KR101797550B1 - Construction System for Power Transmission Tower of Tubular - Google Patents

Abstract

According to a system to construct a tubular transmission tower of the present invention, to install a tubular transmission tower of a cylindrical shape on an uneven mountainous terrain, a part of the tubular transmission tower is installed in a relatively lower part by using a mountain crane, a guide tower is installed on a tubular post of the previously installed and fixated lower part to be able to vertically move, and an additional tubular post is stacked on an upper part of the tubular post of the lower part by using a stacking crane installed in the guide tower; thereby completing a relatively upper part of the tubular transmission tower. Accordingly, as the guide tower wherein the stacking crane is installed moves to an upper part along the tubular post, the tubular transmission tower is assembled; thereby eliminating a need to install a separate crane post from the ground in order to construct the transmission tower. Moreover, as the guide tower is upwardly moved along the tubular post even if the height of the transmission tower is increased; thus being able to reduce manpower required to adjust the height.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a power transmission tower,

The present invention relates to a tubular transmission tower construction system, and more particularly, to a tubular transmission tower construction system in which a crane is mounted on a tubular support so as to stack an additional tubular support for constructing the transmission tower and pull up and pull the subsidiary materials .

Generally, the installation area of the transmission / distribution tower is often installed on a sloping mountainous terrain with difficult working conditions.

Since the material of the transmission / distribution tower is composed of high-strength pipe or section steel, the crane is often used when installing the transmission tower.

In addition, the steel pylons with these materials are installed only on the flat land. In the assembling method, 100TON crane is used to lift and assemble the members.

Since this type of construction is a method of mounting on a flat land as described above, it is not suitable to install it in a mountainous area by using a helicopter or to install it in a mountainous area by using a rope, and there are many problems in installing a tubular main tower there was.

Korean Registered Patent Publication No. 10-0310991

SUMMARY OF THE INVENTION The present invention has been conceived in order to solve the above-mentioned problems. In order to solve the above-mentioned problems, in order to install a tubular transmission tower having a cylindrical shape on an uneven mountainous terrain, a part of the tubular transmission tower is installed using a mountain crane A guide tower is installed so as to be movable up and down on a tubular support of a lower part which is already installed and fixed and an additional tubular support is stacked on the upper part of the tubular support of the lower part using a laminating crane provided on the guide tower, And the guide tower having the laminated crane is moved upward along the tubular support, so that the tubular transmission tower is assembled. Therefore, it is not necessary to provide a separate crane support from the ground for the construction of the transmission tower, Even though the height is high, The present invention provides a tubular transmission tower construction system capable of reducing the number of workings due to height adjustment since the transmission tower is assembled while being moved upward along the main axis.

In order to accomplish the above object, the present invention provides a tubular transmission tower construction system for installing a cylindrical tubular transmission tower on a mountainous terrain. In the lower part of the tower, a tubular main block having a hollow cylindrical shape is stacked by using a mountain crane A part of the tubular transmission tower is installed; A guide tower is installed vertically movably in the main tubular main block of the lower part already installed; The guide tower is supported on the side surface of the tubular main block in a state where the guide tower is separated from the ground surface, and the tubular main block is moved upwards in a stepwise manner so that the additional tubular main block is laminated from the lower layer to the upper layer, Thereby completing the process.

The tubular main block is provided with an angle portion of a rigid material; A tower support of a rigid material is coupled to the angle portion; The guide tower is formed to have a predetermined length and can be moved up and down while being supported through the tower support.

The angle portion is fixedly coupled at one end to the outer peripheral surface of the tubular main block and the other end extends to the other side; The tower support includes a guide roller which is slidably rotatable on the outer circumferential surface of the guide tower on the inner side, and has an angle connection portion extending in the direction of the angle portion on one side thereof; The angle portion and the angle connection portion are coupled to each other so that the tower support can be fixedly coupled to the tubular main block.

A first fastening ring and a second fastening ring are fixedly secured to a lower outer circumferential surface of the guide tower; A first supporting sheave and a second supporting sheave are provided on the outer circumferential surface of the tubular main block positioned higher than the first fastening and second fastening rings; The first hoisting wire and the second hoisting wire may be connected to the first fastening ring and the second fastening ring, respectively, and then connected to the first winch means on the ground via the first supporting sheave and the second supporting sheath, respectively.

The first towing wire and the second towing wire are simultaneously pulled by the first winch means to move the guide towers upward and then the first and second lifting wires and the second lifting wires are fixed; As the guide tower moves upward, the tower support, which has disengaged from the guide tower, is separated from the angle part and fastened. After that, the guide tower moved upward moves back into the inside of the tower, have.

The first hoistway wire connected to the first hoistway and connected to the first winch means via the first hoistway is fixed to the first hoistway by the first winch means, The installation position of the pulley is moved upward and connected; Then, the second lifting wire connected to the second fastening ring and connected to the first winch means via the second supporting sheave is fixed by the first winch means, and then the installation position of the first supporting sheave is moved upward and connected.

A lamination crane rotatably provided at an upper end of the guide tower for stacking an additional tubular main block on the upper part of the tubular main block already installed, from the lower layer toward the upper layer; The laminated crane may be provided with a laminated wire connected to the second winch means on the ground.

According to the above-described tubular transmission tower construction system of the present invention, in order to install a cylindrical tubular transmission tower on a non-flat mountainous terrain, a part of the tubular transmission tower is installed using a mountain crane in a relatively lower portion, A guide tower is installed so as to be movable up and down on a tubular support of a lower part which is already installed and fixed and an additional tubular support is stacked on the upper part of the tubular support of the lower part using a laminating crane provided on the guide tower, And the guide tower having the laminated crane is moved upward along the tubular support, so that the tubular transmission tower is assembled. Therefore, it is not necessary to provide a separate crane support from the ground for the construction of the transmission tower, Even though the height is high, Along the up and down while holding the tubular moves upward it has the effect of reducing the operation of the airborne height adjustment since the towers are assembled.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a view for explaining a relatively lower construction through a tubular transmission tower construction system according to an embodiment of the present invention,
FIG. 2 is a view for explaining relatively upper-level construction through a tubular transmission tower construction system according to an embodiment of the present invention,
3 is a view for explaining a tubular support according to an embodiment of the present invention,
4 and 5 are views for explaining a guide tower according to an embodiment of the present invention,
6 is a view for explaining a connection between a tubular support and a guide tower according to an embodiment of the present invention,
FIGS. 7 through 17 are views for explaining a process of mutual operation of a tubular strut and a guide tower according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings in order to facilitate a person skilled in the art to easily carry out the present invention.

As shown in FIGS. 1 to 6, the system for installing a tubular transmission tower according to an embodiment of the present invention includes a mountain crane 10, a plurality of tubular main blocks, a guide A tower 500 and winch means.

The mountain crane 10 is for constructing a relatively lower part of the tubular transmission tower according to the present invention. The mountain crane 10 includes a first tubular main block 110, a second tubular main block 120, a third tubular main block 120, The block 130, the fourth tubular main block 140 and the fifth tubular main block 150 are stacked in this order from the lower layer toward the upper layer to install a part of the tubular transmission tower.

The height of the lower part of the transmission tower may be about 15 meters. Depending on the shape of the mountainous terrain and the performance of the mountain crane 10, the height corresponding to the lower part may vary, The number of tubular blocks may also vary.

The guide tower 500 is installed vertically movably in the main part of the lower part of the lower part of the guide tower 500. The guide tower 500 is supported on the side of the main part of the tubular main body in a state of being spaced from the ground, An additional tubular main block is laminated from the lower layer to the upper layer so that the tubular transmission tower of the upper portion is relatively completed.

The tubular main block 140 has a hollow cylindrical shape and has angular portions 221 and 223 made of a rigid material on its outer peripheral surface as shown in Figs.

One end of the angle block is fixedly coupled to the outer circumferential surface of the tubular main block 140 by welding or the like, and the other end of the angle block 140 extends in parallel to the other side.

The angle portion includes a pair of upper angle portions 221 located at an upper portion and a pair of lower angle portions 223 located at a relatively lower portion.

A pair of support sheaves 610 and 630 are connected to the outer circumferential surface of the tubular main block at the upper and lower portions of the upper end of the tubular main block 140.

The pair of support sheaves 610 and 630 may be connected to an upper portion of the lower end of the tubular main block.

The guide tower 500 has a plurality of cylindrical tower blocks connected to each other. As shown in FIG. 4, the first tower block 510 and the second tower block 530 are in close contact with each other in the longitudinal direction The upper portion of the first tower block 510 and the lower portion of the second tower block 530 are included so that the upper portion of the first tower block 510 and the plate tower- The plate 550 is brought into close contact.

The tower connection plate 550 and the first tower block 510 are fixedly coupled to each other by fastening means 570 such as screws or bolts and the tower connection plate 550 and the second tower block 530 are fastened together by fastening means 570. [ And the other tower blocks are fixedly coupled to each other in the same manner so that a plurality of tower blocks are connected to constitute the guide tower 500 having a predetermined length.

As shown in Fig. 5, a pair of fastening rings 591 and 593 is provided on the outer peripheral surface of the guide tower 500 at the lower end thereof.

2, the guide tower 500 penetrates and supports the tower supports 311, 321, 331, and 341 of rigid materials coupled with the angles 211, 221, and 231 provided in the main tubular main block, It can be moved up and down.

6, a guide roller R is slidably rotatable on an outer circumferential surface of the guide tower 500, and an angle portion 211 (see FIG. 6) And an angle connecting portion 313 extending in the direction of the arrow 213. The angle portion and the angle connecting portion 313 are fastened to each other by fastening means and the tower support is fixedly coupled to the tubular main block.

As shown in FIG. 2, the tower support base includes a first tower support 311, a second tower support 321, a third tower support 331, and a fourth tower support 341, The flow hole through which the guide tower 500, which is the inner side of the support, penetrates vertically.

The guide rollers R may be provided in the forward / backward / left / right directions on the inside of the tower supporter. The guide rollers R may be provided in the up / down direction so as to be moved up / Only rotation is possible.

The first lifting wire 710 is connected to the first fastening ring 591 provided at the lower end of the guide tower 500 and the second lifting wire 730 is fastened to the second fastening ring 593.

The first elevating wire 710 connected to the first fastening ring 591 is connected to the lower end of the first tubular main block 110 located on the ground by the first supporting sheave 610, The connection direction is connected to the first winch means W1 via the lower pulley 650 connected to the first winch means W1.

The second lifting wire 730 connected to the second fastening ring 593 is switched in the downward direction via the second supporting sheath 630 and the lower end of the first tubular main block 110 The connection direction is connected to the first winch means W1 via the lower pulley 650 connected to the first winch means W1.

The communication holes of the second tower support base 321, the third tower support base 331 and the fourth tower support base 341 pass through the communication holes of the first tower support base 311 in this order and guide the guide tower 500 When the first elevating wire 710 and the second elevating wire 730 are simultaneously pulled and pulled in the other direction in the direction away from the main tubular block by using the winch means W1 after the inserting, The main tubular main blocks are supported on the side surfaces of the main tubular blocks so that they can move upward in a stepwise manner.

At this time, the first supporting sheave 610 and the second supporting sheave 630 are provided on the outer circumferential surface of the main tubular block located higher than the first fastening loop 591 and the second fastening loop 593, As shown, the first supporting sheave 610 and the second supporting sheave 630 may be respectively provided at the upper and lower portions of the fourth tubular main block 140.

A first tower support 311 is connected to the first upper angle portion 211 of the third tubular main block 130 and a second tower support 311 is connected to the second upper angle portion 221 of the fourth tubular main block 140. [ The third tower support 331 is connected to the third upper angle portion 231 of the fifth tubular main block 150 while the fourth tower support 341 is connected to the third tower support 331 And is provided in the guide tower 500 in the state of FIG.

A turntable-type rotating means 810 for driving a laminated crane 850 which is provided with an additional tubular main block on the upper part of the guide tower 500, And the laminated cranes 850 are connected to the second winch means W2 on the ground to extend a laminated wire 750 for lifting or lowering the main tubular block.

The rotating means 810 is constituted by a roller or the like so that the laminated crane 850 can be rotated by using the guide tower 500 as a rotating shaft and is rotated by the external force to rotate the laminated crane 850, So that the laminated crane 850 can be rotated by the remote control.

7, the laminated wire 750 by the second winch means W2 is wound or unwound by using the laminated crane 850 provided at the upper portion of the guide tower 500 to form the sixth tubular main block 160 are lifted and stacked on top of the fifth tubular main block 150 and then connected to the fourth upper support portion 341 of the sixth tubular main block 160 by a fourth tower support 341 .

Next, in order to further laminate the main tubular block to the top of the sixth tubular main block 160, a process of moving the guide tower 500 upward is performed. First, as shown in FIG. 8, The second supporting sheave 630 connected to the tubular main block 140 is separated and connected to the lower portion of the upper end of the fifth tubular main block 150.

At this time, even if the second supporting sheave 630 connected to the fourth tubular main block 140 is separated, the first lifting wire 710 is fixed to the fourth tubular main block 140 by the first supporting sheave 610 Since the guide tower 500 is connected to the first fastening ring 591 to support the guide tower 500, the guide tower 500 can be maintained in its original position without being moved downward.

When the second supporting sheave 630 is connected to the lower portion of the upper end of the fifth tubular main block 150, the second lifting wire 730 is fixed to the second fixing loop 593 by the second supporting sheath 630 The first supporting sheave 610 connected to the fourth tubular main block 140 can be separated and connected to the lower portion of the upper end of the fifth tubular main block 150, The first supporting sheave 610 and the second supporting sheave 630 connected to the fourth tubular main block 140 are connected to the fifth tubular main block 150 as shown in FIG.

By doing so, the first supporting sheave 610 and the second supporting sheave 630 are positioned higher than the first fastening hook 591 and the second fastening hook 593, .

10, when the first winch wire 710 and the second winch wire 730 are pulled by the first winch means W1, the guide tower 500 is moved upward, and at this time, 500 are moved upward, the guide tower 500 is pulled out from the first tower support 311.

The guide tower 500 is supported only by the second tower support 321, the third tower support 331 and the fourth tower support 341 so that the first tower support 311, the second tower support 321 The third tower support 331 and the fourth tower support 341. The first tower support 311, the second tower support 321, the third tower support 311, 331 and the fourth tower supporter 341 are sequentially moved upward and fastened to the guide tower 500 so that the first tower supporter 311, the second tower supporter 321, the third tower supporter 331, So that the support force of the guide tower 500 by the four tower support stand 341 is maintained.

Accordingly, the first tower support 311 is connected to the first upper angle portion 211, the second tower support 321 is connected to the second upper angle portion 221, and the second tower support 311 is connected to the third upper angle portion 231 The first tower support base 311 is separated from the first upper angle portion 211 while the third tower support base 331 is connected and the fourth tower support base 341 is connected to the fourth upper angle portion 241 And is connected to the second lower-angle portion 223.

11, the second tower support base 321 is separated from the second upper angle portion 221 and connected to the third lower angle portion 233, and as shown in Fig. 12, the third tower support base 331 are separated from the third upper angle portion 231 and connected to the fourth lower angle portion 243 and the fourth tower support portion 341 is separated from the fourth upper angle portion 241 To prepare for connection to the tubular main block to be laminated.

14, the first tower support base 311 is separated from the second lower angle portion 223 and connected to the second upper angle portion 221, and as shown in Fig. 15, the second tower support base 311 321 are separated from the third lower angle portion 233 and connected to the third upper angle portion 231 and the third tower support portion 331 is separated from the fourth lower angle portion 243 The first supporting sheave 610 and the second supporting sheave 630 connected to the fourth upper angle portion 241 and connected to the lower portion of the upper end of the fifth tubular main block 150 are connected to the sixth tubular main block 160 To be connected to the lower part of the upper end of the housing.

When the guide tower 500 is moved upward in this manner to provide a space for laminating additional blocks between the laminated crane 850 and the sixth tubular main block 160, as shown in FIG. 17, the stacking crane 850 The seventh tubular main block 170 is lifted up to be stacked on top of the sixth tubular main block 160 and then the fifth top corner portion 251 of the seventh tubular main block 170 is lifted up to the fourth tower support 170. [ (341).

Then, the guide tower 500 is moved upward by one step in order to further laminate the main tubular block to the top of the seventh tubular main block 170. [

By doing so, the guide tower 500 is supported on the side surfaces of the main tubular blocks in a state where they are spaced from the ground, so that the tubular main blocks of the upper layer portion are further laminated on top of the main tubular blocks of the lower layer portion The tubular transmission tower can be completed.

As described above, according to the present invention, in order to install a cylindrical tubular transmission tower on a non-flat mountainous terrain, a part of the tubular transmission tower is installed using a mountain crane in a relatively lower part, A guide tower is installed on the main tubular block of the lower portion so as to be movable up and down and an additional tubular main block is stacked on top of the main tubular main block of the lower portion using a laminating crane provided in the guide tower, Since the guide tower having the laminated crane is moved upward along the main tubular block and the tubular transmission tower is assembled, it is not necessary to provide a separate crane support from the ground for the construction of the transmission tower, and the height of the transmission tower The guide tower will take up the tubular support up and down. So as to move the upper towers are assembled it can be reduced according to the height adjustment operation airborne.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of illustration, It will be readily apparent that various substitutions, modifications, and alterations can be made herein.

10: mountain crane 110: first tubular main block
120: second tubular main block 130: third tubular main block
140: fourth tubular main block 150: fifth tubular main block
160: sixth tubular main block 170: seventh tubular main block
500: Guide Tower

Claims (7)

A tubular transmission tower of a cylindrical shape is mounted on a mountainous terrain.
In the relatively lower part, a tubular main block having a hollow cylindrical shape is stacked using a mountain crane to install a part of the tubular transmission tower;
A guide tower is installed vertically movably in the main tubular main block of the lower part already installed;
The guide tower is supported on the side surface of the tubular main block in a state where the guide tower is separated from the ground surface, and the tubular main block is moved upwards in a stepwise manner so that the additional tubular main block is laminated from the lower layer to the upper layer, To be completed;
Wherein the tubular main block is provided with an angle portion of a rigid material; A tower support of a rigid material is coupled to the angle portion; The guide tower is formed in a predetermined length and is moved up and down while being supported through the tower support;
Wherein the angle portion has one end fixedly coupled to the outer peripheral surface of the tubular main block and the other end extending to the other side; The tower support includes a guide roller that is slidably rotatable on an outer circumferential surface of the guide tower on the inner side, and has an angle connection portion extending on the one side in the direction of the angle portion; And an angle portion and an angle connecting portion are coupled to each other, and a tower supporter is fixedly coupled to the main tubular block. delete delete [2] The apparatus of claim 1, wherein a first fastening ring and a second fastening ring are fixedly secured to a lower outer circumferential surface of the guide tower, A first supporting sheave and a second supporting sheave are provided on the outer circumferential surface of the tubular main block positioned higher than the first fastening and second fastening rings; And the first hoisting wire and the second hoisting wire are connected to the first fastening ring and the second fastening ring and then connected to the first winch means on the ground via the first supporting sheave and the second supporting sheave respectively. Construction system. [Claim 4] The method of claim 4, wherein the guide tower is moved upward by simultaneously pulling the first lift wire and the second lift wire by the first winch means to move the guide tower upward and then moving the first lift wire and the second lift wire Fix; As the guide tower moves upward, the tower support, which has disengaged from the guide tower, is separated from the angle part and fastened, and then connected to the angle part provided at the corresponding position, Wherein the tubular transmission tower construction system comprises: [5] The apparatus according to claim 4, wherein the first hoistway wire connected to the first fastening ring and connected to the first winch means via the first supporting sheave is fixed by the first winch means The second supporting sheave is moved to the upper position to be connected; And then the second lifting wire connected to the second fastening ring and connected to the first winch means via the second supporting sheave is fixed by the first winch means and then the installation position of the first supporting sheave is moved upward and connected A tubular transmission tower construction system. The apparatus of claim 1, wherein a stacking crane is rotatably mounted on the upper end of the guide tower to stack additional tubular main blocks from the lower layer to the upper layer on top of the tubular main block already installed; Wherein a laminated wire connected to the second winch means on the ground is extended to the laminated crane.

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