KR102141468B1 - The transmission tower installation structure of the surface having incline - Google Patents

Abstract

The present invention relates to an electric transmission tower installation structure which can prevent an electric transmission tower from being inclined by loss of ground. An electric transmission tower facility structure includes an electric transmission tower with a transmission line installed in air, and support structures which have different weights and are inserted and installed in corresponding ground to be erected and supported on the ground where the electric transmission tower is placed. The facility structure further includes a binding means to prevent the electric transmission tower from being inclined when ground with an inclined surface is lost by an external influence. The binding means includes: a level control box to sense whether the electric transmission tower is horizontal; a binding unit control box to receive sensing information of the level control box; and a binding unit to penetrate and bind the electric transmission tower and the support structures to prevent the electric transmission tower from being inclined toward the lost ground by a control signal of the binding unit control box.

Description

The transmission tower installation structure of the surface having incline}

The present invention relates to an installation structure of a transmission tower on a ground having an inclined surface among technical fields for transmitting 154 KV or 345 KV of electricity through an overhead transmission line, and more specifically, when the transmission tower is tilted due to the loss of the ground, the binding rod is Since it is inserted into an insertion tube provided in a supporting structure connected to a transmission tower and blocks the occurrence of tilt, it relates to a transmission tower installation structure of a ground having an inclined surface so that the installation state of the transmission tower is maintained on a slope.

In general, the installation area of a transmission tower for transmitting 154 KV or 345 KV of electricity using an overhead transmission line is often installed in a mountainous terrain on a slope with difficult working conditions.

Since the material of the transmission pylon (hereinafter referred to as the ``transmission pylon'') that transmits 154 KV or 345 KV of electricity using overhead transmission lines is made of high-strength pipe or section steel, when installing the transmission pylon, use a crane. The transmission tower with this material supports the load, but is constructed through a support structure using concrete or cement to form an arbitrary flat land.

However, this conventional method supports the support structure due to the influence of weather over a long period of time (for example, absorbed rain or snow, as well as weakening of the ground due to changes in outside temperature) or vibrations due to surrounding construction. The loss occurs due to the weakening, and the loss of the bearing force of the pylon with a significant load decreases due to the loss, resulting in a slow or rapid inclination of the pylon, which causes a safety accident.

Domestic registered patent No. 10-0812197 (Announcement date: 2008.03.10.) Domestic Publication No. 10-2014-140838 (Publication date: 2014.12.10.) Domestic registered patent No. 10-1797550 (Notice: 2017.11.15.)

In order to solve the above-described conventional problems, the present invention detects and detects the inclination of the pylon due to the loss of the ground after installing the pylon on the ground having an inclined surface, thereby quickly and firmly fixing the pylon to the ground. It is an object to provide a structure for installing a transmission tower of a ground having an inclined surface to prevent inclination.

In order to solve the above-mentioned technical problem, the transmission structure of the transmission tower of the ground having an inclined surface according to the present invention has a transmission line and a different weight, but the transmission line can be erected and supported on the ground where the transmission tower is placed. In the transmission tower structure consisting of a supporting structure that is inserted and installed on the ground, the facility structure further includes a binding means for preventing the transmission tower from being inclined when the ground having an inclined surface due to external influence is inclined, the binding means Is a level control box that detects whether the power transmission tower is level, a control unit that receives detection information of the level control box, and a transmission signal through the transmission tower and the supporting structure by the control signals of the control unit, so that the power transmission tower is lost. It characterized in that it comprises a binding portion to prevent the inclination in the direction of the ground.

According to the present invention, when the ground is lost due to an external influence differently from the conventional one and the inclination of the power transmission tower occurs in the lost direction, the inclination is detected in the level control box and the detection information is transmitted to the binding unit control unit. , By the binding rod of the binding portion is inserted into the insertion tube provided in the supporting structure connected to the transmission tower so that no further inclination occurs, it has the effect of safely maintaining the installation state of the transmission tower on the inclined surface.

1 is a conceptual diagram for a transmission tower structure of the ground having an inclined surface according to the present invention.
Figure 2 is a block diagram showing a control unit for the transmission structure of the transmission tower structure of the ground having a slope according to the present invention.
Figure 3 is a view showing a binding portion for the transmission structure of the transmission tower of the ground having a slope according to the present invention.
4 to 6 are views showing the insertion tube for FIG.
7 and 8 is an operational relationship diagram for the transmission structure of the transmission tower of the ground having a slope according to the present invention.

Hereinafter, other objects and features of the present invention in addition to the above object will be apparent through the description of the embodiment with reference to the accompanying drawings, and unless otherwise defined, all terms used herein, including technical or scientific terms, are It has the same meaning as generally understood by a person skilled in the art to which the invention pertains. Terms such as those defined in a commonly used dictionary should be interpreted as having meanings consistent with meanings in the context of related technologies, and should not be interpreted as ideal or excessively formal meanings unless explicitly defined in the present application. Does not.

Hereinafter, with reference to the accompanying drawings, the transmission tower structure of the ground having an inclined surface according to the present invention (hereinafter, simply referred to as'transmission tower tower structure') will be described in detail. Prior to the description, the present invention is fixed with a fastening means (not shown), such as bolts, on the upper portion of the support structure 11 in which the lower part is inserted into the ground G having an inclined surface inclined downward to clarify the gist. An example of a transmission tower 10 equipped with a high-voltage transmission line will be described as an example, but the support structure 11 will have different weights to the rear toward the center of gravity of the transmission tower 10 in an inclined direction of the ground G. Note that it is installed on the ground (G) to have.

First, as shown in Figure 1, the transmission tower structure according to the present invention largely includes a binding means including a level control box 100, a binding unit control box 200 and the binding unit 300, such Advantages of detecting the inclination of the transmission tower 10 when the transmission line 10 is inclined when the ground G on which the inclined surface is formed through the binding means is lost due to weather or construction, etc. Will have

In more detail, as shown in FIGS. 1 and 2, the level control box 100 controls a binding unit to be described later through electric line communication such as a short-range wireless communication network such as Bluetooth or a voice communication network. It is connected to the 200, but is installed on the power transmission tower 10 or the support structure 11 to detect the level of the transmission tower 10, that is, tilt.

To this end, the level control box 100, as shown, is fixed or installed on the outer surface of the transmission tower 10, but is not installed, but is installed on the support structure 11, the transmission tower 10 due to the loss of the ground (G) ) When the support structure 11 is inclined in the lost direction, it senses it and transmits the detection information to the binding control box 200 described later.

The level control box 100 uses a digital level water level, inputs the horizontal value of the first installed transmission tower 10 as a default value, detects a change in the default value, and detects the change in the default value, thereby tilting the transmission tower 10 Be able to judge the degree.

At this time, the slope value transmitted through the level control box 100 may have a slope value of at least 5° to 12° depending on the weight of the transmission tower 10 or the condition of the ground G on which the transmission tower 10 is installed. It is preferable to transmit the detection value to the binding unit control box 200 only when it is detected so that the binding unit 300 can operate through the control of the binding unit control box 200, because the transmission tower This is because it is difficult to bind through the binding unit 300, which will be described later, after tilting at an angle of 12° or more compared to the load of (10).

On the other hand, the level control box 100 in the present invention is provided with a large number to be connected to one binding unit control box 200 to be described later in the front / rear / left / right direction of the transmission tower 10, the ground (G) It is also possible to be installed to detect all the inclination of the transmission tower 10 in response to the loss direction of.

In addition, as shown in FIG. 2, the bundling control box 200 is connected to the level control box 100 described above, as well as the bundling unit 300, which will be described later, by electric line communication to control the level ( 100) in a configuration to determine whether or not the binding unit 300 operates according to the slope value transmitted from the receiving unit 210, the operating unit 220, and the confirmation sensor 230 respectively controlled by the micom 240 ), and may be installed in a box (BOX) form inside/outside the transmission tower 10 or the binding support 310. (See FIG. 7)

For example, the receiving unit 210 is connected to the level control box 100 and a communication network, but receives the gradient information provided by the level control box 100 and transmits it to the microcomputer 240.

The microcomputer 240 receiving the tilt information has a binding unit 300 to be described later by rapidly applying power to the operation unit 220 so that the transmission tower 10 is no longer tilted in the lost direction of the ground G It is possible to bind the power transmission tower 10 by operating through the operation unit 220.

At this time, the operation unit 220 refers to a configuration that enables the tension/contraction operation of the cylinder 330 constituting the binding unit 300, and the operation unit 220 depends on the type of the cylinder 330. It is desirable to be able to supply air pressure or hydraulic pressure.

In addition, the operation unit 220 in the present invention is not limited to being able to operate the cylinder 330, and other configurations other than the cylinder 330 (for example, deviating from the binding rod through a combination of motor and gear) Device).

In addition, the confirmation sensor 230 is configured to check whether the binding rod 350 has been smoothly operated through the operation of the operation unit 220 described above, that is, the binding rod 350 has been lowered to a predetermined position. .

As shown, the confirmation sensor 230 may be provided on the bottom surface of the insertion groove 311 formed on the upper surface of the binding support part 310 in close proximity to the guide tube 320, and confirmed to protrude on the lower surface of the stopper 351 When the protrusion 353 is inserted into the insertion groove 311, after being pressed by the confirmation protrusion 353, an electrical ON state is performed so that the electrical signal can be transmitted to the microcomputer 240, The microcomputer 240 can determine that the binding rod 350 stably descends along the guide tube 320. (See FIG. 4)

Of course, the confirmation sensor 230 is provided on the lower surface of the stopper 351 in which the confirmation protrusion 353 is omitted, not the binding support unit 310, so that the confirmation sensor 230 is lowered by the downward movement of the stopper 351. It is also possible to be pressed by the outer surface of the support 310 to transmit the electrical signal to the microcomputer 240.

On the other hand, the binding unit control box 200 in the present invention may further include a plurality of sensors 250 provided adjacent to each other in the longitudinal direction of the insertion tube 340 provided in the support structure 11, the confirmation sensor It is also possible to allow the microcomputer 240 to determine the insertion depth of the binding rod 350 inserted into the insertion tube 340 through the sensor 250 together with the 230.

At this time, the micom 240 confirms whether the sensor 250 detects that the insertion depth of the binding rod 350 inserted into the insertion tube 340 is not inserted up to the set depth by an algorithm preset by the operator. When possible, it is desirable to promptly display it to the outside through an alarm or light to inform the warning signal.

That is, the transmission tower structure in the present invention detects the inclined value changed in the level control box 100 when the transmission tower 10 is inclined in the lost direction due to the loss of the ground G, and the corresponding transmission tower 10 ) Adopts a method of quickly binding to the binding unit 300 according to the control signal of the binding unit control box 200 so that it is no longer inclined, and the power transmission tower 10 due to insufficient immediate response to the lost speed The binding may not occur or the binding may not be stable. (See FIGS. 7 and 8)

In this case, the micom 240 determines whether the transmission tower 10 is stable or not according to the detection result of the sensors 250 provided adjacent to each other in the longitudinal direction of the insertion tube 340, and this is confirmed by an unspecified number of people. It is possible to perform additional measures on this by displaying it as a sound or lighting signal.(See FIG. 5)

Then, the binding unit 300, as shown in Figures 3 to 6, in accordance with the control signal of the above-described binding unit control box 200, the transmission tower 10 is inclined in the direction of the lost ground (G) It is configured to prevent the binding unit 310, a guide tube 320, a cylinder 330, an insertion tube 340 and a binding rod 350.

For example, the binding support 310 is a structure that can be fixed by the ground (G) is inserted into the ground (G) the lower portion, that is, the support structure for supporting the above-described power transmission tower (10) to the ground (G It has the same function as 11).

The cylinder 330 is fixedly installed on the upper surface of the binding support part 310, and the guide tube 320 is installed to have a length in the vertical direction, so that the binding rod 350 can be moved up and down inside the guide tube 320. It has a structure.

The guide tube 320 provided inside the binding support 310 is installed so that the opened upper part can be opened, but the lower part is inserted into the rock layer in the ground G so that it can be installed together with the binding support part 310. .

That is, when the inclination of the power transmission tower 10 is prevented by the descending binding rod 350, the guide pipe 320 and the guide pipe 320 guiding the binding rod 350 to move up and down in the vertical direction Since the installed binding support 310 is supported on the rock layer, the inclination of the corresponding transmission tower 10 is further maximized and prevented.

The cylinder 330 provided on the upper surface of the binding support 310 has a structure capable of tensioning/shrinking in the horizontal direction by the control signal of the above-described operation unit 220, and the binding rod 350 by the tension/shrinking The through-hole 355 formed in and out to allow the bundling rod 350 to descend quickly or maintain a state prior to descending.

Insertion pipe 340, as shown, so that the upper portion of the opening can be opened to the outside so as to have a length in the vertical direction to the support structure 11 so that the upper portion can be inserted when the binding rod 350 is lowered It is provided.

At this time, the insertion tube 340 is made of a cone shape whose inner diameter gradually narrows from the top to the bottom, and even when the transmission tower 10 is inclined at a certain angle due to the loss of the ground G, the binding rod 350 is It is desirable to have a structure that can be easily inserted through the opened upper portion.

That is, referring to FIGS. 7 and 8, the power transmission due to the insertion of the binding rod 350 in the insertion tube 340 in the process of inclining the power transmission tower 10 at a predetermined angle in the direction of loss of the ground G The present invention, which blocks the inclination of the pylon 10, clearly takes time even if the cylinder 330 described above is rapidly contracted and detached from the through hole 355 formed in the binding rod 350. , Due to this time difference, it may occur that the binding rod 350 cannot be inserted into the opened upper portion of the insertion tube 340.

In order to prevent this problem, the insertion tube 340 in the present invention largely forms the opened upper diameter D1 to which the binding rod 350 is to be inserted, but the lower portion thereof is narrow in comparison with the diameter D2 of the upper portion. By having a losing shape, the ease of insertion of the bundling rod 350, as well as the narrowing diameter after the bundling rod 350 is inserted, stably binds to the tilt of the transmission tower 10 It is possible.

In addition, as shown in the insertion tube 340 in the present invention, a plurality of sensors 250 are provided adjacent to each other in the longitudinal direction of the binding rod 350 inserted into the insertion tube 340 The insertion depth is sensed so that it can be transmitted to the micom 240 (see FIG. 4).

The binding rod 350 is formed to have a rod shape as a whole, but the upper portion is bent in an arc shape to compensate for the gap between the support structure 11 and the binding support portion 310, so that the upper end thereof is the support structure 11 ) Is inserted into the insertion tube 340 formed therein, the lower portion of which is inserted into the guide tube 320 provided in the binding support part 310 to allow the lifting.

In addition, a through hole 355 for the rod to enter and exit is formed on the outer surface of the binding rod 350, that is, on the surface facing the rod end of the cylinder 330.

Furthermore, a stopper 351 is formed on the outer surface of the binding rod 350 to limit the insertion depth of the binding rod 350 descending within the guide tube 320 by the contraction of the cylinder 330, and the ring as necessary After the 357 is further formed and the lowering of the bundling rod 350 is easily raised through equipment such as a crane (not shown) when it is raised, the rod of the cylinder 330 is through-hole 355 It is inserted into the initial state (the state before the binding rod descends).

The structure of the transmission tower according to the present invention having such a configuration is different from the conventional one, and the ground (G) is lost due to an external influence, and when the tilt of the transmission tower (10) occurs in the lost direction, level the inclination. After detecting the control box 100 and transmitting the detection information to the binding unit control box 200, the binding rod 350 of the binding unit 300 is provided in the support structure 11 connected to the transmission tower 10 By being inserted into the inserted tube 340 so that no further inclination occurs, it is possible to install a safe power transmission tower 10 even on the ground G where the inclined surface is formed.

As described above, the present invention has been described by specific matters such as specific components, etc., and by limited embodiments and drawings, which are provided to help the overall understanding of the present invention, but the present invention is not limited to the above embodiments , Anyone having ordinary knowledge in the field to which the present invention pertains can make various modifications and variations from these descriptions.

Accordingly, the spirit of the present invention should not be limited to the described embodiments, and should not be determined, and all claims that are equivalent to or equivalent to the claims as well as the claims described below belong to the scope of the spirit of the present invention. .

100: level control box 200: binding control box
210: receiving unit 220: operating unit
230: confirmation sensor 240: microcomputer
250: sensor 300: binding unit
310: binding support 311: insertion groove
320: guide tube 330: cylinder
340: insertion tube 350: binding rod
351: stopper 353: check protrusion
355: through hole 357: ring
10: Transmission tower 11: Support structure
G: Ground

Claims (1)

A transmission structure in which the transmission line is installed on a high altitude and a support structure 11 having different weights, but inserted and installed in the corresponding ground G so that the transmission line 10 can be erected and supported on the ground G In the transmission tower structure structure consisting of),
The facility structure further includes a binding means for preventing the transmission tower 10 from tilting when the ground G having an inclined surface is formed due to external influences.
The binding means controls the level control box 100 for detecting whether the transmission tower is horizontal, the control unit 200 for receiving the detection information of the level control box 100, and the control for the binding unit control box 200 It includes a binding unit 300 to pass through the transmission tower 10 and the support structure 11 by a signal to prevent the transmission tower 10 is inclined in the direction of the lost ground (G),
The binding unit 300 includes a binding support unit 310, a guide tube 320, a cylinder 330, an insertion tube 340, and a binding rod 350, wherein the binding support unit 310 has a lower portion Inserted and fixed to the ground (G), the upper portion is formed to protrude to be exposed from the ground (G), and the guide tube (320) penetrates the binding support (310) so that the opened top is exposed to the binding support (310). Thus, the lower portion is installed to penetrate the rock layer, and the cylinder 330 is controlled by the binding part control box 200, but the rod is inserted into the through hole 355 formed in the binding rod 350. It is fixedly installed on the upper portion of the binding support portion 310, the insertion tube 340 is inserted and installed to have a length in the vertical direction so that the opened upper portion is exposed on the upper surface of the support structure 11, the binding rod 350 is the outer surface The through hole 355 is formed, but the upper part is formed of a rod shape bent in an arc shape, inserted into the guide tube 320, and the rod of the cylinder 330 is contracted, so that the through hole 355 When separated, the upper part of the arc shape is inserted into the insertion tube 340, so that the binding support part 310 and the support structure 11 are fixedly connected to each other by the binding rod 350. Transmission structure of the transmission tower on the ground with a slope.

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