KR102457616B1 - Safety reinforcement structure of timbering temparary facility structure - Google Patents

Abstract

The present invention is to provide a safety reinforcement structure of a timbering temporary facility structure. According to the present invention, the safety reinforcement structure of a timbering temporary facility structure for reinforcing the timbering temporary facility structure comprising a plurality of support beams (110) installed upright in an excavation area for facility construction, and a plurality of timbering panels (120) installed between two support beams (110) disposed in a direction crossing each other among the plurality of support beams (110) comprises: a wale (140) installed in a transverse direction crossing the plurality of support beams (110); and a reinforcing support unit coupled to the wale (110) installed in a direction crossing an excavation site for facility construction. The present invention can build the sufficiently robust and safe timbering structure.

Description

Safety reinforcement structure of timbering temporary facility structure

The present invention relates to a safety reinforcement structure of a temporary retaining facility structure, and more particularly, a reduction in the number of installations of support structures such as braces according to the depth of excavation during excavation of the ground for construction of underground structures, etc. and obstacles in using the ground excavation space It relates to a safety reinforcement structure of a temporary retaining structure of a new configuration that minimizes factors and can build a retaining structure sufficiently strong and safely.

Temporary earth retaining facilities are excavated during construction such as buildings, subways, electric power outlets, and sewage pipes. In excavating the ground in the area where buildings are to be constructed, temporary retaining facilities are constructed to prevent the collapse of soil and to install underground structures or structures. Construction work in which the ground is excavated to a predetermined depth and lengthwise direction, such as a building, an excavated tunnel, a subway, an electric power outlet, a communication port, a sewage conduit, and the like, and a structure is installed in the internal space of the excavated ground is often performed.

In such a case, since the excavated ground surface always tends to collapse by the earth pressure (main earth pressure), in general, a vertical beam such as an H pile is first driven into the ground and buried, and then the earth is excavated between the vertical beams while excavating the ground. The excavation ground support hole is installed by inserting a wall (mainly, wood is usually used as a retaining plate).

At this time, a horizontal beam-shaped wale 140 (Wale, usually H-pillar) is installed on the vertical beam where the earth wall is installed, which connects the vertical beams in the horizontal direction to form a lattice type between the vertical beam and the wale 140. This is in order to be able to resist the main earth pressure acting on the structure of the structure more effectively.

However, in the conventional excavation ground support holes, since the size of the earth pressure acting increases as the depth of excavation increases, the number of struts installed according to the depth of excavation increases, and the installation interval decreases, which is a significant obstacle in the use of the excavation space. It takes a lot of effort and time, especially when it is necessary to move the position of an already installed brace during work. Therefore, there is a need for development of a construction technology for temporary retaining facilities that minimizes the number of braces installed if possible.

Korean Patent Publication No. 10-2021-0104486 (published on August 25, 2021) Korean Patent No. 10-0998253 (registered on November 29, 2010) Korean Patent Publication No. 10-2021-0104484 (published on August 25, 2021) Korean Patent Registration No. 10-1939024 (Registered on January 09, 2019)

The present invention has been developed to solve the above problems, and an object of the present invention is to reduce the number of installations of support structures such as braces according to the depth of excavation during excavation of the ground for construction of underground structures, etc. The purpose of this is to provide a safety reinforcement structure of a temporary retaining structure of a new configuration that minimizes obstacles in use and can build a sufficiently strong and safe retaining structure.

According to the present invention for solving the above problems, a plurality of support beams 110 installed upright in an excavation area for facility construction, and two support beams disposed in a direction crossing each other among the plurality of support beams 110 As a safety reinforcement structure of a temporary retaining facility structure for reinforcing a temporary retaining facility structure including a plurality of retaining panels 120 installed between the plurality of support beams 110, a wale 140 installed in the crosswise direction ; Reinforcement support unit coupled to the wales 110 installed in a direction intersecting the excavation site for facility construction; a safety reinforcement structure of the temporary retaining facility structure is provided, characterized in that it comprises a.

The reinforcing support unit may include: a cylinder 223 supported by the support beam 110 and disposed between the wales 140 disposed in an intersecting direction; A pair of cylinder rods 224 drawn out to both ends of the cylinder 223; and extending the pair of cylinder rods 224 of the cylinder 223 to cross the excavation site for facility construction It is characterized in that it supports the support beams 110 by pressing the bands 140 installed in the direction to be.

The reinforcing support unit is connected to the pair of cylinder rods 224 of the cylinder 223 and is installed in a direction crossing the excavation site for facility construction, and first coupled to adjacent support beams 110, respectively. The reinforcing support bar 225 and the second reinforcing support bar 226; characterized in that it further comprises.

As the pair of cylinder rods 224 of the cylinder 223 are elongated, the first reinforcing support bar 225 and the second reinforcing support bar 226 press the wales 140 arranged in a direction crossing each other. It is characterized in that it is configured to firmly support the plurality of support beams 110 installed upright in the facility construction area.

An earth anchor 130 is embedded in the ground for supporting the support beam 110 , and the earth anchor 130 is coupled to the wale 140 , and is formed by the wale 140 and the earth anchor 130 . Supporting the plurality of support beams 110, the earth anchor 130 is embedded so as to be inclined upward in the underground (2), characterized in that the earth anchor 130 is configured to be coupled to the wale (140) do.

An anchoring cap 133 is coupled to the distal end of the earth anchor 130 , and a strap coupling hole communicating on both sides is provided inside the anchoring cap 133 , and the strap coupling inside the earth anchor 130 . A wedge 134 composed of a plurality of divided wedge pieces is inserted into the hole so that the connection strap 132 in the interior of the earth anchor 130 is coupled between the plurality of divided wedge pieces of the wedge 134 , so that the Passing through both sides of the anchoring cap 133, the interval between the plurality of divided wedge pieces of the wedge 134 is narrowed, so that the connection strap 132 is gripped to the earth anchor 130 so that the connection strap 132 is attached. It is characterized in that it supports to be firmly coupled.

a shield frame 180 coupled to an upper portion of the connection support frame 172 by a coupling means; and a shield member (182) provided on the shield frame (180).

The shield frame 180 to which the shield member 182 is coupled is detachably coupled by a coupling means, and the coupling means includes an upper coupling support piece at an upper end and a lower end of the connection coupling support piece 184A, respectively. (184B) and a fixing member 184 having a coupling opening hole at the inner end that is configured in a digut shape having a lower coupling support piece (184C); a hinge (HG) for rotatably coupling the upper coupling support piece (184B) of the fixing member (184) to the shield frame (180); A fixing operation that is slidably coupled to the upper coupling support piece 184B, the upper end protrudes to the outer surface of the upper coupling support piece 184B, and the lower end is disposed at a position facing the upper surface of the connection support frame 172 pin 186; and a fixing operation elastic body 187 for pushing and pressing the fixing operation pin 186 from the fixing member 184 toward the upper surface of the connection support frame 172 .

The shield frame 180 including the shield member 182 is disposed to be mounted on the connection support frame 172 , and the fixing member 184 is attached to the connection support frame based on the hinge HG. In a state in which the fixing member 184 is rotated upwardly upward of the 172 and the fixing operation pin 186 is pulled, the fixing member 184 is rotated downward toward the connection support frame 172 with respect to the hinge HG, so that the fixing member When the 184 is inserted into the connection support frame 172 through the coupling opening hole and then the state in which the fixing operation pin 186 is pulled is released, the fixing operation is performed by the elastic force of the elastic body 187 . The lower end of the operation pin 186 is in elastic contact with the upper surface of the connection support frame 172 so that the shield frame 180 and the shield member 182 are stably fixed to the connection support frame 172 . It is characterized by support.

A band 140 is coupled in the transverse direction to the support beams 110 disposed in a direction crossing each other, and a hook 312 is provided on the first reinforcing support bar 225 and the second reinforcing support bar 226 . It is provided, and the hook 312 of the first reinforcing support bar and the hook 312 of the second reinforcing support bar intersect with each other. As the reinforcing support unit 220 is stably spanned over the two bands 140 arranged in a direction crossing each other, as the pair of cylinder rods 224 of the cylinder 223 are elongated, the second The first reinforcing support bar 225 and the second reinforcing support bar 226 are pressed against the support beams 110 disposed in a direction crossing each other, and configured to support the beams disposed in a direction crossing each other. .

At least one wale 140 disposed in a horizontal direction intersecting with the plurality of support beams 110; further comprising, the support beam 110 is embedded in the ground for supporting the earth anchor 130, The earth anchor 130 is coupled to the wale 140 and is configured to support the plurality of support beams 110 by the wale 140 and the earth anchor 130 .

The wale 140 is disposed so that the upper surface and the lower surface are inclined upward with respect to the horizontal direction, and the earth anchor 130 is buried in the ground so as to be inclined upward, and the earth anchor 130 is coupled to the wale 140 . characterized by being

An anchoring cap 133 is coupled to the distal end of the earth anchor 130 , and a strap coupling hole communicating on both sides is provided inside the anchoring cap 133 , and the strap coupling inside the earth anchor 130 . A wedge 134 composed of a plurality of divided wedge pieces is inserted into the hole so that the connection strap 132 in the interior of the earth anchor 130 is coupled between the plurality of divided wedge pieces of the wedge 134 , so that the Passing through both sides of the anchoring cap 133, the interval between the plurality of divided wedge pieces of the wedge 134 is narrowed, so that the connection strap 132 is gripped to the earth anchor 130 so that the connection strap 132 is attached. It is supported to be firmly coupled, and the connection strap 132 is connected to the wale 140 to firmly support the retaining structure.

According to the present invention, a wale is installed on the support beams installed in the direction intersecting the excavation site for facility construction, and the reinforcement support unit is coupled to the wales arranged in the intersecting direction to firmly support the support beams by the wales. Therefore, there is an effect of supporting the temporary retaining structure more firmly and safely.

In addition, according to the present invention, it is prevented that the number of installation of supporting structures such as braces is increased according to the depth of excavation when excavating the ground for construction of underground structures, etc. It relates to a temporary retaining structure of a new configuration that can remove significant obstacles in the construction process and prevent the case that it takes a lot of effort and time, especially when it is necessary to move the position of a support beam installed during work.

The effect according to the present invention is not limited by the contents exemplified above, and more various effects are included in the present invention.

1 is a perspective view showing an example of construction of a support beam and retaining plate of a temporary retaining facility for being supported by the safety reinforcement structure of the retaining temporary facility structure according to the present invention;
2 is a view showing one side wall of the temporary retaining structure shown in FIG. 1 from the front;
3 is a front view showing an enlarged part of the support beam and retaining plate and wale, which are the main parts shown in FIG. 2;
4 is a side view of an earth anchor which is a main part of the present invention;
Fig. 5 is a cross-sectional view of Fig. 4;
6 is a side cross-sectional view showing a state in which the main part of the retaining structure according to the present invention is a support beam, a retaining plate, a wale, and an earth anchor buried in the ground;
7 is a side view of a reinforcement support unit, which is a main part of a safety reinforcement structure of a temporary retaining facility structure according to the present invention;
8 is a plan view showing a state in which the reinforcement support unit shown in FIG. 7 is coupled to two bands arranged to cross;
9 is a side view of a reinforcement support unit, which is a main part of a safety reinforcement structure of a temporary retaining structure structure according to another embodiment of the present invention;
10 is a plan view showing a state in which the reinforcement support unit shown in FIG. 9 is coupled to two bands arranged to cross;
11 is a side view of another embodiment of a reinforcement support unit, which is a main part of a safety reinforcement structure of a temporary retaining structure structure according to another embodiment of the present invention;
12 is a plan view showing a state in which the reinforcing support unit shown in FIG. 11 is coupled to two support beams arranged to cross, and a state in which a hook is crossed over two bands arranged to intersect;
13 is a plan view showing a state in which a connection support frame, which is a main part of another embodiment of the present invention, is installed in the retaining structure shown in FIG. 1;
14 is a plan view showing a state in which the shield frame is coupled to the connection support frame shown in FIG. 13;
15 is an enlarged side view of a part of the shield frame shown in FIG. 14, showing a state in which a fixing member, which is a main part, is rotated upward based on a hinge;
16 is a side view showing a partially enlarged state before the shield frame shown in FIG. 14 is mounted on the upper surface of the connection support frame;
17 is a side view showing a state in which the shield frame shown in FIG. 16 is mounted on the upper surface of the connection support frame;
18 is a side view illustrating a state in which the shield frame is fixed to the connection support frame of FIG. 17 by a fixing member, a fixing operation elastic body, and a fixing operation pin.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The objects, features and advantages of the present invention will be more readily understood by referring to the accompanying drawings and the following detailed description. In addition, in describing the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted.

In addition, in describing the components of the present invention, terms such as first, second, A, B, (a), (b), etc. may be used. These terms are only for distinguishing the elements from other elements, and the essence, order, or order of the elements are not limited by the terms. When it is described that a component is “connected”, “coupled” or “connected” to another component, the component is directly connected to, or may be connected to, the other component, but there is another component between each component. It should be understood that elements may be “connected,” “coupled,” or “connected.”

1 is a perspective view showing an example of construction of a support beam and retaining plate of a temporary retaining facility to be supported by the safety reinforcement structure of the retaining temporary facility structure according to the present invention, FIG. 2 is a side wall of the retaining temporary facility structure shown in FIG. 3 is a front view showing an enlarged part of the support beam and retaining plate and wale which is the main part shown in FIG. 2, FIG. 4 is a side view of the earth anchor which is the main part of the present invention, FIG. Cross-sectional view, Figure 6 is a side cross-sectional view showing the main part of the support beam, retaining plate, wale, and the earth anchor buried in the ground, which are the main parts of the retaining temporary facility structure according to the present invention, Figure 7 is a safety reinforcement structure of the retaining temporary facility structure according to the present invention One side view of the reinforcement support unit, which is a main part of, FIG. 8 is a plan view showing a state in which the reinforcement support unit shown in FIG. 7 is coupled to two wales arranged to cross, FIG. 9 is a temporary retaining structure structure according to another embodiment of the present invention A side view of a reinforcement support unit, which is a major part of the safety reinforcement structure of A side view of another embodiment of the reinforcement support unit, which is the main part of the safety reinforcement structure of the temporary retaining structure by A plan view showing a state in which two wales are arranged and combined, FIG. 13 is a plan view showing a state in which a connection support frame, which is a main part of another embodiment of the present invention, is installed in the temporary retaining structure shown in FIG. 1, FIG. 14 is FIG. 13 A plan view showing a state in which the shield frame is coupled to the connection support frame shown in FIG. 15 , and FIG. 15 is an enlarged side view showing a part of the shield frame shown in FIG. Figure 16 is a view before mounting the shield frame shown in Figure 14 on the upper surface of the connection support frame A side view showing a partially enlarged state, FIG. 17 is a side view showing a state in which the shield frame shown in FIG. 16 is mounted on the upper surface of the connection support frame, and FIG. 18 is a fixing member and fixing operation of the shield frame on the connection support frame of FIG. It is a side view showing the state fixed by the elastic body and the fixing operation pin.

Referring to the drawings, the temporary retaining structure described in the present invention includes a plurality of support beams 110 installed upright in an excavation area for facility construction, and two supports disposed in a direction crossing each other among a plurality of support beams 110 . It includes a plurality of retaining panels 120 installed between the beams (110).

Referring to Figure 1, in the present invention, a plurality of support beams 110 are installed upright in the front and rear left and right directions in the excavation area excavated for the construction of facilities such as underground structures, and the support beams arranged in the intersecting direction ( It is shown that the retaining panel 120 is coupled between the 110).

The present invention provides a plurality of retaining beams installed between a plurality of support beams 110 installed upright in an excavation area for facility construction, and two support beams 110 disposed in a direction crossing each other among the plurality of support beams 110 . As a safety reinforcement structure of a temporary retaining facility structure for reinforcing the structure of a retaining temporary facility structure including a panel 120, a plurality of support beams 110 are installed in a direction that intersects the excavation site for facility construction. It includes a combined wale 140 and a reinforcement support unit coupled to the wale 110 installed in a direction crossing the excavation site for facility construction.

At this time, in the present invention, the reinforcing support unit, as shown in FIGS. 7 and 8 , is supported by the support beam 110 and is disposed between the wales 140 arranged in the intersecting direction and the cylinder 223 and , and a pair of cylinder rods 224 drawn out to both ends of the cylinder 223 .

At this time, the front end of the pair of cylinder rods 224 is provided with a connection support piece 227, the connection support piece 227 is provided with a bolt through hole, and the front end and the outer surface of one cylinder rod 224 . A bolt coupling hole (a hole formed by drilling the wale 140 of the H-beam structure by drilling, etc.) is provided on one side of the wale 140 facing this, and the bolt that has passed through the bolt through hole of the wale 140 is provided. By fastening the bolt coupling hole, one cylinder rod 224 is fixed to one wale 140, and a connection support piece 227 is also provided at the front end of the other cylinder rod 224, and the connection support piece is provided. 227 is provided with a bolt through hole, and a bolt coupling hole (H-beam structure wale 140) is drilled in the other wale 140 where the front end of the cylinder rod 224 and the outer surface of the other side face each other. hole formed by drilling) is provided, and by fastening the bolt passing through the bolt through hole to the bolt coupling hole of the other side of the belt length 140, the cylinder rod 224 of the other side is connected with the other side of the belt length 140. can be fixed on

In this way, in a state in which the reinforcement support unit 220 is fixed to two bands 140 installed so as to cross the excavation site, a pair of cylinder rods 224 of the cylinder 223 are elongated to cross the excavation site. 140) are supported by pressing, and the support beams 110 are firmly supported by pressing the wale (140).

In the present invention, a reinforcement support unit 220 is installed for each of the two bands 140 installed in the direction intersecting the excavation site for facility construction, and the reinforcement support unit 220 presses the bands 140 to make them strong. and the support beams 110 to which the bands 140 are coupled are all firmly supported by the bands 140, as a result, the bands 140 and the support beams 110 are more firmly supported to prevent It has the effect of supporting the temporary structure more firmly and safely.

Preferably, the connecting support piece 227 is connected to the front end of the cylinder rods 224 via a hinge 227HG. See Figure 8.

In this case, each of the connecting support pieces 227 can be rotated by the hinge 227HG at the distal end of the pair of cylinder rods 224 , and the hinge 227HG at the distal end of the pair of cylinder rods 224 . ) to rotate the connecting support piece 227 by, even if the arrangement angle between the two bands 140 arranged to cross the excavation site is different, each connection of the tip of the pair of cylinder rods 224 It is possible to easily fix the support pieces 227 to the two bands 140 intersectingly arranged. That is, the reinforcement support unit 220 can be smoothly and easily fixed to the two bands 140 regardless of whether the angle of arrangement between the two bands 140 intersected at the excavation site is different. will become

On the other hand, in order to dismantle the reinforcing support unit 220 , loosen the bolts that fixed the connection support piece 227 to each of the bands 140 , and then, a pair of cylinder rods 224 of the cylinder 223 . When retracting, the pair of cylinders 244 release the force supporting the two cross-arranged bands 140 by pressing, so the reinforcing support unit 220 may be disassembled in this state.

On the other hand, in the present invention, the support beam 110 is configured to be connected to the earth anchor 130 embedded in the underground (2). The support beam 110 described in the present invention is made of H-beam.

The wale 140 is coupled in a horizontal direction that intersects the plurality of support beams 110 installed upright, and at least one wale 140 is coupled to the support beam 110 to be disposed in the vertical direction. The band 140 is arranged in parallel in the horizontal direction along the vertical direction of the support beam 110 . The wale 140 is placed on and fixed to a plurality of bar mounting brackets provided on the support beam 110 .

The earth anchor 130 is coupled to the wale 140 and is embedded in the underground 2 at the same time to support the plurality of support beams 110 by the wale 140 . The wale 140 is also made of H-beam. A plurality of connection straps 132 protruding from the distal end of the earth anchor 130 are coupled through the wale 140 . The connection strap 132 may be referred to as a tension member. An anchoring cap 133 is coupled to the distal end of the earth anchor 130 , and a strap coupling hole communicating on both sides is provided inside the anchoring cap 133 , and the strap coupling hole in the interior of the earth anchor 130 . A wedge 134 composed of a plurality of divided wedge pieces is inserted into the . The inner diameter of the strap coupling hole is a tapered hole that decreases from the inner surface of the anchoring cap 133 to the outer surface.

The connection strap 132 in the interior of the earth anchor 130 is coupled between a plurality of divided wedge pieces of the wedge 134 and passes through both sides of the anchoring cap 133, and the front of the anchoring cap 133 As the connection strap 132 is pulled out, the gap between the plurality of divided wedge pieces by the strap coupling hole of the tapered hole structure inside the anchoring cap 133 of the plurality of anchoring caps 133 of the wedge 134 is pulled. This narrows by gripping the connection strap 132 to support the connection strap 132 to be firmly coupled to the earth anchor 130, and the connection strap 132 is connected to the wale 140 to firmly secure the retaining temporary structure structure. support At this time, a part of the connection strap 132 is embedded in the earth anchor 130 , and the other part of the connection strap 132 comes out of the anchoring cap 133 of the earth anchor 130 and is welded to the wale 140 . It can be maintained in a coupled state by the bonding means.

Preferably, the wale 140 is disposed so that the upper surface and the lower surface are inclined upward with respect to the horizontal direction, and the earth anchor 130 is buried in the ground so as to be inclined upward, and the earth anchor 130 is attached to the wale 140 . are combined See Figure 6.

As described above, a plurality of connection straps 132 made of tension members protrude from the distal end of the earth anchor 130, and the earth anchor 130 is buried in the ground in an upward inclined direction and at the same time the connection strap 132. It is coupled to the wale (140).

In the present invention, the earth anchor 130 is buried in an upward inclined direction rather than horizontally buried in the ground, so that the earth anchor 130 is supported by the earth anchor 130 by the load of the ground supported by the retaining panel 120 . ), even if the force to push the retaining panel 120 to the front acts, the force withstanding the load of the earth anchor 130 obliquely buried in the ground is maintained stronger and more robustly.

Preferably, the wale 140 made of H-shaped steel is coupled to the connection strap 132 of the earth anchor 130 and at the same time the upper and lower surfaces of the wale 140 are arranged to be inclined upward with respect to the horizontal direction, the wale 140 ) supports the support beam 110 in the vertical direction and maintains the supporting force more firmly. See Figure 6.

The reinforcing support unit, which is a main part of the present invention, includes a cylinder 223 and a first reinforcing support bar 225 and a second reinforcing support bar 226 .

The cylinder 223 is configured to be provided with a cylinder rod 224 at both ends. A pair of cylinder rods 224 are configured to be withdrawable from the cylinder 223 .

In the present invention, the reinforcing support unit 200 is connected to a pair of cylinder rods 224 of the cylinder 223 and installed in a direction crossing the excavation site for facility construction, respectively, coupled to the adjacent wale sheets 140 . It is configured to further include a first reinforcing support bar 225 and a second reinforcing support bar 226 . A first reinforcing support bar 225 and a second reinforcing support bar 226 are connected to a pair of cylinder rods 224 of the cylinder 223 via a coupler. Preferably, the cylinder rod 224 of one side of the cylinder 223 and the first reinforcing support bar 225 are connected by a coupler so that the first reinforcing support bar 225 is the cylinder rod of one side of the cylinder 223 ( 224), the cylinder rod 224 and the second reinforcing support bar 226 on the other side of the cylinder 223 are connected by a coupler, so that the second reinforcing support bar 226 is connected to the cylinder 223 ) is configured to be detachably coupled to the cylinder rod 224 of the other side. The cylinder rod 224 of the cylinder 223 has a circular bar shape and has a threaded portion on its outer circumferential surface, the first reinforcing support bar 225 is a circular bar and has a threaded portion on its outer circumferential surface, and the coupler has a threaded portion on its inner circumferential surface Consists of a circular sleeve, the threaded portion of the inner peripheral surface of the coupler is commonly coupled to the threaded portion of the outer peripheral surface of the cylinder rod 224 of the cylinder 223 and the threaded portion on the outer peripheral surface of the first reinforcing support bar 225, one side of the cylinder 223 The first reinforcing support bar 225 is detachably coupled to the cylinder rod 224 via a coupler, and the cylinder rod 224 on the other side of the cylinder 223 has a circular bar shape and a threaded portion on the outer circumferential surface. The second reinforcing support bar 226 is a circular bar and provided with a threaded portion on the outer circumferential surface, and the coupler is composed of a circular sleeve having a threaded portion on the inner circumferential surface, so that the threaded portion of the inner circumferential surface of the coupler is the other side of the cylinder 223 The second reinforcing support bar is commonly coupled to the threaded portion of the outer circumferential surface of the cylinder rod 224 and the second reinforcing support bar 226 through the coupler to the other cylinder rod 224 of the cylinder 223. 226) may be configured to be detachably coupled.

When the reinforcing support unit 220 is disposed between two bands 110 installed in a direction crossing the excavation site for facility construction, the cylinder 223 is in the middle and the first reinforcing support bar 225 and The second reinforcing support bar 226 is disposed at a position facing the outer surfaces of the two bands 140 with respect to the cylinder 223, and in this state, a pair of cylinder rods 224 of the cylinder 223 are provided. ), the first reinforcing support bar 225 and the second reinforcing support bar 226 are in close contact with the outer surface of each wale 140, and a plurality of upright installed supports by each wale 140 Since the entire bar 110 is firmly supported, two support beams 110 installed in a direction crossing the excavation site for facility construction by the reinforcing support unit 220 are firmly supported and supported. The reinforcing support unit 220 is disposed and supported between the two bands 140 installed in the direction crossing the excavation site. In FIG. 1 , it is shown that two intersecting support beams 110 are disposed at the four corners of the temporary retaining structure, and the reinforcement support unit 220 is installed in a direction crossing the excavation site. It is installed between the 140 and supports the bands 110 arranged so that the reinforcement support unit 220 intersects two in a total of four places.

At this time, the front end of the first reinforcing support bar 225 is provided with a connection support piece 227 , the connection support piece 227 is provided with a bolt through hole, and the front end of the first reinforcing support bar 225 and the outside The support beam 110 facing the surface is provided with a bolt coupling hole (a hole formed by drilling the support beam 110 of the H beam structure by drilling, etc.), and the bolt passing through the bolt through hole is inserted into the support beam 110 ), fixed to one support beam 110 toward the front end of the first reinforcing support bar 225, and a connecting support piece 227 at the front end of the second reinforcing support bar 226. A bolt through hole is provided in the connection support piece 227, and a bolt coupling hole (H-beam structure support beam) is provided in the support beam 110 where the front end of the second reinforcing support bar 226 and the outer surface face each other. (a hole formed by drilling 110 by drilling, etc.) is provided, and by fastening the bolt passing through the bolt through hole to the bolt coupling hole of the support beam 110, the front end of the second reinforcing support bar 226 can be fixed to the support beam 110 on the other side.

In this way, the first reinforcing support bar 225 and the second reinforcing support bar 226 of the reinforcing support unit 220 are fixed to the two support beams 110 installed to cross the excavation site of the cylinder 223. By extending the pair of cylinder rods 224, the support beams 110 arranged to cross the excavation are supported by pressing.

On the other hand, in order to dismantle the reinforcing support unit 220, the bolt is loosened from the bolt coupling hole of the two support beams 110, and then the pair of cylinder rods 224 of the cylinder 223 are retreated. , Since the force for pressing the first reinforcing support bar 225 and the second reinforcing support bar 226 intersecting the two wales 140 is released, the reinforcing support unit 220 is dismantled in this state. Do it.

Therefore, in the present invention, the reinforcement support unit 220 is installed for each of the two bands 140 installed in the direction intersecting the excavation site for facility construction, and the reinforcement support unit 220 presses the bands 140 . to support it firmly, and the support beams 110 to which the bands 140 are coupled are all firmly supported by the bands 140, as a result, the bands 140 and the support beams 110 are more firmly supported. This has the effect of being able to support the temporary retaining structure more firmly and safely. By supporting the wales 140 and the support beams 110 more firmly and safely by the reinforcement support unit 220, the support beams 110 and the retaining plate support the underground support structure more safely. It has the effect of further enhancing safety during the construction of facilities, etc.

In addition, in the present invention, in accordance with the distance between the cross-arranged bands 140 , the drawing stroke of the pair of cylinder rods 224 of the cylinder 223 (a pair of cylinder rods 224 is extended from the cylinder 223 , or By configuring the retracted distance) to be different, there is also an effect of supporting the bands 140 according to the work site. For example, if the distance at which the pair of cylinder rods 224 of the cylinder 223 must support the two crossed bands 140 is 50 cm, the withdrawal stroke of the pair of cylinders 224 is 50 cm. Thus, when the pair of cylinder rods 224 are elongated by 25 cm, respectively, it is possible to support and support the bands 140 .

On the other hand, in the present invention, the connecting support piece 227 is connected to the front end of the first reinforcing support bar 225 via a hinge 227HG, and a hinge 227HG is attached to the front end of the second reinforcing support bar 226 . It is preferable that the connection support piece 227 is configured to be connected as a medium. See Figures 10 and 12.

In this case, the connecting support piece 227 may be rotated by the hinge 227HG at the front end of the first reinforcing support bar 225 , and the hinge 227HG at the front end of the second reinforcing support bar 226 . ) can rotate the connecting support piece 227, so even if the arrangement angle between the two bands 140 arranged to cross the excavation site is different, the connection support of the front end of the first reinforcing support bar 225 is different. The piece 227 and the connecting support piece 227 of the distal end of the second reinforcing support bar 226 can be easily fixed to the two bands 140 intersectingly arranged. That is, the reinforcement support unit 220 can be smoothly and easily fixed to the two bands 110 regardless of whether the angle of arrangement between the two bands 120 intersected at the excavation site is different. will become

At this time, in the present invention, the wale 140 is coupled in the transverse direction to the support beams 110 arranged in the direction crossing each other. 225) and the second reinforcing support bar 226 are provided with a hook 312, and the hook 312 of the first reinforcing support bar 225 and the hook 312 of the second reinforcing support bar 226 are provided. The reinforcing support unit 220 is stably spanned over the two bands 140 arranged in the direction crossing each other by spanning each wale 140 arranged in a direction crossing each other. 11 and 12, one hook 312 is coupled to the bracket BRK, the bracket BRK is coupled to the first reinforcing support bar 225, and the hook 312 on the other side is also coupled to the bracket (BRK). GRK) and the bracket (BRK) is coupled to the second reinforcing support bar 226 , the hook 312 of the first reinforcing support bar 225 and the hook 312 of the second reinforcing support bar 226 . ) takes the provided structure. Two hook hooks 312 are provided on the first reinforcing support bar 225 , and two hook hooks 312 are also provided on the second reinforcing support bar 226 .

By coupling the wales 140 to the two intersecting support beams 110 disposed at the excavation site of the facility construction area, respectively, two intersecting wales 140 are arranged, and two wales 140 are There is a case where the hook 312 of the first reinforcing support bar 225 and the hook 312 of the second reinforcing support bar 226 are spanned, so that the reinforcing support unit 220 flows down during construction. Since there is no such thing, the reinforcing support unit 220 is spread over two bands 140 arranged in a direction crossing each other.

In this state, as the pair of cylinder rods 224 of the cylinder 223 are elongated, the first reinforcing support bar 225 and the second reinforcing support bar 226 are arranged in a direction crossing each other. It is configured to support all of the support beams 110 that are pressed by the 140 and are disposed in a direction crossing each other. At this time, the hook groove 312CG communicating on both sides of the hook 312 is inserted into one side bar piece 141 of the wale 140 of the H-beam structure to be hung, and the hook penetrated on both sides of the hook 312. The width between the front and rear inner surfaces of the groove 312CG is configured to be larger than the thickness between both surfaces of one side bar piece 141 of the wale 140, so that a pair of cylinder rods 224 of the cylinder 223 are elongated. As the first reinforcing support bar 225 and the second reinforcing support bar 226 move forward, the hook 312 also advances from the transverse bar piece 141 of the wale 140, so that the second When the first reinforcing support bar 225 and the second reinforcing support bar 226 move forward and act to pressurize the wales 140 arranged in a direction intersecting with each other, it can be prevented from causing an obstacle.

In order to dismantle the reinforcing support unit 220 , loosen the bolts that fixed the connection support piece 227 to each of the bands 140 , and then retreat the pair of cylinder rods 224 of the cylinder 223 . When the first reinforcing support bar 225 and the second reinforcing support bar 226, the force pressing the wale 140 at two places is released, and the first reinforcing support bar 225 and the second reinforcing support bar are released. Since each hook 312 of the bar 226 is in a state that spans the two armies of the crossed braids 140, the reinforcing support unit 220 does not sag down, and in this state, the reinforcing support unit Remove (220) and dismantle it.

In addition, the present invention prevents an increase in the number of installations of support structures such as braces according to the depth of excavation when excavating the ground for construction of underground structures, etc. It has the effect of removing significant obstacles and preventing a case that takes a lot of effort and time, especially when it is necessary to move the position of the already installed braces during work.

On the other hand, according to another embodiment of the present invention, the earth anchor 130 is configured in a housing shape having a hollow part therein, and an anchoring cap 133 is detachably coupled to the distal end of the earth anchor 130 . do.

In addition, the anchoring cap 133 is provided with a strap coupling hole 133BH. The strap coupling hole 133BH communicates from the outer surface of the anchoring cap 133 to the inner surface.

A connection strap 132 is coupled to the strap coupling hole 133BH of the anchoring cap 133 and is embedded in the internal space of the earth anchor 130 .

The anchoring cap 133 is coupled to the distal end of the earth anchor 130 in a state in which the earth anchor 130 is buried underground, and the inner end of the anchoring cap 133 is attached to the outer peripheral surface of the connection strap 132. A wedge 134 composed of a plurality of combined wedge pieces is coupled, and the connection strap 132 inserted into the strap coupling hole 133BH of the anchoring cap 133 is embedded into the earth anchor 130 . Since the connection strap 132 is firmly embedded in the earth anchor 130 by the wedge 134 composed of the plurality of divided wedge pieces, the connection strap 132 is separated from the earth anchor 130 . The wale 140 is more reliably prevented from falling off, and this has the effect of more firmly maintaining the support structure of the temporary retaining facility by the wale 140 and the support beam 110 .

On the other hand, as shown in FIG. 13 , in the present invention, a connection support frame 172 is coupled to the upper end of the support beams 110 installed in a direction crossing the excavation site for facility construction among a plurality of support beams 110 . The support beam 110 may be fixed to the upper end of the connection support frame 172 by a fastener such as a bolt. At this time, by allowing the divided individual beams (mainly H beams) to be coupled to the support beams 110 installed in the direction crossing the excavation site for facility construction by fixing means such as bolts and brackets, respectively, the connection support frame 172 ) can be installed.

14 , the upper portion of the connection support frame 172 is detachably coupled to the shield frame 180 having the shield member 182 by means of coupling means. The shield frame 180 is configured in a triangular frame shape by connecting a plurality of frame bars, and a shield member 182 having a mesh structure (mainly, a wire mesh structure) is coupled to the shield frame 180 having a triangular frame shape. Meanwhile, the shield frame 180 may be configured to be fixed to the connection support frame by coupling the divided individual frame bars to the connection support frame by fixing means such as bolts and brackets, respectively.

At this time, the coupling means, as shown in Figs. 15 to 18, the upper end and the lower end of the connection coupling support piece (184A), respectively, having an upper coupling support piece (184B) and a lower coupling support piece (184C) provided with a digutja A hinge (HG) in which a fixing member 184 configured in a shape and having a coupling opening hole at an inner end thereof, and an upper coupling support piece 184B of the fixing member 184 are rotatably coupled to the shield frame 180 . ) and is slidably coupled to the upper coupling support piece 184B, the upper end protrudes to the outer surface of the upper coupling support piece 184B, and the lower end is disposed at a position facing the upper surface of the connection support frame 172 It characterized in that it comprises a fixing operation pin 186 which becomes a fixed operation pin 186, and a fixing operation elastic body 187 which pushes the fixing operation pin 186 from the fixing member 184 toward the upper surface of the connection support frame 172 to be pressed. do it with The fixing operation elastic body 187 is constituted by a spring. The fixing operation elastic body 187 is coupled to the outer peripheral surface of the fixing operation pin 186, the upper end of the fixing operation elastic body 187 is in contact with the lower surface of the upper coupling support piece 184B of the fixing member 184, the fixing operation elastic body Since the lower end of the 187 is in contact with the clasp protruding from the outer circumferential surface of the fixing operation pin 186, the fixing member 184 is not coupled to the connection support frame 172 by the elastic force of the fixing operation elastic body. The lower end of the fixing operation pin 186 elastically contacts the upper surface of the lower coupling support piece 184C of the fixing member 184 .

13 is a side view illustrating a state in which the shield frame 180 is fixed to the connection support frame of FIG. 12 by a fixing member, a fixing operation elastic body, and a fixing operation pin, and is an enlarged side view in the direction A of FIG. 12 .

The connection support frame 172 is configured in a triangular frame shape in which a plurality of H-beams are connected to each other. In a state where the fixing member 184 is not inserted into the upper connection frame piece 172UP of the connection support frame 172, the fixing The lower end of the fixing operation pin 186 is in elastic contact with the upper surface of the lower coupling support piece 184C of the fixing member 184 by the elastic force of the operation elastic body.

17 and 18, the shield frame 180 having the shield member 182 is disposed to be placed on the upper part of the connection support frame 172, and the fixing member 184 is attached to the hinge HG. The fixing member 184 is rotated downward toward the connection support frame 172 with respect to the hinge HG in a state in which the connection support frame 172 is rotated upwardly and the fixing operation pin 186 is pulled. When the fixing member 184 is inserted into the connection support frame 172 through the coupling opening hole and then the state in which the fixing operation pin 186 is pulled is released, the fixing operation is operated by the elastic force of the fixing operation elastic body 187 . The lower end of the pin 186 is in elastic contact with the upper surface of the connection support frame 172 to support the shield frame 180 and the shield member 182 to be stably fixed to the connection support frame 172 . .

The fixing member 184 is rotated downward toward the connection support frame 172 so that the fixing member 184 is fitted into the upper connection frame piece 172UP of the connection support frame 172 through the coupling opening hole, and then When the pulling state of the fixing operation pin 186 is released, the lower end of the fixing operation pin 186 by the elastic force of the fixing operation elastic body 187 is the upper surface of the upper connection frame piece 172UP of the connection support frame 172 . 15 ) to support the shield frame 180 and the shield member 182 to be stably fixed to the connection support frame 172 .

Therefore, in the present invention, a worker who works inside a temporary retaining facility installed in a facility construction area such as an underground structure is protected by the shield member 182 provided in the shield frame 180, and the inside of the excavation site is protected from the outside. When an object is about to fall, the shield member 182 receives an external object while preventing an external object from falling on the operator, thereby increasing the safety of the operator.

In addition, when the shield frame 180 and the shield member 182 are to be lifted out, the fixing member 184 is based on the hinge HG connected to the shield frame 180 in a state in which the fixing operation pin 186 is pulled. Since the shield frame 180 can be lifted after lifting In this case, as described above, the shield frame 180 is disposed to be placed on the upper part of the connection support frame 172 , and the fixing member 184 is moved upward of the connection support frame 172 based on the hinge HG. In a state in which the fixing member 184 is rotated and the fixing operation pin 186 is pulled, the fixing member 184 is rotated downward toward the connection support frame 172 with respect to the hinge HG so that the fixing member 184 is connected through the coupling opening hole. When the fixing operation pin 186 is released after being inserted into the support frame 172, the lower end of the fixing operation pin 186 by the elastic force of the fixing operation elastic body 187 is connected to the support frame ( 172), the shield frame 180 and the shield member 182 can be supported so that the shield frame 180 and the shield member 182 are stably fixed to the connection support frame 172, so that the shield frame 180 and the shield member ( The operation of installing the 182 to the connection support frame 172 is also effective quickly and easily.

In the above, specific embodiments of the present invention have been described above. However, the spirit and scope of the present invention is not limited to these specific embodiments, and various modifications and variations are possible within the scope that does not change the gist of the present invention. Anyone who has it will understand.

Therefore, since the embodiments described above are provided to fully inform those of ordinary skill in the art to which the present invention pertains to the scope of the invention, it should be understood that they are exemplary in all respects and not limiting, The invention is only defined by the scope of the claims.

2. Underground 3. Anchor drill hole
110. Support Beam 112. Connecting Beam
113. Front Beam Piece 114. Rear Beam Piece
120. Retaining Panel 130. Earth Anchor
132. Connection strap 133. Anchoring cap
133 BH. Strap connection hole 134. Wedge
140. Waistcoat 141. Sidebar Opium
172. Connection support frame 180. Shield frame
182. Shield member 184. Fixing member
184A. Connection coupling support piece 184B. upper joint support piece
184C. Lower coupling support piece 186. Fixing operation pin
187. Fixing operation elastic body 220. Reinforcement support unit
223. Cylinder 225. First Reinforcement Support Bar
226. Second reinforcement support bar 227. Connection support piece
312. Hanging hook 312CG. hanger home

Claims (5)

A plurality of support beams 110 installed upright in an excavation area for facility construction, and a plurality of retaining panels 120 installed between two support beams 110 disposed in a direction crossing each other among the plurality of support beams 110 ) as a safety reinforcement structure of the temporary retaining facility structure that reinforces the retaining temporary facility structure comprising:
a wale 140 installed in the cross direction of the plurality of support beams 110;
Including; and a reinforcement support unit coupled to the bands 110 installed in a direction intersecting the excavation site for facility construction.
The reinforcing support unit,
a cylinder 223 supported by the support beam 110 and disposed between the bands 140 disposed in an intersecting direction;
and a pair of cylinder rods 224 drawn out to both ends of the cylinder 223;
Support the support beams 110 by extending the pair of cylinder rods 224 of the cylinder 223 and pressing the bands 140 installed in a direction crossing the excavation site for facility construction,
A connection support frame 172 is coupled to the upper end of the support beams 110 installed in a direction crossing the excavation site for facility construction among the plurality of support beams 110,
a shield frame 180 coupled to an upper portion of the connection support frame 172 by a coupling means; The shield member 182 provided in the shield frame 180; further comprising,
The shield frame 180 to which the shield member 182 is coupled is detachably coupled by a coupling means, and the coupling means includes an upper coupling support piece ( 184B) and a fixing member 184 having a coupling opening hole at the inner end that is configured in a digut shape having a lower coupling support piece (184C); a hinge (HG) for rotatably coupling the upper coupling support piece (184B) of the fixing member (184) to the shield frame (180); A fixing operation that is slidably coupled to the upper coupling support piece 184B, the upper end protrudes to the outer surface of the upper coupling support piece 184B, and the lower end is disposed at a position facing the upper surface of the connection support frame 172 pin 186; and a fixing operation elastic body 187 that pushes the fixing operation pin 186 from the fixing member 184 toward the upper surface of the connection support frame 172 to be pressed.
The shield frame 180 including the shield member 182 is disposed to be mounted on the connection support frame 172 , and the fixing member 184 is attached to the connection support frame based on the hinge HG. In a state in which the fixing member 184 is rotated upwardly upward of the 172 and the fixing operation pin 186 is pulled, the fixing member 184 is rotated downward toward the connection support frame 172 with respect to the hinge HG, so that the fixing member When the 184 is inserted into the connection support frame 172 through the coupling opening hole and then the state in which the fixing operation pin 186 is pulled is released, the fixing operation is performed by the elastic force of the elastic body 187 . The lower end of the operation pin 186 is in elastic contact with the upper surface of the connection support frame 172 so that the shield frame 180 and the shield member 182 are stably fixed to the connection support frame 172 . support,
In a state in which the fixing operation pin 186 is pulled, the fixing member 184 is lifted based on the hinge (HG) connected to the shield frame 180, and then the shield frame 180 is lifted. Reinforcement structure for safety of temporary retaining structure.
delete According to claim 1,
The reinforcing support unit,
A first reinforcing support bar 225 connected to the pair of cylinder rods 224 of the cylinder 223, installed in a direction crossing the excavation site for facility construction, and coupled to adjacent support beams 110, respectively. And a second reinforcing support bar 226; safety reinforcement structure of the temporary retaining structure, characterized in that it further comprises.
According to claim 1,
An earth anchor 130 is buried in the ground for the support beam 110 to support,
The earth anchor 130 is coupled to the wale 140 to support the plurality of support beams 110 by the wale 140 and the earth anchor 130,
The earth anchor 130 is embedded so as to be inclined upward in the underground (2), the earth anchor 130 is a safety reinforcement structure of the temporary retaining structure, characterized in that configured to be coupled to the wale (140).
5. The method of claim 4,
An anchoring cap 133 is coupled to the distal end of the earth anchor 130 , and a strap coupling hole communicating on both sides is provided inside the anchoring cap 133 , and the strap coupling inside the earth anchor 130 . A wedge 134 composed of a plurality of divided wedge pieces is inserted into the hole so that the connection strap 132 in the interior of the earth anchor 130 is coupled between the plurality of divided wedge pieces of the wedge 134 , so that the Passing through both sides of the anchoring cap 133, the interval between the plurality of divided wedge pieces of the wedge 134 is narrowed, so that the connection strap 132 is gripped to the earth anchor 130 so that the connection strap 132 is attached. Safety reinforcement structure of the temporary retaining structure, characterized in that it supports to be firmly coupled.

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