the lower portion of the first and second bodies 54 and 56b. Fitted between the two body 58, the bellows (56a, 56b) is configured to be interconnected with a plurality of connecting members (63) slidably coupled to the shaft (61). The shaft 61 is configured to be fixed to the first body 54 and the second bodies 58a and 58b by the fastening member 61a.

The bellows 56a and 56b are fitted to the shaft 61 so as to be movable along the plurality of connecting members 63 to prevent the bellows 56a and 56b from being separated in the event of an earthquake or earthquake. The pair of bellows 56a and 56b is slid left and right stepwise in the X direction along the shaft 61 between the three coils 35a to 35c and between the three coils 35a to 35c. When a collision occurs, the shock absorbing / absorption may be prevented, thereby preventing damage to the coils 35a to 35c.

As shown in FIG. 5, the pair of connecting members 60a and 60b are provided with shafts 66a at the center and fastening plates 66c at both sides thereof, and elastic members 66b at the shafts 66a. ) Is configured to fit. In addition, a fastening portion 66d is disposed at one side of the fastening plate 66c, and the fastening portion 66d is formed by a second body 58 or a pair of fastening members (ie, bolts and nuts) not shown. Is fixed to the widthwise side walls 95a and 95b.

Hereinafter, the first and second upper buffer units 140a and 140b and the third and fourth upper buffer units 110a and 110b will be described with reference to FIGS. 1 and 6.

Referring to FIG. 6, the upper frame 80 is disposed above the three coils 35a to 35c, and a pair of racks 84 having rack gears 82 are formed at both sides of a central portion thereof. have. The pair of racks 84 formed on the upper frame 80 are disposed to correspond to the coil 35b disposed at the center of the three coils 35a to 35c. In addition, the rack gear 82 of the upper frame 80 is engaged with the pinion 92 of the third and fourth upper buffer units (110a, 110b) to be described later. In addition, the three coils 35a-35c disposed below the upper frame 80 are connected to the upper frame 80 through the plurality of connecting plates 45.

Both ends of the pair of longitudinal sidewalls 90a and 90b are connected to the pair of widthwise sidewalls 95a and 95b to form a rectangular support frame, as shown in FIG. 6.

The pair of widthwise sidewalls 95a and 95b are vertically disposed between the first and second plates 20 and 30, the upper frame 80, and the pair of longitudinal sidewalls 90a and 90b and are arranged in a first direction. And the second plates 20, 30, the upper frame 80, and the pair of longitudinal sidewalls 90a, 90b.

The third and fourth upper shock absorbing units 110a and 110b are connected to the pinion 92 and the pinion 92 respectively engaged with the rack gears 82 disposed on both sides of the upper frame 80, respectively. It consists of the arm 94 which becomes. The arm 94 is fixed by a hinge pin 98 to a pivot portion 96 disposed at a predetermined position on the pair of longitudinal sidewalls 90a and 90b.

The third and fourth upper buffer units (110a, 110b) is applied to the horizontal direction (X direction) vibration by the earthquake on the upper end of the three coils (35a-35c) to move the coils (35a-35c) When the pinion 92 meshes with the rack gear 82 of the rack 84, the pinion 92 catches the longitudinal vibration on both sides of the coils 35a-35c and can mitigate the vibration in the X direction.

As shown in FIG. 6, the first and second upper buffer units 140a and 140b are spaced apart from the coils 35a and 35c so as to surround portions of the coils 35a and 35c respectively disposed on both sides. And four support assemblies 130a disposed at intervals of 90 ° in the circumferential direction.

The four support assemblies 130a are connected to the four supports 122 surrounding the portions of the coils 35a and 35c disposed on both sides of the three coils 35a to 35c, and the four supports 122, respectively. Four shafts 126 having elastic members 124, four shafts 126 connected to the shaft 126 and disposed on a pair of longitudinal sidewalls 95a and 95b and a pair of longitudinal sidewalls 90a and 90b. It is composed of a connecting member (128).

As a result, the first and second top buffer units 140a and 140b are spaced apart from the coils 35a and 35c so as to surround a part of the coils 35a and 35c having four supports 122 disposed on both sides, respectively. It is arranged in the position and prevents the movement and fluctuation of the left and right and front and rear directions (X and Y directions) of the coils 35a and 35c disposed on both sides of the three coils 35a to 35c due to the occurrence of an earthquake or earthquake. Will be performed.

The eight supports 122 are arranged at four intervals of 90 ° with respect to the coils 35a and 35c, respectively, and a buffer material 132 made of a rubber material is connected to the inside of the support 122. The reason why four supporters 122 are arranged at intervals of 90 ° is because it is most preferable to support the cylindrical coils 35a and 35c to alleviate the impact. In addition, the support 122 may be arranged two or three according to the user's request (that is, may be arranged at intervals of 180 degrees or 120 degrees). In addition, the plurality of supports 122 may be configured in an arch form or a crescent form so as to easily support the coils 35a to 35c disposed on both sides.

Four connecting members 128 are arranged with respect to the coils 35a and 35c disposed on both sides of the three coils 35a to 35c, respectively, two of which are a pair of widthwise sidewalls 95a and 95b or a pair. It is disposed at an edge between the longitudinal sidewalls 90a and 90b and the pair of widthwise sidewalls 95a and 95b, and the other two are disposed on the pair of longitudinal sidewalls 90a and 90b.

That is, the connecting member 128 disposed on the pair of widthwise sidewalls 95a and 95b has a hinge pin 138 at the pivot portion 136 disposed at an upper predetermined portion of the pair of widthwise sidewalls 95a and 95b. The connecting member 128, which is fitted by the pair of longitudinal sidewalls 90a and 90b, is hinged to the pivot portion 146 disposed below the pivot portion 96 on which the arm 94 is disposed. 148).

An operation process of the seismic mold transformer of the present invention configured as described above will be described.

1 and 2, the earthquake-resistant mold transformer 100 of the present invention, when the earthquake does not occur, the first and second stop buffer unit (70a, 70b) is the three coils (35a-35c) in the horizontal direction In a state where there is no movement, a pair of bellows 56a and 56b is disposed between the first body 54 and the second bodies 58a and 58b, and the pair of connecting members 60a and 60b are the second body 58. And are disposed between and support the pair of widthwise side walls 95a and 95b, and the three first to third lower shock absorbing units 40a to 40c also have the first and second bodies 54, 58a and 58b. Will support the bottom.

The base frame 10 of the present invention is disposed below the portion where the three coils 35a to 35c are installed on the ground G, and may be formed in two or more square shapes. Inside the base frame 10, a pair of shock absorbing members 15a having four support blocks 4 and a cushioning material 8 for mitigating shock or vibration due to an earthquake or earthquake transmitted to the fixed block 2. Since 15b) is disposed, vibrations of the left and right and front and rear directions are primarily absorbed when an earthquake or earthquake occurs.

The first plate 20 and the second plate 30 are disposed on the fixing block 2 disposed inside the base frame 10, and the first plate 20 and the second plate 30 are disposed on the upper side of the fixing block 2. Between the three coils 35a to 35c corresponding to the three first to third lower buffer units (40a-40c) are arranged to absorb the front and rear and left and right vibrations.

The first to third lower shock absorbing units 40a-40c may have a lower L guide 24 disposed below the lower L guide 24 along the lower L rail 22 disposed on the first plate 20 in the longitudinal direction (X direction). When moving to the left and right direction can be moved according to the vibration, the upper L guide (34a, 34b) disposed on the upper direction along the three (3) rails 32 installed on the second plate 30 (32) In the Y direction), the first to third lower end buffer units 40a-40c absorb second, second, and second directions, because the first to third lower shock absorbing units 40a-40c are configured to be movable according to vibrations in the front and rear directions.

In addition, since the movable body 47 is elastically supported by the elastic member 42 in each of the first to third lower buffer units 40a-40c, the vibration degree in the vertical direction (Z direction) is also increased. In addition, it becomes possible to absorb / buffer.

As described above, the first to third lower shock absorbing units 40a to 40c of the present invention can absorb vibrations in the up and down direction as well as the left and right vibrations against earthquakes, earthquakes and external vibrations. Shaking or breaking in all directions of 35c) can be prevented.

In addition, in the present invention, when the coil 30a-30c moves in the horizontal direction in the horizontal direction due to the inertia of the horizontal vibration of the earthquake, a pair of the first and second stop buffer units 70a and 70b may be used. By returning to the original position by the elastic force and the restoring force of the bellows 56a, 56b, the horizontal movement of the coil 30a-30c in the horizontal direction can be controlled primarily.

That is, the first and second stop buffer units (70a, 70b) is the first body 54 and the first body (54) for accommodating the lower end of the coil (35a-35c) corresponding to the number of coils (35a-35c) And a pair of bellows disposed between the first body 54 and the pair of second bodies 58a and 58b, having a pair of second bodies 58a and 58b spaced apart from each other. And a pair of connecting members 60a and 60b disposed between the 56a and 56b, the second bodies 58a and 58b, and the pair of widthwise side walls 95a and 95b.

As a result, when the first and second stop buffer units 70a and 70b transmit vibrations during an earthquake or seismic occurrence, the first body 54 and the second bodies 58a and 58b are shown in FIGS. 2 and 5. As shown, since the vibration is not directly transmitted to the three coils (35a-35c) by the pair of bellows (56a, 56b) are absorbed by the bellows (56a, 56b). In addition, since the bellows 56a and 56b are connected to the shaft 61 by the connecting member 63, the bellows 56a and 56b are absorbed / buffered while moving left and right along the shaft 61.

When only the bellows 56a and 56b of the first and second stop buffer units 70a and 70b cannot alleviate the vibration of the earthquake, the second body 58a and 58b and the pair of widthwise sidewalls 95a and 95b may be used. By using a pair of connecting members (60a, 60b) disposed between the to further reduce the vibration of the earthquake step by step.

If the earthquake or seismic vibration becomes more severe, the bellows 56a and 56b continue to move along the shaft 61 in correspondence to the movement direction of the earthquake, and then the fitting portions 57a disposed on both sides of the bellows 56a and 56b. And 57b are fitted to the receiving portions 52a and 62a of the first and second connecting portions 52 and 62 of the first and second bodies 54,58a and 58b, respectively. If severe vibration is continuously transmitted in this state, the pair of connecting members 60a and 60b disposed between the pair of second bodies 58a and 58b and the pair of widthwise side walls 95a and 95b operate to further operate. It will alleviate earthquakes and earthquakes. That is, since the connecting member (60a, 60b) is disposed on the shaft 66a, the elastic member (66b), respectively, it is possible to further reduce the vibration.

When the bellows 56a and 56b primarily correspond to an earthquake or seismic vibration, and only the bellows 56a and 56b cannot cope with an earthquake or seismic vibration, the connecting members 60a and 60b operate secondly. This will further mitigate this in response to severe vibrations.

In addition, the third and fourth upper buffer units (110a, 110b) of the present invention, as shown in Figure 6, the earthquake transmitted to the upper end of the coil 35b disposed in the center of the three coils (35a-35c) To reduce the impact of earthquakes or seismic. That is, the pinions 92 of the third and fourth upper buffer units 110a and 110b are engaged with the rack gears 82 of the rack 84 disposed on both sides of the upper frame 80 so that the three coils 35a -35c) will further mitigate the seismic or earthquake vibrations transmitted. Here, since the arm 94 connected to the pinion 92 is connected to the pivot portion 96, the arm 94 also pivots 96 as the pinion 92 moves in response to the earthquake direction along the rack gear 82. ) Will move in conjunction with the center. In addition, since the pinion 92 is moved in a regulated state of two first and second upper buffer units 140a and 140b to be described later disposed on both sides, the pinion 92 may be moved. Will be.

Furthermore, even if the pinion 92 and the rack 84 are damaged due to the severe earthquake or the vibration of the earthquake, the first and second upper shock absorbing units 140a and 140b additionally have coils 35a and 35c disposed on both sides. Since it serves to support the coil (35b) disposed in the center to prevent damage to the coil (35b).

The first and second upper buffer units 140a and 140b of the present invention reduce the impact of earthquakes or earthquakes transmitted to the upper ends of the coils 35a and 35c disposed on both sides of the three coils 35a to 35c. That is, since the support bodies 122 of the first and second upper shock absorbing units 140a and 140b are arranged at four intervals of 90 ° with respect to the coils 35a and 35c disposed on both sides, the earthquake or the earthquake may be impacted in any direction. Even if this is delivered, it can be alleviated. Here, the first and second upper buffer units 140a and 140b are coils 35a disposed on both sides of the third and fourth upper buffer units 110a and 110b even though the third and fourth upper buffer units 110a and 110b are damaged due to a severe earthquake or an earthquake. It is elastically supported in the front, rear and left and right directions of, 35c) can mitigate the horizontal vibration of severe earthquakes or earthquakes. In addition, since the buffer material 132 made of a rubber material is disposed inside the support body 122, damage or damage to the coils 35a to 35c may be prevented. In addition, since the elastic member 124 is disposed on the shaft 126, the impact transmitted to the support 122 may be reduced step by step.

Therefore, the seismic mold may be reduced by the third and fourth upper shock absorbing units 110a and 110b and the first and second upper shock absorbing units 140a and 140b in the second and second directions, respectively. Various accidents such as damage and failure of the transformer 100 can be prevented.

As described above, the earthquake-resistant mold transformer 100 of the present invention primarily uses the shock absorbing members 15a and 15b disposed inside the base frame 10 against the shaking of the ground during the earthquake. It can absorb the vibration in the direction and by using the first to third lower shock absorbing unit (40a-40c) to absorb the vibration in the left and right and front and rear direction and the up and down direction, so that vibration of earthquake or earthquake can be alleviated. .

In addition, the seismic mold transformer 100 according to the present invention, when the vibration of the earthquake is applied to the three coils (35a-35c), the first and second lower buffer unit (40a-) at the lower end, the middle and the upper end of the coil, respectively 40c), the first and second stop buffer units (70a, 70b), the first to fourth top buffer units (70a, 70b, 110a, 110b) by applying a three-dimensional vibration to a stable seismic transformer Can be maintained.

In addition, in the present invention, the stepped shock absorbing and absorption is also performed inside each buffer unit.

First, the first and second interruption buffer units (70a, 70b), when the vibration is transmitted when the earthquake or earthquake occurs, primarily absorbs the vibration by a pair of bellows (56a, 56b), only the bellows (56a, 56b) If it is not possible to alleviate the vibration of the earthquake, the earthquake is secondary by using a pair of connecting members 60a and 60b disposed between the second bodies 58a and 58b and the pair of widthwise side walls 95a and 95b. The vibration of the step is mitigated.

In addition, the upper end of the coil (30a-30c) first by the third and fourth upper buffer unit (110a, 110b) to reduce the vibration primarily in the left and right direction and the front and rear direction of the earthquake, the first and second top buffer By the units 140a and 140b, vibration can be reduced secondarily.

The seismic mold transformer of the present invention can be widely applied to the field of high pressure transformer, which can absorb and buffer shocks from earthquakes in three dimensions / steps at the bottom, middle and top of the coil, respectively.

10: base frame 15a, 15b: shock absorbing member
20,30: first and second plate 22,32: L rail
24, 34a, 34b: LM guide 35a-35c: coil
40a-40c: first to third lower buffer units 41: support blocks
42: elastic member 43: stepped portion
44: housing 45: connecting plate
46: load 47: movable body
52, 58a, 58b: body 56a, 56b: bellows
60a, 60b: connecting member 66b: elastic member
70a, 70b: first stop buffer unit 80: upper frame
82: rack gear 84: rack
90a, 90b: longitudinal side wall 92: pinion
94: arm 95a, 95b: widthwise side wall
96: pivot 98: hinge pin
100: seismic mold transformer 130a: support assembly
110a, 110b: third and fourth upper buffer units
140a and 140b: first and second upper buffer units

Claims (6)

A base frame 10;
A first plate 20 installed on the base frame 10;
A second plate 30 spaced apart from each other above the first plate 20;
Three coils (35a-35c) disposed at intervals in the longitudinal direction on the second plate (30);
It is disposed above the three coils 35a-35c to support the coils 35a-35c, and is adjacent to both sides of the central coil 35b positioned at the center of the three coils 35a-35c. An upper frame 80 each having a rack 84 having 82;
A pair of longitudinal sidewalls (90a, 90b) disposed vertically at intervals on both sides along the three coils (35a-35c);
A pair of widthwise sidewalls 95a and 95b connected to both ends of the first and second plates 20 and 30, the upper frame 80 and the pair of longitudinal sidewalls 90a and 90b, respectively, and installed in a vertical direction. )and;
Each of the three coils 35a to 35c is spaced between the first plate 20 and the second plate 30 so as to correspond to the lower portions of the three plates 35a to 35c, and absorbs the vertical and horizontal shocks caused by the vibration of the earthquake. And first to third lower buffer unit (40a-40c) for buffering;
The first body 54 surrounding the central coil 35b positioned at the center of the three coils 35a-35c and having the first connecting portion 52 disposed on both sides thereof, and on both sides of the first body 54. A pair of second bodies 58a and 58b disposed at intervals and having a second connection portion 62 disposed on one side and a third connection portion 64 disposed on the other side, and a pair of first bodies 54 and the first body 54; A pair of bellows (56a, 56b) disposed between the two bodies (58a, 58b), each having an elastic member (55) inside, one side of each of the third connection portion 64 of the second body (58a, 58b) And a pair of connecting members 60a and 60b connected to each other and to the pair of widthwise side walls 95a and 95b, and when horizontal vibration is applied by an earthquake at the interruption of the coils 35a to 35c. First and second stop buffer units 70a and 70b for absorbing and cushioning an impact from an earthquake by the elastic force and the restoring force of the pair of bellows 56a and 56b having the elastic member 55 therein;
Four support members 122 disposed at 90 ° intervals with respect to the coils 35a and 35c disposed on both sides of the three coils 35a to 35c, respectively, and surrounded by the coils 35a and 35c. Four shafts 126 connected to the two support bodies 122, each having an elastic member 124, and connected to the other end of the shaft 126, and a pair of longitudinal sidewalls 95a and 95b and a pair of longitudinal sidewalls. Four connecting members 128 respectively provided at 90a and 90b, and four shock absorbing members 132 made of a rubber material and installed inside the support body 122, and the three coils 35a to 35c. When the longitudinal or widthwise vibration is applied by the earthquake at the top of the), the four supports 122 are spaced apart from the coils 35a and 35c so as to surround a part of the coils 35a and 35c disposed on both sides. First and second upper shock absorbing units 140a and 140b disposed to be disposed to prevent horizontal movement or oscillation of the coils 35a and 35c;
Pinions 92 respectively engaged with rack gears 82 disposed on both sides of the upper frame 80 in correspondence with the central coil 35b positioned at the center of the three coils 35a-35c, respectively, An arm 94 connected to the pinion 92 and secured by a hinge pin 98 pivotably to a pivot 96 provided at a rear end of the side walls 90a and 90b, wherein the three coils When the longitudinal vibration is applied to the upper end of the 35a-35c by the earthquake, the pinion 92 meshes with the rack gear 82 of the rack 84, thereby catching the longitudinal vibration on both sides of the coils 35a-35c. It includes; and the third and fourth upper buffer unit (110a, 110b),
The first to third lower shock absorbing units 40a-40c may have three lower EL guides arranged to be movable in the longitudinal direction along the lower EL rail 22 installed in the longitudinal direction on the first plate 20. 24 and three upper LM guides 34a and 34b respectively installed to be movable in the width direction along three upper LM rails 32 provided in the width direction in the second plate 30, and an upper portion thereof is opened. Three cylindrical housings 44 having a lower end installed in the three lower L guides 24 and elastically supported in the housing 44 are accommodated, and the lower end of the rod 46 is connected to the support block 41, and the rod The upper end of the 46 is extended to the outside of the housing 44 and the three movable bodies 47 connected to the lower portions of the three upper LM guides 34a and 34b, respectively, and accommodated in the housing 44 respectively. It is provided with three elastic members 42 for elastically supporting the support block 41,
The lower, middle and upper ends of the three coils 35a to 35c respectively absorb and cushion shocks from earthquakes in three dimensions.
The method of claim 1,
Both ends of the three upper RAM rails 32 are respectively fitted into three through holes 30a formed in the width direction in the second plate 30 and fixed thereto.
A portion excluding both ends of the upper RAM rail 32 has a gap formed between the second plate 30 and the upper RAM rail 32, so that the upper RAM guides 34a and 34b installed on the upper RAM rail 32 are provided. The seismic mold transformer, characterized in that the flow is installed in the width direction along the upper rail (32).
The method of claim 1,
A quadrilateral fixed block 2 disposed inside the base frame 10, four support blocks 4 disposed at intervals on the outer circumferential surface of the fixed block, and one side thereof is provided on the support block 4. Four beams 6 connected to each other and arranged on the base frame 10 and between the outer circumferential surface of the fixed block 2 and the plurality of support blocks 4 and four buffer members 8 made of rubber material. Shockproof mold transformer further comprises a pair of shock absorbing members (15a, 15b) consisting of.
The method of claim 1,
The connecting member 128 disposed on the pair of widthwise sidewalls 95a and 95b is connected to the hinge pin 138 on the pivot portion 136 disposed at an upper predetermined portion of the pair of widthwise sidewalls 95a and 95b. The connecting member 128, which is fitted by the pair of longitudinal sidewalls 90a and 90b, is hinge pin 148 to the pivot portion 146 disposed below the pivot portion 96 on which the arm 94 is disposed. Earthquake-resistant mold transformer, characterized in that fitted by).
The method of claim 1,
The first connection portion 52 disposed on both sides of the first body 54 of the first and second stop buffer units 70a and 70b and the second connection portion disposed on one side of the second body 58a and 58b ( Receiving portions 52a and 62a are formed in the 62, and the third connecting portion 64 of the second body 58a and 58b is a pair of widthwise side walls 95a by a pair of connecting members 60a and 60b. And 95b).
The method of claim 1,
The pair of bellows 56a and 56b of the first and second suspension buffer units 70a and 70b have fitting portions 57a and 57b at both sides thereof, and a shaft 61 at the lower portion of the first body 54. And a pair of second bodies 58a and 58b, the bellows 56a and 56b are interconnected with a plurality of connecting members 63 disposed on the shaft 61,
In the pair of connecting members 60a and 60b of the first and second stop buffer units 70a and 70b, a shaft 66a is disposed at the center and fastening plates 66c are disposed at both sides, respectively, and the shaft 66a is disposed. ) Seismic mold transformer, characterized in that the elastic member (66b) is fitted.

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