KR101306208B1 - Device for lifting of power transmission steel tower - Google Patents

Abstract

The present invention relates to a transmission tower pulling apparatus, and provided between the lower transmission tower and the upper transmission tower to support and raise the upper transmission tower against the separated lower transmission tower, the post is variable in length, and the length of the post And a support for firmly supporting the post so that the state is maintained.
The present invention is provided with a self-propelled height-adjustable lifting equipment that can be mounted on the transmission tower lifting device when the transmission tower is raised, unlike the prior art, by adjusting the height of the transmission tower lifting device to prevent member interference between the existing steel towers.

Description

Transmission tower raising device {DEVICE FOR LIFTING OF POWER TRANSMISSION STEEL TOWER}

The present invention relates to a transmission tower lifting device, and more particularly, to provide a self-propelled height-adjustable lifting equipment that can be mounted to the transmission tower lifting device when the transmission tower is raised to avoid interference with the existing steel tower member when installed on the tower. It is possible to assemble the existing steel tower members for assembling as it is very easy to use it relates to a transmission tower raising device that can improve the work efficiency and ensure the safety and construction quality of workers.

As the industry develops, the demand for electricity is increasing. Accordingly, the number of facilities for transmitting electric power is increasing. In addition, facilities are becoming larger and larger due to urbanization. Due to the enlargement of such facilities, there is an increase in the risk of contact because the safety separation distance between the facilities and the transmission tower where the transmission lines are installed is not secured. In addition, as the safety separation distance is not secured, high-quality power supply and occurrence of failure are also increasing. In order to prevent this, it is necessary to raise the transmission tower in order to secure a safe separation distance between the transmission tower and the facility.

However, in order to raise the transmission tower, it is troublesome to construct a separate temporary transmission tower or a new transmission tower. In order to install such a temporary transmission tower or a new transmission tower, it is difficult to secure a site and a large cost.

Accordingly, a transmission tower raising apparatus for raising a transmission tower is disclosed in Korean Patent Registration No. 10-1038078.

Pylon Upward Construction using transmission tower raising equipment is a new construction method that raises the height of steel tower by raising the top of existing steel tower by constructing a temporary transmission line by installing Helper- Tower on the existing steel tower without establishing a separate steel tower. For example, land problems with land owners due to land development, prolonged consultation period of land stakeholders, delays in lending and permits, generation of civil complaints due to ceasefires, burden of development constraints due to reduced power generation, excessive construction costs, etc. It was possible to solve the realistic difficulties.

In particular, the transmission tower lifting equipment separates the transmission tower body where the electric wire is installed to the top and the bottom, and when lifting the transmission tower by lifting the separated top transmission tower, one end in the transmission tower support device mounted on the transmission tower body. It is configured to include a transmission tower support device for supporting the upper transmission tower mounted on the upper transmission tower and the other end is mounted to the upper transmission tower.

The technical structure described above is a background technique for assisting the understanding of the present invention, and does not mean the prior art widely known in the technical field to which the present invention belongs.

In order to assemble the transmission tower raising equipment (Helper-Tower), the main equipment of the transmission tower raising equipment was mixed for 1.5m and 2.0m in order to minimize the interference with members. However, if the transmission tower raising equipment is installed without sufficient image review and the site situation before installing the transmission tower raising equipment, there is a problem that a difficult situation is encountered during the operation.

In addition, conventionally, since there are various types of steel towers and their connections, there is a problem that there is always a possibility that member interference occurs even when properly mixed and assembled as a main material of transmission tower raising equipment for 1.5m and 2.0m.

In addition, all the wires installed in the existing steel tower were moved to the transmission tower raising equipment, and a temporary transmission line was constructed, and arm interference was applied to the existing steel tower between the upper portion of the existing steel tower, the extension material installation, and the transmission tower raising equipment. If found, there is a problem that it is more difficult to finish the work within a limited truce.

Until now, in order to deal with this situation, the first arm (C1 arm) and the second arm (C2 arm) can be installed in the main tower to move the air to finish the work, but the third arm (C3 arm) raises the transmission tower. After leaving power in the equipment and completing the work on the opposite side, it is troublesome to dismantle the upper part of the transmission tower raising equipment and cease fire again to install the third arm (C3 arm) on the main tower. As the number of workforce increases as the number of truce ceases, it can also cause work deterioration.

Therefore, there is a need to improve this.

The present invention has been made in order to improve the above problems, it is equipped with a self-propelled height-adjustable lifting equipment that can be mounted on the transmission tower lifting device when the transmission tower is raised to avoid interference with the existing steel tower member when installed on the existing tower The purpose of the present invention is to provide a transmission tower raising device for assembling existing steel tower members for assembling, which can be utilized very easily, thereby improving work efficiency and ensuring worker safety and construction quality.

Transmission tower lifting apparatus according to the present invention: a post is provided between the lower transmission tower and the upper transmission tower in order to support and raise the upper transmission tower against the separated lower transmission tower, and the variable length of the post, and the length of the post And a support for firmly supporting the post to maintain the closed state.

The post may include a housing in which one side is opened along an axial direction, and a shaft which is axially inserted into an open side of the housing and is forced out by a hydraulic oil supplied to the housing and whose length is exposed to the outside of the housing. Include.

The support part may include a first clamp member provided on a circumferential surface of a portion of which the length of the post is fixed, a second clamp member provided on a circumferential surface of a portion of the post that is variable in length, and assist in varying the length of the post. And a restraining portion for restraining the variable length of the post by supporting the second clamp member with respect to the first clamp member.

The restraint part is disposed in parallel in the axial direction of the post and is opened to both sides, the lower socket is provided with one side to be accessible to the lower side of the casing and the other side is fixedly connected to the first clamp member, and the casing The upper side of the other side is provided to be accessible and one side includes an upper socket fixedly connected to the second clamp member.

The lower socket and the upper socket is preferably provided by screwing the nut member in close contact with the corresponding end of the casing.

The restraint part further includes a rotation part forcibly rotating the casing in one direction and the other direction to allow the lower socket and the upper socket to enter and exit in different directions with respect to the casing.

The rotating part is constrained to the outer circumferential surface of the casing, the ring member having a concave-convex frame on the outer circumferential surface, the handle for axially inserting the ring member, and the handle is provided in one direction or the other of the handle relative to the ring member And a locking portion for rotating the casing in a direction in which the handle is constrained by restraining the directional rotation.

The locking portion may include a locking pin provided on the handle to allow access to the ring member, an elastic member provided inside the handle to elastically support the locking pin, and a position at which the locking pin is elastically pressed. The hinge is connected to the handle so as to seesaw to form a latching jaw on both sides comprises a latch member corresponding to the rotational direction of the handle is caught on the uneven frame.

The length fixing portions of the posts arranged side by side and the variable length portions of the posts arranged side by side are connected by horizontal members, and the neighboring horizontal members are fixed on a variable rod fixed in a variable length such that a spaced state is supported. It is preferred to be connected.

The variable rod may include a main post hinged to one of the neighboring horizontal members, and may be inserted into the main post so as to be accessible in the axial direction and hinged to another one of the neighboring horizontal members, and a plurality of concave along the axial direction. A subpost having a groove formed therein, a communication hole passing through the inner and outer surfaces of the main post, and having a spherical shape accommodated in each of the communication holes to form a cloud along the concave groove during the axial movement of the subpost. A coupler for rotating the ball member, and a taper surface extending toward the center from the edge along the axial direction of the main post on the inner side to press the ball member when the main post is inserted to fix the position of the subpost. It includes.

The variable rod includes a stopper member detachably coupled to a circumferential surface of the main post, and fixed to an inner surface of the coupler so that one side is supported by the stopper member to move the coupler outward in the axial direction of the main post. It further includes an elastic restoring member to elastically return to the center direction when removing the external force.

As described above, the transmission tower lifting device according to the present invention is provided with a self-propelled height-adjustable lifting equipment that can be mounted on the transmission tower lifting device when the transmission tower is raised, unlike the prior art, and the existing steel tower member when the tower is installed. It is possible to assemble existing steel tower members for assembly, avoiding interference, and thus it is very easy to use, thus improving work efficiency and ensuring worker safety and construction quality.

1 is a front view of a transmission tower lifting apparatus according to an embodiment of the present invention.
Figure 2 is an enlarged view of the transmission tower lifting apparatus according to an embodiment of the present invention.
3 is a cross-sectional view of the transmission tower lifting apparatus according to an embodiment of the present invention.
Figure 4 is an enlarged cross-sectional view of the transmission tower lifting apparatus according to an embodiment of the present invention.
Figure 5 is a perspective view of the main portion of the transmission tower lifting apparatus according to an embodiment of the present invention.
FIG. 6 is an exploded perspective view of FIG. 5. FIG.
7 is a plan sectional view showing the operating state of the rotating unit of the transmission tower lifting apparatus according to an embodiment of the present invention.
Figure 8 is a perspective view of a variable rod of the transmission tower lifting apparatus according to an embodiment of the present invention.
9 is a partially developed view of a variable rod of the transmission tower lifting apparatus according to an embodiment of the present invention.
10 is a cross-sectional view showing a variable rod operating state of the transmission tower lifting apparatus according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described an embodiment of the transmission tower lifting apparatus according to the present invention. In this process, the thicknesses of the lines and the sizes of the components shown in the drawings may be exaggerated for clarity and convenience of explanation. In addition, terms to be described below are terms defined in consideration of functions in the present invention, which may vary according to the intention or convention of a user or an operator. Therefore, definitions of these terms should be made based on the contents throughout this specification.

1 is a front view of a transmission tower lifting apparatus according to an embodiment of the present invention, Figure 2 is an enlarged view of the transmission tower lifting apparatus according to an embodiment of the present invention.

3 is a cross-sectional view of a transmission tower lifting apparatus according to an embodiment of the present invention, Figure 4 is an enlarged cross-sectional view of the transmission tower lifting apparatus according to an embodiment of the present invention.

Figure 5 is a perspective view of the main portion of the transmission tower lifting apparatus according to an embodiment of the present invention, Figure 6 is an exploded perspective view of Figure 5, Figure 7 is a rotating unit operating state of the transmission tower lifting apparatus according to an embodiment of the present invention It is a plan sectional view shown.

8 is a perspective view of a variable rod of the transmission tower lifting apparatus according to an embodiment of the present invention, Figure 9 is a partially developed view of a variable rod of the transmission tower raising apparatus according to an embodiment of the present invention, Figure 10 is a view of the present invention Sectional view showing a variable rod operating state of the transmission tower lifting apparatus according to an embodiment.

1 and 2, the transmission tower lifting apparatus 20 according to an embodiment of the present invention is separated after the transmission tower 10 is installed in the lower transmission tower 14 and the upper transmission tower 12 and then transmission In order to raise the height of the pylon 10 is installed in the form surrounding the transmission tower 10 so as to support the upper transmission tower 12 against the lower transmission tower (14). The transmission tower 10 is a tower made of steel frame or cast iron, and may be, for example, a support of an electric wire for distributing electric power.

Transmission tower lifting device 20 is assembled in a planar circular or polygonal frame is installed in a form surrounding the transmission tower (10). For convenience, the transmission tower lifting device 20 is shown as assembled in a rectangular frame on the plane.

In addition, the transmission tower lifting device 20 can be assembled in a modular structure.

That is, the transmission tower lifting device 20 may be assembled by the vertical member 22, the horizontal member 24 and the diagonal member 26.

The vertical material 22 is an assembly material of the transmission tower raising apparatus 20 assembled in the height direction. The height of the transmission tower pulling apparatus 20 may be determined by the number and length of the vertical members 22.

The horizontal member 24 is an assembly material of the transmission tower raising apparatus 20 assembled in the width direction. The horizontal member 24 may be connected to one side of the vertical member 22 at a right angle with the vertical member 22.

The diagonal member 26 is an assembly member positioned between the vertical member 22 and the horizontal member 24 and assembled in the diagonal direction. The transmission tower lifting device 20 may be assembled into a rectangular frame shape by the vertical member 22 and the horizontal member 24. In addition, the transmission tower lifting device 20 may be assembled to support the corners of the rectangular frame with the diagonal material 26.

The vertical members 22, the horizontal members 24, and the diagonal members 26 constituting the transmission tower raising apparatus 20 are made of circular or polygonal pipes in cross section. Of course, the vertical member 22, the horizontal member 24 and the diagonal member 26 is applicable to a variety of materials.

On the other hand, the vertical member 22 is made of a unit length, provided in the number corresponding to the set height of the transmission tower 10 is connected along the axial direction.

For example, the vertical member 22 has an inlet portion 23 formed on the lower side thereof, and an insertion portion 21 extends on the upper side thereof. Thus, as the insertion portion 21 of the vertical member 22 positioned on the lower side is inserted into the inlet portion 23 of the vertical member 22 positioned on the upper side, the plurality of vertical members 22 are male and female coupled to the axial direction. Connected along. Of course, the neighboring vertical member 22 is preferably bound by a mechanical fastening element such as bolting in a male and female coupled state.

In addition, the transmission tower lifting device 20 may include a temporary wire arm 28.

Temporary wire arms 28 are installed to extend in the lateral direction of the transmission tower lifting device 20. For example, the temporary wire arm 28 may be installed to be connected to the horizontal member 24 of the transmission tower lifting device 20. Temporary wire arms 28 are temporarily installed in the wire tower 10 is installed. The temporary wire arm 28 may be connected to the horizontal member 24 by various methods, and made of an insulating material.

In addition, the lower side of the transmission tower lifting device 20 is preferably fixedly connected to the lower transmission tower (14). Thus, the transmission tower 10 connection device is provided so that the transmission tower lifting device 20 is fixedly connected to the lower transmission tower (14).

The transmission tower connection device 30 may include a transmission tower support device connection end 32, a transmission tower connection end 34, and an angle adjustment end 36.

The transmission tower support device connection end 32 is connected to the lower side of the vertical member 22 located at the lowermost side of the transmission tower lifting device 20.

And, the transmission tower connection end 34 is connected to the lower transmission tower (14). For example, the transmission tower connection end 34 may be in the form of an angle structure that is connected to the lower transmission tower 14 in a cross shape. Of course, the transmission tower connection end 34 may be variously applied.

The angle adjusting end 36 connects the transmission tower support device connection end 32 and the transmission tower connection end 34. The angle adjusting end 36 may adjust an angle between the transmission tower support device connection end 32 and the transmission tower connection end 34. When the transmission tower support device is installed in the lower transmission tower 14 having a slope by the angle adjustment end 36, the transmission tower support device can be easily joined to the lower transmission tower 14 by the angle adjustment. Can be. Of course, the angle adjusting stage 36 may be configured in various ways.

On the other hand, it is necessary to adjust the height of the plurality of transmission tower pulling apparatus 20 spaced by a set distance along the wiring direction of the wire. This is to prevent interference between the wire and the member such as the vertical member 22, the horizontal member 24 or the diagonal member 26 when the wire is wired.

Therefore, the transmission tower raising apparatus 20 according to an embodiment of the present invention further includes a post 100.

2, 3 and 4, the post 100 is provided to support and pull up the upper transmission tower 12 against the separated lower transmission tower 14, the length is variable for height adjustment. In other words, the posts 100 are connected between the vertical members 22 connected along the axial direction. That is, the post 100 is connected to the upper side of the vertical member 22 at the position set at the time of assembly installation of the vertical member 22. In addition, the vertical member 22 is connected to the upper side of the post 100. At this time, the vertical member 22 is fixed in length, the post 100 is variable in length. Of course, although not shown, one or more posts 100 may be installed between the lower transmission tower 14 and the upper transmission tower 12 rather than being interposed between the vertical member 22.

In particular, the post 100 includes a housing 110 and a shaft 120.

The housing 110 is formed such that one side is opened along the axial direction. In addition, the shaft 120 is inserted into the open side of the housing 110 by the hydraulic force supplied to the housing 110 is forced out and the length exposed to the outside of the housing 110 is variable.

That is, the housing 110 includes a first port 112 on one side of the circumferential surface along the axial direction, and a second port 114 on the other side.

Thus, when the hydraulic oil flows into the first port 112, the shaft 120 is drawn outward along the axial direction of the housing 110. As a result, the overall length of the post 100 is increased.

On the contrary, when the hydraulic oil flows into the second port 114, the shaft 120 is drawn inward along the axial direction of the housing 110. As a result, the overall length of the post 100 is reduced. At this time, the working oil is air or oil.

As the length of the posts 100 provided between the vertical members 22 increases, the height of the transmission tower pulling apparatus 20 increases.

In addition, the transmission tower lifting apparatus 20 according to an embodiment of the present invention further includes a support 200.

The support 200 serves to firmly support the post 100 so that the length of the post 100 is maintained.

The support part 200 includes a first clamp member 210, a second clamp member 220, and a restraining part 300.

The first clamp member 210 is provided on a portion of the post 100 that is fixed in length, that is, on the circumferential surface of the housing 110, and the second clamp member 220 is a portion of which the length of the post 100 varies, that is, the shaft. It is provided in the peripheral surface of the 120. That is, the first clamp member 210 is a member clamped to the housing 110 and may be variously formed. The second clamp member 220 is a member clamped to the shaft 120 and may be variously formed.

In addition, the restraining part 300 assists in varying the length of the post 100 and supports the second clamp member 220 with respect to the first clamp member 210 to restrain the variable length of the post 100. Play a role.

That is, when the post 100 gradually supplies the working oil, the restraining part 300 is interlocked with the increase in the length of the post 100 to support the second clamp member 220 with respect to the first clamp member 210. It serves to maintain the length of the 100 is increased.

The restraining part 300 includes a casing 310, a lower socket 320, an upper socket 330, and a rotating part 350.

The casing 310 is disposed side by side in the axial direction of the post 100 and is open to both sides. In particular, one or more casings 310 are disposed along the circumference of each post 100.

And, the lower socket 320 is provided with one side to be accessible to the lower side of the casing 310, the other side is fixedly connected to the first clamp member (210). At this time, the lower socket 320 is screwed to the casing 310 is provided to be accessible to the casing (310). In addition, the lower socket 320 is fixedly connected to the first clamp member 210 fixedly coupled to the housing 110 in various ways.

In addition, the upper socket 330 is provided so that the other side into the upper side of the casing 310 to be accessible, one side is fixedly connected to the second clamp member (220). At this time, the upper socket 330 is screwed to the casing 310 is provided to be accessible to the casing (310). In addition, the upper socket 330 is fixedly connected to the second clamp member 220 fixedly coupled to the shaft 120 in various ways.

In particular, the upper socket 330 and the lower socket 320 is screwed in the opposite direction to the casing (310). Accordingly, when the casing 310 is rotated, the upper socket 330 and the lower socket 320 move in opposite directions along the axial direction of the casing 310 and vary in length.

In addition, the lower socket 320 and the upper socket 330 is screwed to the nut member 340 in close contact with the corresponding end of the casing 310. After withdrawing or withdrawing the lower socket 320 and the upper socket 330 from the casing 310 by the required length, the nut member 340 is screwed in each of the lower socket 320 and the upper socket 330 in the axial direction. It moves along and is in close contact with the end of the corresponding casing 310. Accordingly, the lower socket 320 and the upper socket 330 is to maintain a variable length.

In addition, the rotating unit 350 may force the casing 310 to be rotated in one direction and the other direction in place to allow the lower socket 320 and the upper socket 330 to enter and exit in different directions with respect to the casing 310. Play a role.

As in FIGS. 5, 6, and 7, the rotation part 350 includes a ring member 352, a handle 354, and a locking part 356.

The ring member 352 is constrained to the outer circumferential surface of the casing 310. That is, the casing 310 is axially inserted into the ring member 352. The casing 310 and the ring member 352 are restrained from each other. For example, the outer circumferential surface of the casing 310 and the inner surface of the ring member 352 are recessed to form a key groove 353b at a corresponding position. Thus, a key 353a is accommodated in the pair of key grooves 353b corresponding thereto. Of course, the key 353a may be integrally formed on the outer circumferential surface of the casing 310 or the inner surface of the ring member 352. In this case, the key groove 353b is recessed only on the inner surface of the ring member 352 or the outer circumferential surface of the casing 310 corresponding to the key 353a. Accordingly, when the ring member 352 is forcibly rotated, the casing 310 is rotated together with the ring member 352.

In addition, the ring member 352 forms the concave-convex frame 351 along the circumferential direction on the outer circumferential surface. The concave-convex frame 351 is formed to protrude on the circumferential surface of the ring member 352 to be spaced apart at regular intervals along the circumferential direction.

The handle 354 axially inserts the ring member 352. That is, the handle 354 has an installation portion 355a having a ring shape to insert the ring member 352, and a grip portion connected to the installation portion 355a so that an operator can hold it by hand ( 355b).

At this time, the installation portion 355a is applicable to a variety of shapes, for convenience, it is shown as a pair of branches in the grip portion 355b to insert both edges in the axial direction of the ring member 352. Of course, the ring member 352 may be located between the pair of grip portions 355b.

In addition, the locking portion 356 is provided on the handle 354 to restrict the rotation of the handle 354 in one direction or the other direction with respect to the ring member 352 to force the casing 310 in the direction in which the handle 354 is constrained. It serves to rotate. The locking portion 356 is preferably provided at the end of the grip portion 355b exposed as branched to the installation portion 355a.

For example, the locking portion 356 may include a locking pin 357, an elastic member 358, and a latch member 359.

The locking pin 357 is provided at an end portion of the grip part 355b of the handle 354 to allow access to the ring member 352. At this time, the grip part 355b is recessed to receive the receiving groove 357a to accommodate the locking pin 357 and the elastic member 358.

In addition, the elastic member 358 is provided inside the receiving groove 357a of the handle 354 to serve to elastically support the locking pin 357. At this time, the elastic member 358 is preferably a coil spring. Of course, the elastic member 358 and the locking pin 357 is installed in the grip portion 355b so as not to be completely separated to the outside of the receiving groove 357a.

In addition, the latch member 359 is hinged to the handle 354 so as to seesaw the movement according to the position where the locking pin 357 is elastically pressed. The latch member 359 is preferably hinged to a hinge pin (359b) that is supported on both sides by a pair of mounting portion (355a). Thus, the latch member 359 can be rotated to both sides along the circumferential direction of the ring member 352. At this time, according to the position where the locking pin 357 elastically presses the latch member 359, the latch member 359 is maintained in a state rotated to one side, or maintained in a state rotated to the other side.

In particular, the latch member 359 forms a relatively sharp latching jaw 359a at both sides in the rotating direction. Thus, the latching jaw 359a corresponding to the rotational direction of the handle 354 is caught by the uneven frame 351, so that the latch member 359 restrains the ring member 352 in the rotational direction of the handle 354. Accordingly, the ring member 352 and the casing 310 is forcibly rotated in the corresponding direction. At this time, when the handle 354 is rotated in the direction of the locking step (359a) not caught by the uneven frame 351, the handle 354 is rotated alone without restraining the ring member 352. Accordingly, the operator can rotate the ring member 352 and the casing 310 in a desired direction by standing in place and rotating the handle 354 in both directions.

Of course, the operator rotates the latch member 359 in accordance with the desired rotational direction of the ring member 352, so that the corresponding latching jaw 359a of the latching jaw 359a on both sides of the latch member 359 is uneven frame 351. You can get caught on.

Meanwhile, the length fixing portions of the posts 100 arranged side by side, that is, the housings 110, are connected to the horizontal members 24, and the variable length portions of the posts 100 arranged side by side, that is, the shafts 120, are arranged on the horizontal members 24. Leads to.

In addition, the horizontal member 24 adjacent to each other in the vertical direction between the posts 100 which are arranged side by side is connected to the variable rod 400 which is fixed while being variable in length so as to support a space-adjusted state.

8, 9, and 10, the variable rod 400 includes a main post 410, a sub post 420, a communication hole 430, a ball member 440, a coupler 450, and a stopper member 460. And an elastic restoring member 470.

In particular, the number of the variable rods 400 is not limited, but is shown as provided with two for convenience.

The main post 410 is hinged to one of the neighboring horizontal members 24, that is, the lower horizontal member 24.

Then, the sub post 420 is inserted to enter and exit along the axial direction at one side of the main post 410, is hinged to another one of the neighboring horizontal member 24, that is, the upper horizontal member 24, the axial direction Accordingly, a plurality of concave grooves 422 are formed. At this time, the recess 422 is recessed continuously in the same circumferential direction of the subpost 420, and is disposed to be spaced apart along the axial direction of the subpost 420.

Of course, the main post 410 and the sub post 420 may be connected to a separate member other than the horizontal member 24 included in the transmission tower lifting device 20. That is, the housings 110 and the shafts 120 of the posts 100 arranged side by side may be connected to separate members.

In addition, the communication hole 430 is in communication with the inner and outer communication on the circumferential surface of the main post 410. In this case, at least one communication hole 430 is formed on the same circumferential trajectory of the main post 410.

The ball members 440 are accommodated in each of the communication holes 430 and have a spherical shape, and the ball members 440 are rolled along the concave groove 422 when the subpost 420 moves in the axial direction.

The coupler 450 forms a tapered surface 452 on the inner side of the main post 410 that extends from the edge toward the center in the axial direction. Thus, when the coupler 450 is inserted into one side of the main post 410, that is, the side edge that guides the subpost 420 in and out, the ball member 440 may be caused by friction with the inner surface of the coupler 450. It moves along the concave groove 422 of 420. Then, the ball member 440 is pressed to the inner surface of the coupler 450 to fix the position of the sub post 420. Accordingly, when the coupler 450 is inserted into the main post 410 by a set distance, the subpost 420 is not randomly separated along the axial direction of the main post 410. Here, the 'set distance' is the coupler 450 is the main post until the ball member 440 presses the sub-post 420 in a certain recessed groove 422 by the pressing force on the inner surface of the coupler 450 It refers to the degree to be inserted into one side of the 410.

In addition, the stopper member 460 is detachably coupled to the circumferential surface of the main post 410. In particular, the stopper member 460 is provided on the outer side corresponding to the edge direction from the communication hole 430 in the main post 410. The stopper member 460 is preferably screwed to the circumferential surface of the main post 410.

And, the elastic restoring member 470 is fixed to the inner surface of the coupler 450, one side is supported on the inner side of the coupler 450, the other side is inserted into the end of the coupler 450 to be slidably movable, the main post 410 It is supported by the stopper member 460 coupled to).

At this time, the coupler 450 forms a tapered surface 452 inside one side about the center with respect to the axial direction, and is provided with an elastic restoring member 470 inside the other side and then closed with a stopper member 460 to restore elasticity. The separation of the member 470 is prevented.

Here, the elastic restoring member 470 is preferably a coil spring.

Thus, when the coupler 450 is forcibly moved from the main post 410 to the subpost 420 by the external force, the pressing force for pressing the subpost 420 by the ball member 440 is removed. At this time, the elastic restoring member 470 is compressed so that the elastic restoring force acts.

Thus, the subpost 420 can be pulled out in the axial direction of the main post 410.

Then, when the operator removes the force to pull the coupler 450, the coupler 450 is automatically moved in the opposite direction by the elastic restoring force of the elastic restoring member 470.

At this time, the coupler 450 is moved until the ball member 440 can press and fix the subpost 420.

Looking at the operation of the transmission tower lifting device 20 according to an embodiment of the present invention configured as described above are as follows.

First, an operator gradually supplies hydraulic oil to the first port 112 of the housing 110 of the post 100.

Subsequently, another worker rotates the latch member 359 in a direction corresponding to a direction in which the lower socket 320 and the upper socket 330 are drawn out from the casing 310. Then, the latching jaw 359a located at one side of the latch member 359 is caught by the uneven frame 351 of the ring member 352.

At this time, when the operator rotates the latch member 359, the elastic member 358 is compressed while allowing the latch member 359 to rotate. When the latch member 359 is completely rotated, the locking pin 357 is advanced by the elastic restoring force of the elastic member 358 and presses the latch member 359 so as not to be rotated arbitrarily.

Then, when the operator rotates the handle 354 by a certain amount in one direction, the ring member 352 is rotated in one direction while restraining the casing 310. Thus, the lower socket 320 and the upper socket 330 is gradually drawn out of the casing 310. Here, as the shaft 120 is drawn out of the housing 110 by hydraulic or pneumatic pressure, the operator can turn the handle 354 with a relatively small force.

In addition, when the operator rotates the handle 354 by a predetermined amount in the other direction, since the locking jaw 359a located on the other side of the latch member 359 is not caught by the uneven frame 351 of the ring member 352, the handle 354 is rotated alone relative to the ring member 352. Thus, by the operator reciprocating the handle 354 in place, the lower socket 320 and the upper socket 330 can be finely withdrawn from the casing 310.

As a result, the distance between the horizontal members 24 adjacent to each other in the vertical direction is increased.

In particular, another worker or the worker who rotates the handle 354 forcibly moves the coupler 450 from the main shaft 120 toward the subpost 420 before the handle 354 is rotated.

As a result, the taper surface 452 of the coupler 450 causes the ball member 440 not to press the subpost 420. Thus, in a state in which both sides of the variable rod 400 are hinged to the horizontal members 24 adjacent to each other in the vertical direction, the subpost 420 is drawn out by a length corresponding to the pair of horizontal members 24 away from each other.

At this time, the elastic restoring member 470 is in a compressed state.

The operator stops the supply of the hydraulic oil supplied to the first port 112 after the length of the post 100 is set or increased by a desired distance. Then, the operation of the handle 354 is stopped. At the same time, the operator removes the external force pushing the coupler 450. Then, the coupler 450 is restored to the center direction of the main post 410 by the elastic restoring force of the elastic restoring member 470. At this time, the ball member 440 is pressed on the tapered surface 452 to press the sub post 420, the sub post 420 is fixed by the pressing force of the ball member 440. Of course, since the ball member 440 is located in any concave groove 422, the subpost 420 can be firmly fixed relative to the main post 410.

Likewise, in order for the worker to reduce the overall length of the post 100, the worker supplies hydraulic oil to the second port 114 of the housing 110.

Thereafter, the length of the post 100 is reduced through the above-described process.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, 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 by the appended claims. I will understand. Therefore, the true technical protection scope of the present invention will be defined by the claims below.

10: transmission tower 20: transmission tower raising device
22: vertical material 24: horizontal material
30: transmission tower connection device 32: transmission tower support device connection end
34: transmission tower connection end 36: angle adjustment end
100: post 110: housing
120: shaft 200: support
210, 220: first and second clamp members 300: restraining portion
310: casing 320: lower socket
330: upper socket 340: nut member
350: rotating portion 352: ring member
354: handle 356: locking portion
357: locking pin 358: elastic member
359: latch member 400: variable rod
410: main post 420: sub post
430: communication hole 440: ball member
450: coupler 460: stopper member
470: elastic restoring member

Claims (11)

A post provided between the lower transmission tower and the upper transmission tower to support and lift the upper transmission tower against the separated lower transmission tower, the post being variable in length; And
It includes a support for firmly supporting the post so that the variable length of the post is maintained,
The support part may include a first clamp member provided on a circumferential surface of a part of which the length of the post is fixed;
A second clamp member provided on a circumferential surface of a portion of which the length of the post is variable; And
And a restraining part configured to assist the length of the post, and to restrict the length of the post by changing the length of the post by supporting the second clamp member with respect to the first clamp member.
The restraint part may include a casing disposed side by side in the axial direction of the post and open to both sides;
A lower socket having one side accessible to the lower side of the casing and the other side fixedly connected to the first clamp member; And
The transmission tower of the transmission tower, characterized in that the other side is provided in the upper side of the casing to be accessible, one side is fixed to the second clamp member.
The method of claim 1, wherein the post,
A housing in which one side is opened along the axial direction; And
The transmission tower lift apparatus, characterized in that it comprises a shaft is inserted into the open one side of the housing forcibly entered by the hydraulic oil supplied to the housing and the length is exposed to the outside of the housing.
delete delete The method of claim 1,
The lower socket and the upper socket is a transmission tower lifting device, characterized in that provided by screwing the nut member in close contact with the corresponding end of the casing.
The method of claim 1,
The restraint unit further includes a rotating part forcibly rotating the casing in one direction and the other direction to allow the lower socket and the upper socket to enter and exit in different directions with respect to the casing.
The method of claim 6, wherein the rotating unit,
A ring member constrained to the outer circumferential surface of the casing and having an uneven frame on the outer circumferential surface;
A handle for shaft insertion of the ring member; And
And a locking portion provided on the handle to rotate the casing in a direction in which the handle is constrained by restraining the rotation of the handle in one direction or the other direction with respect to the ring member.
The method of claim 7, wherein the locking portion,
A catching pin provided on the handle to allow access to the ring member;
An elastic member provided inside the handle to elastically support the locking pin; And
The latch pin is hinged to the handle to perform the seesaw movement according to the position in which the locking pin is elastically pressed, and the locking jaw corresponding to the rotational direction of the handle is formed by the locking jaw on both sides, the latch member including the latch member. Transmission tower raising device, characterized in that.
3. The method according to claim 1 or 2,
The length fixing portions of the posts arranged side by side and the length variable portions of the posts arranged side by side are connected by horizontal members;
The neighboring horizontal member is a transmission tower lifting apparatus, characterized in that connected to the variable rod is fixed while the variable length is maintained so that the state is adjusted.
The method of claim 9, wherein the variable rod,
A main post hinged to one of the adjacent horizontal members;
A subpost inserted into the main post to be accessible in the axial direction, hinged to another one of the neighboring horizontal members, and a plurality of subposts formed in the axial direction;
Communication holes that are in communication with the inner and outer circumferential surface of the main post;
A ball member accommodated in each of the communication holes and formed in a spherical shape to be cloud-rotated along the concave groove when the subpost moves in the axial direction; And
And a coupler configured to form a tapered surface extending from the edge toward the center along the axial direction of the main post on the inner surface to press the ball member when the main post is inserted to fix the sub post. Transmission tower raising device.
The method of claim 10, wherein the variable rod,
A stopper member detachably coupled to a circumferential surface of the main post; And
It is fixed to the inner surface of the coupler, the one side is supported by the stopper member, characterized in that it further comprises an elastic restoring member to elastically return to the center direction when removing the external force for moving the coupler outward in the axial direction of the main post Transmission tower raising device.

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