KR100758546B1 - The overthrow preventive construction of high pressure electricity steel tower - Google Patents

Abstract

A structure for preventing overthrow of a high pressure electricity steel tower is provided to firmly support the high pressure electricity steel tower by coupling a caisson to legs of the high pressure electricity steel tower by using an anchor. A structure for preventing overthrow of a high pressure electricity steel tower comprises a steel drum anchor(110), a support post caisson(120), a coupling bolt(130), and a base concrete structure(140). The steel drum anchor(110) includes upper and lower cylindrical openings, a disk-shaped base plate soldered to the upper surface thereof, and a first flange soldered to the bottom surface thereof. The support post caisson(120) includes a second flange having a shape corresponding to the first flange. The coupling bolt(130) are coupled to the first flange of the steel drum anchor(110) and the second flange of the support post caisson(120) to fix the first and second flanges.

Description

OVERTHROW PREVENTIVE CONSTRUCTION OF HIGH PRESSURE ELECTRICITY STEEL TOWER}

1 is a view showing a general transmission tower;

Figure 2 is a front view showing a high-voltage electric pylon base fall prevention structure according to the present invention,

Figure 3 is an exploded perspective view showing the configuration of the steel drum anchor and the support pile caisson of the reinforcing structure of the transmission tower according to the present invention.

<Description of Main Configuration of Drawing>

1: high-voltage electric tower 3: bridge

110: steel drum anchor 120: support pile caisson

130: fastening bolt 140: foundation concrete structure

The present invention relates to a high-voltage electric tower base fall prevention structure, and more particularly, to a high-voltage electric tower foundation fall prevention structure to prevent the occurrence of conduction phenomenon due to strong winds, ground subsidence, ground behavior and the like.

There are many homes in the public living quarters and new homes are also being built. Each house is inhabited by people, so supplying power is necessary to operate household appliances necessary for people's residence.

To power each house, there are several routes from the power plant to the house. Distribution lines from residential areas to houses are usually through telephone poles.

However, out-of-city areas, such as rural areas, are far from power plants. In addition, in order to reach a place that requires electricity, various types of features are located, it is common to install a high-voltage electric tower to pass through the features.

As shown in FIG. 1, the high-voltage electric tower 1 as described above is a truss-type steel structure which is constructed at a ground height of several tens of meters in order to construct a transmission line. It consists of a heavy material to reach. 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 pylon, first, the ground is broken to form a flat concrete floor horizontally, and then there are four basic concrete structures that are arranged in a square on it, and at an appropriate angle to each foundation concrete structure. An angle (angle) having a certain length on the main pillars exposed to the top is inclined to be inclined to assemble in sequence in a truss to the required height to complete.

However, such a high-voltage electric tower has a conduction phenomenon due to strong winds, ground subsidence, ground behavior, etc. As a result, large-scale accidents such as accidents such as power outages of nearby residential areas and damage caused by overturning occur.

The present invention is to solve the above problems, by connecting the bridge of the caisson fixed by the grouting mortar and the high-voltage electric tower to the ground, it is not known that the conduction phenomenon occurs due to strong wind, ground subsidence, ground behavior, etc. It is an object of the present invention to provide a high-voltage electricity pylon-based conduction prevention structure to prevent.

Features of the present invention for achieving the above object,

A truss structure, having four legs arranged in a square shape, the base structure of a high-voltage electric tower installed on the ground; A steel drum anchor having an upper and lower surfaces formed in an open cylindrical shape, a base plate having a disk shape welded to an upper surface thereof, and a first flange formed to have a disk shape welded to a lower surface thereof; A support pile caisson formed on an open cylindrical upper surface and welded to a second flange of a shape corresponding to the first flange and inserted into the soft ground layer; A fastening bolt fastened to the first flange of the steel drum anchor and the second flange of the support pile caisson to fix them to each other; And it characterized in that it comprises a foundation concrete structure that is poured from the upper end of the support pile caisson to the legs of the high-voltage electric pylon.

Here, the support pile caisson is provided with a mortar discharge hole forming a plurality of rows in the longitudinal direction, mutually adjacent mortar discharge holes are formed to cross each other, the second flange is formed with a mortar injection hole in the center.

Here, the base plate of the steel drum anchor is welded to the leg of the high-voltage electric tower on the upper surface.

Hereinafter, described in detail with reference to the accompanying drawings the configuration of the high-voltage electric pylon base fall prevention structure according to the present invention.

In the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted. Terms to be described later are terms defined in consideration of functions in the present invention, and may be changed according to intentions or customs of users or operators. Therefore, the definition should be made based on the contents throughout the specification.

Figure 2 is a front view showing a high-voltage electric pylon base fall prevention structure according to the present invention, Figure 3 is an exploded perspective view showing the configuration of the steel drum anchor and the support pile caisson of the reinforcing structure of the transmission tower according to the present invention. In FIG.2 and FIG.3, the structure same as FIG.1 attaches | subjects the same code | symbol, and the duplication description is abbreviate | omitted.

2 and 3, the reinforcing structure 100 of the transmission tower according to the present invention, the steel drum anchor 110, the support pile caisson 120, the fastening bolt 130, the foundation concrete structure Consisting of 140.

First, the steel drum anchor 110 is formed in a cylindrical shape with the upper and lower surfaces open, the base plate 111 of the disc shape is welded to the upper surface, the first flange 113 formed in the shape of a disc on the bottom is welded. . Here, the base plate 111 of the steel drum anchor 110, the leg 3 of the high-voltage electric tower 1 is welded to the upper surface.

The support pile caisson 120 is formed in a cylindrical shape with an open top surface, and a second flange 121 of a shape corresponding to the first flange 113 is welded and inserted from the ground layer to the rock line. Here, the support pile caisson 120 is provided with a mortar discharge hole 123 forming a plurality of rows in the longitudinal direction, the mortar discharge holes 123 adjacent to each other are formed to cross each other, the second flange 121 ) Is a mortar injection hole 125 is formed in the center.

In addition, the fastening bolt 130 is fastened by the nut 131 to the first flange 113 of the steel drum anchor 110 and the second flange 121 of the support pile caisson 120 to fix them mutually.

In addition, the foundation concrete structure 140 is poured from the upper end of the support pile caisson 120 to the leg 3 of the high-voltage electric tower 1.

Hereinafter, the installation process of the reinforcing structure of the transmission tower according to the present invention will be described in detail with reference to the accompanying drawings.

First, the ground is carried out to the depth where the foundation concrete structure 140 is inserted, and then four supporting pile caissons 120 are excavated in a position corresponding to the legs 3 of the transmission tower 1. Insert into the rock line using).

Then, the grouting mortar is injected into the support pile caisson 120 through the mortar injection hole 125 formed in the second flange 121 using a grouting equipment (not shown).

Then, the grouting mortar is discharged to the ground through the mortar discharge hole 123 of the support pile caisson 120 to firmly fix the support pile caisson 120 to prevent settlement and fall.

In this state, the second flange 121 of the support pile caisson 120 and the first flange 113 of the steel drum anchor 110 are fastened to each other using the fastening bolts 130. At this time, the upper surface of the base plate 111 of the steel drum anchor 110 is a state in which the leg 3 of the high-voltage electric tower 1 is welded in advance.

Then, the base concrete structure 140 is poured to fix the upper and lower portions of the steel drum anchor 110.

Subsequently, an angle (angle) having a predetermined length on the legs 3 exposed from the foundation concrete structure 140 is sequentially assembled in a truss shape up to a required height to complete the high-voltage electric tower.

Therefore, before placing the foundation concrete structure of the high-voltage electric tower, put the caisson to the ground rock line, inject the grouting mortar into the caisson and fix it, and fasten the legs of the caisson and the high-voltage electric tower by using anchors, By installing the foundation concrete structure, it can firmly support the high-voltage electric tower.

According to the present invention, the structure of the high-voltage electricity pylon base conduction prevention structure configured as described above, by connecting the bridge of the caisson and the high-voltage electricity pylon fixed by grouting mortar on the ground, conduction phenomenon occurs due to strong wind, ground subsidence, ground behavior, etc. There is an advantage that can be prevented in advance.

As those skilled in the art would realize, the described embodiments may be modified in various ways, all without departing from the spirit or scope of the present invention. It is to be understood, however, that the present invention is not limited to the specific forms referred to in the description, but rather includes all modifications, equivalents, and substitutions within the spirit and scope of the invention as defined by the appended claims. Should be.

Claims (3)

delete A truss structure, which has four legs arranged in a square, and is the basic structure of the high-voltage electric tower installed on the ground, A steel drum anchor having an upper and lower surfaces formed in an open cylindrical shape, a base plate having a disk shape welded to an upper surface thereof, and a first flange formed to have a disk shape welded to a lower surface thereof; A support pile caisson formed on an open cylindrical upper surface and welded to a second flange of a shape corresponding to the first flange and inserted into the soft ground layer; A fastening bolt fastened to the first flange of the steel drum anchor and the second flange of the support pile caisson to fix them to each other; And In the high-voltage electricity pylon basic fall prevention structure configured to include a foundation concrete structure that is poured from the upper end of the support pile caisson to the legs of the high-voltage electricity pylon, The support pile caisson, A mortar discharge hole having a plurality of rows in a longitudinal direction is provided, and adjacent mortar discharge holes are formed to cross each other, and a mortar injection hole is formed at the center of the second flange. Fall prevention structure. delete

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