KR101319784B1 - Reinforcement structure of steel tower and reinforcement method thereof - Google Patents

Abstract

The present invention relates to a steel tower reinforcement structure and a reinforcing method, and in particular, reinforcement beam 110 of reinforced concrete material which is installed diagonally in the base portion of the old tower 100; A piers 130 installed below the intersections of the reinforcing beams 110 to transfer the entire load to the ground; It characterized in that it comprises a new steel tower main body 121 for connecting the end of the reinforcing beam 110 and the main material 101 of the old iron tower 100 to form a new iron tower 120, Reinforcing beam installation step (S10) for installing the reinforcement beam 110 of reinforced concrete material in a diagonal direction on the base of the old tower 100 in a state of maintaining 100; Pier installation step (S20) for installing the pier 130 in the lower center of the intersection of the reinforcing beam 110; On the basis of the reinforcing beam 110, a new steel tower installation step (S30) for installing the main material 121 of the new steel tower 120 on the outside of the old steel tower 100, characterized in that By reinforcing the steel tower without replacing or relocating it, it is possible not only to reduce work-related costs but also to reinforce the existing steel tower in an uninterrupted state, so that it is effective in solving problems caused by power interruption.

Description

Reinforcement structure of steel tower and reinforcement method

The present invention relates to a steel tower reinforcement structure and a reinforcing method, and in particular, even when severe floating displacement occurs in the foundation of an existing steel tower due to ground subsidence or failure of foundation materials, the existing steel tower is reinforced or replaced without relocation. It relates to a steel tower reinforcement structure and reinforcement method for enabling.

In general, there are several paths from a power plant to a home to power a home, and the distribution line from the residential area to the home is connected by telephone poles.

On the other hand, in areas outside the city such as rural areas, because it is far from the power plant, it is difficult to deliver power to the place that requires electricity. For this purpose, a high-voltage electric pylon is installed.

1 is a view showing a conventional steel tower.

The conventional steel tower 1 is a truss-type steel structure which is constructed at a height of several tens of meters to construct a transmission line as shown in FIG. 1, and has a weight of several tens to hundreds of tons. It is made of heavy material.

This pylon has four legs 3 arranged in a square, and the bottom of each leg 3 is supported on the ground by being connected to the foundation concrete structure 5 embedded in the ground.

In order to install such a high-voltage electric tower (1), the ground is first formed to form a flat concrete floor horizontally, and then four basic concrete structures are arranged on a square thereon, and each foundation concrete structure Buried inclined at an appropriate angle is completed by assembling the angle (angle) having a certain length on the main pillars exposed to the top in order to the required height in the form of a truss.

However, in the conventional steel tower 1, when a floating displacement occurs due to strong winds, ground subsidence, ground behavior, etc., power supply is interrupted to neighboring residential areas, or an accident such as an overturn of the steel tower occurs. .

As such, in the past, when a problem occurs in an existing steel tower, a new steel tower must be manufactured. However, in order to manufacture a new steel tower, there was a problem of securing a separate steel tower site for a steel tower relocation work. There was a problem that gives a great inconvenience to the operator and the user because a power outage occurs during.

The present invention relates to a steel tower reinforcement structure and a reinforcing method for solving the above problems, and in particular, even when a serious floating displacement occurs on the foundation of the existing steel tower due to ground subsidence of the existing steel tower or poor foundation materials. The purpose is to enable reinforcement without replacing or relocating.

The steel tower reinforcement structure of the present invention includes a reinforcement beam made of reinforced concrete material which is installed diagonally in the base portion of the old steel tower; A piers installed below the intersection of the reinforcing beams to transfer the entire load to the ground; It is achieved by including a new steel tower main material for connecting the end of the reinforcing beam and the main material of the old steel tower to form a new steel tower.

In addition, it is preferable to have a filler plate for connecting the old iron tower and the new iron tower at the connection point of the old iron tower main material and the new iron tower main material.

In addition, it is preferable that the pressure plate is installed on the coupling portion of the old tower main material and the reinforcing beam.

On the other hand, the reinforcing method of the steel tower of the present invention includes a reinforcing beam installation step of installing a reinforcing beam of reinforced concrete material in a diagonal direction on the base of the old tower in the state of maintaining the old tower; A pier installation step of installing a pier below the intersection of the reinforcing beams; It is achieved by including a new steel tower installation step of installing the main material of the new steel tower on the outside of the old steel tower on the basis of the reinforcing beam.

In addition, it is preferable that the filler plate insertion step for connecting the old iron tower and the new iron tower is added by inserting a filler plate at the connection point between the old iron tower main material and the new iron tower main material in the new steel tower installation step.

In addition, in the reinforcing beam installation step, it is preferable to add the acupressure plate installation step for installing the pressure plate in the coupling portion of the main column and the reinforcing beam main body.

The present invention as described above can not only reduce the work-related costs by reinforcing the steel tower without replacing or relocating the existing steel tower, it is possible to reinforce the existing steel tower in an uninterrupted state, which is effective in solving the problems caused by power interruption. It is an invention.

1 is a view showing a conventional pylon,
2 and 3 is a view showing a state in which the old tower and the new pylon combined in the steel tower reinforcement structure of the present invention,
4 is a view showing a coupling relationship between the new pylon and the old steel tower through the pillar plate in the steel tower reinforcement structure of the present invention,
Figure 5 is a view showing a pressure plate installed between the reinforcing beam and the old tower main body in the steel tower reinforcement structure of the present invention.
6 is a flowchart illustrating a method for reinforcing steel tower of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Steel tower reinforcement structure and reinforcement method of the present invention, as shown in Figures 2 to 6, the reinforcement beam 110 is installed on the old installed iron tower 100, and the piers (installed on the reinforcement beam 110) 130 and a new steel tower 120 installed outside the old steel tower 100, and installing a reinforcing beam 110 in the old steel tower 100, and piers below the reinforcing beam 110. 130) and the step of installing the new steel tower 120 on the outside of the old steel tower 100 through the reinforcing beam 110, so that the steel tower can be reinforced without replacing or relocating the existing steel tower In addition to reducing costs, it is possible to reinforce existing steel towers in an uninterrupted state to solve the problems caused by power interruption.

Hereinafter, each component of the steel tower reinforcement structure of the present invention will be described with reference to the accompanying drawings.

First, the steel tower reinforcement structure of the present invention is a reinforcement beam 110 is installed in the old tower 100, the new steel tower 120 is installed outside the old tower 100, the piers installed in the reinforcement beam 110 It is based on 130.

As shown in Figures 2 and 3, the old steel tower 100 is made of a steel structure, the lower portion is connected to the existing foundation 102 is buried in the ground, the upper portion is provided on the ground is formed high toward the sky.

At this time, the old tower 100 is made of a shape that narrows the cross section as it goes upward from the bottom, the old tower 100 is provided with a main material 101 to form an appearance and the main of the old tower 100 The main body 101 is connected to the plurality of auxiliary mains 103 so that the inside is formed in a complex radial shape.

The reinforcement beam 110 is a reinforcement means for supporting the old steel tower 100 and the new steel tower 120 to be described below. The reinforcement beam 110 is formed of a reinforced concrete material and installed at a base corresponding to the bottom of the old steel tower 100. .

On the other hand, the reinforcing beam 110 is installed diagonally in the base portion of the old tower 100, the old tower main body 101 is connected to the existing foundation 102 through the reinforcing beam 110. .

Pier 130 is installed below the intersection of the reinforcement beam 110 formed to cross in the diagonal direction to transfer the load of the new pylon 120 and the old tower 100 to the ground.

At this time, the pier 130 is made of '工' shape, the upper surface is connected to the reinforcement beam 110, the lower surface is buried in the ground to support the load of the old steel tower 100 and the new steel tower 120.

On the other hand, the reinforcement beam 110 is formed to be formed longer in the outer direction than the old tower main body 101, the old tower 100 and the new iron tower from the support block (A) provided at the end of the reinforcing beam 110 ( By connecting the new steel tower main body 121 to the coupling point (B) to which the 120 is coupled to form the new steel tower 120 on the outside of the old steel tower (100).

As such, the pylon 120 is formed through a plurality of pylon tower main body 121, a plurality of the pylon tower auxiliary material 122 is formed between the pylon tower main material 121, the pylon tower main material The pylon 120 is formed through the 121 and the pylon auxiliary material 122.

At this time, the connection plate (B) of the old steel tower main material 101 and the new steel tower main material 121, the pillar plate 140 for interconnecting the old steel tower 100 and the new steel tower 120 as shown in FIG. ) Is preferably provided further.

Here, the pillar plate 140 is made of a panel shape of 6mm thickness, to prevent the coupling force is lowered when connecting the old iron tower main material 101 and the new iron tower main material 121, the old iron tower main material (101) Holes are formed in the main steel tower main material 121 and the pillar plate 140 is connected to the old steel tower main material 101 and the new steel tower main material 121 through bolt fastening.

On the other hand, when the reinforcing beam 110 and the old iron tower main body 101 is combined, the old iron tower main body 101 penetrates the reinforcing beam 110. It is preferable to form a hole in the spherical tower main body 101 at the coupling site so that the pressure plate 150 is installed through the bolt fastening as shown in FIG. 5.

At this time, the acupressure plate 150 is refracted in a 'b' shape, one end is bolted to the old tower main body 101, the other end is inserted into the reinforcement beam 110 of reinforced concrete material in the horizontal direction to the acupressure plate Through 150 to improve the coupling force of the old tower main material 101 and the reinforcing beam (110).

Here, the pressure plate 150 to be installed in the joint portion of the main tower material 101 and the reinforcing beam 110 is installed when the new steel tower 120 is added to reinforce the old tower 100 and the old tower 100 and new Lifting force is generated in the reinforcing beam 110 because the steel tower 120 is maintained in a connected state, the reinforcing beam through the pressure plate 150 installed between the reinforcing beam 110 and the old steel tower main body 101. By lowering the concrete acupressure stress degree of the 110 to improve the binding force of the old tower main body 101 and the reinforcing beam 110 to enable the transfer of load of the foundation foundation 102 connected to the old tower tower base material 101 This is because the lifting force generated in the reinforcing beam 110 can be reduced.

Below with reference to the accompanying drawings, each component for the reinforcement method of the present invention will be described as follows.

First, the steel tower reinforcement method of the present invention includes installing the reinforcement beam 110 in the old steel tower 100 as shown in FIGS. 2 and 6, and installing the piers 130 under the reinforcement beam 110. Step and, based on the step consisting of installing the new pylon 120 outside the old tower 100 through the reinforcing beam 110.

Reinforcing beam installation step (S10) is a step of installing the reinforcing beam 110 in the old tower 100, the base portion corresponding to the bottom of the old tower 100 in the state that the old tower 100 maintains the existing form Install the reinforced beam 110 of reinforced concrete in the diagonal direction.

Pier installation step (S20) is a step to install the pier 130 below the reinforcement beam 110, the pier '130 of the' engine 'shape to be installed below the reinforcement beam 110 to lower the pier 130 It is buried in the ground to transfer the load of the new pylon 120 and the old tower 100 safely to the ground to support the load.

On the other hand, in the reinforcing beam installation step (S10) so that the acupressure plate installation step (S11) for installing the pressure plate (150, see Fig. 5) to the combined portion of the old tower construction material 101 and the reinforcement beam 110 is added to the old tower It is preferable to reduce the lifting force generated in the reinforcing beam 110 when the 100 and the pylon 120 is connected.

The new steel tower installation step (S30) is a step of forming a new steel tower 120 by installing a new steel tower main body 121 on the outside of the old steel tower 100 based on the reinforcement beam 110, the old steel tower 100 From the end portion of the reinforcing beam 110 protruding outwards is installed a new steel tower main body 121 to the upper portion of the old tower 100 needs to be reinforced.

In this case, in the new steel tower installation step (S30), a plurality of new steel tower main members 121 are installed outside the old steel tower 100, and a plurality of new steel tower auxiliary materials 122 are formed between the new steel tower main materials 121. To allow the pylon 120 to be formed radially.

In addition, the filler plate insertion step (S31) for inserting the filler plate (140, see FIG. 4) to the connection point of the old iron tower main material 101 and the new iron tower main material 121 in the new steel tower installation step (S30) is added. It is desirable to be able to improve the bonding force of the old tower 100 and the new steel tower 120 to be.

The steel tower reinforcing structure and reinforcing method of the present invention configured as described above include a reinforcing beam made of reinforced concrete material that is diagonally installed at the base of the old steel tower; A piers installed below the intersection of the reinforcing beams to transfer the entire load to the ground; And a new steel tower main body connecting the end of the reinforcing beam and the main steel material of the old steel tower to form a new steel tower. A reinforcing beam installation step of installing a reinforcing beam of material; A pier installation step of installing a pier below the intersection of the reinforcing beams; And a new steel tower installation step of installing a main material of the new steel tower on the outside of the old steel tower based on the reinforcing beam, thereby reducing work-related costs by reinforcing the steel tower without replacing or relocating the existing steel tower. In addition to being able to reinforce the existing steel tower in the uninterrupted state is an invention having an excellent advantage in solving the problems caused by power interruption.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It is to be understood that various changes and modifications may be made without departing from the scope of the appended claims.

100: old iron tower 101: old tower
110: reinforcement beam 120: new steel tower
121: the owner of the new steel tower 130: pier
S10: reinforcement beam installation step S20: pier installation step
S30: New pylon installation stage

Claims (6)

A main material having an outer shape and connected to a plurality of auxiliary main parts and intersecting in a diagonal direction at a base portion of a spherical tower having a radial shape, and reinforced beams of reinforced concrete material through which the main material of the spherical tower passes;
A piers installed below the intersection of the reinforcing beams to transfer the entire load to the ground;
A plurality of new steel tower main materials connecting the ends of the reinforcing beams with the main material of the old steel tower to form a new steel tower;
The steel tower reinforcement structure comprising a; a plurality of new steel tower auxiliary main body connecting between the new steel tower main material.
The method of claim 1,
The pillar reinforcing structure, characterized in that the filler plate for connecting the old iron tower and the new iron tower is provided at the connection point of the old iron tower main material and the new iron tower main material.
The method of claim 1,
Steel tower reinforcement structure, characterized in that the pressure plate is installed on the coupling portion of the old tower main material and the reinforcing beam.
A reinforcement beam installation step of installing a reinforcement beam made of reinforced concrete material so as to cross diagonally in the base portion of the spur tower while maintaining the spur tower and penetrate the spherical tower main material forming the outer shape of the spur tower;
A pier installation step of installing a pier below the intersection of the reinforcing beams;
And installing a new steel tower main body to form a new steel tower on the outside of the old steel tower based on the reinforcing beam, and connecting the new steel tower main material to a new steel tower auxiliary material. Steel tower reinforcement method.
5. The method of claim 4,
The pillar reinforcement method characterized in that the filler plate insertion step for connecting the old iron tower and the new iron tower by inserting a filler plate at the connection point of the old iron tower main material and the new iron tower main material in the new steel tower installation step.
5. The method of claim 4,
Steel plate reinforcement method characterized in that the step of installing the pressure plate to install the pressure plate in the coupling portion of the main column and the reinforcing beam main body in the reinforcing beam installation step.

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