KR102234397B1 - The distributing board with smart earthquake-proof diminution device - Google Patents

Abstract

The present invention is configured such that the four horizontal elastic blocks are in inclined surface contact with the lower four surfaces of the vertical elastic block, so that when the vertical elastic block vertically descends when a seismic wave occurs, the vertical elastic block is elastically supported in the process of pushing the horizontal elastic block. Provides a switchboard with a smart seismic damping device that can effectively respond to strong seismic waves, attenuates the vibration of seismic waves when an earthquake occurs, and supports the switchboard safely and reliably.

Description

The distributing board with smart earthquake-proof diminution device}

The present invention relates to a switchboard having a smart seismic attenuation device, and more particularly, to a switchboard having a smart seismic damping device that can support the switchboard safely and reliably by attenuating the vibration of seismic waves when an earthquake occurs.

In general, in collective power demanding places such as schools, buildings, apartment complexes, factories, etc., it is a number that receives the extra high voltage of 6600V or more and 22900V class supplied from the substation to obtain the power each needs and transforms it into a commercial voltage of 380V or 220V. Substation facilities are provided, and electrical facilities such as heavy electricity, switch devices, and other safety devices are installed inside the enclosure to construct a switchboard that controls the power supply, mainly heavy electric devices having a sense of weight are arranged.

In particular, the automatic load transfer switch (ALTS) used for automatic load switching between heavy electricity or main line and spare line to transform extra high voltage, instrument transformer (MOF) that converts high voltage/high current into low voltage/small current, vacuum Circuit breakers (VCBs) are representative heavy electric machines.

On the other hand, since the switchboard consisting of these components is fixedly installed on the ground, deformation may occur in the enclosure provided in the switchboard due to vibration of the seismic wave when an earthquake occurs, or various electric devices installed inside the switchboard may be damaged. There is a problem that it may fall, and as a result, it is not possible to stably supply power to a place where power is needed, and there is a problem that may cause an electric shock accident or the like due to a short circuit.

As a prior art for solving the above problems, the Korean Intellectual Property Office Registered Patent Publication No. 10-1810334 and No. 10-1749152 may be exemplified.

In the seismic isolator of the prior art, a vibration isolating rubber pad is generally used.

However, the seismic isolator of the prior art depends only on the tensile and compressive strength of the vibration-proof rubber pad when seismic waves are generated, and as it is a structure that absorbs shock, the material of rubber has limitations. There is a disadvantage in that it cannot effectively respond to safety accidents such as the loss of function and the switchboard overturns.

Document 1: Korean Intellectual Property Office Registered Patent Publication No. 10-1469164 Document 2: Korean Intellectual Property Office Registered Patent Publication No. 10-1810334 Document 3: Korean Intellectual Property Office Registered Patent Publication No. 10-1749152

Accordingly, an object of the present invention for solving the above-described problems is to make at least one horizontal elastic block inclined surface contact with the outer surface of the vertical elastic block and to support the vertical elastic block, so that the elastic force of the vertical elastic block itself when seismic waves occur. In addition, it is to provide a switchboard having a smart seismic attenuation device that allows the horizontal elastic block to support the vertical descending motion of the vertical elastic block so that it can effectively respond to strong seismic waves.

Another object of the present invention is to provide a switchboard having a smart seismic damping device capable of adjusting the supporting force of a horizontal elastic block supporting a vertical elastic block according to an increase or decrease in the number of pads for compression control.

Another object of the present invention is to provide a switchboard having a smart seismic damping device capable of adjusting the support force of the horizontal elastic block supporting the vertical elastic block by separably inserting at least one pressing wedge in the center of the horizontal elastic block. Is in.

Another object of the present invention is to provide a switchboard having a smart seismic damping device in which a leaf spring is installed at the rear of the horizontal elastic block to support the horizontal elastic block elastically.

The present invention for achieving the above objects is a switchboard having a smart seismic attenuation device installed on the bottom surface of the chassis of the switchboard to attenuate vertical vibration in the event of an earthquake, the smart seismic damping device as a frame installed on the ground, A lower frame comprising a lower plate constituting a floor and a lower side plate integrally provided on both sides of the upper surface of the lower plate to form a space between the lower side plates, and a lower frame that can be moved up and down on the lower frame. As a frame, the upper frame is integrally provided in a state that is vertically erected on both sides of the lower side of the upper plate and is formed of an upper side plate positioned outside the lower side plate of the lower frame, and a head fixed by welding to the center of the upper surface of the lower plate of the lower frame The upper and lower frames are fastened with double nuts to the corners of the bottom surface of the case while passing through the hole in the center of the upper plate of the upper frame overlapped on the upper surface of the lower frame and being exposed to the outside of the upper plate. A bolt composed of a body portion to be fixed to the surface, is accommodated in the space of the lower frame and is molded in a rectangular parallelepiped shape of a material having elasticity, and a flange portion in contact with the inner surface of the upper frame is extended on the upper surface, and four A guide hole through which the bolt passes through is formed in the center of the inclined surface portion, such as a vertical elastic block vertically descending the bolt by a guide in the process of elastically absorbing the vibration transmitted to the housing, and the vertical elastic block. It is made of a material having elasticity, and four are arranged along the inclined surface portion formed on the outer, left, and right bottom outer edges of the vertical elastic block, and the inclined surface portions for surface contact with the inclined surface portion of the vertical elastic block are each It is formed and is pushed in the horizontal direction according to the vertical descent of the vertical elastic block and is installed on the outer surface of the horizontal elastic block and the horizontal elastic block for elastically supporting the vertical elastic block, and elastically supporting the horizontal direction push of the horizontal elastic block. A plate spring, a compression adjustment space formed in the center of the horizontal elastic block, the Consisting of at least one compression adjustment pad fitted in the compression adjustment space, the horizontal elastic block is divided into two with the compression adjustment space interposed therebetween, as the number of the compression adjustment pads fitted into the compression adjustment space increases. The horizontal elastic block located inside the compression adjustment space is pushed out to increase the compression force with the vertical elastic block, and the horizontal elastic block located outside the compression adjustment space is pushed out and increases the compression force of the leaf spring. Among the four horizontal elastic blocks, the horizontal elastic blocks located on the left and right sides of the vertical elastic blocks are elastically supported by plate springs on the lower side plates installed on both sides of the lower frame. , It is characterized in that it is configured to be elastically supported by the plate spring on the locking plate in a state in which locking plates are provided in front and rear of the lower plate of the lower frame on the rear surface of the horizontal elastic block located at the rear.

Leadscrews installed in front and rear of the upper and lower frames and having an outer diameter threaded, nuts screwed to the outer diameter of the leadscrews, connecting plates coupled to the nuts and extending to the connecting plates, and pressing It is preferable that a pressing means composed of an arm for pressing the pressing type wedge in contact with the upper end of the type wedge is further installed.

The smart seismic damping device of the present invention is configured so that the four horizontal elastic blocks are in inclined surface contact on the lower four surfaces of the vertical elastic block, and the horizontal elastic block is configured to be elastically supported by the leaf spring, so that the vertical elastic block can vertically descend when a seismic wave occurs. At this time, the vertical elastic block is elastically supported in the process of being pushed out, so that it can effectively respond to strong seismic waves.

In addition, by separably inserting at least a pressing wedge in the center of the horizontal elastic block, it is possible to adjust the compression force between the vertical elastic block and the horizontal elastic block, so that it has the effect of increasing the support of the switchboard in the area where a large earthquake occurs.

1 is a view showing the configuration of a switchboard having a smart seismic attenuation device according to the present invention.
Figure 2 is a diagram showing a three-dimensional disassembled by extracting the configuration of the smart seismic attenuation device of Figure 1;
Figure 3 is a cross-sectional view of Figure 2;
Figure 4 is a plan view of Figure 3;
Figure 5 is a view showing the operation state of the smart seismic damping device.
6 is a diagram showing the configuration of a power distribution having a smart seismic attenuation device according to a second embodiment of the present invention in three dimensions.
Figure 7 is a cross-sectional view of Figure 6;
Figure 8 is a three-dimensional view of the combination of the smart seismic damping device in which the pressing means is installed in Figure 6.
Figure 9 is a front view of Figure 8;
10 is an operation state diagram of FIG. 7.
11 is a view showing the configuration of an earthquake detection device for detecting an earthquake in the switchboard installed with the smart seismic attenuation device of the present invention.

1 is a view showing the overall structure of a switchboard having a smart seismic attenuation device according to a first embodiment of the present invention.

The switchgear shown in FIG. 1 accommodates various components constituting the heavy electric machine and the switchboard, and constitutes an external appearance of a case 200 with a door installed on the front side.

The bottom surface 210 supporting the enclosure 200, preferably, the smart seismic attenuation device 100 proposed in the present invention is installed at a predetermined distance apart from the bottom surface of the enclosure with the same structure.

2 is a diagram showing a three-dimensional exploded view of the configuration of the smart seismic damping device of Figure 1, Figure 3 is a cross-sectional view of Figure 2, Figure 4 is a plan view of Figure 3, Figure 5 It is a diagram showing the operation state of the smart seismic damping device.

As shown in FIGS. 2 to 5, the smart seismic attenuation device 100 includes upper and lower frames 10 and 20, support bolts 30, and vertical and horizontal elastic blocks 40 and 50.

The lower frame 20 is a frame directly installed on the ground, and consists of a lower plate 22 constituting the floor, and a lower side plate 24 integrally provided in a state vertically erected on both sides of the upper surface of the lower plate 22 In addition, a space 28 is formed between the lower side plate 24 so that the seismic isolation bearing 50 can be installed.

The upper frame 10 is a frame that can be moved up and down on the lower frame 20, and the upper side plate 14 is integrally provided in a state vertically erected on both sides of the upper plate 12 and the lower surface of the upper plate 12, respectively. ).

Between the upper side plate 14 of the upper frame 10, the lower side plate 24 of the above-described lower frame 20 is inserted, and preferably, the lower frame when assembling the upper and lower frames 10 and 20 The upper and lower frames 10 and 20 are assembled with each other in a state in which the lower side plate 24 of 20 is located on the inner surface of the upper side plate 14 of the upper frame 10, respectively.

When the upper and lower frames 10 and 20 are transmitted to the enclosure 200 when an earthquake occurs, the upper frame 10 can flexibly flow up and down while supporting the enclosure 200 so that the vibration is reduced. It is to be effectively transmitted to the vertical and horizontal elastic blocks sandwiched between the upper and lower frames 10 and 20.

The bolt 30 is a means for fixing the upper and lower frames 10 and 20 to the corners of the bottom surface of the enclosure 200 and guiding the vertical elastic block 40 to move up and down. The head 32 of the bolt 30 is fixed to the center of the upper surface of the lower plate 22 of the lower frame 20 by welding, and the body part 34 of the bolt 30 is Screw in the corner of the bottom surface 210 of the enclosure 200 in a state that passes through the hole 16 in the center of the top plate 12 of the upper frame 10 and is exposed to the outside of the top plate 12 It is fastened with a double nut 36 in the coupled state in a manner, and the upper and lower frames 10 and 20 are fixed to the bottom surface 210 of the enclosure 200.

The vertical elastic block 40 and the horizontal elastic block 50 are injection-molded of a material having elasticity to perform a seismic isolation function to attenuate the transmission of vibration to the enclosure 200 when an earthquake occurs. It is inserted into the space provided between the frames 10 and 20.

In the following, the assembly structure of the vertical elastic block 40 and the horizontal elastic block 50 will be described.

As shown in Figs. 2 to 4, the vertical elastic block 40 has a rectangular parallelepiped shape, and the upper surface is formed with a flange portion 42 that contacts the inner surface of the upper frame 10, and an inclined surface portion 44 is formed outside the lower surface. It is formed to be inclined at an angle.

The inclined surface portion 44 is formed to be inclined toward the center of the vertical elastic block 40 from top to bottom based on the cross-section of the vertical elastic block 40.

In the center of the vertical elastic block 40, a guide hole 46 is vertically penetrated, and the bolt 30 penetrates through the guide hole 46 so that the vertical elastic block 40 is formed when seismic waves are generated. When descending, the vertical elastic block 40 is guided to move vertically and vertically without being distorted.

The vertical elastic block 40 described above is elastically contracted by the vibration transmitted to the housing 200 when an earthquake occurs in a state where the housing 200 is supported at a certain distance from the ground, and at the same time, it is vertically lowered by riding the bolts 30. And attenuates the vibration transmitted to the enclosure 200.

Meanwhile, as shown in FIG. 5, at least one or more contraction grooves 48 may be further formed at a predetermined distance apart from the outer diameter of the vertical elastic block 40.

The contraction groove 48 of the vertical elastic block 40 allows the contraction groove 48 to contract when vibration is transmitted to the vertical elastic block 40 when an earthquake occurs, so that the vertical elastic block 40 is self-contained in addition to the material characteristics. It is possible to increase the canceling effect of vibration by making it possible to absorb some of the shocks. In addition, it is preferable that a spring 49 for elastically supporting the descending of the vertical elastic block 40 is further installed under the vertical elastic block 40.

The horizontal elastic block 50 is a block disposed along the lower outer outer surface of the vertical elastic block 40 and elastically supports the downward motion of the vertical elastic block 40.

The horizontal elastic block 50 has the same structure and has four structures along the lower circumference of the vertical elastic block 40, that is, the same structure in the front, rear, left and right directions based on the vertical elastic block 40. Each of the horizontal elastic blocks 50 is installed.

When explaining the assembly structure of one horizontal elastic block 50 and vertical elastic block 40, the horizontal elastic block 50 is placed on the upper surface of the lower plate 22 of the lower frame 20, and the inclined surface 52 ) Is formed. When the inclined surface portion 52 of the horizontal elastic block 50 is in surface contact with the inclined surface portion 42 of the vertical elastic block 40 described above, when the vertical elastic block 40 vertically descends due to vibration during an earthquake, The horizontal elastic block 50 is pushed in the horizontal direction through the inclined surface portions 42 and 52 in contact, and elastically supports the vertical descending motion of the vertical elastic block 40.

A leaf spring 54 is installed on the rear surface of the horizontal elastic block 50. The leaf spring 54 elastically supports the horizontal elastic block 50 being pushed in the horizontal direction.

The leaf spring 54 is installed on the rear of the four horizontal elastic blocks 50, and at this time, the leaf spring installed on the rear of the two horizontal elastic blocks 50 located on both sides of the lower end of the vertical elastic block 40 ( 54) is to be supported by the lower side plate 24 provided on both sides of the lower plate 22 of the lower frame 20.

And the plate spring 54 installed on the rear of the two horizontal elastic blocks 50 located at the bottom front and rear of the vertical elastic block 40 further provides a separate locking plate 26 on the lower frame 20, and It is configured to be supported on the locking plate 26.

Meanwhile, a compression adjustment space 156 is formed in the center of the horizontal elastic block 50, and at least one compression adjustment pad 160 is fitted in the compression adjustment space 156. The horizontal elastic block 50 is divided into two with the compression adjustment space 156 interposed therebetween, and at this time, the horizontal elasticity according to whether the number of compression adjustment pads 160 fitted into the compression adjustment space 156 increases. Blocks 50 are each open to the outside with the space for compression adjustment 156 interposed therebetween, and at this time, the horizontal elastic block 50 is more strongly adhered to the vertical elastic block 40 in the process of being pushed outward and at the same time the plate By compressing the spring 54 more strongly, the elastic force is maximized.

That is, as the number of compression adjustment pads 160 fitted into the compression adjustment space 156 increases, the compression force of the horizontal elastic block 50 supporting the vertical elastic block 40 increases, thereby resiliently resisting stronger vibrations. I can.

On the other hand, among the horizontal elastic blocks 50, the horizontal elastic blocks 50 located on the left and right of the vertical elastic block 40 are plate springs on the lower side plates 24 installed on both sides of the lower frame 20. The horizontal elastic block 50 positioned at the front and rear of the vertical elastic block 40 is provided with a separate locking plate 26 and a plate spring is attached to the locking plate 26 to be elastically supported by 54. It is configured to be elastically supported by (54). The locking plate 26 is provided at the front and rear of the lower plate 22 of the lower frame 20.

The smart seismic attenuation device having such a structure is installed in the same structure along the outer edge of the bottom surface 210 of the housing 200 of the switchboard to support the switchboard.

On the other hand, when vertical vibration is transmitted to the housing 200 when the support is generated, the vertical elastic block 40 primarily absorbs the shock caused by the vibration while supporting the weight of the housing 200 as shown in FIG. 5. That is, the vertical elastic block 40 first attenuates vibration by an elastic force due to its own material, and also absorbs more vibration in the process of contracting the contraction groove 48 formed on the outer surface of the vertical elastic block 40.

In addition, the vertical elastic block 40 performs a vertical lowering operation while riding the bolt 30 in the process of being pressed together with its own vibration absorption. At this time, the inclined surface formed on the lower outer surface of the vertical elastic block 40 The horizontal elastic block 50 in surface contact with the part 42 is pushed in the horizontal direction according to the vertical lowering motion of the vertical elastic block 40 while elastically supporting the vertical elastic block 40, At this time, the plate spring 54, which elastically supports the horizontal elastic block 50, is compressed and elastically supports the vertical descending motion of the vertical elastic block 50, and absorbs the vibration generated by the earthquake during this process, and the enclosure 200 Will be safeguarded.

On the other hand, when it is desired to support strong vibrations with the smart seismic damping device of the present invention in areas where large earthquakes frequently occur, it is necessary to improve the supporting force of the vertical elastic block 40 (that is, the force supporting the enclosure 200). In this case, if the number of the compression adjustment pads 160 fitted into the compression adjustment space 156 of the horizontal elastic block 50 is increased, the horizontal elastic blocks 50 interposed between the compression adjustment space 156 Among them, the horizontal elastic block 50 located inside the compression adjustment space 156 is spread outward and is compressed to apply to the vertical elastic block 40, and, on the contrary, a horizontal elastic block located outside the compression adjustment space 156 (50) spreads outward and increases the compressive force of the leaf spring 54, so that the vertical elastic block 40 receives a higher pressure from the horizontal elastic block 50, so that it is subjected to strong vibration transmitted to the enclosure 200. You can resist.

FIG. 6 is a three-dimensional view showing the configuration of a water distribution with a smart seismic attenuation device according to a second embodiment of the present invention, FIG. 7 is a cross-sectional view of FIG. 6, and FIG. 8 is a pressurizing means installed in FIG. It is a combined three-dimensional view of the smart seismic damping device, Figure 9 is a front view of Figure 8, Figure 10 is an operation state diagram of Figure 7.

6 to 10, the switchboard having a smart seismic damping device according to the second embodiment of the present invention is a lower frame consisting of a lower plate 22 and a lower side plate 24 as in the first embodiment. 20), an upper frame 10 composed of a top plate 12 and a top plate side plate 14, a bolt 30, a vertical elastic block 40, four horizontal elastic blocks 50, and the four horizontal elastic blocks 50 ), each supporting four leaf springs 54, but without inserting a compression adjustment pad in the compression adjustment space 56 of the horizontal elastic block 50, the first and second support wedges 58, 60 ), a pressing wedge 64 and a pressing means 80 for pressing the pressing wedge 64 are installed.

The horizontal elastic block 50 is provided with a compression adjustment space 56, and the compression adjustment space 56 has two first and second support wedges 58 and 60, and the first and second support wedges. It has a structure in which the push-type wedge 64 is fitted in a wedge manner between (58, 60).

A space 62 having a "V" shape in cross section is provided between the first and second support wedges 58 and 60, and a pressing wedge 64 is fitted in the space 62 in a wedge manner. At this time, the upper end (64a) of the pressing wedge 64 is configured to be fitted in a state protruding a predetermined distance from the top surfaces of the first and second supporting wedges 58, 60, and the arm 88 of the pressing means 80 It is configured so that the pressing wedge 64 can be pressed according to the pressure of.

The shape of the push-type wedge 64 is also molded into a "V" shape to correspond to the space 62 of the first and second support-type wedges 58, 60, and presses the push-type wedge 64 from above. Depending on the pressure, the first and second supporting wedges 58 and 60 are made to open outward. At this time, the first support wedge 58 pushes the horizontal elastic block 50 located inside the compression adjustment space 56 to press the horizontal elastic block 50 to the vertical elastic block 40, and vice versa. The two support wedge 60 pushes the horizontal elastic block 50 located outside the compression adjustment space 56 to compress the plate spring 54 to maximize the elastic force.

That is, as the pressure pressing the pressing wedge 64 increases, the pressing force of the horizontal elastic block 50 supporting the vertical elastic block 40 increases, so that it is possible to elastically resist stronger vibrations.

Among the horizontal elastic blocks 50, the horizontal elastic blocks 50 located on the left and right of the vertical elastic block 40 are provided on the lower side plates 24 installed on both sides of the lower frame 20. ) To be elastically supported, and the horizontal elastic block 50 positioned at the front and rear of the vertical elastic block 40 is provided with a separate locking plate 26 and a plate spring ( 54) is configured to support elasticity. The locking plate 26 is provided at the front and rear of the lower plate 22 of the lower frame 20.

The operation of the push-type wedge 64 and the first and second support-type wedges 58, 60 is the supporting force of the vertical elastic block 40 according to the strong vibration due to a large earthquake (that is, supporting the enclosure 200). To increase the force), when pressing the push-type wedge 64 accommodated in the compression adjustment space 56 of the horizontal elastic block 50, the push-type wedge 64 is in close contact with both sides of the push-type wedge 64 in a wedge manner. The first and second pedestal wedges (58, 60) are each widened outward in the horizontal direction, and at this time, the first pedestal wedge (58) pushes the horizontal elastic block (50) and the horizontal elastic block (50). Is compressed to the vertical elastic block 40, and on the contrary, the second supporting wedge 60 compresses the leaf spring 54 to maximize the compressive force of the leaf spring 54. That is, the vertical elastic block 40 receives a higher pressure from the horizontal elastic block 50 by the pressing of the pressing pad 64 as described above, so that it can resist strong vibration transmitted to the enclosure 200.

Meanwhile, the pressing means 80 is a device provided to easily press the pressing wedge 64 from the outside in order to increase the pressing force of the horizontal elastic block 50.

The pressing means 80 is provided at the front and rear of the upper and lower frames 10 and 20, respectively, and a plurality of lead screws 82 having a screw thread 82a formed therein as an outer diameter, and a screw on the outer diameter of the lead screw 82 The connection plate is formed extending from the nut 84 coupled to the nut 84, the connection plate 86 coupled to the nut 84, and the connection plate 86 and in contact with the upper end of the pressing wedge 64 It descends by the operation of (86) and consists of an arm (88) that presses the push-type wedge (64).

That is, when the lead screw 82 is rotated, the nut 84 screwed to the outer diameter of the lead screw 82 performs a lowering operation, and the nut 84 and the connecting plate ( The arm 88, which is connected by 86), performs a lowering operation and presses the push-type wedge 64.

The pressing wedge 64 pressed by the operation of the arm 88 spreads the first and second support wedges 58 and 60 outward, thereby increasing the compression force between the horizontal elastic block 50 and the vertical elastic block. Will be ordered.

On the other hand, in the switchgear in which the smart seismic isolator described in the first and second embodiments of the present invention is installed, an earthquake detection device for transmitting vibration in real time to a control room or the like when an earthquake occurs is further installed.

As shown in FIG. 11, the seismic detection device includes an MCU as a control means, an industrial PC that is connected to the MCU and a usb converter to display the seismic wave data of the waveform sent from the MCU in real time on a monitor, and the earthquake is connected to the MCU. It includes an earthquater sensor that detects and an acidometer sensor that enables the control unit to specifically express the input seismic wave as a waveform in an industrial PC.

The seismic detection device of the above configuration detects an earthquake by the earthquater sensor and transmits it to the MCU, and the MCU transmits the data in the state of converting the seismic wave into a waveform through the acidometer sensor to the industrial PC to detect the earthquake occurrence in real time in the control room. I made it possible to confirm.

10: upper frame 20: lower frame
22: lower plate 24: lower side plate
26: locking plate 30: bolt
40: vertical elastic block 44: inclined surface portion
46: hole 48: shrink groove
50: horizontal elastic block 52: inclined surface portion
54: leaf spring 56: space for compression adjustment
58: first supporting wedge 60: second supporting wedge
62: space 64: pressing wedge

Claims (3)

delete In the distribution board having a smart seismic damping device that is installed on the bottom surface 210 of the housing 200 of the distribution panel to attenuate the vibration in the vertical direction when an earthquake occurs,
The smart seismic attenuation device;
A frame installed on the ground, consisting of a lower plate 22 constituting the floor, and a lower side plate 24 integrally provided on both sides of the upper surface of the lower plate 22 in a vertically erected state. A lower frame 20 forming a space 28;
As a frame that can be moved up and down on the lower frame 20, the upper plate 12 and the lower side of the upper plate 12 are integrally provided in a vertically erected state, respectively, and the lower side plate of the lower frame 20 ( An upper frame 10 composed of an upper side plate 14 positioned on the outside of 24);
The head 32 fixed to the center of the upper surface of the lower plate 22 of the lower frame 20 by welding, and the hole in the center of the upper plate 12 of the upper frame 10 overlapped on the upper surface of the lower frame 20 ( 18) to be exposed to the outside of the upper plate 12, and fastened with a double nut 36 to the corner of the bottom surface 210 of the enclosure 200, and the upper and lower frames 10 and 20 are attached to the enclosure ( A bolt 30 composed of a body part 32 that is fixed to the bottom surface 210 of 200);
It is accommodated in the space 28 of the lower frame 20 and is formed in a rectangular parallelepiped shape of a material having elasticity, and a flange portion 42 contacting the inner surface of the upper frame 10 is extended on the upper surface thereof, and the lower outer frame The vertical elastic block 40 vertically descends in the process of elastically absorbing the vibration transmitted to the enclosure 200 by configuring the four inclined surface portions 44 to be formed;
A guide hole 46 formed through the center of the vertical elastic block 40 and allowing the bolt 30 to pass therethrough to guide a vertical downward motion of the vertical elastic block 40;
At least one or more contraction grooves 48 formed at predetermined intervals apart from the outer diameter of the vertical elastic block 40;
It is made of a material having the same elasticity as the vertical elastic block 40, and four are disposed along the inclined surface portion 44 formed on the outer, left, and right bottom edges of the vertical elastic block 40, and the inner surface thereof In the vertical elastic block 40, the inclined surface portion 52 for making surface contact with the inclined surface portion 44 is formed, and is pushed in the horizontal direction according to the vertical descending of the vertical elastic block 40, and the vertical elastic block ( Four horizontal elastic blocks 50 for elastically supporting 40;
Four leaf springs 54 installed on the outer surfaces of the four horizontal elastic blocks 50 and elastically supporting the horizontal elasticity blocks 50 in the horizontal direction;
A compression adjustment space 56 formed in the center of the horizontal elastic block 50;
First and second support wedges (58, 60) fitted into the compression adjustment space (56) and provided with a "V"-shaped space (62) at the center;
It has a "V" cross-sectional shape corresponding to the central space 62 of the first and second pedestal wedges 58, 60, and is a wedge method in the space 62 of the first and second pedestal wedges 58, 60 Consisting of a pressing wedge 64 to open the first and second supporting wedges 58 and 60 outward in the process of descending according to the external pressing pressure while being inserted into
The first support wedge 58 pushes the horizontal elastic block 50 located inside the compression adjustment space 56 to increase the compression force with the vertical elastic block 40, and the second support The mold wedge 60 pushes the horizontal elastic block 50 located outside the compression adjustment space 56 to increase the compressive force of the plate spring 54, so that the vertical elastic block 40 according to the strong vibration due to a large earthquake. ) To increase the support capacity;
Among the four horizontal elastic blocks 50, the horizontal elastic blocks 50 located on the left and right of the vertical elastic block 40 are plate springs on the lower side plates 24 installed on both sides of the lower frame 20. In the rear of the horizontal elastic block 50 located in front and rear of the vertical elastic block 40, it is elastically supported by 54, and a locking plate at the front and rear of the lower plate 22 of the lower frame 20 ( 26) is configured to be elastically supported by the plate spring 54 on the locking plate 26;
Between the upper and lower frames (10, 20), a pressing means (80) for pressing the pressing wedge (64) is installed;
The pressing means 80;
Leadscrew 82 installed at the front and rear of the upper and lower frames 10 and 20 and having a thread 82a having an outer diameter thereof;
A nut 84 screwed to the outer diameter of the leadscrew 82;
A connection plate 86 coupled to the nut 84 and;
It is formed extending from the connection plate 86 and configured with an arm 88 that presses the push-type wedge 64 in a state in contact with the upper end of the push-type wedge 64, thereby forming the push-type wedge 64. Power switchboard having a smart seismic damping device, characterized in that to increase the pressing force of the horizontal elastic block (50) by pressing. delete

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