KR101907879B1 - Apparatus for reducing debris of pile net type - Google Patents

Abstract

Provided is a pile type debris flow reducing net device. According to the present invention, the pile type debris flow reducing net device comprises a plurality of pile parts vertically installed at a predetermined height and a wire rope installed to cross the pile parts adjacent to each other to reduce shock force caused from a debris flow. The pile part comprises a plurality of pile pipes including a first connection part having a first elongated hole formed at a bottom to be lengthily penetrated in a falling direction of the debris flow and a second connection part having a second elongated hole formed at a top to be lengthily penetrated in the falling direction of the debris flow, such that the pile pipes are assembled in a height direction by a coupling member coupled through the second elongated hole of the second connection part of a lower side pile pipe and the first elongated hole of the first connection part of an upper side pile pipe. The wire rope is locked to a locking part disposed in the pile pipe to be perpendicular to the first and second elongated holes. Accordingly, when an external force transferred to the pile pipe through the wire rope in occurrence of the debris flow is relatively greater than a coupling force of the coupling member coupled through the first and second elongated holes, the upper and lower side pile pipes are relatively moved to each other from the coupling member as a boundary, thereby absorbing shock energy.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001]

The present invention relates to a device for reducing debris flow, and more particularly, to a device for reducing debris flow that absorbs impact energy caused by debris flow in a pile supporting a wire rope in the event of a natural disaster, ≪ / RTI >

In general, when the flow rate is rapidly increased in the valley due to rockfall, rocky slope of the rock surface, rocky slope, and collapse of the rock adjacent to the road, debris flows to the residential area Traffic obstacles, damage to road structures, property and loss of life.

In addition, the function of the conventional destructive earth abstraction facility is to absorb the impact energy by absorbing the impact energy to prevent the inflow of the earth rock into the road, to change the direction of the falling of the earth rock, to be.

A typical use of this type of de-stones reduction facility is a debris-reducing wire, which is a type of wire that has a little elasticity to cover the incision surface of rocks and rocks, It is a structure that prevents the stone from coming to the bottom of the prevention net, not the road, when the earth stone is generated.

In addition, the undrained-earth reduction fence is constituted by an end support to which the lower end is fixed to the foundation of the ground or concrete, a wire support rope installed between the support and the support, and a grid wire network. At this time, the wire rope and the grid-type wire mesh are fixed by a connecting ring.

In the case of conventional destructive earth reduction fences, the impact energy is directly transmitted to the wire net, the wire rope, and the support as it is when the low-destructing earth rocks collide with the wire net and the wire rope. This has the problem that if the collision energy is large, it destroys or penetrates the destructive fence, which provides the biggest cause of threatening the safety accident.

Therefore, various types of soil erosion reduction fences have recently been proposed. For example, shock absorbers and impact cushioning structures can be installed by using cross-connected wire ropes across the strut and interconnecting crossed wire ropes, The displacement structure was used to prepare for impact energy.

However, the shock absorbing and shock absorbing structures applied to the above-mentioned undestroy reduction fences can not be used because the components connected to the wire rope due to the collision of the earth rocks can not withstand the impact energy and are easily broken before the shock absorption, The impact energy can not be efficiently defended and the function can not be performed properly.

In addition, since the impact energy can not be dissipated in the event of collision of the earth rock with the unforeseen stone fence, even if the wire rope is provided with the gap maintaining device, there is a problem that the wire mesh penetrates easily.

(Patent Document 1) KR10-1704771 B1

(Patent Document 2) KR10-1676807 B1

It is therefore an object of the present invention to solve the above-mentioned problems, and an object of the present invention is to provide a wire rope supporting structure capable of absorbing impact energy caused by debris falling from a pillar portion supporting a wire rope, To provide a de-stoker flow reduction device.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are not restrictive of the invention, unless further departing from the spirit and scope of the invention as defined by the appended claims. It will be possible.

As a specific means for achieving the above object, a preferred embodiment of the present invention includes a wire rope provided across a plurality of support portions provided at a predetermined height vertically to a bottom surface and between adjacent support portions, Wherein the support portion has a first connection portion formed at a lower end thereof so as to penetrate through a first long hole penetratingly formed in a direction of falling of the earth stone, and a second connection portion formed at the upper end of the support member, And a plurality of ground supporting tubes having a second connecting portion formed to penetrate through the first connecting portion of the second connecting portion of the lower side main pipe and the first long hole of the first connecting portion of the upper side main pipe, And the wire rope is hooked on a hook portion provided on a plurality of ground supporting pipes so as to be orthogonal to the first and second long holes So that when the external force transmitted to the ground main pipe through the wire rope becomes larger than the fastening force of the fastening member fastened through the first long hole and the second long hole at the time of occurrence of the earth stone, And the upper side main pipe and the lower side main pipe are moved relative to each other to absorb the impact energy.

Preferably, the first connection portion is composed of a pair of rectangular plates which are integrally fixed to a lower end inner surface of the support main pipe and integrally fixed to the body, the remaining body being exposed through the first long hole, May be formed of a pair of quadrangular plates which are integrally fixed to the upper outer surface of the supporting pipe and integrally fixed to the body,

Preferably, the first connecting portion is formed of a pair of rectangular plates which are bent so as to be collected inward from the lower end of the supporting tube and then extend in parallel to each other at a predetermined length and through the first long hole, May be formed of a pair of rectangular plates which are bent so as to flare outwardly from the top end of the supporting pipe and then extend in parallel to one another with a predetermined length and through the second long hole.

Preferably, the hooking portion includes a cutout portion formed on the outer surface of the main pipe corresponding to the wire rope, the cutout portion being disposed on the cutout portion and integrally fixed to the main pipe, And may include a tubular member for restraining and fastening the wire rope to the ground pipe.

Preferably, the hooking portion includes a cut portion formed outwardly on the outer surface of the main pipe corresponding to the wire rope, and a wire rope extending from the lower end of the cut- As shown in Fig.

Preferably, the hooking portion may include a tubular member integrally fixed to an outer surface of a main pipe corresponding to the wire rope and having a slit opened to allow the wire rope to enter, thereby restricting the wire rope to the main pipe. have.

Preferably, the main pipe provided at the lowermost end of the support part is fixed to the bottom surface of the support part and assembled with the support part. The support part includes a first long hole of a pair of first connection parts provided on the support main pipe, A pair of first connection brackets having a connection hole formed through a circular hole or a long hole so as to be assembled by the first connection bracket and a first fixing plate having the first connection bracket and an anchor hole of the first fixing plate, And may include a first anchor bolt fixed thereto.

Preferably, both ends of the wire rope are connected to a rope fixing portion fixedly installed on a floor surface, the rope fixing portion includes a pair of second connection brackets having a connection bar to which one end of the wire rope is connected, And a second anchor bolt inserted through the anchor hole formed in the second fixing plate at a predetermined depth.

Preferably, the cover includes a lid portion for sealing an opened upper end of a main pipe constituting the uppermost end of the support portion, and the lid portion is provided with a cover plate having an inner jaw fitted to the upper end of the opened main pipe, .

The present invention as described above has the following effects.

A plurality of ground supporting pipes, which are arranged and bound by a plurality of wire ropes, are assembled in multiple stages in the height direction, and adjacent main pipes are connected by fastening members fastened through the first and second long holes, When the external force transmitted to each main pipe of the support part is relatively larger than the fastening force of the fastening member, the upper side support main pipe is relatively moved with respect to the lower side main pipe with the fastening member as a boundary, The impact energy transmitted to the wire rope can be absorbed and dissipated.

In addition, it is possible to prevent bending deformation of the strut part due to difficulty in recycling due to the impact energy transmitted through the wire rope at the time of the occurrence of the earth stone, thereby reducing the facility maintenance cost and the maintenance cost.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an overall configuration diagram showing a gravel-type net-type soil erosion reducing apparatus according to a preferred embodiment of the present invention.
FIG. 2 is an exploded perspective view illustrating a strut part included in a gravel-and-nut type soil erosion reducing apparatus according to a preferred embodiment of the present invention.
FIG. 3 is an exploded perspective view showing a main pipe constituting a strut part included in the ground-net type soil erosion reducing apparatus according to the preferred embodiment of the present invention.
FIG. 4A is a perspective view illustrating a support and a support provided in the support net type earth-and-soil reducing apparatus according to the preferred embodiment of the present invention. FIG.
FIG. 4B is a perspective view illustrating a rope fixing unit provided in the apparatus for reducing earth-stone-type earths according to a preferred embodiment of the present invention.
FIGS. 5A and 5B are diagrams showing a main pipe of a strut of a ground net type earth-and-soil reduction apparatus according to a preferred embodiment of the present invention.
FIGS. 6A and 6B are block diagrams illustrating a hanging part provided in the apparatus for reducing earth-stone-type earth, according to a preferred embodiment of the present invention.
FIGS. 7A and 7B are schematic views showing a state of absorbing impact energy transmitted to a ground net type soil erosion reducing apparatus according to a preferred embodiment of the present invention. FIG.
FIG. 8 is a perspective view illustrating a ground-and-gas type soil erosion reducing apparatus according to a preferred embodiment of the present invention,
(a) is a perspective view that is applied to both sides of the wire rope bushing, which is a horizontal member,
(b) is a perspective view in which a wire rope as a horizontal member and a connecting wire as a vertical member are applied to only one side of the support. .

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description, a detailed description of known functions and configurations incorporated herein will be omitted when it may obscure the subject matter of the present invention.

The same reference numerals are used for portions having similar functions and functions throughout the drawings.

In addition, in the entire specification, when a part is referred to as being 'connected' to another part, it may be referred to as 'indirectly connected' not only with 'directly connected' . Also, to include an element does not exclude other elements unless specifically stated otherwise, but may also include other elements.

As shown in FIGS. 1 to 3, a ground net type soil erosion reduction apparatus 100 according to a preferred embodiment of the present invention includes a plurality of ground supports 110 installed at a predetermined height perpendicular to a floor surface, A plurality of wire ropes 120 installed across the circumferential portion to absorb the impact energy caused by debris such as driftwood or rocks falling downward at the time of the occurrence of the debris flow.

As shown in FIGS. 1, 2 and 3, the support portion 110 includes a plurality of support tubes 113 connected in a multistage manner in the height direction. A pair of first connecting portions 111 formed so as to penetrate through a first elongated hole 111a penetrating long in the falling direction of the earth rock and a pair of second elongated holes 112a penetratingly formed in the upper end of the second elongated hole 112a And a second connecting portion 112 of a substantially rectangular pipe member.

The second elongated hole 112a of the second connection part 112 provided in the lower side main pipe 113 is aligned with the first elongated hole 111a of the first connection part 111 provided in the upper side main pipe, And a plurality of supporting tubes 113 are continuously assembled in the height direction by at least one fastening member 114 fastened through the first and second long holes, It can be installed.

 At this time, a pair of fastening members 114 arranged at both ends are fastened to the first and second long holes 111a and 112a in which the pair of first connection portions 111 and the pair of second connection portions 112 are overlapped with each other, And the lower side main pipe 113 are connected and assembled with each other. However, the present invention is not limited thereto, and the upper and lower side main pipes may be assembled and connected to each other by one or two or more fastening members.

The fastening member 114 is composed of a long bolt 114a fastened through the first and second long holes 111a and 112a in which a pair of first connection portions 111 and a pair of second connection portions 112 are overlapped with each other And a short bolt 114b fastened through the first and second long holes 111a and 112a and having a relatively shorter length than the long bolt, the first and second connection portions being overlapped one on top of the other.

The main pipe 113 provided at the lowermost end of the piercing portion 110 is fixed to the bottom surface of the main pipe 113 and is assembled with the piercing portion 115, And a connection hole 115a formed through the circular hole or the long hole so as to be assembled by the other fastening member and the first long hole 111a of the pair of first connection portions 111 provided in the supporting tube 113 And a first fixing plate 115c that includes a pair of first connection brackets 115b and integrally includes the first connection bracket on an upper surface thereof. The first fixing plate 115c includes an anchor hole formed through the first fixing plate 115c And a plurality of first anchor bolts 115d fixedly inserted and fixed on the ground.

Accordingly, the main pipe 113 constituting the lowermost end of the support part is connected to the connection bracket 115b of the first fixing plate 115c firmly fixed by the first anchor bolt fixedly inserted into the ground surface, It can be fixed on the ground.

And a lid portion 116 for sealing the opened upper end of the main pipe 113 constituting the uppermost end of the support portion 110. The lid portion 116 is provided at the upper end of the open main pipe And a cover plate 116a having an inner rim 116b fitted to the lower surface thereof to prevent rainwater or foreign matter from entering the inside of the support.

At this time, the inner protuberance 116b of the lid unit 116 has been shown to be fixed to the upper end of the main pipe from which the second connection unit has been removed to fix the lid plate. However, the present invention is not limited to this, And the inner plate is assembled to the second connecting portion.

As shown in FIG. 1, the wire rope 120 is hooked and constrained on a hook 121 provided for each of a plurality of guiding pipes 113 so as to be orthogonal to the first and second long holes 111a and 112a will be.

As shown in FIG. 4B, one end of the wire rope 120 is connected to a rope fixing portion 125 fixedly installed on a floor surface. The rope fixing portion 125 is connected to one end of the wire rope And a second fixing plate 125c including a pair of second connection brackets 125b having connection bars 125a and integrally having the second connection brackets on the upper surface thereof, And a second anchor bolt 125d inserted and fixed at a predetermined depth on the ground through an anchor hole formed at the center of the first anchor bolt 125c.

Here, the wire rope 120 is connected to both ends of a rope fixing part fixed to a horizontal plane, and is installed between a pair of right and left support parts 110, but the present invention is not limited thereto. And a plurality of rope members which are connected to and fixed to the rope fixing unit fixedly installed on the rope fixing unit or disposed across the three or more support members.

A plurality of wire ropes (120) arranged perpendicularly to the wire rope (120) arranged across the pair of pivots (110) arranged in the left and right directions include a plurality of connecting wires The upper and lower ends of the wire rope are connected to the upper and lower wire ropes, respectively, and the intersection of the wire rope and the connecting wire can be maintained at the intersection of the wire rope and the connecting wire, .

Accordingly, the unsteady debris falling down to the lower portion is hooked on the hook portion 121 provided at each of the main pipe of the strut and is brought into contact with the constrained wire rope 120, and at the same time, The impact energy is transmitted to the plurality of support tubes 113 constituting the support portion 110 by an external force, respectively.

At this time, an external force transmitted to each of a plurality of support pipes corresponding to the plurality of wire ropes is fastened to the fastening member (not shown) through the first long hole 111a and the second long hole 112a so as to connect the first and second connection parts 114, the upper side main pipe is relatively moved with respect to the lower side main pipe with the connecting member 114 as a boundary, or the lower side main pipe is relatively moved with respect to the upper side main pipe, The impact energy transmitted to the wire rope can be absorbed and dissipated.

5A, the first connection part 111 provided at the lower end of the plurality of ground main pipes constituting the support part 110 has a body part at the lower end inner surface of the support main pipe 113 And a second connection part 112 provided at an upper end of the plurality of supporting tubes 113 is formed of a pair of rectangular plate members which are integrally fixed to each other and which are exposed to the outside, And a pair of rectangular plates having a second elongated hole 112a formed through the other body exposed to the outside, the second elongated hole 112a being integrally fixed to the upper end outer surface of the retainer pipe 113.

As shown in FIG. 5B, the first connection portions 111 provided at the lower ends of the plurality of ground supporting pipes constituting the grounding portion 110 are bent so as to be inward from the lower end of the grounding pipe 113 And a second connecting part 112 provided at an upper end of the plurality of supporting tubes 113 is formed of a pair of rectangular plates extending through the first elongated hole 111a, And may be formed of a pair of rectangular plates which are bent so as to flare outward from the upper end of the support tube 113 and then extend in parallel to one another and extend through the second long hole 112a.

At this time, the width between the pair of first connection portions provided at the lower end of the retainer pipe is larger than the width between the pair of second connection portions provided at the upper end of the retainer pipe, And the second connection portion contacts the outer side of the first connection portion and overlaps with each other.

At least one contact member may be disposed between the first connection portion and the second connection portion such that the relative movement between the lower side main pipe and the upper side main pipe due to impact energy transmitted to the wire rope can be more smoothly performed .

As shown in FIG. 6A, the hook 121, which is engaged with the wire rope 120 and restrains the wire rope 120, is disposed on the outer surface of the main pipe corresponding to the wire rope so as to be parallel to the wire rope And slits 122a are formed in the slits 113a and 113b so as to be integrally fixed to the main pipe and open so as to enter the wire rope, And a use tube 122 for holding and fastening the wire rope 120 that has entered through the main pipe.

6 (b), the hooking portion 121 includes cutouts 113a and 113b formed on the outer surface of the main pipe corresponding to the wire rope so as to be parallel to the wire rope, And a catching protrusion 123 extending from the lower end of the cutout 113a and 113b at a predetermined height to hook the wire rope into the cutter main body.

6C, the hook 121 is integrally fixed to the outer surface of the main pipe 113 corresponding to the wire rope, and the slit 122a is formed as an opening And a use tube 122 for fastening and fastening the wire rope 120, which has entered through the slit, to the ground pipe.

Here, the cut-out portion is formed by being cut out on both sides of the support main pipe so as to correspond to a pair of wire ropes disposed on both sides of the support portion, but is not limited thereto and may be selectively provided.

The hooking tube 122 may be formed of a rectangular pipe member having a slit formed in a long side of the outer surface of the hooking pipe 122, corresponding to the outer diameter of the wire rope.

 As shown in FIGS. 7A and 7B, when the soil erosion reducing apparatus 100 having the above-described structure is installed on a valley or a slope, the soil stone rolling down to the downstream side when the earth stone is generated is sandwiched between a pair of left and right ground supports 110 The external force F is applied to the wire rope 120, which is supported across the wire rope 120, to generate an impact energy to pass through.

Since the wire rope 120 is engaged with the hook 121 provided for each of the plurality of ground tubes 113 constituting the strut and is constrained to be difficult to be separated from the external, F are directly transferred to a plurality of ground supporting pipes 113 corresponding to a plurality of wire ropes.

In this case, an external force F indirectly transmitted to the corresponding supporting tube 113 through the wire rope is applied to the first and second connection portions (first and second connection portions) 112a and 112b, which are overlapped with each other through the first long hole 111a and the second long hole 112a 111, and 112, the plurality of main pipes are continuously assembled in the height direction, and the vertical movement of the connected support portions is maintained while preventing the undrained stones from passing to the downstream side .

However, since the external force F indirectly transmitted to the corresponding support main pipe through the wire rope is connected to the first and second connection portions 111 and 112, which are overlapped with each other through the first long hole 111a and the second long hole 112a, The upper side main pipe relative to the lower side main pipe 113 is moved relative to the lower side main pipe 113 with the connecting member 114 as a boundary or the lower side main pipe is relatively moved with respect to the upper side main pipe And the impact energy transmitted to the wire rope can be absorbed and dissipated because the side pipe main body is relatively moved.

As shown in FIG. 1, the wire rope 120, which is disposed so as to be interposed between the pair of left and right support portions 110, is disposed on both sides of the support portion, As shown in FIG. 8A. However, as shown in FIG. 8A, the impact energy is absorbed by the debris flowing from the side of the strut, Or as shown in Fig. 8 (b), they may be engaged with one another on either side of the strut via the connecting wire and the fastening hole, which are vertical members.

In addition, a shock absorbing device is provided at the middle of the length of the wire rope 120 so that impact energy can be first absorbed and dissipated in the wire rope before the impact energy is absorbed by the relative movement of the plurality of support pipes constituting the support portion. May be additionally provided.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the inventions. It will be apparent to those of ordinary skill in the art.

110: The housewife
111: first connection portion
111a: First slot
112: second connection portion
112a: the second slot
Article 113
113a, 113b:
114: fastening member
116:
115: Ji and the government
115:
120: Wire rope
121:
122: Walking tube
122a: slit
123: hanging jaw
125: rope fixing portion

Claims (9)

There is provided an apparatus for reducing an impact force caused by a debris flow by providing a plurality of grounding portions provided at a predetermined height vertically to a bottom surface and wire ropes provided across the adjacent supporting portions,
Wherein the support part has a first connection part formed at a lower end thereof in a direction of falling of the earth stone in a long first long hole and a second connection part having a second connection part formed at an upper end of the support part, The upper and lower ends of the upper side main pipe and the lower end of the upper side main pipe, and the upper end of the lower side main pipe, Assembling the plurality of paper guide tubes in a plurality of stages in the direction of the paper guide,
Wherein the wire rope is hooked on a hook provided on a plurality of ground supporting pipes so as to be orthogonal to the first and second long holes,
The slit is formed in the main pipe so as to be integrally fixed to the main pipe, and the slit is formed in the slit so as to enter the wire rope, Wherein the wire rope is used to fasten the wire rope to the ground pipe,
When the external force transmitted to the ground main pipe through the wire rope becomes larger than the fastening force of the fastening member fastened through the first long hole and the second long hole when the earth stone is generated, And the bottom main pipe and the bottom side main pipe are moved relative to each other to absorb the impact energy. The method according to claim 1,
Wherein the first connection portion is made of a pair of rectangular plates which are integrally fixed to a lower end inner surface of the support main pipe and integrally fixed to the body and the first long hole is formed through the remaining body exposed to the outside, And a pair of quadrangular plates which are integrally fixed to the upper outer surface of the main pipe and are integrally fixed to each other and which are formed through the second elongated hole in the other body exposed to the outside. The method according to claim 1,
Wherein the first connection portion is formed by a pair of rectangular plate members which are bent so as to be gathered inward from the lower end of the support main pipe and then extend in parallel to each other and parallel to each other and penetrate through the first long hole, And a pair of quadrangular plates extending from the upper end of the main pipe to extend outwardly from the upper end of the main pipe and having a predetermined length extending in parallel to each other and penetrating the second long hole. delete delete delete 4. The method according to any one of claims 1 to 3,
The main pipe provided at the lowermost end of the support part is fixed to the floor and is assembled with the support part. The support part is assembled by the first long hole of the pair of first connection parts provided in the support main pipe and the fastening member A first fixing bracket having the first connection bracket and a second fixing bracket having a first fixing bracket and a second fixing bracket interposed between the first fixing bracket and the first fixing bracket, And an anchor bolt. 4. The method according to any one of claims 1 to 3,
Wherein the rope fixing portion includes a pair of second connection brackets having a connection bar to which one end of the wire rope is connected, and a pair of second connection brackets And a second anchor bolt inserted and fixed at a predetermined depth to the ground through an anchor hole formed through the second fixing plate and the second fixing plate. 4. The method according to any one of claims 1 to 3,
And a lid part for sealing the opened upper end of the main pipe constituting the uppermost end of the support part, wherein the lid part includes a cover plate having an inner step on the lower surface to be fitted to the upper end of the opened main pipe A method and apparatus for reducing soil -

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