KR20210125667A - Anti-deformed gabion - Google Patents

Abstract

The present invention relates to an anti-deformed gabion. A frame-type support frame having the shape of a square frame is provided inside a mesh body. The frame-type support frame can support the load applied to a lower part when a plurality of gabion walls are stacked, and thus deformation or damage to the mesh body can be prevented. The frame-type support frame of the gabion walls stacked in the lower part receives most of the load of the gabion walls stacked in an upper part to support the load from the ground, and thus even if the mesh body of the gabion walls is damaged, the entire retaining wall can stand without collapsing. A plurality of frame-type support frames are provided, and a rod-type support frame is provided between the frame-type support frames to further support the load of the mesh body and easily attach and detach crane hooks during construction, thereby shortening construction time. The gabion walls are produced at a remote factory and the completed gabion walls are stacked and simply fixed at the site, and thus the production speed of the gabion walls can be increased and the construction speed at the site can also be increased. The anti-deformed gabion comprises: a mesh body having a hollow interior and for accommodating a lump made of stone or a synthetic resin; and a frame-type support frame accommodated inside the mesh body, and contacting both sides of the mesh body opposite to each other, and the inner side surfaces of the upper and lower surfaces thereof.

Description

Anti-deformed gabion

The present invention relates to a deformation-resistant gabion, and more particularly, a frame-type support frame having a rectangular frame shape is provided inside the mesh body, and the frame-type support frame supports the load applied to the lower part when stacking a plurality of gabion walls. By making it possible, it is possible to prevent deformation or damage of the mesh, and since the frame-type support frame of the gabion wall loaded on the bottom receives most of the load of the gabion wall loaded on the top and is supported from the ground, the mesh of any one gabion wall Even if it is damaged, the entire retaining wall can withstand without collapsing, and a plurality of frame-type support frames are provided, and a rod-type support frame is provided between the frame-type support frames, so that the load of the mesh body is further supported and the crane ring during construction. It is easy to detach and shortens the construction time, and since the gabion wall is produced at a remote factory and the completed gabion wall is stacked and fixed at the site, the production speed of the gabion wall is increased and the construction speed in the field is also increased. It is about prevention gabions.

Gabion (gabion) is an eco-friendly construction method used as an alternative to retaining walls or shore blocks in rivers and slopes, etc. In recent years, the interior and exterior of buildings by utilizing the advantages of natural beauty, artistry, aesthetics, eco-friendliness, constructability, and long lifespan. It is also used for finishing materials, interior and exterior walls, landscaping fences and landscaping facilities.

These gabions are basically composed of a mesh with a wire mesh and have a structure in which irregular crushed stone is filled in the mesh.

However, when building a retaining wall using such gabions, in some cases, 4, 5, or more stages must be built. There was a risk of the retaining wall itself collapsing due to appearing or even being damaged.

In order to prevent the fullness of the gabion, a technique for preventing the fullness of the gabion in the front direction by connecting the front mesh body and the rear mesh body with a wire is known. Because it is effective, it took a long time to manufacture because the wire had to be installed while putting the crushed stone in the mesh. Also, as the load is gradually applied from the top, the iron stones accommodated inside move subtly and the wire installed to prevent fullness is cut, etc. Problems occurred frequently.

In addition, in the configuration using such a wire, when the wire for preventing the fullness of the gabion disposed at the lower part is cut for various reasons and a fullness phenomenon occurs in the front of the gabion, there is no room to support the load, and there is a fear that the entire retaining wall may collapse.

Therefore, even when several gabions are stacked, the load applied directly to the lower mesh body is minimized and thus deformation such as fullness can be prevented. This was needed.

KR10-1674974 (registration number) 2016.11.04.

The present invention is provided with a rectangular frame-shaped frame-type support frame on the inside of the net body, and by allowing the frame-type support frame to support the load applied to the lower part when stacking a plurality of gabion walls, the deformation or damage of the net body is prevented An object of the present invention is to provide an anti-deformation gabion that can do this.

In addition, in the present invention, since the frame-type support frame of the gabion wall loaded on the lower part receives most of the load of the gabion wall loaded on the upper part and is supported from the ground, even if the mesh body of the gabion wall is damaged, the entire retaining wall does not collapse An object of the present invention is to provide an anti-deformation gabion that can withstand.

In addition, the present invention is composed of a plurality of frame-type support frames and a rod-type support frame is provided between the frame-type support frames, thereby further supporting the load of the mesh body and at the same time simplifying the removal of the crane ring during construction, thereby reducing the construction time. An object of the present invention is to provide an anti-strain gabion that is shortened.

In addition, the present invention produces a gabion wall at a remote factory and simply stacks the completed gabion wall at the site and simply fixes it. but it has a purpose.

The present invention, a mesh body configured to have a hollow interior to accommodate a lump made of stone or synthetic resin material therein; It is accommodated on the inside of the mesh body, and a frame-type support frame that is in contact with both sides of the mesh body opposite to each other and the inner side surfaces of the upper and lower surfaces at the same time; includes.

In addition, the frame-type support frame of the present invention is provided with a plurality of spaced apart parallel to each other.

In addition, the present invention includes a rod-type support frame in which both ends are coupled to the frame-type support frame between the frame-type support frames spaced apart from each other.

In addition, the present invention, after configuring the lower surface and four sides of the mesh body, insert the frame-type support frame into the mesh body, and combine the lower surface and the four sides of the mesh body with the frame-type support frame, and then the inner side of the mesh body It accommodates a lump made of stone or synthetic resin material, and is configured by coupling the upper surface of the mesh body to the four sides of the mesh body and the frame-type support frame.

In addition, the rod-shaped support frame of the present invention includes an upper rod-type support frame provided between the upper ends of the frame-type support frame, and a lower rod-type support frame provided between the lower ends of the frame-type support frame so as to be parallel to the upper rod-type support frame. a support frame.

In addition, the present invention, the central portion of the upper rod-shaped support frame and the lower end of the frame-shaped support frame is coupled to both ends of the rod-type dispersion frame; includes.

In addition, the present invention, the inclination sensor or deformation sensor installed in the front direction of the frame-type support frame or the mesh body; and a control box that receives the measured value of the inclination sensor or the deformation detection sensor and generates an evacuation alarm in the vicinity by notifying the manager terminal or driving an alarm device when the measured value exceeds a set value.

The present invention is provided with a rectangular frame-shaped frame-type support frame on the inside of the net body, and by allowing the frame-type support frame to support the load applied to the lower part when stacking a plurality of gabion walls, the deformation or damage of the net body is prevented There is an effect that can be done.

In addition, in the present invention, since the frame-type support frame of the gabion wall loaded on the lower part receives most of the load of the gabion wall loaded on the upper part and is supported from the ground, even if the mesh body of the gabion wall is damaged, the entire retaining wall does not collapse It has a durable effect.

In addition, the present invention is composed of a plurality of frame-type support frames and a rod-type support frame is provided between the frame-type support frames, thereby further supporting the load of the mesh body and at the same time simplifying the removal of the crane ring during construction, thereby reducing the construction time. shortening effect.

In addition, in the present invention, since the gabion wall is produced in a remote factory and the completed gabion wall is stacked and fixed in the field, the production speed of the gabion wall is increased and the construction speed in the field is also increased.

1 is a perspective view of a deformation-resistant gabion according to an embodiment of the present invention.
Figure 2 is a front view of the deformation prevention gabion according to an embodiment of the present invention.
3 is a plan view of a deformation-resistant gabion according to an embodiment of the present invention.
Figure 4 is an exploded perspective view of the deformation prevention gabion according to an embodiment of the present invention.
Figure 5 is a front view of the multi-stage stacked anti-deformation gabion according to an embodiment of the present invention.
Figure 6 is a perspective view of the support frame assembly of the deformation prevention gabion according to another embodiment of the present invention.

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

The present invention is configured to have a hollow interior and is configured to accommodate the mass 101 made of stone or synthetic resin material therein, and the mesh body 100 is accommodated inside the mesh body 100 and the mutual of the mesh body 100 It is configured to include a frame-type support frame 210 in contact with both opposite sides and the inner surfaces of the upper and lower surfaces at the same time.

The mesh body 100 serves to form a wall by accommodating the lump 101 made of stone or synthetic resin material, and for this purpose, a tetrahedron made of a grid-type wire mesh has four sides, a lower surface and an upper surface 110 of a hexahedron. are combined with each other to form

The coupling portion of the tetrahedron constituting each side of the mesh 100 may be coupled by using a connecting ring or the like, or by welding the edges of the octahedron to each other.

The mesh 100 of the present invention consists of 1 m in horizontal length and 0.5 m in vertical length of the facet positioned in the front and rear directions, and the horizontal and vertical length of the facet body positioned in both side directions is 0.5m, This is not limiting.

The frame-type support frame 210 is inserted and fixed to the inner side of the mesh body 100 so as to be in contact with both sides of the mesh body 100 and the inner side surfaces of the upper surface 110 and the lower surface.

The frame-type support frame 210 serves to prevent deformation of the mesh 100 by supporting the upward pressure applied to the mesh 100 , and for this purpose, it is inserted into the mesh 100 and fixed to the mesh 100 . do.

Accordingly, the frame-type support frame 210 is formed in a rectangular frame shape, and the cross-section of each side of the frame-type support frame 210 may be configured in an H-shape or 'ㅁ'-shape, etc. to properly withstand a vertical load.

Such a frame-type support frame 210 is preferably provided to be in contact with the facet, the upper surface 110 and the lower surface of the front and rear direction of the mesh body 100 . In addition, a plurality of frame-type support frames 210 are provided to be spaced apart from each other in parallel. In the embodiment of the present invention, it is illustrated that two frame-type support frames 210 are configured, but the present invention is not limited thereto.

On the other hand, according to the embodiment of the present invention, the frame-type support frame 210 is spaced apart from each other 0.5m, each frame-type support frame 210 is configured to be spaced apart by 0.25m from the side face of the mesh 100. This is to ensure that the same load is distributed to each frame-type support frame 210, and preferably, the distance from the horizontal end of the facet in the front or rear direction of the mesh 100 to one frame-type support frame 210 is mutually adjacent to the frame-type support It is configured to be 1/2 of the distance between the frames 210 . That is, if the horizontal length in the front or rear direction of the mesh 100 is 1 m and there are two frame-type support frames 210, one frame-type support frame 210 from the horizontal end of the mesh 100 in the front or rear direction. The distance to is 0.25 m, the distance between the frame-type support frame 210 is composed of 0.5 m. If the horizontal length of the front or rear direction of the mesh 100 is 1.2 m, and there are three frame-type support frames 210, one frame-type support frame from the front or rear end of the mesh body 100 in the horizontal direction. The distance to the 210 is 0.2m, and the distance between the frame-type support frames 210 is 0.4m. By this configuration, the load carried by each of the frame-type support frames 210 is equalized.

However, in the case of the above-described configuration, theoretically, the same load acts on each frame-type support frame 210, but due to the structural characteristics of the mesh 100, the mesh 100 is a lump 101 of stones or synthetic resin inside the grid-type wire mesh. ), so it has a flexible characteristic rather than a perfect block-type solid. Therefore, there is a possibility that the mesh body 100 is bent downward between the pillars, that is, between the frame-type support frame 210 like a flexible substrate mounted on a support pillar.

Therefore, in order to prevent this bending of the mesh 100 and to firmly fix the position of the frame-type support frame 210, both ends are coupled to the frame-type support frame 210 between the frame-type support frames 210. 220 is further provided.

The rod-type support frame 220 is coupled between the frame-type support frames 210 and serves to support the mesh 100, which is likely to be bent between the frame-type support frames 210, preferably with a frame-type support adjacent to each other. It is provided between the upper end or the lower end of the frame 210 . At this time, the rod-type support frame 220 is more preferably provided between the upper central portion or the lower central portion of the frame-type support frame 210 to support the mesh 100 , and between the lower ends of the frame-type support frame 210 . However, when provided not only between the lower ends of the frame-type support frame 210 but also between the upper ends, when the gabion of the present invention is installed using a crane, the crane is placed on the rod-type support frame 220 provided at the upper end. can be connected, which increases the convenience of installation.

In addition, when the gabion wall 10 is stacked in several stages to form a retaining wall, most of the load of the gabion wall 10 located at the upper part is supported by the frame-type support frame 210 of the gabion wall 10 located at the lower part. Since it is supported from, even if the mesh 100 of the gabion wall 10 is damaged, the entire retaining wall does not collapse and can be held by the frame-type support frame 210, thereby greatly reducing the risk of a safety accident.

When combining the frame-type support frame 210 and the bar-type support frame 220 to the mesh 100, first, the support frame assembly 200 that combines the frame-type support frame 210 and the bar-type support frame 220 with each other. produce Then, the support frame assembly 200 is inserted into the mesh body 100 from the upper side of the mesh body (100). At this time, the upper surface 110 of the mesh body 100 should be in a removed state.

Thereafter, the support frame assembly 200 and the face and lower surfaces in the front and rear directions of the mesh body 100 are firmly coupled to each other by welding or other methods. Then, a lump 101 made of a stone or synthetic resin material is put into the inside of the mesh body 100 and accommodated. When all the lumps 101 are accommodated inside the mesh body 100, the top surface 110 of the mesh body 100 is seated on the top, and then the top surface 110 and the four sides and the support frame are firmly welded or other methods. combine

The gabion wall 10 of the present invention is manufactured in the above-described manner, and such manufacturing may utilize a method of manufacturing and transporting to the site in a separate factory. In the case of adopting such a factory manufacturing method, there is no need to load each material for constituting the gabion wall 10 in the field of a limited space, and since it is easy to secure various tools and work lines, productivity is improved, and , since the transported gabion wall 10 is lifted and loaded with a crane in the field and only needs to be fixed, it has the effect of improving the working speed. In particular, when the roadside retaining wall is formed of gabions, it is often necessary to control the passage of the road.

In addition, since the gabion wall 10 is already completed, it is only necessary to put it down using a crane even in the water, so the problem that was difficult in the conventional underwater construction can also be solved.

On the other hand, the rod-type support frame 220 prevents the net body 100 from being bent downward, but does not distribute the load that is biased in the center between the frame-type support frames 210 by the net body 100 .

Therefore, in the present invention, the rod-type support frame 220 is provided between the upper end of the frame-type support frame 210 and the upper rod-type support frame 221, and the frame-type support frame so as to be parallel to the upper rod-type support frame 221 ( It is composed of a lower bar-shaped support frame 222 provided between the lower ends of the 210, and both ends are coupled to the central portion of the upper bar-shaped support frame 221 and the lower end of the frame-shaped support frame 210, the bar-shaped dispersion frame 230 ) is further included. At this time, the lower end of the rod-shaped dispersion frame 230 is preferably coupled to the center of the lower end of the frame-shaped support frame (210).

Therefore, the load that is biased between the frame-type support frames 210 is transferred back to the frame-type support frame 210 by the rod-type distribution frame 230, and when the gabion wall 10 of the present invention is stacked in multiple stages, the central portion Since the unbalanced load is transmitted to the ground along the frame-type support frame 210 , it is possible to further prevent the deformation of the gabion wall 10 .

On the other hand, nevertheless, if a part of the gabion retaining wall formed by the combination of the gabion wall 10 is damaged or the gabion retaining wall collapses due to various reasons such as ground subsidence, soil leakage, corrosion, etc., there is a fear that a large accident may occur.

Therefore, in the present invention, a tilt sensor or a deformation detection sensor is installed in the front direction of the frame-type support frame 210 or the mesh body 100 so as to detect and warn such abnormal signs of the gabion retaining wall to prevent accidents such as human life in advance. More may be provided.

The inclination sensor detects when the gabion retaining wall is tilted and generates a measured value, and the deformation detection sensor is composed of a conventional strain gauge, etc. to detect and measure the swelling of the frame-type support frame 210 or the mesh 100 create a value

The measured value measured by the inclination sensor or the deformation sensor is transmitted to the control box, and when the measured value exceeds the set value, the control box notifies the manager terminal or drives the alarm device to generate an evacuation alarm. is composed of Although the control box and the alarm device may receive driving power from a commercial power source, it is preferable to receive driving power from a storage battery equipped with a solar panel due to the characteristics of a gabion retaining wall installed on a roadside or the like. However, the method of supplying the driving power is not limited thereto.

The present invention made of the above configuration is provided with a frame-type support frame 210 in the shape of a square frame on the inside of the mesh 100, and the load applied to the lower portion when stacking a plurality of gabion walls 10 is applied to the frame-type support frame. By allowing the 210 to be supported, there is an effect that can prevent deformation or damage of the mesh body 100 .

In addition, in the present invention, since the frame-type support frame 210 of the gabion wall 10 loaded on the lower part receives most of the load of the gabion wall 10 loaded on the upper part and is supported from the ground, any one gabion wall 10 Even if the mesh 100 is damaged, there is an effect that the entire retaining wall body can withstand without collapsing.

In addition, the present invention, the frame-type support frame 210 is composed of a plurality and the rod-type support frame 220 is provided between the frame-type support frame 210, while further supporting the load of the mesh body 100 and construction It has the effect of shortening the construction time as it is easy to attach and detach the crane hook at the time of installation.

In addition, in the present invention, since the gabion wall 10 is produced in a remote factory and the completed gabion wall 10 is stacked and fixed in the field, the production speed of the gabion wall 10 is increased and construction in the field The speed also increases.

10 : Gabion wall
100: mesh 101: lump
110: upper surface
200: support frame assembly 210: frame-type support frame
220: rod-type support frame 221: upper rod-type support frame
222: lower bar type support frame 230: bar type distribution frame

Claims (7)

a mesh body configured to have a hollow interior to accommodate a lump made of stone or synthetic resin material therein;
A frame-type support frame accommodated inside the mesh body and in contact with both sides of the mesh body opposite to each other and the inner side surfaces of the upper and lower surfaces at the same time;
Deformation-resistant gabion comprising a.
The method of claim 1,
The frame-type support frame is a deformation-resistant gabion provided with a plurality of parallel and spaced apart from each other.
3. The method of claim 2,
Deformation prevention gabion comprising a; rod-type support frame in which both ends are coupled to the frame-type support frame between the frame-type support frames spaced apart from each other.
4. The method of claim 3,
After configuring the lower surface and four sides of the mesh body, the frame-type support frame is inserted into the mesh body, and the lower surface and four sides of the mesh body are coupled to the picture frame-type support frame, and then into the inside of the mesh body with stone or synthetic resin material. An anti-deformation gabion configured to accommodate a lump made of, and to combine the upper surface of the mesh with the four sides of the mesh and the frame-type support frame.
5. The method of claim 4,
The rod-shaped support frame includes an upper rod-shaped support frame provided between the upper ends of the frame-shaped support frame, and a lower rod-shaped support frame provided between the lower ends of the frame-shaped support frame so as to be parallel to the upper rod-shaped support frame. Strain-resistant gabion.
6. The method of claim 5,
Deformation prevention gabion comprising a; rod-type dispersion frame in which both ends are coupled to the central portion of the upper rod-type support frame and the lower end of the frame-type support frame.
7. The method of claim 6,
a tilt sensor or a deformation detection sensor installed in the front direction of the frame-type support frame or the mesh body;
a control box that receives the measured value of the inclination sensor or the deformation detection sensor and generates an evacuation alarm in the vicinity by notifying the manager terminal or driving an alarm device when the measured value exceeds a set value;
Deformation-resistant gabion comprising a.

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