KR102140115B1 - Structure equipment having check up part of leakage current - Google Patents

Abstract

The present invention relates to an earthquake-proof switchgear device having a checkup function of a leakage current. More particularly, the present invention relates to an earthquake-proof switchgear device having a checkup function of a leakage current which has a checkup function to check an occurrence of the leakage current, and has a double security device consisting of a first switching device and a second switching device in a structure to allow only professional management personnel to open and close the structure when it is equal to or greater than a setting value of a user, and prevent damage and the like due to vibrations generated from the outside such as earthquakes and the like.

Description

Seismic switchgear with leakage current detection function {Structure equipment having check up part of leakage current}

The present invention relates to an earthquake-proof switchgear device having a leakage current detection function in the field of water distribution technology, and more specifically, to provide a detection function to detect the generation of leakage current, the structure has a first opening and closing device and a second opening and closing device It is equipped with a double security device that is equipped with a leakage current detection function to prevent damage caused by vibrations generated from outside, such as earthquakes, while only a professional management personnel can open and close the structure if it is above the user's set value. It relates to a seismic switchgear device.

In general, structures are used at high voltages in a wide range of electricity consumers, such as residential areas (eg, apartments), buildings, schools, factories, ports, airports, water/sewage plants, substations, heavy industrial plants, subways, chemical complexes, and steel mills. It is installed in a water distribution system that converts power to low voltage and supplies it to the facility, and is used for power monitoring, control, and protection.

The conventional structure does not have a facility capable of monitoring the change of the leakage current at all times, and there is a hassle that a measurement auxiliary electrode is installed for each measurement and a measurement line must be installed to measure the leakage current.

In addition, the leakage current means a current flowing out of the converter, and if the leakage current continuously flows, the insulation state deteriorates rapidly.

The leakage current may be an instantaneous leakage current measured due to harmonics due to insulation damage or other causes.

In this case, safety accidents due to electric leakage may occur if wrong. In this case, only professional management personnel should check the abnormality of the structure, but safety accidents occur due to inspection by general management personnel.

As a conventional technology that partially improves these problems, Korean Patent Registration No. 10-1365258 (2014.02.20.) discloses an'impact sensing device for electrical facilities'.

However, such a conventional electrical facility has a problem in that an electric power failure or a fire may occur along with damage to the inside and outside of the electrical facility while failing to buffer vibrations generated from the outside.

Republic of Korea Patent Registration No. 10-1365258 (2014.02.20.)'Shock detection device for electrical facilities'

The present invention was devised to solve the above-mentioned problems, and an object of the present invention is to provide a detection function to detect the occurrence of leakage current, and to provide a structure of a double security device comprising a first opening and closing device and a second opening and closing device. It is to provide a seismic switchboard device equipped with a leakage current detection function to prevent damage caused by vibrations generated from outside, such as earthquakes, while locking the structure so that only professional management personnel can open and close the structure if the user exceeds the set value.

The problem to be solved of the present invention is not limited to those mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the following description.

In order to achieve the above object, the present invention is a leakage current detector (80) installed inside the structure (1); A control unit 60 connected to the leakage current detector 80; An earth leakage alarm (90) connected to the control unit (60); And first and second opening and closing devices 10 and 30 installed on the door 2 of the structure 1 and connected to the control unit 60, wherein the control unit 60 includes a control panel 70. And the short circuit alarm 90, the first and second opening and closing devices 10 and 30 are opened by the password input by the operation button of the control panel 70, and the leakage current detector 80 If the measured value at which the leakage current is detected exceeds the set value set by the user as a password in the control panel 70 as a dangerous value, the electric current is cut off after the electric leakage alarm in the electric leakage alarm 90, and the first and second The opening/closing devices 10 and 30 are operated to be in a locked state, and the first open/close device 10 if the measured value of the leakage current detected by the leakage current detector 80 does not exceed a value set by the user as a dangerous value Only is operated to be in a locked state, and when the short circuit alarm 90 is operated in the locked state of the first switchgear 10 and the first and second switchgears 10 and 30 are locked at the same time, professional management In the seismic switchgear device having a detection function of leakage current configured to open the door (2) only by an agent,

Further comprising a seismic portion 100 for cushioning vibrations transmitted from the outside to the structure 1, the seismic portion 100 is a plate 111 disposed on the ground so as to be located at the bottom of the structure (1) ), the support portion 110 including a plurality of piles 112 to prevent the plate 111 from being shaken or moved by vibrations generated from the outside while fixing the plate 111 to the ground; Leveling means 140 for adjusting the horizontal state of the structure (1); Installation means 150 for installing the pile 112 on the plate 111; And a storage box 160 for storing the installation means 150, wherein the horizontal adjustment means 140 is formed with a hollow 141a protruding outward from both sides of the structure 1 and penetrating in the vertical direction. Flange 141; A fastening ring 142 provided on an upper portion of the plate 111 so as to face the flange 141; A guide tube 143 extending upwardly from a circumference forming the hollow 141a and having guide holes 143a extending downwardly from the upper side on both sides; A lifting bar 144 rotatably coupled to the guide hole 143a so that both ends thereof protrude outward of the guide tube 143; The lower end is connected to the fastening ring 142, the upper end of the wire 145 wound on the lifting bar 144; A driving motor 146 that transmits rotational force to the lifting bar 144; A detachment preventing member 147 coupled to the outside of the guide tube 143 so as to be located on the upper portion of the elevating bar 144 to prevent the elevating bar 144 from falling off; While being coupled to the outside of the wire 145 so as to be positioned between the plate 111 and the flange 141, while protecting the wire 145, the spring 149 that cushions the shock while contracting and relaxing by external force Included, the flange 141 is provided with a horizontal system, the operator visually checks the horizontal state, controls the driving of the driving motor 146, and the plate 111, the front and rear ends of the structure (1) More protruding forward and backward, the pile 112 is coupled to the front and rear ends of the plate 111 so as to be located at the front and rear of the structure 1, fixing the plate 111 to the ground, In the groove portion 118 is formed, fastening holes 119 are formed on both sides constituting the groove portion 118, the installation means 150 is disposed on the top of the pile 112, the groove portion 118 ) Communicating with the installation bar 151 is formed in the hollow (151a); A guide bar 152 where both ends pass through both sides of the installation bar 151 and a central part is positioned in the hollow 151a; A binding member 153 for binding the guide bar 152 to the installation bar 151; A pair of press bars 154 which are movably coupled to the guide bar 152 in the longitudinal direction so as to be located in the hollow 151a, and formed with fastening projections 154a introduced into the fastening holes 119 at the bottom. ); A spring 155 coupled to the outside of the guide bar 152 to be positioned between the pair of press bars 154; And a handle bar 156 extending upwardly from both sides of the upper portion of the installation bar 151.

According to the present invention, when a danger of leakage current occurring at a value higher than the value set by the user occurs by detecting the leakage current at all times, only professional management personnel can open and close the door of the structure, thereby preventing safety accidents. It has an effect.

In addition, there is an effect that can prevent damage caused by vibration by buffering the vibration generated from the outside, such as an earthquake.

The effects of the present invention are not limited to those mentioned above, and other solutions that are not mentioned will be clearly understood by those skilled in the art from the following description.

1 is a perspective view showing a seismic switchgear device having a detection function for leakage current according to the present invention.
Figure 2 is a cross-sectional view showing the first and second switchgear in the seismic switchgear equipped with a detection function of the leakage current according to the present invention.
3 is a perspective view showing a state in which the first opening and closing device is locked in an earthquake-proof switchgear device having a detection function for leakage current according to the present invention.
4 is a perspective view showing a state in which the first opening and closing device is opened in the seismic switchgear device having the detection function of the leakage current according to the present invention.
5 is an exploded perspective view showing a first opening and closing device in an earthquake-proof switchgear equipped with a detection function for leakage current according to the present invention.
6 is a partial cross-sectional perspective view showing a second opening and closing device in an earthquake-proof switchgear equipped with a detection function for leakage current according to the present invention.
7 is a partial cross-sectional perspective view showing a state in which the second switchgear is locked in the seismic switchgear equipped with the detection function of leakage current according to the present invention.
8 is an operation flowchart showing an earthquake-proof switchgear equipped with a detection function for leakage current according to the present invention.
9 is a block diagram showing a control unit in an earthquake-proof switchgear equipped with a detection function for leakage current according to the present invention.
10 is a front cross-sectional view showing a state in which the anti-vibration part is provided in the seismic switchgear equipped with the detection function of the leakage current according to the present invention.
11 is a side cross-sectional view showing a support in FIG. 10.
12 is a partially enlarged view showing the horizontal adjustment means in FIG.
13 is an exploded perspective view showing a state in which installation means are installed on a pile in an earthquake-proof switchgear equipped with a detection function for leakage current according to the present invention.
14 is an exploded perspective view showing the installation means in FIG.
15 is a use state diagram showing the installation means in FIG.
And
16 is a front view showing a state in which the storage box is provided in FIG. 10.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings.

Referring to Figures 1 to 9, the seismic switchgear equipped with a detection function of the leakage current according to the present invention, the leakage current detector 80 is installed inside the structure 1 to always measure the leakage current, the leakage current detector ( 80) is connected to the control unit 60 and analyzes the detection value of the leakage current to configure different operations according to the set value above and below, and the door 2 of the structure 1 under the control of the control unit 60 Is configured to switch to the automatic lock state.

At this time, when a leakage current occurs, a dangerous situation is notified through an earth leakage alarm 90 connected to the control unit 60.

The structure 1 may be made of a water distribution box, etc., and a door 2 for opening and closing inside and outside is installed at one side, and in addition to the general opening and closing device for the door 2, the first opening and closing device 10 and the second opening and closing device ( 30) is additionally installed.

The first opening and closing device 10 and the second opening and closing device 30 are electrically connected to the control unit 60 and operated by a signal from the control unit 60.

The control unit 60 is connected to the control panel 70 and the ground fault alarm 90 as shown in FIG. 9, and the first opening/closing device 10 and the first opening/closing device 10 are controlled by a password input by the operation button of the control panel 70. Two opening and closing devices 30 are configured to open.

When setting the dangerous value of the leakage current in the control panel 70 as a set value, a password is input.

When the measured value of the leakage current detected by the leakage current detector (80) exceeds the set value set by the user as a dangerous value, the electric current is cut off by the leakage alarm (90) and the current is cut off. The two switchgears 30 are operated to be locked.

There are two levels of security for the first level and the second level, and the second locking device is opened only when a password consisting of a first level security level is entered.

If the leakage current detected by the leakage current detector 80 does not exceed a value set by the user as a dangerous value, only the first switch 10 is operated to be locked. Therefore, the management personnel monitor the condition of the structure to determine whether it is abnormal.

In case of leakage current increase due to instantaneous harmonic abnormality, the alarm state is canceled when the leakage current value is restored. However, if leakage current is continuously generated, it is notified to professional management personnel for precise diagnosis.

The leakage current detector 80 may be used in general.

In the locked state of the first opening/closing device 10 due to leakage current, the earth leakage alarm 90 is operated, and the earth leakage alarm is sent directly to the management personnel by text.

In addition, when the first opening and closing device 10 and the second opening and closing device 30 are locked at the same time due to an emergency, the door 2 of the structure 1 is opened only by a professional management personnel.

In this way, the first opening and closing device is intended to be effectively configured to be selectively opened and closed.

The first opening/closing device 10 is configured to be inserted into and fixed to the groove portion 42 formed in the fixing body 40 while the opening/closing plate 20 is rotated.

One end of the rectangular plate body 21 of the opening/closing plate 20 is fixed to the rotating shaft 25 of the motor 24. A key 25-1 is formed at an end of the rotating shaft 25 of the motor 24 and inserted into the key hole 22 formed in the plate body 21 of the opening/closing plate 20. The rotation shaft 25 and the opening/closing plate 20 are rotated together by the key 25-1 and the key hole 22.

The bracket 26 is fixed to the motor 24 such that the rotating shaft 25 of the motor 24 faces the inner surface of the door 2, as illustrated in FIG. 2.

As the motor 24 fixed to the door 2 with the bracket 26 is rotated by the control unit 60, the opening/closing plate 20 is inserted into the groove portion 42 of the fixed body 40, and the door is locked. , As it is separated from the groove portion 42, the door is released.

The fixed body 40 is fixed to the structure 1 adjacent to the door 2 to which the opening and closing plate 20 is fixed.

The second opening and closing device 30 is configured to prevent the opening and closing plate 20 from rotating, and a second locking hole 23 is formed on one side of the plate body 21 of the opening and closing plate 20, and the opening and closing plate 20 is high. The second locking hole 23 is formed such that the second locking hole 23 is positioned inside the groove 42 while being inserted into the groove 42 of the stagnation 40.

A lock hole 43 penetrating the entire groove portion 42 of the fixed body 40 in the same position as the second locking hole 23 is formed in the body 41 of the fixed body 40, and of the solenoid 50 The rod 51 is fixed to one side of the fixture 40 so as to penetrate the second locking hole 23 and the locking hole 43 simultaneously.

When the leakage current is measured as configured in this way, the first opening/closing device 10 is first locked, and when the leakage current is detected by the control unit over a set value, the second opening/closing device 30 is locked.

The seismic switchboard device having the detection function of the leakage current according to the present invention further includes a seismic unit 100 for buffering vibrations transmitted from the outside to the structure 1 as shown in FIGS. 10 to 11.

The earthquake-resistant portion 100 prevents a power failure or a fire from occurring inside and outside the structure 1 due to vibration generated from the outside, such as an earthquake.

The earthquake-proof portion 100 includes a support portion 110 including a plate 111 disposed on the ground so as to be located at the bottom of the structure 1, a side wall 120 and a plate extending downward from the edge of the structure 1 While supporting the side wall 120 from (111), it includes a buffer means 130 for buffering the vibration.

The plate 111 forms a square shape and has a certain load while stably supporting the structure 1 from the ground.

The plate 111 may have a lower portion seated on the ground or may be embedded in the ground.

Accordingly, the plate 111 may protrude upward from the ground or may form an approximately same surface as the ground.

The support 110 further includes a plurality of piles 112 for fixing the plate 111 to the ground.

As shown in FIG. 11, the plate 111 protrudes forward and backward from the front and rear ends of the structure 1.

The pile 112 is coupled to the front and rear ends of the plate 111 so as to be located at the front and rear of the structure 1, thereby fixing the plate 111 to the ground.

The plate 111 may be prevented from shaking or moving due to vibration generated from the outside by fixing the front and rear ends to the ground by the pile 112.

The pile 112 has a conical shape that narrows in width from the top to the bottom, and has a body portion 113 in which spiral protrusions are formed along the longitudinal direction, and a head portion 114 provided at the top of the body portion 113. Can be divided.

The plate 111 is preferably formed with a hollow 115 through which the body portion 113 passes.

Pile 112 is preferably the head portion 113 does not protrude upward than the upper surface of the plate (111).

The plate 111 is formed to extend inward from the circumference forming the hollow 115 and a stepped portion 116 on which the head portion 113 is seated may be formed.

The side wall 120 is formed to extend downward from the edge of the structure 1 to form a square ring.

The plate 111 is formed with an inlet groove 117 through which the side wall 120 is introduced.

The buffer means 130 is accommodated in the inlet groove 117 and includes a plurality of springs 131 supporting the side walls 120.

The spring 131 supports the side walls 120 while being disposed along the inlet groove 117, while cushioning the shock caused by vibrations generated from the outside.

The plate 111 is preferably formed with a plurality of fitting grooves 117a in which the lower part of the spring 131 is fitted on the bottom surface constituting the inlet groove 117.

Accordingly, each spring 131 may be disposed in a stable state at a predetermined position while being coupled to the fitting groove 117a.

The shock absorber 130 may further include caps 132 provided on upper and lower parts of each spring 131.

The cap 132 allows the contact with the side wall 120 to be smoothly made, while allowing the side wall 120 to be stably supported.

The buffer means 130 may further include a buffer member 133 provided on both sides of the inlet groove 117.

The shock absorbing member 133 may be made of silicon or rubber, and shock absorbs while contacting the side wall 120 according to the shaking of the structure 1 due to vibration generated from the outside, while preventing damage.

The earthquake-proof portion 100 further includes a horizontal adjustment means 140 for adjusting the structure 1 to be horizontal.

The horizontal adjustment means 140 can adjust the horizontal by adjusting the separation distance between both sides of the structure 1 and the plate 111.

The horizontal adjustment means 140 protrudes outward from both sides of the structure 1 and is provided at the top of the plate 111 so as to face the flange 141 and the flange 141 through which the hollow 141a penetrates vertically. A fastening ring 142, a guide tube 143 extending from the circumference forming the hollow 141a upwardly and forming guide holes 143a extending downwardly from the top on both sides, and both ends of the guide tube ( 143) the lifting bar 144 rotatably coupled to the guide hole 143a so as to protrude outward, the lower end is connected to the fastening ring 142 and the upper end is wound on the lifting bar 144 ( 145), the driving motor 146 that transmits the rotational force to the lifting bar 144 and the outside of the guide tube 143 so as to be located on the upper portion of the lifting bar 144 is separated to prevent departure of the lifting bar 144 It includes a prevention member (147).

The guide tube 143 is formed to extend upward from the circumference forming the guide hole 143a and forms an integral part with the flange 141.

The guide tube 143 is formed with a screw thread on the outer circumferential surface, and the escape prevention member 147 is made of a nut or the like with a screw thread formed on the inner circumferential surface, and is screwed to the guide tube 143 so as to be elevated or lowered.

The departure prevention member 147 is screwed to the guide tube 143 so as to be located outside the lifting bar 144, thereby preventing the lifting bar 144 from being detached from the guide tube 143.

When the separation preventing member 147 is separated from the guide tube 143, the lifting bar 144 may be separated from the guide tube 143.

Accordingly, the replacement of the wire 145 and the lifting bar 144 according to long-term use and the like can be smoothly performed.

The lifting bar 144 is preferably provided with bearings 148 at both ends in contact with the adjusting member 146.

This is to prevent rotation from being made smoothly due to friction due to contact with the adjusting member 146.

The driving motor 146 may be directly connected to the lifting bar 144 and transmits rotational force to the lifting bar 144 while being driven by an externally applied power source so that the wire 145 is wound around the lifting bar 144 or , To be released.

The structure 1 may be lowered as the wire is wound on the lifting bar 144, or may be elevated as the wire 145 is released from the lifting bar 144.

The horizontal adjustment means 140 may further include a spring 149 coupled to the outside of the wire 145 so as to be positioned between the plate 111 and the flange 141.

The spring 149 protects the wire, while cushioning and relaxing the external force to cushion the impact.

As the flange 141 is provided with a horizontal system (not shown), an operator or the like can check the horizontal state with the naked eye and control driving of the driving motor 146.

Accordingly, the horizontal adjustment means 140 can appropriately adjust the horizontal state of the structure 1.

12 to 14, the earthquake-proof portion 100 further includes an installation means 150 for rotating the pile 112 and installing it on the plate 111.

When the installation means 150 is installed on the pile 112, the body part 113 on which the spiral protrusion is formed is rotated so that it is smoothly stuck on the ground.

The pile 112 is formed with grooves 118 at the top, and fastening holes 119 are formed at both sides of the grooves 118.

The installation means 150 is disposed on the top of the pile 112, the installation bar 151 is formed with a hollow (151a) in communication with the groove portion, both ends are passed through both sides of the installation bar 151, the central portion is hollow (151a ) Is coupled to the guide bar 152, the binding member 153 for binding the guide bar 152 to the installation bar 151, the guide bar 152 so as to be located in the hollow (151a) in the longitudinal direction The spring is coupled to the outside of the guide bar 152 so as to be positioned between the pair of pressure bars 154 and the pair of pressure bars 154, which are formed with a fastening protrusion 154a that is introduced into the fastening hole 119 at the bottom. It includes a handle bar 156 extending upward from both sides of the 155 and the installation bar 151.

The installation bar 151 forms a square shape and is formed to extend in a direction crossing the length direction of the pile 112.

The installation bar 151 is formed with a hollow 151a penetrating in the vertical direction in the central portion, while a through hole 151b penetrating in both sides, that is, in the longitudinal direction is formed.

A pair of pressure bars 154 are arranged as the hollow 151a, and a guide bar 152 is coupled as the through hole 151b.

The guide bar 152 is coupled to the through hole 151b, and both ends protrude outward from the installation bar 151.

The guide bar 152 is formed with threads on the outer circumferential surface of both ends, and the binding member 153 is formed with threads on the inner circumferential surface and screwed to the outside of both ends of the guide bar 152, thereby installing the guide bar 152 to the installation bar 151. Unite.

The pair of pressure bars 154 are formed to extend in the vertical direction, and guide holes 154b passing through both sides are formed to be movably coupled to the guide bars 152 in the longitudinal direction.

The pair of pressure bars 154 may be smoothly in contact with the circumference forming the groove portion 118 while the opposite side forms a horizontal surface while the other side forms a curved surface.

The fastening protrusion 154a is formed under the other side of the pressure bar 154 and is introduced into the fastening hole 119 by the pressure of the spring 155.

The spring 155 contracts as the pair of press bars 154 are pressed in opposite directions, while being released by releasing the pressure on the pair of press bars 154.

That is, the installation means 150, when installing to the pile 112, presses the pair of pressure bars 154 in opposite directions so that the lower portion of the pressure bar 154 is drawn into the groove portion 118.

When the lower portion of the pair of pressure bars 154 is drawn into the groove portion 118, the pressure is released while the fastening protrusion 154a is adjusted to be pulled into the fastening groove 119 to be installed on the pile 112.

The installation means 150 may be separated into the pile 112 through the opposite process, and of course, after the pile 112 is installed on the ground, it should be separated.

The handle bar 156 is formed in a pair and is disposed on both sides of the upper portion of the installation bar 151, and after the installation means 150 are installed on the pile 112, the installation means 150 and the installation means 150 are gripped by hands. Together, the pile 112 is allowed to rotate.

Accordingly, the installation means 150 may make it easy to install the pile 112.

The seismic part 100 according to the present invention further includes a storage box 160 for storing the installation means 150.

The storage box 160 is provided on both sides of the structure 1 so that the storage for the installation means 150 is smoothly performed.

The structure 1 may be provided with an opening/closing door (not shown), and the installation means 150 may be drawn in or out according to the opening/closing.

The installation means 150 may be taken out of the structure 1 as needed while being accommodated in the storage box 160.

Due to this, the earthquake-resistant portion 100 can be prevented from generating a power failure or a fire with damage to the inside and outside of the structure 1 due to vibration generated from the outside, such as an earthquake.

What has been described above is only an embodiment for implementing an earthquake-proof switchgear with a detection function for leakage current according to the present invention, and the present invention is not limited to the above-described embodiment, and is claimed in the following claims. Likewise, without departing from the gist of the present invention, any person having ordinary knowledge in the field to which the present invention pertains will have the technical spirit of the present invention to the extent that various changes can be implemented.

1: Structure 10: 1st switchgear
20: opening and closing plate 30: second opening and closing device
40: fixture 50: solenoid
60: control unit 70: control panel
80: Leakage current detector 90: Leakage alarm
100: earthquake-resistant portion 110: support portion
120: side wall 130: buffer means
131: elastic member 132: cap
133: buffer member 140: horizontal adjustment means
150: installation means 160: storage box

Claims (1)

Leakage current detector (80) installed inside the structure (1);
A control unit 60 connected to the leakage current detector 80;
An earth leakage alarm (90) connected to the control unit (60); And
In the seismic switchgear device equipped with the detection function of the leakage current, which is installed on the door (2) of the structure (1), the first and second switchgear (10,30) connected to the control unit 60,
The shock absorber 100 further includes an earthquake-resistant part 100 that cushions vibrations transmitted from the outside to the structure 1 to prevent damage to the inside and outside of the structure 1.
The earthquake-proof portion 100,
The plate 111 disposed on the ground so as to be located at the bottom of the structure 1, and the plate 111 is fixed to the ground while preventing the plate 111 from being shaken or moved by vibrations generated from the outside. A support unit 110 including a plurality of piles 112;
A side wall 120 forming a rectangular ring shape while extending downward from the edge of the structure 1;
While supporting the side wall 120 from the plate 111, the buffer means 130 to dampen the vibration;
Leveling means 140 for adjusting the horizontal state of the structure (1);
Installation means 150 for installing the pile 112 on the plate 111; And
It is provided on both sides of the structure (1), and includes a storage box 160 for storing the installation means 150,
The pile 112,
It is divided into a body part 113 in which a spiral protrusion is formed along the longitudinal direction and a head part 114 provided on the upper part of the body part 113, forming a conical shape that narrows in width from the top to the bottom, and a groove part at the top (118) is formed, fastening holes 119 are formed on both sides of the groove 118,
The plate 111,
The body portion 113 is passed through the hollow 115, the inner side from the circumference forming the hollow 115 is formed extending inward and the head portion 114 is seated step 116 and the side wall 120 is A plurality of fitting grooves 117a in which a lower portion of the spring 131 is fitted on the bottom surface constituting the drawing groove 117 and the drawing groove 117 are formed,
The buffer means 130,
A plurality of springs 131 accommodated in the inlet grooves 117 to support the sidewalls 120 and cushion vibrations generated from the outside;
A cap 132 provided on an upper portion of each spring 131 to stably support the side wall 120; And
It is provided on both sides forming the inlet groove 117, while contacting the side wall 120 according to the shaking of the structure 1 according to the vibration generated from the outside to buffer the shock, while preventing the damage buffer member 133 ),
The horizontal adjustment means 140,
A flange 141 protruding outward from both sides of the structure 1 and having a hollow 141a penetrating in the vertical direction;
A fastening ring 142 provided on an upper portion of the plate 111 so as to face the flange 141;
A guide tube 143 extending upwardly from the circumference forming the hollow 141a, and having guide holes 143a extending downwardly from the top on both sides;
A lifting bar 144 rotatably coupled to the guide hole 143a so that both ends thereof protrude outward of the guide tube 143;
The lower end is connected to the fastening ring 142, the upper end of the wire 145 wound on the lifting bar 144;
A driving motor 146 that transmits rotational force to the lifting bar 144;
A departure preventing member 147 coupled to the outside of the guide tube 143 so as to be located on the upper portion of the lifting bar 144 to prevent the lifting bar 144 from falling off;
While being coupled to the outside of the wire 145 so as to be positioned between the plate 111 and the flange 141, while protecting the wire 145, the spring 149 that cushions the shock while contracting and relaxing by external force While controlling the horizontal distance of the structure (1) by adjusting the separation distance between both sides of the structure (1) and the support plate 111 according to the driving,
While the flange 141 is provided with a horizontal system, the operator visually checks the horizontal state and controls the driving of the driving motor 146,
The plate 111,
The front and rear ends protrude forward and backward than the structure (1),
The pile 112,
The plate 111 is fixed to the ground while being coupled to the front and rear ends of the plate 111 so as to be located at the front and rear of the structure 1, but a groove 118 is formed at the top, and the groove 118 is Fastening holes 119 are formed on both sides of the forming,
The installation means 150,
An installation bar 151 disposed on the pile 112 and having a hollow 151a in communication with the groove 118;
A guide bar 152 where both ends pass through both sides of the installation bar 151 and a central part is positioned in the hollow 151a;
A binding member 153 for binding the guide bar 152 to the installation bar 151;
A pair of press bars 154 which are movably coupled to the guide bar 152 in the longitudinal direction so as to be located in the hollow 151a, and which are formed with fastening projections 154a introduced into the fastening holes 119 at the bottom. );
A spring 155 coupled to the outside of the guide bar 152 so as to be positioned between the pair of press bars 154; And
Includes a handle bar 156 to rotate the pile 112 through gripping by hand while extending upward from both sides of the installation bar 151, after the pile 112 is installed on the ground Is separated from the pile 112, the structure having a detection donation of leakage current, characterized in that stored in the storage box 160.

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