KR101945799B1 - Seismic design reinforcement device of underground transmission line - Google Patents

Abstract

The present invention relates to a seismic design reinforcement device of an underground transmission line and, more specifically, to a seismic design reinforcement device of an underground transmission line, which can effectively protect an underground wire which is buried in the ground and connected by a mutual bolt fastening in a manhole from an external force, specially an earthquake. In addition, the seismic design reinforcement device comprises a fixing stand for underground wire wiring.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a seismic design reinforcement device for an underground transmission line,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an apparatus for reinforcing earthquake-resistant design of an underground transmission line in transmission technology, and more particularly, The present invention relates to an earthquake-resistant design reinforcing apparatus for an underground transmission line.

Generally, electricity used in each home, office and large-scale factory is supplied through a substation equipped for each region. This substation is installed for the purpose of modifying voltage and current and distributing power, The power generated by the power line will be sent through the transmission line.

The substations are usually installed on the ground. In such a substation, high-voltage currents must be transmitted. Most of the high-voltage cables are exposed to the outside. High-voltage cables exposed to the outside are short- And high-voltage wires are installed underground because there are problems such as hatching of the surrounding scenery due to the high-tension wires that have been erroneously installed.

In this way, when a high-voltage electric wire is installed in the underground, problems such as external interference and damage to surrounding scenery are eliminated, but the length of the originally designed high-voltage electric wire takes more time depending on the conditions of the site, Is still being implemented, despite the problem of having to use more connections.

In the case of high-voltage wires, since the diameter of the high-voltage wires is considerably large due to the characteristic of supplying power at high pressure, bolts are fastened to each other in a state of being in contact with each other, and insulating tapes are wound around the joints.

Especially, since the high-voltage wires are connected to each other easily, when the ground is easily cooled as in winter, the inner copper wire and the outer surface of the inner wire are shrunk with rapid cooling to cause excessive tensile, There is a problem such as short-circuiting easily. In the past, there has been no means to notify in advance that such excessive tension is generated.

In addition, a lot of damages are expected in the case of underground transmission line where earthquake-resistant design is lacking due to frequent earthquakes that are soaring recently.

Furthermore, in the case of an underground cable that is embedded in the ground and connected by a bolt fastening in the inside of the manhole, there is no countermeasure against earthquake. Therefore, if a large earthquake occurs, it can cause serious problems due to electricity and communication paralysis.

Korea Patent Registration No. 10-0904917 (Jun. 19, 2009) 'Seismic Design Reinforcement Device for Underground Transmission Line'

SUMMARY OF THE INVENTION The present invention has been made in view of the above-mentioned problems in the prior art, and it is an object of the present invention to provide a method for effectively protecting an underground wire embedded in a ground through a bolt- The present invention relates to an earthquake-resistant design reinforcing device for an underground transmission line.

The present invention provides a means for achieving the above object, which comprises a fixed base 11 for underground cables L1 and L2 installed inside a manhole 1, and is characterized in that the underground transmission line CLAIMS 1. An earthquake-resistant design reinforcing apparatus comprising:
A manhole wall 100, which is a rectangular box-shaped concrete structure having an open upper part, is seated in the installation space by excavating the ground surface where the manhole 1 is to be installed larger than the manhole 1, A plurality of seismic absorbing units 110 are installed in a lattice shape at a predetermined interval on the inner wall surface except the bottom surface of the built-in case 110, And an earthquake-resistant filling material 120 is filled between the manhole wall 100 and the inner case 110;
The earthquake-resistant filling material 120 is composed of 20% by weight of allophane powder, 20% by weight of loess, 15% by weight of silica gel, and residual sand;
The seismic shock absorber unit 200 includes a fixing member 210 having a thread on the circumferential surface thereof and screwed to the mounting groove 112 of the inner case 110, Shaped resilient flow hole 230 having a protrusion guide hole 220 formed at the center thereof and a protrusion 232 protruding through the protrusion guide hole 220 and inserted into the fixture 210, A coil spring 240 urged to the rear surface of the elastic flow hole 230 and a spring fixing piece 250 screwed to an open end of the fixing hole 210 while pressing the coil spring 240;
The concrete structure constituting the manhole wall 100 is composed of 4% by weight of calcium sulfoaluminate, 3.5% by weight of cresyl glycidyl ether, 2.5% by weight of titanium dioxide, 10 wt% of epoxy resin, 2.5 wt% of metaphosphate, 2.5 wt% of methylsiliconate, 2.5 wt% of ammonium alginate, 3.5 wt% of phosphoric acid ester sodium salt, 15 wt% of sand, 20 wt.% And balance water;
The lower end of the fixing table 11 is bolted to the center of the upper surface of the fixing table fixing plate 300 and the fixing table fixing plate 300 is fixed to the center of the bottom surface of the manhole 1, And the first and second semicircular covers 310 and 320 are fixed to the bottom surface of the manhole 1 by an anchor bolt to form a single disk The inner diameter of which is smaller than that of the fixing table fixing plate 300 so that the fixing table fixing plate 300 is constrained by the first and second semicircular covers 310 and 320, Wherein a plurality of coil springs (330) are installed at intervals of 60 degrees in the circumferential direction between the outer diameter of the fixing table fixing plate (300) and the inner space (340) formed by the first and second semicircular covers (31, 320) The present invention provides an apparatus for reinforcing an earthquake-resistant design.

According to the present invention, it is possible to obtain an effect of effectively protecting an underground electric wire, which is buried in the ground and connected by bolt fastening in the inside of a manhole, from an external force, especially an earthquake.

1 is an exemplary sectional view showing an installation example of an underground transmission line according to the present invention.
FIG. 2 is a perspective view of a main portion of a ground transmission line according to the present invention. FIG.
3 is a block diagram showing interconnections between components of an underground transmission line according to the present invention.
4 and 5 are operational diagrams of an underground transmission line according to the present invention.
6 is an exemplary sectional view of a manhole installation structure according to the present invention.
7 is an exemplary view of an earthquake cushioning unit according to the present invention.
8 is a view showing an example of an earthquake-proof structure of a fixing table according to the present invention.

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

Before describing the present invention, the following specific structural or functional descriptions are merely illustrative for the purpose of describing an embodiment according to the concept of the present invention, and embodiments according to the concept of the present invention may be embodied in various forms, And should not be construed as limited to the embodiments described herein.

In addition, since the embodiments according to the concept of the present invention can make various changes and have various forms, specific embodiments are illustrated in the drawings and described in detail herein. However, it should be understood that the embodiments according to the concept of the present invention are not intended to limit the present invention to specific modes of operation, but include all modifications, equivalents and alternatives falling within the spirit and scope of the present invention.

Prior to a specific description of the present invention, the present invention uses most of the configuration of the above-mentioned Patent No. 10-0904917 as it is. Therefore, the contents of the above-mentioned registered patent will be quoted as it is in the basic structure described below.

As shown in FIGS. 1 to 3, the present invention includes a support 10 fixed to a bottom surface of a manhole 1 and guiding the protection 20 so that the protection 20 can be reciprocated vertically; A protector 20 installed to be vertically reciprocable on the support part 10 and protected by receiving underground wires L1 and L2 fastened by bolts to each other; A spring S which is fixed to the bottom surface of the protector 20 and whose other end is inserted into the insertion groove 11a of the protector 10 to elastically support the protector 20 in one direction; A switch 30 installed on the supporting piece 12 and turned on / off by a protective member 20 which is reciprocated vertically; A fire detection sensor 40 installed inside the manhole 1 for detecting heat generated during a fire; A control unit 50 receiving an operation signal from the switch 30 and outputting an emergency signal, receiving a fire detection signal from the fire detection sensor 60, and outputting an operation signal; A transmission unit 60 that is controlled by the control unit 50 and wirelessly transmits an emergency signal and a fire detection signal from the control unit 50 to the outside; A fire hydrant 70 for spraying the fire extinguishing liquid injected into the manhole 1 through the injection valve 71 and spraying the fire extinguishing liquid 70 into the fire area is provided with an injection valve 71 controlled to be operated by the operation signal of the control unit 50, )and; And a pair of rotating rollers 80 rotatably installed on the sidewalls of the manhole 1 and guiding the covering of the ground wires L1 and L2 so as not to be damaged, as shown in FIGS. 1 and 2. FIG.

The manhole (1) to be buried in the ground is made up of a concrete material, an upper portion is opened, and a manhole cover (2) is installed to be openable on the upper side and an underground cable L1 and L2, and a wiring tube 3 buried so as to be able to be wired.

The support portion 10 which is installed on the bottom surface of the manhole 1 and guides the protection hole 20 to be vertically reciprocable can include an insertion groove 11a having an upper opening, And a pair of supporting pieces 12 protruding from the upper surface of the fixing table 11 and having guide grooves 12a perpendicular to the inner surface of the fixing table 11 so as to face each other .

The protector 20 is installed in the support portion 10 so as to be vertically reciprocable so that the underground wires L1 and L2 fastened by bolts are received and protected by the guide piece 12a. A first cap 21 which is provided with a first end 21a and is reciprocally fixed in the vertical direction of the fixing stand 11; A second cap 22 which is rotatably installed on the first cap 21 so as to surround the ground wires L1 and L2 housed therein and has an injection hole 22a formed at an upper center thereof; And an encapsulant (SC) which is injected through the injection hole (22a) to cover and insulate the joints of the ground wires (L1, L2) connected to each other.

The fixing rods 21b and the fixing rods 22b corresponding to the fixing rods 21b are formed at the portions where the first and second caps 21 and 22 are folded and abutted to be mutually engageable.

A single rod (not specifically shown) is integrally formed on the bottom surface of the first cap 21 so as to project downward and to be loaded with a spring S on its outer circumferential surface.

In addition, the sealing agent (SC), which is injected into the interior through the injection hole (22a) to cover the joint portion and can be insulated, is hardened after a lapse of a predetermined time to maintain a predetermined elasticity, It is preferable to form it from silicon.

The guide pieces 21a protruding horizontally at both ends of the guide pieces 12a are horizontally protruded from the guide grooves 12a of the support pieces 12 in a plan view, So that it can be stably slid without being detached outwardly.

The spring S protrudes from the fixing base 11 of the supporting part 10 and is fixed to a single end of the protecting part 20 so as to elastically support the protecting part 20 in one direction.

A switch 30 is provided on the support piece 12 of the support portion 10 and the switch 30 is connected to a protective member 12 which is reciprocally moved between a pair of support pieces 12 by a normal limit switch (Not specifically shown) projected horizontally by the arm 20 are rotated around the axis to sense the movement of the protection member 20 to the restricting position.

In the case of the present embodiment, the restricted position means a position where the protector 20 is vertically lowered and the tensile force of the ground wires L1 and L2 is maximized.

Accordingly, when the switch 30 senses the protective member 20 moved to the limit position, the sensing signal output from the switch 30 is input to the control unit 50, and the control unit 50 receives the sensing signal And outputs the emergency signal to the transmission unit 60. The transmission unit 60 having received the emergency signal transmits the emergency signal to the central control room (not specifically shown) where the worker resides wirelessly, The state of the current ground wires L1 and L2 can be determined through the received emergency signal and can be quickly responded.

A fire detection sensor 40 is installed in the manhole 1. In the present embodiment, the fire detection sensor 40 is a conventional heat detection sensor. The fire detection sensor 40 detects excessive fire due to excessive shrinkage of ground wires L1 and L2 If a fire occurs due to electrical short circuit due to break of part of the conductor, or when the penetration water enters into the inside of the conductor which has lost its protective function due to aging, it contacts with the conductor through which electric current flows. The fire detection sensor 40 detects the heat of the high temperature, and the fire detection signal is transmitted to the controller 50.

The control unit 50 receives the fire detection signal from the fire detection sensor 40 and transmits a fire hydrant operation signal to the injection valve 71 of the fire hydrant 70 installed in the manhole 1, 71 so that the fire extinguishing liquid can be injected into the manhole 1, and at the same time, outputs a fire detection signal to the transmitter 60.

The inside of the fire hydrant 70 is filled with a fire extinguishing agent and compressed air or a non-combustible gas (nitrogen, carbon dioxide, halogen gas) liquefied at a high pressure, And an injection valve 71 for interrupting the outflow of the extinguishing agent and the incombustible gas.

In this embodiment, when the hydrant operation signal is inputted from the control unit 50, the inlet of the injection valve 71 is opened, and the extinguishing agent and the incombustible gas filled in the iron vessel are pressurized by the internal pressure of the injection valve 71 It is sprayed into the manhole 1 through the inlet to suppress the fire area for a moment, thereby minimizing the damage caused by the fire.

The control unit 50 receives the fire detection signal from the fire detection sensor 40 and transmits a fire hydrant operation signal to the injection valve 71 of the fire hydrant 70 installed in the manhole 1, (Fire extinguishing agent and nonflammable gas) can be injected into the manhole 1 through the fire extinguisher 71 and simultaneously outputs a fire detection signal to the transmitter 60. The transmitter 60 ) Wirelessly transmits a fire detection signal to a central control room (not specifically shown) where the worker resides, so that other wires wired in the manhole 1 are connected to the main control room It is possible to respond promptly to follow-up measures so as not to be burnt.

The pair of rotating rollers 80 for guiding the coating of the ground wires L1 and L2 are not damaged is a bracket having one end fixed to the inner wall of the manhole 1 and the other end projecting inwardly And a roller (not specifically shown) installed at the end of a bracket (not specifically shown) so as to idle.

Hereinafter, the operation of the present invention will be described.

As shown in FIGS. 4 and 5, in the seasons when the temperature changes little, that is, in spring and autumn, the underground wires L1 and L2 are fastened to each other, Is always kept elastically held by the spring (S) installed at the center of the support portion (10).

In winter, however, the copper wires forming the ground wires (L1, L2) and the covering wire surrounding the wires are contracted to generate tensile force, and the ground wires (L1, L2) connected to each other are pulled in opposite directions.

When the ground wires L1 and L2 are pulled in opposite directions to each other, the ground wires L1 and L2 are coupled to each other so that the protector 20 drawn into the inside is gradually lowered vertically along the support portion 10 And the spring S disposed on the bottom surface of the protector 20 is squeezed.

The guide piece 21a of the protection member 20 inserted into the guide groove 12a of the support portion 10 is vertically lowered by the tensile force generated in the underground wires L1 and L2 The manipulation piece (not specifically shown) of the switch 30 provided at the limit position of the support piece 12 is pressed against the lower protective cover 20 20, and the sensing signal is transmitted to the control unit 50.

The control unit 50 receives the detection signal of the switch 30 and outputs an emergency signal. The emergency signal is output to a central control room (specifically, a central control room The emergency signal is transmitted.

Accordingly, the operator can easily recognize the current state of the underground wires L1 and L2 through the received emergency signal, and can quickly follow-up.

On the other hand, the ground wires L1 and L2 wired in the manhole 1 repeatedly generate tensile stress and shrinkage as the temperature changes, so that stress is generated inside.

When a certain period of time has elapsed in the above-described state, a part of the lead wire is broken due to repeated tensile and contraction, and an electric short-circuit accident occurs, or the penetration water is introduced into the inside of the covered wire which has lost its protective function due to aging, As a result, a fire due to short-circuit and short-circuit occurs.

Therefore, when a fire occurs in the manhole 1 due to the electrical short circuit, the fire detection sensor 40 installed in the manhole 1 senses the heat generated in the fire and transmits a fire detection signal to the controller 50 The control unit 50 receives the fire detection signal from the fire detection sensor 40 and transmits a fire hydrant operation signal to the injection valve 71 of the fire hydrant 70 installed in the manhole 1, 71 so that the fire extinguishing liquid can be injected into the manhole 1, and at the same time, outputs a fire detection signal to the transmitter 60.

When the hydrant operation signal is input from the controller 50, the inlet of the injection valve 71 is opened. At this time, the extinguishing agent and the incombustible gas filled in the iron vessel are discharged through the inlet of the injection valve 71 to the manhole 1 ), And the fire area is suppressed instantaneously.

Further, the transmission unit 60, which receives the fire detection signal from the fire detection sensor 40, transmits a fire detection signal to a central control room (not specifically shown) where the worker resides wirelessly, It is possible to quickly respond to follow-up measures so that other wires wired in the manhole 1 are not burnt through the fire detection signal.

The pair of rotating rollers 80 provided on the sidewall of the manhole 1 and abutted against the ground wires L1 and L2 are idly rotated by the ground wires L1 and L2 to be moved outwardly, (L1, L2) is prevented from being damaged by the wiring tube (3) charged in the wall of the manhole (1).

Therefore, when the tension applied to the ground wires L1 and L2 is released, the protector 20, which has been pressing the spring S, is gradually discharged by the spring S and returns to the initial state.

In addition, the present invention has a manhole installation structure as shown in FIG. 6 to allow a seismic design out of the conventional manner in which the manhole 1 is simply inserted after excavating the ground.

6, before the manhole 1 is installed, a ground surface on which the manhole 1 is to be installed is excavated to a greater extent than the manhole 1 to make an installation space, and the manhole wall 100, which is a concrete structure, is seated in the installation space .

At this time, the manhole wall 100 is in the shape of a rectangular box with an open top.

Particularly, the concrete structure constituting the manhole wall 100 is composed of 4% by weight of calcium sulfoaluminate, 3.5% by weight of cresyl glycidyl ether, 2.5% by weight of titanium dioxide, , 10 wt% of an epoxy resin (Epoxy Resins), 2.5 wt% of metaphosphate, 2.5 wt% of methylsiliconate, 2.5 wt% of ammonium alginate, 3.5 wt% of phosphoric acid ester sodium salt, 15 wt% , 20% by weight of cement and the balance of water.

Here, the calcium sulfo-aluminate (calcium sulfo-aluminate) is added to a compound of _{3CaO · 3Al 2 O 3 · CaSO} , hydration promotes coagulation by creating a ettringite (ettringite) and early strength gain.

Further, the cresyl glycidic ether is added to maintain the stable binding property of the epoxy resin.

The titanium dioxide is added to enhance resistance to water by bonding with an epoxy resin to enhance water resistance and moisture resistance.

In addition, the epoxy resin is a generic term for thermosetting resins having an epoxy group in the molecule and is added for improving weather resistance and tensile strength.

In addition, the metaphosphate is added to enhance the antioxidant function on the concrete surface, and the methylsiliconate is added to increase the tensile strength while maintaining water repellency. The alginic acid ammonium salt is added to the stability of the structure and viscosity do.

In addition, the phosphate ester sodium salt is added to refine the crystal to strengthen the stiffness and thermal deformation of the structure.

Since the manhole wall 100 having such a composition has a higher tensile strength than conventional concrete, the seismic performance can be improved.

A built-in case 110, which is a cushioning wall formed of a synthetic resin material, is installed at an interval from the manhole wall 100.

The inner case 110 is formed in a rectangular box shape having an open upper part. The inner case 110 is formed with 8.0 weight% of sorbitan olivate and 0.5 weight% of hydroxyproline 2.5 to provide corrosion resistance, chemical resistance, chemical resistance and durability. By weight, butyl prop-2-propenoate of 15% by weight, urosolic acid of 10% by weight, isohexadecane of 2.5% by weight, cyanoacrylate, 5.0% by weight of perfluoropolyether, 3.5% by weight of methacrylic acid, 2.5% by weight of silicon nitride, 4.5% by weight of calcined ytterbium oxide, 1.5% by weight of alumina and the balance of polycarbonate resin ≪ / RTI >

In this case, the sorbitan olivate is a monoester of fatty acid derived from sorbitol-derived hexitolanhydride and olive oil and is added to enhance the natural emulsification function according to the surfactant enhancement to improve the moldability, Roxy-proline is added to increase the flexibility of the resin composition by increasing the flexibility of the resin composition as it is gelatinized when heat is received in the drying process, which will be described later, as a Renee salt in the gelatin hydrolyzate.

The butyl-2-enoate is added to increase the bending strength while providing ductility, impact reinforcement and binding property to the composition, and the uronic acid is a powder having excellent needle-like absorbability and adsorbs the polymer particles on the surface of the inorganic material Is added to improve bufferability, bending properties and durability and crack resistance.

In addition, the isohexadecane is added so as to contribute to separation and removal of foreign substances adhering to the surface of the molded article, and the cyanoacrylate is added to suppress the high thermal expansion and to enhance the binding force between the compositions .

The perfluoropolyether increases the slip property to further enhance the degree of molding freedom. The methacrylic acid is added to maintain corrosion resistance because it is resistant to acid, and the silicon nitride is nitrided in the amorphous nanoparticle size It is added by dispersing boron in order to absorb heat shock to suppress micro cracks and to enhance corrosion resistance.

In addition, the sintered ytterbium oxide is added as a rare earth metal to increase the chemical resistance and chemical resistance while increasing the durability through grain refinement, and the alumina is added as an oxide of aluminum in order to improve the heat resistance.

In addition, the polycarbonate resin is added as a base resin in order to strengthen and maintain scratch resistance and crack resistance.

In addition, a plurality of seismic dampening units 200 are installed on the inner wall surface of the built-in case 110 except for the bottom surface at a predetermined interval in a lattice form. The seismic dampening unit 200 will be described later.

Further, the earthquake-resistant filler 120 is filled between the manhole wall 100 and the inner case 110.

The earthquake-resistant filling material 120 is composed of 20% by weight of allophane powder, 20% by weight of loess, 15% by weight of silica gel, and residual sand.

At this time, the allopene powder is obtained by pulverizing a porous allopene clay mineral to have a particle size of 0.01 mm or less and pulverizing it. Allopen is a clay mineral generated in the weathering process of volcanic ash, which has no exceptional crystal structure, It is clay. In particular, allopen is made of porous fine particles and is effective in achieving seismic function by buffer while realizing excellent humidity control function.

And loess and sand is a typical soil substitute filling material, and silica gel is a substance to strengthen the buffering property while maintaining the space between them.

In addition, the above-described manhole 1 is inserted into the interior case 110.

Meanwhile, the seismic shock absorbing unit 200 which is fixed to the built-in case 110 and absorbs elastic shock while maintaining the gap with the manhole 1 is the same as the example of FIG.

7, the seismic shock absorber unit 200 includes a fixture 210 having a 'C' shape in which a thread is formed on a circumferential surface thereof and is screwed to a mounting groove 112 of the built-in case 110, And a protrusion 232 protruding through the protrusion guide hole 220 and inserted into the fixture 210. The protrusion protrusion 220 protrudes through the protrusion guide hole 220, A coil spring 240 urging the coil spring 240 against the coil spring 240 and a spring fixing piece 250 fixed to the open end of the fixing hole 210 while pressurizing the coil spring 240, ).

At this time, the spring fixing piece 250 is formed in the shape of 'ㅑ', and one end of the coil spring 240 can be more stably fixed by having the spring receiving groove 252 at the center of one side, The tool groove 254 is further formed so as to be rotatably operated using a tool such as a screwdriver.

In addition, since the tip of the protrusion 232 is rounded to minimize the friction between the protrusion 232 and the contact surface during contact, the protrusion 232 functions to obtain an earthquake-proof function by buffering while preventing the outer wall of the manhole 1 from being easily shaved.

That is, when the impact energy is transmitted due to the occurrence of an earthquake, the protruding portion 232 is pushed in contact with the outer wall of the manhole 1, so that the impact is mitigated by that time to prevent the manhole 1 from being damaged by impact energy .

8, the fixing base 300 is mounted on the center of the bottom surface of the manhole 1, and the center of the upper surface of the fixing base 11 is fixed to the center of the upper surface of the fixing base 11 The lower end is bolted.

The first and second semicircular covers 310 and 320 are fixed by a pair of first and second semicircular covers 310 and 320 having a cross section of 'a' An inner diameter is formed at the center of the circular plate, and the inner diameter is smaller than that of the fixed plate 300. [

The fixing plate 300 is constrained by the first and second semicircular covers 310 and 320 and the outer diameter of the fixing plate 300 and the inner space 340 formed by the first and second semicircular covers 31 and 320, A coil spring 330 is installed.

At this time, a plurality of the coil springs 330 are installed at intervals of 60 degrees in the circumferential direction.

Therefore, when the external force is transmitted by an earthquake or the like, the external force is absorbed and dispersed while being elastically buffered in the direction in which the external force advances, so that the external force is absorbed and dispersed, And when the external force is extinguished, it is centered again by the returning force of the coil spring 330.

As described above, according to the present invention, it is possible to prevent the ground wires L1 and L2 from being broken by designing the fixing table fixing plate 300 so as to be capable of being grounded.

One; Manhole 10: Support
20: Protector 30: Switch
40: a fire detection sensor 50:
60: Transmission unit 70: Fire hydrant
80:

Claims (1)

1. An earthquake-resistant design reinforcing apparatus for an underground transmission line including a grounding wire fixing wire (11) for underground wires (L1, L2) installed in a manhole (1), said manhole (1)
A manhole wall 100, which is a rectangular box-shaped concrete structure having an open upper part, is seated in the installation space by excavating the ground surface where the manhole 1 is to be installed larger than the manhole 1, A plurality of seismic absorbing units 110 are installed in a lattice shape at a predetermined interval on the inner wall surface except the bottom surface of the built-in case 110, And an earthquake-resistant filling material 120 is filled between the manhole wall 100 and the inner case 110;
The earthquake-resistant filling material 120 is composed of 20% by weight of allophane powder, 20% by weight of loess, 15% by weight of silica gel, and residual sand;
The seismic shock absorber unit 200 includes a fixing member 210 having a thread on the circumferential surface thereof and screwed to the mounting groove 112 of the inner case 110, Shaped resilient flow hole 230 having a protrusion guide hole 220 formed at the center thereof and a protrusion 232 protruding through the protrusion guide hole 220 and inserted into the fixture 210, A coil spring 240 urged to the rear surface of the elastic flow hole 230 and a spring fixing piece 250 screwed to an open end of the fixing hole 210 while pressing the coil spring 240;
The concrete structure constituting the manhole wall 100 is composed of 4% by weight of calcium sulfoaluminate, 3.5% by weight of cresyl glycidyl ether, 2.5% by weight of titanium dioxide, 10 wt% of epoxy resin, 2.5 wt% of metaphosphate, 2.5 wt% of methylsiliconate, 2.5 wt% of ammonium alginate, 3.5 wt% of phosphoric acid ester sodium salt, 15 wt% of sand, 20 wt.% And balance water;
The lower end of the fixing table 11 is bolted to the center of the upper surface of the fixing table fixing plate 300 and the fixing table fixing plate 300 is fixed to the center of the bottom surface of the manhole 1, And the first and second semicircular covers 310 and 320 are fixed to the bottom surface of the manhole 1 by an anchor bolt to form a single disk The inner diameter is formed at the center thereof and the inner diameter is smaller than that of the fixing table fixing plate 300 so that the fixing table fixing plate 300 is constrained by the first and second semicircular covers 310 and 320 And a plurality of coil springs 330 are arranged at intervals of 60 degrees in the circumferential direction between the outer diameter of the fixed base plate 300 and the inner space 340 formed by the first and second semicircular covers 31 and 320 Seismic Design Reinforcement of Underground Transmission Line.

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