KR101341152B1 - The distribution board with earthquake-proof device - Google Patents

Abstract

The present invention relates to a distribution board with an earthquake-proof device. According to the present invention, the distribution board with an earthquake-proof device includes a lower support part (30); a moving part (40); a cylinder part (70); an upper support part (50); and an earthquake-proof device (1). [Reference numerals] (93) Earthquake measuring sensor unit;(94) Controller

Description

[0001] The present invention relates to a distribution board with earthquake-proof device,

The present invention relates to a switchgear with an earthquake-proof device capable of preventing twisting, tilting, and breakage of a switchboard due to vibrations or impacts caused by earthquakes such as earthquakes, and more particularly, It is possible to minimize the deterioration of the function even if the seismic isolation device does not operate for a long period of time and can save manpower and cost for maintenance and is easy to manufacture, The present invention relates to a seismic surveillance system capable of effectively absorbing a seismic wave and minimizing an impact transmitted to a transmission / reception system, thereby effectively preventing breakage of a transmission / reception system due to an earthquake.

In general, switchgear is an electric facility that supplies industrial power to users securely. It is a device used for monitoring, controlling, and protecting electric system when the power supplied from a power plant or a substation is delivered to a customer several times.

The switchgear consists of a structure that attaches and supports unit devices such as a circuit breaker or a protective relay, and a collection of conductors that connect and connect the unit devices. The electrical devices are safely insulated and stored in a rectangular steel enclosure. .

Various unit electric devices included in the enclosure of the switchboard are very vulnerable to vibration, so they must be designed to minimize the vibration transmitted to the switchboard. However, the conventional switchboard is installed directly on the floor with various unit electric devices built in the enclosure, In addition, it is necessary to design seismic isolation system for power distribution system in connection with mandatory seismic design for power supply facilities.

As shown in FIG. 1, the upper plate 110, which is coupled to the lower surface of the housing of the cab of the switchgear, A spring plate 130, a support plate 140 and a ball 150 are stacked in a spaced space between the lower plate 120 and the lower plate 120 fixed to the ground surface. In a normal state where no earthquake occurs, air in the spaced space is discharged to the outside The upper plate 110 and the lower plate 120 are tightly fixed to each other to fix and support the cabinet. When an earthquake occurs, the vacuum state of the separated space is released, The upper plate 110 and the lower plate 120 are separated from each other so that the lower plate 120 is separated from the upper plate 110 through the spring 130 and the ball 150, Although it is configured to attenuate the transmission of one vibration,

There is a problem in that the apparatus is structured such that an expensive high-capacity air suction device is required to realize a vacuum state of the spacing space in which the upper plate 110 and the lower plate 120 are tightly fixed,

Even if the vacuum state of the spacing space is realized so that the upper plate 110 and the lower plate 120 can be tightly fixed to each other, And the lower plate 120, so that it is difficult to firmly support the enclosure of the power plant and the maintenance and repair of the enclosure is expensive. In addition,

Further, in the case of the spring 130 which is maintained in the state of being compressed for a long time, the elastic force thereof is rapidly lowered, so that vibration is absorbed by a low elastic force which is less than the elastic force at the time of the first installation upon occurrence of an earthquake, .

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to prevent twisting or tilting of a switchboard by attenuating vibration or shock propagation caused by an earthquake and to prevent breakage of a switchboard due to an earthquake together,

It is possible to firmly fix the upper support portion fixedly coupled to the lower surface of the cabinet of the switchgear and the lower support portion fixedly coupled to the ground surface with a simple structure,

The upper support portion and the lower support portion are firmly fixed to each other even when the earthquake does not occur for a long period of time, so that it is possible to firmly support and hold the enclosure of the switchboard at all times, and the cost required for maintenance and repair of the earthquake- And,

In addition, it is possible to maintain the original elasticity force at the time of installation without degrading the elastic force of the elastic supporter, so that the seismic wave can be absorbed smoothly when the earthquake occurs and the shock transmitted to the switchboard can be minimized, .

In order to solve the above-mentioned problems, according to one aspect of the present invention, a seismic wave introduced from the ground surface 10 is absorbed by a lower portion of a housing 20 of a switchboard, so that vibration or shock of a seismic wave is transmitted to the housing 20 A lower support portion (30) having a lower surface fixedly coupled to the ground surface (10) and having a receiving space portion (31) therein; A movable part 40 provided in the accommodation space 31 so as to be movable up and down; A pair of side cylinder parts 70 provided at both left and right sides of the accommodation space 31 to fix or release the movable part 40; A plurality of lower elastic supports 90 provided below the accommodating space 31 at predetermined intervals to elastically support the movable part 40; An upper support portion 50 fixedly coupled to a lower portion of the housing 20 of the switchboard and having a lower surface formed to be slidable in contact with the upper surface of the movable portion 40; And an upper cylinder part 80 provided at the center of the upper support part 50 to fix or release the movable part 40. To provide.

In the switchgear equipped with the seismic device 1 of one embodiment of the present invention, a Teflon coating layer 91 may be formed on an upper surface of the movable part 40 or a lower surface of the upper support part 50. And

Preferably, earthquake measurement sensor unit 93 for measuring the occurrence of earthquake; When receiving a signal according to whether an earthquake occurs from the seismic measurement sensor unit 93, and when receiving a normal signal from which the earthquake does not occur from the seismic measurement sensor unit 93, the pair of side cylinder portion 70 And a control signal to the upper cylinder portion 80 to fix the movable portion 40 and to receive an earthquake generation signal from the seismic measurement sensor 93, the pair of side cylinder portions 70. And a controller 94 inputting a control signal to the upper cylinder part 80 to release the movable part 40 from being fixed.

INDUSTRIAL APPLICABILITY The switchgear with the earthquake-proof device according to the present invention can prevent the transmission and reception of electric power from being distorted or tilted by attenuating the vibration or vibration due to the earthquake and prevent breakage of the power-

It is possible to firmly fix the upper support portion fixedly coupled to the lower surface of the housing of the switchgear and the lower support portion fixedly coupled to the ground surface with a simple structure,

The upper support portion and the lower support portion can be firmly fixed to each other even when the earthquake does not occur for a long period of time, so that the enclosure of the power plant can be firmly fixedly supported at all times and the cost required for maintenance and repair of the earthquake- ,

In addition, it is possible to maintain the original elasticity force at the time of installation without degrading the elastic force of the elastic supporter. Therefore, it is possible to absorb the seismic wave smoothly in case of an earthquake and to minimize the shock transmitted to the switchboard, thereby effectively preventing breakage of the power- .

1 is a cross-sectional view of a conventional earthquake-proof apparatus in a conventional switchboard;
Fig. 2 is a sectional view showing a part of a housing lower portion of a power transmission system equipped with an earthquake-proof apparatus according to the present invention in a normal state in which no earthquake occurs; Fig.
3 is a cross-sectional view showing a part of a housing lower portion of a switchboard with an earthquake-proof device according to the present invention when an earthquake occurs;
FIG. 4A is an operational state diagram showing that the seismic isolation device is out of the center, in a switchboard having an earthquake-proof apparatus according to the present invention; FIG.
FIG. 4B is an operating state diagram showing that the seismic equipments are held in a center through a pair of central holding elastic members in a power transmission switchboard equipped with an earthquake-proof apparatus according to the present invention; And
5 is a configuration diagram showing the configuration of the above-described earthquake-proof apparatus in a switchboard provided with a earthquake-proof apparatus according to the present invention.

Hereinafter, embodiments of the present invention in which the above object can be specifically realized will be described with reference to the accompanying drawings. In describing the embodiments, the same names are denoted by the same reference numerals, and further description thereof will be omitted below.

2 is a sectional view showing a part of the lower portion of a housing 20 of a power transmission and distribution system equipped with the earthquake-proof apparatus 1 according to the present invention at a normal time when an earthquake does not occur. Sectional view showing a part of a lower portion of a housing 20 of a power transmission / 4A is an operational state diagram showing that the seismic device 1 is out of the center in the switchgear equipped with the seismic device 1 according to the present invention, and FIG. 4B is a seismic device 1 according to the present invention. In the equipped switchgear, it is an operation state diagram showing that the earthquake-resistant device 1 is maintained through a pair of center holding elastic body 92, Figure 5 is provided with a seismic device 1 according to the present invention It is a block diagram which shows the structure of the said earthquake-proof apparatus 1 in the switchgear.

As shown in FIG. 2, the switchgear equipped with the seismic device 1 according to the present invention has a lower support part 30 which is located at a lower part of the seismic device 1 and is fixedly coupled to the ground surface 10. ) And the upper support part 50, which is fixedly coupled to the lower part of the enclosure 20 of the switchgear including various electric devices therein, and is in contact with the upper support part 50, which is in contact with the upper support part 50. Movable part 40 for supporting 50, a plurality of lower elastic supports 90 for elastically supporting the movable part 40, a pair of side cylinders for fixing or releasing the movable part 40, and an upper cylinder It is comprised including the part 80.

2 and 3, the lower surface of the lower support 30 is fixedly coupled to the ground surface 10 and the accommodation space 31 for accommodating the movable part 40 is provided inside the lower support 30 . The lower support part 30 can be firmly fixed to the ground surface 10 through an anchor (not shown) or the like and can be fixed to a rectangular box Box) shape.

As shown in FIG. 2, the movable part 40 is provided in the accommodation space 31 inside the lower support part 30 so as to be supported by a plurality of lower elastic support bodies 90 so as to be movable up and down. A pair of side cylinder portions 70 and an upper cylinder portion 80 are provided in the left and right side rooms and the upper side of the movable portion 40. Each of the cylinder portions is moved The movable part 40 is fixed or released according to the rotation of the movable part 40.

Referring to the fixing and de-locking method for the movable portion 40 of each cylinder portion, as shown in Figures 2 and 3, the pair of side cylinder portion 70, each cylinder body to the lower support portion 30 The inner and outer spaces provided on the left and right inner surfaces of the upper and lower surfaces of the movable assembly 40 to be fixedly coupled to each other. When the earthquake does not occur normally, the transfer ram 71 of the cylinder portion at the opposite position of the locking groove is projected to be inserted into the locking groove so that the left and right sides of the movable part 40 are fixed. When the earthquake occurs, the transfer ram 71 of the protruding cylinder portion is transferred into the cylinder body to be separated from the locking groove, thereby releasing the left and right sides of the movable part 40.

In addition, the upper cylinder portion 80 is fixed to the inner body of the installation space 60 provided on the central inner surface of the upper support portion 50, the movable portion facing the upper cylinder portion 80 ( In the center of the outer surface of the 40 to form a locking groove, when the earthquake does not occur normally, the transfer ram 81 of the cylinder in the opposite position of the locking groove is projected to be inserted into the locking groove to be coupled, the movable portion The center portion 40 is fixed so as not to move left and right, and in the event of an earthquake, the movable ram 40 of the protruding cylinder is transferred into the cylinder body to be separated from the locking groove, thereby allowing the movable part 40 to be separated. Unlock the central part so that it can be moved left and right.

The lower portion of the movable part 40 is provided with a plurality of lower elastic support 90 at a predetermined interval from each other to elastically support the movable part 40, when the movable part 40 is released from the earthquake, The movable part 40 is elastically supported to attenuate the shock transmitted to the movable part 40 up and down.

In addition, the lower surface of the upper support 50 is in contact with the upper surface of the movable portion 40 is provided to be supported by the movable portion 40 and to slide in contact with the upper surface of the upper support 50 The upper portion of the housing 20 of the switchgear is fixedly coupled. 2 and 3, a Teflon coating layer 91 is formed on an upper surface of the movable portion 40 or a lower surface of the upper support 50, respectively, so that the movable portion 40 is formed. The upper support portion 50 can be easily moved left and right by sliding the upper surface of the movable portion 40 with a low frictional force when releasing the lock. As shown in FIGS. 4A and 4B, one end of the lower support portion The center retaining elastic body 92 fixedly coupled to the inner side of the 30 and the other end fixedly coupled to the outer side of the upper support 50 opposite to the left is symmetrically centered about the center of the upper support 50. By providing the right pair, the center holder is provided on the left and right sides of the upper support part 50 when the movable part 40 is released and the upper support part 50 moves left and right of the upper side of the movable part 40. The upper support part 50 is centered by the elastic force of the elastic body 92. It is automatically reconfigured so that it can be centered.

In addition, as shown in Figure 5, the earthquake measurement sensor unit 93 for measuring the occurrence of earthquake, and when receiving a signal from the earthquake measurement sensor unit 93, each of the normal and earthquake occurrence, such as when the earthquake does not occur An additional earthquake occurs by further configuring a controller 94 for outputting a control signal according to a situation to the pair of side cylinder parts 70 and the upper cylinder part 80 to fix or release the movable part 40. In addition to normal operation as well as in case of an earthquake, automatic operation ensures safe and easy switchgear support.

In the switchgear equipped with the seismic device 1 according to the present invention, the operation of the seismic device 1 will be described in more detail, and in normal times when an earthquake does not occur, as shown in FIGS. 2 and 5, An earthquake-free signal is input from the seismic measurement sensor unit 93 to the controller 94, and the controller 94, which receives the earthquake-free signal, receives the pair of side cylinder parts 70 and an upper cylinder part ( And a pair of side cylinder portion 70 and an upper cylinder portion 80 receiving the control operation signal to move forward the transfer rams 71 and 81 of the respective cylinder portions. Each of the transfer rams 71 and 81 is fitted into the engaging grooves of the opposing movable portions 40 to fix the movable portions 40, and the movable portions 40 are fixed through the fixing of the movable portions 40. The upper support part 50 and the switchgear panel provided in contact with the upper surface The sieve 20 is firmly fixed and supported.

Preferably, as shown in FIG. 2, the plurality of points at which the transfer rams 71 of the pair of side cylinder portions 70 are fitted into the engaging grooves of the movable portions 40 to be opposed to each other are coupled to each other. When the seismic body provided in the lower elastic support 90, generally the coil spring, when the seismic device 1 is first installed, it can be formed at the same height as the length, even if the earthquake-free usual times last longer The lower elastic support 90 minimizes the deterioration of the elastic force due to the long-term maintenance of the compression or extension state, and when the intermittent earthquake occurs, the lower elastic support 90 is the original elastic force at the time of the installation, the up and down vibration Can be effectively attenuated.

In addition, when an earthquake occurs, as shown in FIG. 3, an earthquake generation signal is input from the earthquake measurement sensor unit 93 to the controller 94, and the controller 94 receiving the earthquake generation signal receives the pair. It outputs a control operation signal to the side cylinder portion 70 and the upper cylinder portion 80 of the, each cylinder portion receiving the control operation signal is fitted into each engaging groove 41 of the opposing movable portion 40 The movable rams 71 and 81 are moved to separate and separated from each of the coupling grooves 41, thereby releasing the movable part 40, and the plurality of lower elastic supports provided at the lower part of the movable part 40. The upper support portion 50, which is movable up and down while being elastically supported by the 90, and which is provided in contact with the upper side surface of the movable portion 40, also slides along the upper side surface of the movable portion 40. It becomes movable.

Preferably, in the control operation signal output time of the controller 94 which receives the earthquake signal from the earthquake measurement sensor unit 93 and outputs the control operation signal to the respective cylinder units, when the initial earthquake signal is received, the control is immediately performed. Instead of outputting the operation signal to each cylinder part, the control operation signal is output to each cylinder part only when a predetermined delay time is input from the user and the earthquake generation signal is continuously input beyond the predetermined delay time. This prevents invalid seismic operation caused by the slight vibration generated during the initial moment.

When the earthquake occurs, the movable portion 40 is released from the fixed portion and is movable upward and downward, and the upper support portion 50 is freely movable left and right along the upper surface of the movable portion 40, It is possible to minimize the transmission of vibrations or shocks due to earthquakes to the housing 20 of the switchgear fixedly coupled to the upper surface of the support portion 50.

As described above, the switchgear with the earthquake-proof apparatus 1 according to the present invention can omit a high-capacity, high-priced vacuum apparatus required for forming a vacuum state for conventional fastening and fixing, It is possible to securely fix the housing 20 of the power transmission /

It is possible to firmly and firmly support the switchboard housing 20 in a stable manner even if the normal period of time without occurrence of the earthquake continues for a long period of time and the cost required for maintenance and repair of the earthquake-

In addition, the plurality of lower elastic supports 90, generally coils, a point at which the transfer rams 71 of the pair of side cylinder portions 70 are fitted into and engaged with the respective engaging grooves of the movable portions 40 facing each other. When the seismic device 1 of the spring is first installed, it is formed at the same height point as the length, so that the original elastic force at the time of installation can be maintained as usual without degrading the elastic force of the lower elastic support 90, so that the seismic wave can be smoothly generated when an earthquake occurs. It can be absorbed, and by minimizing the shock transmitted to the enclosure 20 of the switchgear panel can effectively prevent damage accident of the switchgear caused by the earthquake.

It is to be understood by those skilled in the art that the present invention may be embodied in many other forms without departing from the spirit and scope of the invention,

Accordingly, the above-described embodiments are to be considered illustrative and not restrictive, and all embodiments within the scope of the appended claims and their equivalents are intended to be included within the scope of the present invention.

1: Seismic device 10: Earth surface
20: Switchboard enclosure 30: Lower support
31: accommodating space part 40: moving part
41: coupling groove 50: upper support
60: installation space 70: side cylinder part
71: Feed ram 80: Upper cylinder part
81: upper cylinder transfer ram 90: lower elastic support
91: Teflon coating layer 92: centering elastomer
93: seismic measurement sensor 94: controller

Claims (3)

A seismic transducer equipped with an earthquake-resistant device provided at a lower portion of a housing (20) of a switchboard for absorbing seismic waves introduced from the ground surface (10) to attenuate vibration or shock of the seismic waves transmitted to the enclosure (20)

A lower support 30 fixedly coupled to the ground surface 10 and having a receiving space 31 therein;
A movable part 40 provided in the accommodation space 31 so as to be movable up and down;
A pair of side cylinder parts 70 provided at both left and right sides of the accommodation space 31 to fix or release the movable part 40;
A plurality of lower elastic supports 90 provided below the accommodating space 31 at predetermined intervals to elastically support the movable part 40;
An upper support portion 50 fixedly coupled to a lower portion of the housing 20 of the switchboard and having a lower surface formed to be slidable in contact with the upper surface of the movable portion 40; And
The upper switch unit is provided in the center of the upper support portion 50, the upper cylinder portion 80 for fixing or releasing the movable portion (40).
The method of claim 1,
A switchgear equipped with a seismic device (1), characterized in that the Teflon coating layer 91 is formed on the upper surface of the movable part 40 or the lower surface of the upper support part 50.
3. The method according to claim 1 or 2,
An earthquake measurement sensor unit 93 measuring an earthquake occurrence;
When receiving a signal according to whether an earthquake occurs from the seismic measurement sensor unit 93, and when receiving a normal signal from which the earthquake does not occur from the seismic measurement sensor unit 93, the pair of side cylinder portion 70 And the control signal to the upper cylinder portion 80 to fix the movable portion 40,
When receiving an earthquake generating signal from the seismic measurement sensor 93, the controller for inputting a control signal to the pair of side cylinder portion 70 and the upper cylinder portion 80 to release the movable part 40 fixed (94); the switchgear is provided with a seismic device (1), characterized in that it further comprises.

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