KR101914693B1 - Multi stage separated earth and stone flow buffer net and method for constructing this same - Google Patents

Abstract

The present invention relates to a multi-stage separable avalanches protection buffer net, and a construction method thereof. An object of the present invention is to prevent avalanches from downstream (residential area, roads, etc.), to safely prevent loss of the avalanches through multi-stage cushioning against forces exerted from the avalanches, and to easily install in a mountainous area without using large equipment. The multi-stage separable avalanches protection buffer net according to the present invention comprises: a net (10); a rope (20); and a multi-stage separable buffer means (30).

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a multi-

More particularly, the present invention relates to a multi-stage detachable type multi-stage detachable type multi-stage detachable type multi-stage detachable type multi-stage detachable type multi- And a method of constructing the buffer net.

In Korea, mountainous areas account for more than 70% of the whole country, and the landslide caused by torrential rains such as rainy season causes huge damage every year. Especially, the landslide caused by the suddenly flowing debris along the valley of the mountain is the largest damage compared with other kinds of landslides.

Deokseok is a kind of landslide where the steep slope of the mountain is collapsed. It is a type of landslide that has been weathered for a long time and the mountain slope, which has lots of soil and rocks, is saturated with water due to heavy rain or rainy season. This phenomenon is called "mud flow".

There are technologies using buffered net, and the technology of Sambang dam.

Patent Literature 10-1747423 discloses a structure for preventing debris from entering the valley where the ground is eroded and fixed to both side slopes of the valley, A floor fixing plate fixed to a bottom surface of the valley; A net frame connected by a rectangular frame having a plurality of rail lines and vertical lines fixed in a lattice form, the lower side being fixed to the bottom fixing plate and the longitudinal side sides being connected to the slope fixing plate by joist lines; And a fixed body fixed to the ground and connected to a top end of a side surface of the mesh frame by a fixed line, wherein the fixed body is positioned upstream of the valley with respect to the slope fixed plate, An intermediate fixing pin for limiting a position of a fixed line is detachably installed on the ground to maintain a constant distance between the net frame and the bottom of the valley, Therefore, it is not possible to prevent debris flow, and the anchoring fixation is disengaged or the net is torn. As a result, the function as a destructive defense facility can not be achieved. In addition, since construction is required using large equipment, the construction is not very good considering the fact that the destructive defense facilities are installed in mountainous areas.

Patent No. 10-1747423 Published Utility Model No. 20-2008-0003416

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems and it is an object of the present invention to provide a multi-stage separating type multi-stage separating type air conditioner capable of safely preventing the destruction of the earths rocks through multi- And to provide a method of constructing the buffer layer and the method thereof.

The multi-stage separation type soil erosion protection buffer net according to the present invention comprises: a net; A rope connected to the net, the ropes being fixed to both sides of the site where the left and right sides are devoid of the earth rock; The rope is fixed so as to have a cushion portion made of non-linear wiring, and when the net is pushed by the earth stone, the net is divided into two or more stages and the clearance is provided by the buffer portion of the rope, So as to absorb impact applied to the net.

The multi-stage separation type buffering means includes a base plate, a rope holder spaced apart from the base plate by a predetermined distance to fix the rope to the base plate and fixing the buffer to the buffer through the non-linear wiring, Wherein at least one of the rope holder and the fixture is broken when the rope is pulled by the load applied from the earth stone so that the rope holder is disengaged from the base plate so that the buffer is released .

The multi-stage separation type buffer means includes a base plate and a rope holder spaced apart from each other by a predetermined distance from the base plate to fix the rope to the base plate and fix the buffer to have a cushion portion of an allowable length through non-linear wirings The base plate has a rope holder fixing part for fixing the rope holder on one side thereof with a break wall therebetween, and a detachment guide part having a size larger than that of the fixing part for fixing the rope holder to the base plate is formed on the other side Thus, when a load is applied to the rope, the rope holder moves to the fall-off guide portion while breaking the break wall, and then falls off, thereby buffering the buffer by the buffer portion of the rope.

According to the present invention, it is possible to prevent the destruction of the settlement area by the destructive stones and to safeguard the residents by preventing the destruction of the earths from the mountains to the settlement areas due to heavy rain or the like. The net is moved (multi-step movement) by the load exerted by the unsteady flow to mitigate the impact, thereby preventing the damage caused by the impact from the earth stone, thereby improving the reliability as the undestanding protection facility and protecting the downstream more safely.

In addition, the anchoring work for fixing the rope to the ground can be carried out only with small equipment, and it is possible to install the multi-stage separation type shock absorber without equipments, so it is very easy and easy to move to the mountainous area, .

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a front view of a construction state of a multi-stage detached destruction blocking buffer net according to Embodiment 1 of the present invention. Fig.
FIG. 2 is an enlarged perspective view of a multi-stage detachable shock absorber applied to a multi-stage detachable detonation cushioning cushion net according to Embodiment 1 of the present invention. FIG.
3 is an exploded perspective view of a multi-stage detachable shock absorber applied to a multi-stage detachable detonation cushioning cushion net according to Embodiment 1 of the present invention.
4 is a perspective view showing an example of a rope holder applied to a multi-stage detachable shock absorber of a multi-stage detachable destocking protective cushion net according to Embodiment 1 of the present invention.
5 and 6 are an exploded perspective view and a coupled state sectional view showing an example in which a rope holder and a rope holder detachment guide of a multi-stage detachable shock absorber applied to a multi-stage detachable detonation cushioning cushion net according to the first embodiment of the present invention are connected by a coupler.
7 and 8 are views showing examples of a rope holder detachment guide applied to the multi-stage detachment type buffering means of the multi-stage detachable detonated earth protection buffer net according to the first embodiment of the present invention.
9 is a view showing an example in which a rupture guiding portion of a multi-stage separation type soil erosion protection buffer net according to Embodiment 1 of the present invention is provided in a rope holder.
10 is an operational state diagram of a multi-stage separation type soil erosion protection buffer net according to Embodiment 1 of the present invention.
11 is a perspective view of a multi-stage detachable shock absorber applied to a multi-stage detachable detonation cushioning cushion net according to a second embodiment of the present invention.
FIG. 12 is an operational view of a multi-stage detachable shock absorber applied to a multi-stage detachable detonation protective buffer according to Embodiment 2 of the present invention; FIG.
FIG. 13 is a plan view showing another example of a fracture wall applied to a multi-stage detachable detonation cushioning cushioning net according to the second embodiment of the present invention. FIG.

In the following description of the present invention, detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. The following terms are defined in consideration of the functions of the present invention, and these may be changed according to the intention of the user, the operator, or the like. Therefore, the definition should be based on the contents throughout this specification.

≪ Example 1 >

As shown in Fig. 1, the multi-stage separation type soil-detonated protective buffer net according to the present embodiment is constructed in such a manner that the net 10, which protects against the loss of the earth's stone, the rope 20 supporting the net 10, And a buffering means (30) for providing a buffering effect by providing a margin length of the buffering means (30).

The net 10 is a mesh structure that can prevent the debris from drifting downstream.

As shown in FIG. 2, the ropes 20 are arranged and fixed in multiple stages along the vertical direction at one or more sides of the downstream side and the upstream side of the net 10, and both the left and right sides are fixed around the valleys through the anchors 21 . Here, the rope 20 is configured to provide buffering by providing a multi-stage margin length through the multi-stage separation type buffering means 30, and for example, the first, second and third buffering portions 20-1, 20-2, 20-3. The first to third buffer parts 20-1, 20-2, and 20-3 buffer the net 10 by pushing the net 10 toward the downstream side in the event of a collision of the earth rocks, and various methods for securing an allowable length are possible For example, there is a method of ensuring a length longer than a straight line by bending without being tightened between the multi-stage separable buffer means 30, and a method of securing a length by winding a coil several times, that is, wiring in a non-linear manner.

3, the multi-stage detachable shock absorber 30 includes a base plate 40, a rope holder 50, and a rope holder detachment guide 60 as a fastener.

Although the multi-stage detachable shock absorber 30 is illustrated as being applied to only two left and right sides of the rope 20, it is not limited thereto, and it is also possible to install one, or three or more, between the left and right sides.

The base plate 40 is large enough to accommodate the plurality of rope holders 50 and the rope holder detachment guide 60 and can be installed on a support base on which the rope 20 fixed via the anchor 21 Or it may be fixed directly through an anchor.

The base plate 40 is made of a material and a structure having greater stiffness than the rope holder detachment guide 60.

The rope holder 50 is a medium for connecting the rope 20 and the rope holder detachment guide 60. The rope holder 50 preferably includes a first engaging portion 51 and a first engaging portion 51, And a second engaging portion 52 to which the rope holder detachment guide 60 is engaged.

The first engagement portion 51 is preferably supported on the circumferential surface of the rope 20 so as to move together with the rope 20 when a load (force pulling toward the center) is applied to the rope 20 by the earth stone, (20). However, as shown in FIG. 4, the rope holder 50 has two semicircular shapes, that is, a semicircular shape and a semicircular shape, The first and second semicylindrical pieces 51-1 and 51-2 are foldably connected to form the first engaging part 51 and the first and second semicircular pieces 51-1 and 51-2 The first and second bolt rods 52-1 and 52-2 are formed in a semicircular cross section to form a second engaging portion 52, respectively.

A wedge piece for adjusting the frictional force of the rope 20 and firmly fixing the rope 20 may further be applied between the first coupling portion 51 and the rope 20.

The second coupling portion 52 is coupled to the rope holder detachment guide 60 through a nut type coupler 53 (see FIG. 5) with a bolt rod having a thread formed on the outer peripheral surface.

The rope holder detachment guide 60 is a fixture for fixing the rope holder 50 to the base plate 40 and separates the rope holder 50 from the base plate 40 when a load is applied to the rope 20, 20-2, and 20-3 of the first to third buffers 20-1, 20-2, and 20-3.

The rope holder detachment guide 60 is formed in a connecting portion 61 and a connecting portion 61 connected to the rope holder 50 and is connected to the connecting portion 61 when a load is applied to the rope holder 50 through the rope 20 And a head 62 that is broken.

The connecting portion 61 is formed in a bolt shape having a thread on the outer circumferential surface and the head portion 62 has a cross sectional area larger than that of the connecting portion 61. The rope holder removing guide 60 having the above- The connecting portion 61 is connected to the rope holder 50 on the opposite side of the rope holder 50 and the head portion 62 is supported on the base plate 40 to fix the rope 20 to the base plate 40 And the connecting portion 61 and the head portion 62 are broken when the load is applied to the rope 20 so that the rope holder 50 is separated from the base plate 40, So that buffering by the units 20-1, 20-2, and 20-3 is performed.

The rope holder detachment guide 60 has a structure in which the strength of the connecting portion 61 and the head portion 62 are made different from each other so as to cause the weak portion to be broken and the head portion 62 is provided on the opposite side of the connecting portion 61 7, the head portion 62 may be formed thinly so that the strength of the head portion 62 is weaker than that of the connecting portion 61 without any change in cross-section, and further, As shown in FIG. 8, it is also possible that the connection portion 61 has a smaller cross-sectional area (diameter) than that of the head portion 62 and a fracture guide portion 63 having a smaller cross-sectional area at its periphery.

9, the rope holder detachment guide 60 is configured to fix the rope holder 50 to the base plate 40, and the rope holder detachment guide 60 may be fixed to the base plate 40, It is also possible to form the breakage guide portion 54 having a smaller cross-sectional area in the holder 50 and a weaker rigidity than other portions.

It is also possible for the rope holder 50 and the rope holder fall-off guide 60 to have the break guide portions 54 (63).

The rope holder 50 and the rope holder detachment guide 60 may be configured to have different strengths so as to sequentially fall off from the net 10 for buffering action over a plurality of stages, So that the strength gradually increases.

The method for constructing the multi-stage detachable detonation cushioning net according to the present invention includes the steps of preparing the rope 20 by fixing the rope 20 to the net 10 at multiple stages by mounting the multi-stage detachable buffer means 30 on the rope 20, And fixing the opposite end of the rope 20 to the ground via the anchor 21 while spreading the net 10 to the opposite side.

The operation of the multi-stage separation type soil erosion protection buffer net according to the present embodiment will be described with reference to FIG.

The multi-stage detachable shock absorber 30 is provided with four rope holders 50 and rope holder detachment guide 60 spaced apart from each other by a predetermined distance so that the first to third shock absorbers 20-1, 2,20-3) are prepared as an example.

The first cushioning portion 20-1 is loosened in a straight line while the first rope holder 50-1 is disengaged from the base plate 40 when the earth stone collides with the net (10) is pushed downward to absorb the impact applied from the debris flow. At this time, the second to fourth rope holders 50-2, 50-3, and 50-4 are fixed to the base plate 40 to support the rope 20.

In this state, when the earth stone collision occurs, the second rope holder 50-2 is detached from the base plate 40 and the net 10 is moved to the downstream side by the length of the second buffer 20-2 Let it absorb the shock from the earth's stone. In this case, the third and fourth rope holders 50-3 and 50-4 are fixed to the base plate 40 to support the rope 20.

Through this operation, the net 10 can be buffered through the third buffer part 20-3.

≪ Example 2 >

As shown in FIG. 11, the multi-stage split soil type protection buffer net according to the present embodiment includes a net 10, a rope 20 (first to third buffer parts 20-1, 20-2, Is different from that of the first embodiment in that the base plate 40 of the multi-stage detachable shock absorber 30 constitutes the breaking wall 41 and the rope holder 50 is removed .

The base plate 40 is formed with a rope holder fixing portion 42 and a fall-off guide portion 43 with a breaking wall 41 therebetween. Of course, the rope holder fixing portion 42 and the fall-off guide portion 43 can be formed in a number corresponding to the number of the rope holders 50. [

The rope holder 50 may have the same structure as that of the first embodiment or may have various structures for fixing the rope 20 and the rope holder 50 may be replaced with the base plate 40 (Not shown). The fastener 54 can be both bolt and nut and depends on the structure of the rope holder 50. However, the fixture 54 is configured to have a larger cross-sectional area than the rope holder securing portion 42.

The rope holder fixing portion 42 is formed at one side of the rupture wall 41 and is a hole sized to prevent the rope holder 50 and the fixing member 54 from passing.

The dropout guide portion 43 is a hole formed on the opposite side of the rope holder fixing portion 42 with respect to the breaking wall 41 and is a hole through which the fixing hole 54 passes.

The breaking wall 41 is broken by the rope holder 50 provided on the rope holder fixing portion 42. The breaking strength can be adjusted by adjusting the thickness as a whole so that the breaking can be performed. It is also possible that the unit is constituted together.

The rope holder 50 pushes the rupture wall 41 in the direction of the load when a load caused by the earth stone is applied to the rope 20 as shown in Fig. The fastener 50 and the fastener 54 move to the dropout guide 43 and the fastener 54 drops off the base plate 40 due to the size of the dropout guide 43. Through this process, the first to third buffer parts 20-1, 20-2, and 20-3 of the rope 20 are loosened in a straight line to buffer the net 10.

In the present embodiment, since the rope holder 50 is dropped by the breakage of the breakage wall 41, the breakage wall 41 is manufactured separately (Adhesion, bolting or the like) after it is formed.

The rope holder fixing portion 42 and the fall-off guide portion 43 are formed so as to communicate with each other in the above-described size relationship and the breaking wall 41 is attached to the relatively large fall- And the dropout guide portion 43 are separated.

In this embodiment, similarly to the first embodiment, the breaking wall 41 is formed so as to have a different strength so as to extend from the vicinity of the net 10 to a position farther away from the net 10, As shown in Fig.

10: net, 20: rope
20-1, 20-2, 20-3: first to third buffers,
30: multi-stage detachable buffer means,
40: base plate, 41: rupture wall
42: rope holder fixing portion, 43: dropout guide portion
50: rope holder,
60: Rope holder detachment guide,

Claims (6)

A net 10;
A rope (20) connected to the net, the rope (20) being fixed to both sides of a place where the left and right sides are devoid of debris;
The rope is fixed so as to have a cushion portion made of non-linear wiring, and when the net is pushed by the earth stone, the net is divided into two or more stages and the clearance is provided by the buffer portion of the rope, (30) for absorbing an impact applied to the net,
The ropes are bent without being tightened between the multi-stage separating type shock absorbers 30 so as to ensure a length longer than the linear distance, or they are wound several times in the form of a coil to secure the length of the shock absorbers 20-1, 20-2, / RTI >
The multi-stage separable type shock absorber comprises a base plate 40, a rope holder 50 spaced apart from the base plate by a predetermined distance to fix the rope to the base plate and fixing the rope to have the buffer, And a fastener (54) fastened to the rope holder on the opposite side of the rope holder with respect to the base plate and fixing the rope holder to the base plate,
The base plate has a rope holder fixing part 42 through which the rope holder is fixed by a hole having a size that does not allow the rope holder and the fixing member to pass through at one side of the breaking wall 41, When the load is applied to the rope, the rope holder moves to the dropout guiding portion while breaking the breaking wall, and then the loose holder is dropped from the base plate together with the fixing hole Wherein the cushioning is performed by a cushion of the rope. delete delete delete The multi-stage detachable method according to claim 1, wherein the rope holder fixing portion is formed to communicate with the detachment guide portion, and the breaking wall is coupled to the detachment guide portion to divide the rope holder fixing portion and the detachment guide portion. Net. A method for constructing a multi-stage separation type soil erosion protection buffer net according to claim 1,
Assembling and preparing one or more multi-stage detachable buffer means on the rope while connecting the ropes along the transverse direction to the net;
And spreading the net across the drainage area of the unburnt soil, and fixing the left and right sides of the rope to the ground.

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