KR101947798B1 - Earthquake-proof apparatus of transmission steel tower and steel structure for substation - Google Patents

Abstract

The present invention relates to an earthquake-proof apparatus of a transmission steel tower and a steel structure for a substation and, more specifically, relates to an earthquake-proof apparatus of a transmission steel tower and a steel structure for a substation, which can prevent a plurality of steel structures installed in a transmission steel tower or a substation from being reversed by a strong wind, ground subsidence, ground motion, or the like in advance. Moreover, earthquake-proof design can be reinforced.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an earthquake-proof apparatus for a transmission tower and a steel structure for substation,

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a transmission tower and a substation steel structure having a reinforced earthquake-resistant design, and more particularly, to a steel structure for a transmission tower or an outdoor substation, The present invention relates to a power transmission tower and an earthquake-resistant apparatus for a substation iron wire reinforced by an earthquake-resistant design for reinforcing earthquake-resistant design while preventing occurrence of a conduction phenomenon due to an earthquake and the like.

It is necessary to supply high quality electric power stably to all electric power receiving facilities, industrial complexes, factories and various plants such as residential, commercial, education and facilities according to urbanization.
To this end, it goes through various routes from the power plant to the power grid, and directs special high voltage such as 345kV, 154kV, or distributes the power to the various power loads.
In particular, the transmission line installed between the grid substations and the grid substations in the power plant is a source of power supply, which requires a high degree of stability, and various types of features are located in the grid, so that a given load condition Transmission towers suitable for topography are generally installed.
The transmission tower is a truss-type steel structure installed at a height of several tens of meters above the ground to lay transmission lines, etc., and is made up of heavy materials having tens of tons to hundreds of tons in weight.
In order to install such a transmission tower, first, the foundation concrete is flatly formed horizontally by tilting the ground, and then four basic concrete structures arranged in a square shape are constructed thereon. In each foundation concrete structure, The slabs are installed with the slabs, and the trusses are assembled to form the trusses up to the required height of the angle with the main body of a certain length exposed at the top.
However, such a transmission tower has a problem that a conduction phenomenon occurs due to strong wind, subsidence, and ground motion, which causes accidents such as a shortage in a nearby residential area, and large accidents such as damage caused by overturning.
On the other hand, the phenomenon occurring in such an iron structure occurs not only in the transmission tower but also in the steel structure of the outdoor substation, that is, the steel strip of the outdoor substation.
As a conventional technique in which such problems are partially improved, Korean Patent Registration No. 10-0662883 (Dec. 28, 2006) discloses a structure for reinforcing a transmission tower.
However, such a conventional reinforcing structure for a transmission tower has a problem that vibration due to an earthquake or the like is difficult to buffer.

Korea Patent Registration No. 10-0662883 (Dec. 28, 2006) 'Reinforcing structure of steel tower for transmission'

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a steel structure for a steel structure, a steel structure, And to provide a power transmission tower and an earthquake-proof device of a substation steel wire reinforced with an earthquake-proof design so as to reinforce the earthquake-resistant design.
The problems to be solved by the present invention are not limited to those mentioned above, and other solutions not mentioned can be clearly understood by those skilled in the art from the following description.

In order to achieve the above-mentioned object, the present invention provides a foundation concrete structure having four legs (3) and connected to a foundation concrete structure (5) in which a lower end of each leg (3) And a flange 113 is formed on the bottom bottom surface of the clip 111. The side surface of the clip 111 is connected to a straight line 115 by a transverse link 115, A reinforcing support 110 to which a strength reinforcing bar 117 formed in the shape of a triangle is attached; And a reinforcement foundation concrete structure 120 installed on a side surface of the foundation concrete structure 5 and having a reinforcing base structure 120 coupled to the reinforcement support frame 110. The transmission tower and the substation steel reinforcement, The vibration damping unit 200 further includes a support plate 210 extending outwardly from the reinforcing support plate 110. The vibration damping unit 200 includes a vibration damping unit 200, ; A base plate 220 seated on the ground so as to face the support plate 210; A support bar (230) having a lower portion embedded in the reinforced foundation concrete structure (120) and an upper portion extending upwardly and passing through the foundation plate (220) and the support plate (210); The supporting plate 210 is supported from the base plate 220 while being coupled to the outside of the supporting bar 230 so as to be positioned between the base plate 220 and the supporting plate 210, A spring 240 that shrinks and relaxes according to shaking and buffers the shock; And a binding member 250 which is screwed to the outside of the supporting bar 230 and binds the supporting bar 230 to the supporting plate 210 so as to be positioned on the upper side of the supporting plate 210 Provides a power transmission tower with reinforced seismic design and a seismic system for substation steel girder.

According to the present invention, it is possible to prevent a conduction phenomenon from occurring due to strong wind, ground subsidence, ground motion, and the like, in addition to being able to prevent a large number of steel structures, There is an effect that a shock due to an earthquake or the like can be buffered.
The effects of the present invention are not limited to those mentioned above, and other problems not mentioned can be clearly understood by those skilled in the art from the following description.

1 is a perspective view showing a power transmission tower and a substation iron core earthquake-proof apparatus reinforced by a seismic design according to the present invention.
FIG. 2 is a state diagram showing a state where a power transmission tower and a substation steel frame having an earthquake-resistant design according to the present invention are installed.
FIG. 3 is a front view showing a state in which an earthquake-resistant portion is provided in a power transmission tower and a substation steel wire earthquake-proof apparatus having a reinforced earthquake-resistant design according to the present invention.
And
4 is a partially enlarged cross-sectional view showing an anti-vibration portion in Fig.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.
1 and 2, an earthquake-proof apparatus 100 of a power transmission tower and a substation iron wire reinforced with earthquake-resistant design according to the present invention includes a transmission tower or a plurality of steel structures installed in an outdoor substation, A support base 110 and a reinforced foundation concrete structure 120.
In the present invention, as shown in FIG. 2, a transmission tower 1 will be described.
The reinforcing support member 110 is formed in a straight bar shape and has a lower end tapered outwardly, a clip 111 connected to the leg at a predetermined interval, a flange 113 formed on the lower end surface, And the strength reinforcement bar 117 formed in the form of a straight bar is welded to the transverse link 115. [
The reinforcing support 110 is formed in such a manner that the upper end is straight, the clip 111 is formed at the upper end so as to be fastened by the clip in the same line as the column, and the lower end is curved and widened outward.
The clip 111 is formed in a semi-cylindrical shape, and bolt holes 112 are formed on both sides thereof, and are engaged with the legs 3 by the bolts 101.
The reinforced foundation concrete structure 120 is formed in a convex shape and is installed on a side surface of the foundation concrete structure 5 so that the reinforcing support 110 is engaged.
The reinforced foundation concrete structure 120 has a slope at its upper end so as to have the same slope as the lower slope of the reinforcing support 110. [
The reinforced foundation concrete structure 120 is provided with a support flange 121 therein and the flange 113 of the reinforcement support 110 is fixedly coupled to the support flange 121 by bolts 101.
Hereinafter, an earthquake-proof apparatus 100 of a power transmission tower and a substation iron wire reinforced with earthquake-resistant design according to the present invention will be described in detail.
A plurality of transverse connecting rods 115 are welded to one side of the reinforcing supporting rods 110 so as to match the height of the power transmission tower 1 and the strength reinforcing bars 117 ).
Then, the clip 111 is welded to the other side of the reinforcing support 110, and the flange 113 is welded to the bottom.
In this state, when the transmission tower 1 is installed or installed, the reinforcement foundation concrete structure 120 is installed after performing the treading on the side surface of the foundation concrete structure 5.
The reinforcing foundation concrete structure 120 is provided with a support flange 121 and the flange 113 of the reinforcement support 110 is cured with the bolts 101 connected to the support flange 121.
Then, each clip 111 of the reinforcing support 110 is fixed to the leg 3 of the power transmission tower 1 by the bolts 101. Then,
In this manner, reinforcing supports 110 are installed on the four legs 3 of the power transmission tower 1.
Therefore, since the reinforcement support is installed at the side of the bridge of the transmission tower, the lower end of the transmission tower is more stably fixed to the ground.
The power transmission tower and the substation iron core earthquake-proof apparatus 100 with the reinforced earthquake-resistant design according to the present invention further include a dustproof portion 200 for buffering vibrations transmitted from the outside as shown in FIG. 3 to FIG.
The dustproof portion 200 prevents the power transmission tower 3 from being shaken by vibrations caused by an earthquake or the like, thereby maintaining a stable installation state.
The seawater 200 includes a support plate 210 extending outward from the reinforcement support 110, a foundation plate 220 seated on the ground so as to face the support plate 210, A support bar 230 extending upward from the base plate 220 and passing through the support plate 210 and extending outwardly from the support bar 230 so as to be positioned between the base plate 220 and the support plate 210. [ And a binding member 250 which is screwed to the outside of the supporting bar 230 to bind the supporting bar 230 to the supporting plate 210 so as to be positioned on the upper side of the supporting plate 210 do.
The base plates 220 may be connected to one another by welding or the like while having a length enough to be in contact with each other and disposed on the ground so as to be positioned below the reinforcing supports 110.
Alternatively, the base plate 220 may be placed on the ground so as to be positioned outside the transmission tower 3 in the form of a square ring. Needless to say, the reinforcing supports 110 are disposed at the lower portion of the support plate 210 at this time.
The base plate 220 is preferably stably mounted on the ground with a constant load.
One end of the support plate 210 is fixed to the lower portion of the reinforcing support 110 and the other end is extended outward to face the base plate 220.
The support bar 230 is bottomed in the reinforced foundation concrete structure 120.
The support bar 230 may be embedded in the reinforced foundation concrete structure 120 in connection with the support flange 121. At this time, it can be understood that the reinforced foundation concrete structure 120 is cured when the lower portion of the support bar 230 is connected to the support flange 121.
The supporting bar 230 may have threads formed on the outer circumferential surface thereof and the binding member 250 may be screwed to the outside of the supporting bar 230 while forming a thread on the inner circumferential surface thereof.
The binding member 250 is screwed to the outside of the supporting bar 230 so as to be positioned on the upper side of the supporting plate 210 to prevent the supporting bar 230 from being separated from the supporting plate 210. [
The dustproof portion 200 may further include an anti-shake member 260 that is screwed to the outside of the support bar 230 so as to be positioned at an upper portion of the base plate 220.
The anti-shake member 260 binds the support bar 230 to the base plate 220 to prevent contact between the support bar 230 and the base plate 220 in response to vibration due to vibration.
The spring 240 supports the support plate 210 from the base plate 220 while being coupled to the outside of the support bar 230 so as to be positioned between the base plate 220 and the support plate 210, And shrinks and relaxes to cushion the shock.
The seals 200 may further include a flexible tube 270 coupled to the outside of the spring 240.
The flexible tube 270 protects the spring 240 from the outside while allowing the spring 240 to smoothly contract and relax.
The flexible tube 270 is made of a rubber material and has a central portion between both ends protruding outward.
The flexible tube 270 has a shape in which the central portion between both ends is folded or unfolded in accordance with the contraction and relaxation of the spring 240.
Preferably, the flexible tube 270 is filled with a plurality of elastic strands 271 along the periphery thereof.
As a result, the flexible tube 270 can be stiffened, and the spring 240 can be expected to be smoothly folded and unfolded due to shrinkage and relaxation.
Therefore, the dustproof part 200 can buffer the vibration transmitted from the outside, and can prevent the transmission tower 3 from being shaken by the vibration generated due to an earthquake or the like, so that the stable installation state can be maintained.
It is to be understood that the present invention is not limited to the above-described embodiment, but may be modified in various ways within the scope of the following claims It will be understood by those of ordinary skill in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined in the appended claims.

1: Pylon dedicated to the Song 3: Bridge
5: foundation concrete structure 110: reinforcement support
111: clip 113: flange
115: transverse link 115: transverse link
117: Strength reinforcing bar 120: Reinforced foundation concrete structure
200: abutment 210: support plate
220: base plate 230: support bar
240: spring 250: coupling member
260: Anti-shake member 270: Flexible tube
271: Wiring

Claims (1)

Is supported on the ground by being connected to a foundation concrete structure (5) having four legs (3) and a lower end of each leg (3) embedded in the ground,
A clip 111 formed in a straight bar shape and having a lower end inclined outwardly and coupled to the legs at regular intervals, a flange 113 formed at a lower end bottom, A reinforcing support 110 to which a strength reinforcing bar 117 formed in a straight bar shape is attached; And
The present invention relates to a reinforced concrete structure having a reinforced concrete structure that is formed in a convex shape and is installed on a side surface of the foundation concrete structure to be coupled with the reinforcing support frame, In the earthquake-proof apparatus (100)
And a vibration proof portion (200) for absorbing vibration transmitted from the outside,
The sealsection 200,
A support plate 210 extending outwardly from the reinforcing support 110;
A base plate 220 seated on the ground so as to face the support plate 210;
A support bar (230) having a lower portion embedded in the reinforced foundation concrete structure (120) and an upper portion extending upwardly and passing through the foundation plate (220) and the support plate (210);
The supporting plate 210 is supported from the base plate 220 while being coupled to the outside of the supporting bar 230 so as to be positioned between the base plate 220 and the supporting plate 210, A spring 240 that shrinks and relaxes according to shaking and buffers the shock; And
A binding member 250 which is screwed to the outside of the supporting bar 230 to bind the supporting bar 230 to the supporting plate 210 so as to be positioned on the upper side of the supporting plate 210;
The supporting bar 230 is coupled to the base plate 220 while being screwed to the outside of the supporting bar 230 so as to be positioned on the upper part of the base plate 220, (260) for preventing contact between the base plate (220) and the base plate (220). And
And a flexible tube 270 that is coupled to the outside of the spring 240 to protect the spring 240 from the outside while allowing the spring 240 to smoothly contract and relax,
The base plate (220)
And is disposed on the ground so as to be positioned below the reinforcing supports 110. The reinforcing supports 110 are connected to each other by welding,
The flexible tube (270)
The middle portion between the both ends is folded and unfolded in accordance with the contraction and relaxation of the spring 240, while a plurality of elastic strands 271 are embedded along the circumference, Wherein the reinforced concrete structure is reinforced with a rigid structure.

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