KR100934443B1 - River frontal reinforcement structure with protective rod - Google Patents

Abstract

According to the present invention, in a river front reinforcement structure having an inclined adaptive structure, a concrete layer 104 is formed on a river bottom surface adjacent to the river law surface, and the rubble layer 114 composed of a plurality of layers on the concrete layer. It is formed by stacking stepwise along the inclined surface of the river law surface, each rubble layer is formed surrounded by a rubble escape prevention wire mesh 112, the seed cloth is formed inside the wire mesh to surround the rubble layer, A plurality of horizontal members 108 are inserted in the middle of the plurality of rubble layers, and vertical members are coupled between the upper and lower horizontal members, and at least some vertical members are formed to be adjacent to the outer edge of the wire mesh. It is coupled across the vertical member by a coupling clamp, a plurality of bolt holes are formed in the horizontal member, both sides of the vertical member However, a bolt hole is formed in the horizontal member, and the bolt penetrating the bolt hole of the horizontal member and the bolt hole of the vertical member is coupled to the nut, thereby coupling the horizontal member and the vertical member, and a plurality of radial ribs are formed radially around the bolt hole of the horizontal member. And a plurality of radial ribs are formed radially around the bolt hole of the vertical member, and the horizontal member and the vertical member can be joined at various angles by changing the coupling angle through the coupling between the radial ribs. It relates to a reinforcement structure.

Rivers, rubble, reinforcement

Description

A reinforcing structure for a riverside incline with protecting sticks}

1 is a schematic diagram of one embodiment of the present invention.

2 is a schematic view from another direction of an embodiment of the present invention.

3 and 4 are views for explaining the configuration associated with the fastening of the protective rod.

5 is a view for explaining the coupling of the horizontal member and the vertical member.

6 is a view for explaining the combination of the protective net and the vertical member and / or horizontal member.

<Description of Major Symbols in Drawing>

100: river bottom 102: water

104: concrete layer 105: circular ring

106: vertical material 107: protective rod

108: horizontal material

112: wire mesh 114: rubble layer

The present invention relates to a river surface reinforcement structure.

In order to prevent the fall of the river surface in preparation for natural disasters such as floods, there has been a conventional method of forming a concrete structure on the river surface. However, in this case, there are disadvantages and problems such as excessive cost to install the structure and not environmentally friendly due to excessive use of concrete.

Of course, you can take the method of stacking the Gabion method on the surface, but as time passes, damage to the wire mesh occurs due to the impact of the stones scattered in the river, and the existing shape is deformed or collapsed due to the separation of rubble. The problem was on the rise.

The present invention simply reduces the construction period and construction costs required for river surface reinforcement simply by taking a method of stacking rubble, while preventing the loss of rubble and effectively preventing damage to the rubble escape prevention net. The purpose is to provide a structure.

It is also an object of the present invention to be able to adaptively change the structure according to the inclination of the inclined surface.

According to the present invention, in the stream reinforcement structure, the concrete layer 104 is formed on the bottom surface of the river adjacent to the river normal surface, and the rubble layer 114 composed of a plurality of layers on the concrete layer forms the slope of the river surface. It is stacked and formed step by step, wherein each rubble layer is formed surrounded by the rubble escape prevention wire mesh 112, the inner seed of the wire mesh is formed to surround the rubble layer, the plurality of rubble A plurality of horizontal members 108 are formed in the middle, vertical members are coupled to each other between the upper and lower horizontal members, and some of the vertical members connecting the upper and lower horizontal members are installed to be adjacent to the outer edges of the wire mesh. It is coupled across the vertical member by a coupling clamp, a plurality of bolt holes are formed in the horizontal member, A bolt hole is also formed at the side end, and the horizontal member and the vertical member are coupled to each other by being fastened to the nut by a bolt passing through the bolt hole of the horizontal member and the bolt hole of the vertical member, and the horizontal member 108 and the vertical member 106 coupled to each other. Each bolt ball is formed with radial ribs 109 and 111 which can be joined to each other in radial directions from the center of the bolt ball, i.e. radially at regular intervals, thereby changing the coupling between the radial ribs. It relates to a river surface reinforcement structure, characterized in that the coupling angle of 106) can be changed. (If the structural angle is firmly explained, when the joint angle is not 90 °, the torque to rotate the vertical member due to the weight of the vertical member acts.The vertical member is prevented from rotating by the radial ribs, so it is easy to join an angle other than 90 °. This principle can be seen by looking at the radial ribs shown in the drawing of Figure 5).

Here, the protective rod coupling clamp is composed of four ring-shaped bent portion of the L-shape, the ring portion is formed with a bolt hole, in the state in which the protective rod is disposed in the middle of the two ring portions in the vertical material The bolts that penetrate the bolt holes in both rings are coupled to the nut, and are coupled to each other by bolts passing through the bolt holes in both rings at the lower side. And, the log is coupled to prevent the log from coming out, the wire mesh 112 is formed with a plurality of circular rings, the wire mesh is coupled by the horizontal member and / or the vertical member is coupled through the circular ring .

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIG. 1, concrete is poured on a river bottom surface adjacent to a river law surface to first form a concrete layer 104. Thereafter, a plurality of layers of reinforcement structures are formed step by step on the concrete layer. That is, the rubble forms the rubble layer 114 in a form trapped in the wire mesh 112. At this time, the wire mesh surrounding the rubble layer is formed by bending a c-shaped shape encircling the rubble layer in a state in which a part of the wire mesh is covered and fixed by the rubble layer, or a wire mesh laid under the rubble, vertical wire mesh, covering the top of the rubble. Each wire mesh is formed of individual wire meshes. The rubble layer inside the wire mesh is filled with soil. On the other hand, the rubble layer is covered with a vegetation sheet containing a plant seed called a seed sheet (not shown) inside the wire mesh, that is, between the wire mesh and the rubble layer. On the other hand, the outside of the wire mesh is formed by combining the frame structure consisting of a horizontal member and a vertical member to the wire mesh to be structurally securely supported. By enclosing the layer of rubble filled with seed sack, the seeds contained in the seed stalk will germinate and grow the plant.

As shown in FIG. 6, a plurality of circular rings 105 may be formed on one surface of the wire mesh, and the wire mesh may be coupled by inserting a horizontal member and / or a vertical member into the circular ring. Through the combination of the horizontal member and / or the vertical member through the circular ring, the gap between the wire mesh and the wire mesh is prevented by earth pressure at the boundary between the wire mesh and the wire mesh, and the structural stability is sustained, thereby preventing the separation of rubble.

On the other hand, on the rubble layer on one layer, another rubble layer is formed stepwise along the river slope, and of course, the rubble layer is surrounded by a wire mesh to prevent the separation of rubble and the inner layer of the wire mesh surrounds the rubble layer by a seed cloth. Preferably, the outer edge of the wire mesh is also firmly supported by the horizontal and vertical members. The rubble layer at the top is stacked on top of the rubble layer at the bottom and is in close contact with the rubble layer at the bottom by its own weight.

Thus, a plurality of rubble layers are stacked in a step shape, but the rubble layer is surrounded by a c-shaped wire to prevent the separation of rubble. Of course, a wire mesh laid under the rubble, a wire mesh standing vertically, and a wire mesh covering the top of the rubble may be formed as individual wire meshes. Furthermore, the frame structure composed of a plurality of horizontal and vertical members is formed on the outer side of the wire mesh to be coupled to the wire mesh to form a skeleton of the entire structure. In other words, between the rubble layer at the bottom and the rubble layer at the top, the horizontal members are formed to be sandwiched in several places, and the vertical members are fastened between these horizontal members, but some of the vertical members are formed adjacent to the outer edge of the wire mesh. . At this time, the coupling between the vertical member and the horizontal member is preferably performed by fastening the bolts through the plurality of bolt holes formed in the horizontal member and the bolt holes formed at both ends of the vertical member to the nut. However, a plurality of radial ribs 109 are radially formed around the bolt hole of the horizontal member, and a plurality of radial ribs 111 are formed radially around the bolt hole of the vertical member, thereby changing the coupling angle through the coupling between the radial ribs. As a result, the horizontal member and the vertical member are formed to be coupled at various angles. As a result, as shown in FIG. 1, the vertical members are coupled to the horizontal members at various angles, even if they are not vertical, thereby making the slope of the rubble inclined like the slope of the vertical members, thereby forming a more stable structure and different specifications according to the slope of the river. The construction cost can be reduced by not only needing the vertical and horizontal members, but also by using the vertical and horizontal members of the same standard to be installed on various slopes. (If the structural angle is firmly explained, when the joint angle is not 90 °, the torque to rotate the vertical member due to the weight of the vertical member acts.The vertical member is prevented from rotating by the radial ribs, so it is easy to join an angle other than 90 °. This principle can be seen by looking at the radial ribs shown in the figure of FIG. 5).

On the other hand, as shown in Figure 1, as shown in Figure 1, the protective rod 107 formed of a log or the like is coupled across the vertical member by a protective rod coupling clamp 120, so that the protective rod is formed to wrap and protect the wire mesh from the outside. That is, by receiving a protective rod made of a log or the like to the impact applied from the outside to prevent a direct impact to the wire mesh to prevent breakage of the wire mesh.

The protective rod coupling clamp 120 is composed of four ring-shaped bent portion as shown in Figure 3 and 4, the ring portion is formed with a bolt hole, the protective rod is disposed in the middle In the upper side, the two ring portions are coupled to each other by the bolts passing through the bolt holes of both ring portions with the vertical member 106 interposed therebetween. The bolts penetrating the through are coupled to each other by the nut, so that the log does not escape by the hook portion.

In other words, the structure formed as described above is formed in a direction along the length of the stream, as shown in FIG. 107 is transversely fastened so that when the impact occurs toward the wire mesh in the direction of the river, the protection rod absorbs the impact, thereby preventing breakage of the wire mesh.

The embodiments of the present invention described above are examples of one of the embodiments of the present invention, and the present invention is not limited thereto, and the present invention includes equivalents and equivalents thereof.

The present invention by simply taking a method of stacking rubble basically reduces the construction period and construction cost required to reinforce the river surface, while at the same time prevent the loss of rubble to reduce the cost and at the same time have the effect of having a solid structure Have

On the other hand, by changing the coupling angle between the horizontal member and the vertical member freely by the coupling between the radial ribs, it is possible to adaptively change the structure according to the inclination of the inclined surface and to form a more stable river surface reinforcement structure.

Claims (3)

In the river surface reinforcement structure, Concrete layer 104 is formed on the bottom surface of the river adjacent to the river law surface, Rubble layer 114 composed of a plurality of layers on the concrete layer is formed by stacking stepwise along the slope of the river law, Each rubble layer is formed surrounded by a rubble escape prevention wire mesh 112, Seed cloth is formed inside the wire mesh to surround the rubble layer, A plurality of horizontal members 108 are inserted in the middle of the plurality of rubble layers, vertical members are coupled between the upper and lower horizontal members, and at least some vertical members are formed to be adjacent to the outer edge of the wire mesh, Protective rod is coupled to the vertical member across the vertical member by a protective rod coupling clamp, A plurality of bolt holes are formed in the horizontal member, and bolt holes are formed at both ends of the vertical member, and the horizontal member and the vertical member are coupled by fastening bolts through the bolt hole of the horizontal member and the bolt hole of the vertical member to the nut. , A plurality of radial ribs are radially formed around the bolt hole of the horizontal member, and a plurality of radial ribs are radially formed around the bolt hole of the vertical member, so that the horizontal member and the vertical member are changed by changing the coupling angle through the coupling between the radial ribs. Characterized by being able to be combined at various angles River slope reinforcement structure The method of claim 1, The protective rod coupling clamp is composed of four ring-shaped bent portion of the L-shape, The ring portion is formed with a bolt hole, In the state in which the protective rod is disposed in the middle, the two rings are connected to each other by the bolts passing through the bolt holes of the two rings in the upper part, and the two rings are disposed in the middle of the vertical material. The bolts penetrating the bolt holes of both ring portions are mutually coupled by being coupled to the nut, Characterized in that the log is coupled so as not to escape River slope reinforcement structure The method according to claim 1 or 2, The wire mesh 112 is formed with a plurality of circular rings, The wire mesh is coupled to the horizontal member or the vertical member by penetrating the circular ring. River slope reinforcement structure

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