KR102298312B1 - High Energy Absorption type Rockfall/Soil Protection Structure and Construction Methods thereof - Google Patents

Abstract

The present invention relates to a high-energy absorption type rockfall/soil protection structure (S) and a construction method thereof (M). To achieve the purpose, in regard to a rockfall/soil protection structure formed as upper and lower cables fastened laterally with upper and lower parts of a capture net are sequentially placed on a plurality of posts, each of the posts has a lower support part coupled with the bottom of an upper post part such that forward/backward behavior can be possible, an upper placement part is formed in an upper part of the upper post part to place the upper cable therein, a lower placement part is formed in the lower support part to place the lower cable therein, and one end of a support cable is placed in the upper placement part and the other end of the same is fixed to a rear side under the ground. Accordingly, there can be an advantage of enabling effective shock absorption even when a strong shock is applied by rockfall or soil or a shock is concentrated onto a specific part of the capture net.

Description

High Energy Absorption type Rockfall/Soil Protection Structure and Construction Methods thereof

The present invention relates to a high-energy absorption-type rock and debris flow protection structure and a construction method therefor, and more particularly, to a plurality of upper and lower cables that are laterally bound to the upper and lower parts of a trapping net so that only forward and backward movements are possible. The present invention relates to a high energy absorption type rock and debris protection structure which is sequentially mounted on a pole and supported by a supporting cable fixed to the rear of the pole with an upper part of the pole, and a construction method therefor.

A rockfall prevention facility is a function that inhibits rockfall movement by resisting the impact of falling rocks, blocks the flow of falling rocks into the road by absorbing the energy of falling rocks, or changes the direction of falling rocks to guide them to a place where there is no risk of damage carry out These fall prevention facilities can be divided into reinforcement and protection methods according to their functions, and the most commonly constructed protection methods include a fall prevention net, a fall prevention fence, a fall prevention retaining wall, a piam tunnel, and a vegetation method.

Among them, the rock fall prevention fence is a facility that prevents damage caused by falling rocks by absorbing the energy of falling rocks from the slope by connecting them with wire ropes and wire mesh.

As a related prior art document, there is a "prevention of high tension rock fall" (registered on Nov. 12, 2020, hereinafter referred to as 'prior art document') of Korean Patent Registration No. 2180372. The prior art document mounts the wire rope 3 bound to the net 2 on the upper portion of the H-beam 1 as shown in FIG. 1 , and the lower portion of the H-beam 1 is an anchor 4 . The wire rope 3 receives the impact caused by falling rocks or debris flow by fastening it so that it can rotate back and forth with the pedestal 5 fixed in the ground, and transmits it to a plurality of H beams 1 arranged in the width direction, and the H beam 1 ) was installed so that the load transferred to the ground could be transmitted to the ground based on the anchor (4).

In the prior art document, the H-beam 1 was manufactured to accommodate some displacement so as to buffer the impact load applied in the front-rear direction, but it was relatively vulnerable to the torsional load generated in the lateral direction, and the net (2) As only the upper part of the wire rope 3 is provided, there is a problem in that the shackle is easily damaged when the impact force caused by falling rocks or debris is concentrated on the lower part of the net 2 .

Above all, in the prior art document, when a local impact force is generated as the wire rope 3 is one-to-one with all individual H-beams 1, the impact load is concentrated on the adjacent specific H-beam 1, resulting in partial damage However, there was another problem in which refraction occurred.

In addition, there was a problem that the wire rope 3 is easily broken over time due to wear on the sharp edge or shackle of the top of the H-beam 1, and accordingly the net 2 and the wire rope 3 are to be replaced. Even in this case, there was a limitation that maintenance was not easy.

The present invention has been devised to solve the above problems, and effective shock absorption is possible even if a strong impact force is applied by falling rocks or debris or concentrated in a specific part of the trapping net, and it is stable even with torsional load generated in the lateral direction, It is possible to prevent breakage due to abrasion of cables, and based on this, the durability of the overall structure can be expected, and it is an object to provide a high energy absorption type rock and debris protection structure that is easy to maintain and a construction method thereof.

The high energy absorption type rock and debris protection structure (S) according to an embodiment of the present invention includes a plurality of upper and lower cables (200) and lower cables (300) that are laterally bound to the upper and lower portions of the trapping network (N). It is formed by being sequentially mounted on the posts 100 , and each post 100 has the lower end of the upper post part 110 fastened to the lower support part 120 so that it can move back and forth, and the upper post part 110 . An upper mounting part 130 is formed on the upper part of the , the upper cable 200 is mounted, and a lower mounting part 140 is formed on the lower supporting part 120 to receive the lower cable 300, and the upper mounting part 120 is mounted. It is characterized in that one end of the support cable 400 is mounted on the part 130 and the other end is underground fixed to the rear.

In addition, in the lower holder 140 , a pair of guide plates 141 and 142 are formed side by side in front of the lower support 120 to provide seating surfaces 141a and 142a, and the guide plate Both ends of the (141) and (142) may be extended so that the interval therebetween is widened to provide guide surfaces (141b) and (142b).

In addition, the upper cable 200 includes an upper mounting cable 210 and an upper displacement cable 220 bound to the capture network N, wherein the upper mounting cable 210 and both ends of the upper displacement cable 220 ) can only be mounted on the upper holder 130 .

In addition, the upper mounting cable 210 and the upper displacement cable 220 of the upper cable 200 are bound simultaneously with the capture network N via the binding member SC, but the upper mounting portion 130 is the center As a result, the predetermined binding members SC provided on both sides may be bound only to the upper displacement cable 220 .

In addition, the lower cable 300 includes a lower mounting cable 310 and a lower displacement cable 320 bound to the capture network N, wherein the lower mounting cable 310 and both ends of the lower displacement cable 320 ) can be mounted on the lower holder 140 .

And the lower mounting cable 310 and the lower displacement cable 320 of the lower cable 300 are bound simultaneously with the capture network N via the binding member SC, but with the lower mounting portion 140 as the center The predetermined binding members SC provided on both sides may be bound only to the lower displacement cable 320 .

On the other hand, the construction method (M) of the high energy absorption type rock and debris flow protection structure of the present invention includes a post installation step (S100) of installing the posts 100 at regular intervals in the lateral direction on the slope; A support cable installation step (S200) of mounting one end of the support cable 400 on the upper mounting part 130 of each post 100, and fixing the other end in the rear ground; The upper cable 200 is sequentially mounted on the upper holder 130 of each post 100 , and the lower cable 300 is sequentially mounted on the lower holder 140 , so that the upper cable 200 and the lower cable are sequentially mounted. An upper and lower cable installation step (S300) of fixing both ends of (300) in the lateral underground; and a trapping network installation step (S500) of binding the upper and lower portions of the trapping network (N) to the upper cable 200 and the lower cable 300.

In addition, after the upper and lower cable installation step (S300), the side cables 500 are sequentially mounted to the upper mounting part 130 and the lower mounting part 140 on the posts 100 located at both ends to measure both ends. It may further include a side cable installation step (S400) for fixing the direction underground.

And the trapping net installation step (S500), the fastening means providing step (S510) having a fastening means (SC) to the upper cable 200 and the lower cable 300; and a capture net binding step (S520) of binding the capture net (N) to the fastening means (SC).

According to the high energy absorption type rock and debris flow protection structure (S) of the present invention and its construction method (M), an upper holder is formed on the upper post of the post, an upper cable is mounted, and the lower support is mounted on a lower part. There is an advantage that effective shock absorption is possible even if a strong impact force is applied or concentrated in a specific part of the trapping net by the formation of a part and the mounting of the lower cable.

In addition, one end of the support cable is mounted on the upper mounting portion of the post and the other end is fixed in the rear ground to ensure structural stability even in torsional load generated in the lateral direction.

The upper mounting portion is composed of a pair of cylindrical guide bars protruding forward, and the lower mounting portion is formed with a pair of guide plates side by side to provide a seating surface and a guide surface of sufficient surface area to protect the upper and lower cables from abrasion. Breakage can be prevented in advance.

In particular, the upper and lower cables include upper and lower mounting cables and upper and lower displacement cables bound to the trapping network, wherein the upper and lower displacement cables are mounted on the upper and lower mounting portions of the pole except for both ends. A technical effect that enables stable absorption even when high-energy impact force is applied to the bar by dispersing the impact force to a plurality of poles arranged in succession by preventing the impact force from occurring and allowing some displacement to be accommodated in the event of impact force caused by rockfall or sediment. is demonstrated

Furthermore, even when a local impact force occurs, there is an advantage in that the impact force can be distributed to adjacent posts based on the displacement of the upper and lower displacement cables.

In addition, the high energy absorption type rock and debris protection structure of the present invention can expect the durability of the overall structure based on the shape of a plurality of upper and lower cables and upper and lower mounting portions.

And, since the high-tensile bolt closing the guide bar of the upper mounting part can be selectively separated and fastened, there is an advantage of easy maintenance.

1 is a perspective view showing a fall prevention fence according to the prior art document.
Figures 2a and 2b is a front view and a side view showing a rock and debris flow protection structure according to an embodiment of the present invention.
Figure 3 is a perspective view and an exploded perspective view showing a post according to an embodiment of the present invention.
4A to 4E are perspective views showing time series of a method of constructing a structure for protection against rocks and debris according to an embodiment of the present invention;
Figure 5 is a perspective view showing a capture net according to another embodiment of the present invention.
6 is a perspective view illustrating a fastening structure between a cable and a fastening means according to an embodiment of the present invention.
7 is a cross-sectional view showing a long chain device according to an embodiment of the present invention.
8 is a time-series block diagram illustrating a method of constructing a structure for protection against rocks and debris according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in more detail with reference to the accompanying drawings. The embodiments of the present invention may be modified in various forms, and the scope of the present invention should not be construed as being limited to the following examples. This example is provided to more completely explain the present invention to those of ordinary skill in the art.

As shown in Figures 2a and 2b, the high-energy absorption type rock and debris flow protection structure (S) of the present invention is installed at the lower part of the slope where there is a risk of falling rock or debris flow, and the falling rock or debris flow is falling onto the road and other facilities. In order to prevent the catching network (N) from being continuously installed along the width direction, the catching network (N) is a plurality of the upper and lower cables through the upper and lower cables 200 and the lower cables 300 in the lateral direction. It is sequentially mounted on the support 100 of the.

As shown in Figure 3, the plurality of posts 100 are fixed to the ground along the width direction at the lower part of the slope, and each post 100 is an upper post part ( 110) is formed by fastening the lower end.

The upper holding part 110 according to an embodiment may be manufactured as an H-beam having a pair of flanges and a web, and the lower supporting part 120 is the upper part of the supporting plate 121 provided to contact the slope. A pair of guide flanges 122 and 123 are formed upright side by side, and between the guide flanges 122 and 123, the fastening web 111 is formed to protrude lower than the lower web of the upper post 110 between the guide flanges 122 and 123. High tension bolts 150 may be fastened to pass through the fastening holes formed in each in a state in which is provided.

In addition, depending on the embodiment, it is possible to secure the resistance to buckling by repeatedly coupling the fastening piece 160 connecting the pair of flanges of the upper support part 110 in the vertical longitudinal direction.

The high-tensile bolt 150 is fastened to ensure some degree of fluidity rather than being completely tightened so that the upper holding part 110 and the lower support part 120 can be hinged in the front-rear direction so that the impact force is applied to the trapping net (N). It is preferable to manufacture so that a predetermined forward and backward rotation is possible when applied.

On the other hand, as shown in Figure 4e, the capture network (N) is usually fastened to the upper cable 200 and the lower cable 300 provided at the upper and lower sides via a binding member (SC) referred to as a shackle, respectively. can be The upper cable 200 may be configured to include at least one or more cables, and is mounted on the upper holder 130 formed on the upper part of the upper support 110 , and the lower cable 300 also includes at least one or more cables. It may be configured to include a cable, and is mounted on the lower holder 140 formed in the lower support unit 120 .

That is, the upper cable 200 and the lower cable 300 mounted on the plurality of posts 100 even if a strong impact force is applied to the rock or debris flow generated on the slope or the impact force is concentrated on a specific part of the trapping net (N). Based on this, the impact force is dispersed, which has the advantage of effective shock absorption.

In addition, one end of the support cable 400 is mounted on the upper mounting portion 130 of the post 100 and the other end is fixed in the rear ground, so that structural stability can be ensured even in the torsional load generated in the lateral direction. At this time, as shown in FIG. 2A , a plurality of the support cables 400 are bound around one post 100 , and the plurality of support cables 400 are diagonal lines that change directions around the post 100 . Stable resistance to torsional load is possible by being fixed symmetrically in the rear direction.

On the other hand, as shown in FIG. 3A , in the upper holder 130 according to an embodiment, a pair of cylindrical guide bars 131 and 132 are formed to protrude vertically spaced apart from each other, and the guide bar 131 . The front of the 132 may be formed to be closed by a high tension bolt 133 . That is, the upper cable 200 mounted on the upper holder 130 can be prevented from being separated and separated by the high-tensile bolt 133 , and the impact force applied to the trapping net N as well as the holding force 100 itself. A predetermined tensile force is continuously applied to the upper cable 200 by its own weight, and the guide bars 131 and 132 in contact with the upper cable 200 are manufactured in a cylindrical structure to minimize the contact surface area to minimize wear. can

In addition, since the high tension bolt 133 can be disassembled and reassembled if necessary, if replacement is required due to damage or wear of the capture net N or the upper cable 200, after disassembling the high tension bolt 133 , there is an advantage that maintenance becomes possible by reassembling.

Furthermore, in the lower mounting portion 140 , a pair of guide plates 141 and 142 are formed in front of the lower support portion 120 in parallel to provide seating surfaces 141a and 142a. That is, a predetermined tensile force is continuously applied to the lower cable 300 mounted on the lower holder 140 by not only the impact force applied to the trapping net N, but also the weight of the post 100 itself. Both ends of the guide plates 141 and 142 are spaced apart to provide seating surfaces 141a and 142a in contact with 200, as well as to provide a sufficient contact surface area without being worn on the edge and breaking even when deformed. The outer shell is expanded to form an obtuse angle so as to be widened, and guide surfaces 141b and 142b may be provided.

In addition, as shown in Figure 3b, the upper mounting portion 130 is coupled to the fastening web 134 formed to protrude upward from the upper web of the upper holding portion 110, and the front and rear shackles 135, respectively. 136 is formed so that the upper cable 200 is mounted on the front shackle 135 via the binding member SC, and the support cable 400 is mounted on the rear shackle 136 via the binding member SC. can be

A pair of front shackles 135 are formed in the upper mounting portion 130 of the post 100 disposed at the end in the above embodiment, so that the upper mounting cable 210 and the upper displacement cable of the upper cable 200 to be described later are formed. 220 may be bound to each of the front shackle 135 via the binding member SC.

Meanwhile, as shown in FIG. 4D , high tension bolts 143 are also fastened between the guide plates 141 and 142 of the lower mounting portion 140 to prevent the lower cable 300 from being separated, and at the end A side cable 500 may be additionally mounted and fixed to the positioned post 100 .

The side cable 500 is sequentially mounted on the upper mounting part 130 of the upper holding part 110 and the lower holding part 140 of the lower support part 120, and then both ends are lateral to the ground in the front-rear direction. It can be fixed in a state spaced apart by a predetermined interval. In this case, the side cable 500 may be mounted on the high tension bolt 143 of the lower holder 140 . In addition, as shown in Figure 4e, the side cable 500 is provided with a plurality of fastening means (SC) in the vertical direction can be bound to the end of the trap net (N).

On the other hand, the high energy absorption type rock and debris protection structure (S) of the present invention consists of a plurality of upper cables (200) and lower cables (300) bound to the capture network (N), respectively, as shown in FIG. , There is a major technical difference in the point installed to include an upper mounting cable 210 and an upper displacement cable 220 and a lower mounting cable 310 and a lower displacement cable 320 .

In one embodiment, only the upper mounting cable 210 and the upper displacement cables 220 at both ends may be mounted on the upper mounting portion 130 of the post 100 . That is, the upper mounting cable 210 and the upper displacement cable 220 of the upper cable 200 are simultaneously bound with the capture network N via the binding member SC, and the upper displacement cable 220 is positive Except for the upper mounting portion 130 of the end-side post 100 , it is indirectly mounted through the upper mounting cable 210 without being directly mounted on the upper mounting unit 130 .

As a result, even when an impact force is generated in the trapping net (N) due to rockfall or earth and sand, the upper displacement cable 220 accommodates some displacement based on the degree of freedom and at the same time, the impact force is generated by a plurality of poles 100 arranged in series. By dispersing the bar, even when a high-energy impact force is applied, a technical effect capable of stable absorption is exhibited.

Similarly, the lower cable 300 also includes a lower mounting cable 310 and a lower displacement cable 320 bound to the capture network N, wherein the lower mounting cable 310 and both ends of the lower displacement cable 320 ) can only be mounted on the lower mounting portion 140 of the post 100 . That is, the lower mounting cable 310 and the lower displacement cable 320 of the lower cable 300 are simultaneously bound with the capture network N via the binding member SC, and the lower displacement cable 320 is positive Except for the lower mounting portion 140 of the end-side post 100 , it is indirectly mounted through the lower mounting cable 310 without being directly mounted on the lower mounting unit 140 .

In addition, according to the embodiment, as shown in FIG. 6 , the upper mounting cable 210 and the upper displacement cable 220 of the upper cable 200 simultaneously with the capture network N via the binding member SC. However, the predetermined binding members SC provided on both sides around the upper mounting portion 130 may be bound only to the upper displacement cable 220 .

Accordingly, even when a local impact force occurs in the trapping net (N), the impact force can be partially distributed by the displacement in the upper displacement cable 220 without the load being concentrated on the specific post 100, so structurally stable high energy absorption It is possible to provide a type rock rock/earthstone flow protection structure (S).

Similarly, the lower mounting cable 310 and the lower displacement cable 320 of the lower cable 300 are bound simultaneously with the capture network N through the binding member SC, but the lower mounting portion 140 is the center As a result, the predetermined binding members SC provided on both sides may be bound only to the lower displacement cable 320 .

On the other hand, as described above, the support cables 400 are preferably arranged in plurality around one post 100 , and at this time, each support cable 400 has one end surrounding the upper support part 110 . It is mounted on the upper holder 130 in a closed state and may be manufactured so as not to be broken by strong tensile strength based on a sufficient surface area.

In addition, as shown in FIG. 7 , the other end of the support cable 400 may be fixed via an attenuator 600 fastened to the ground at the rear. In an embodiment, the damping device 600 includes a damping member 610 that is deformed according to the impact energy to absorb and dissipate the impact force caused by a rockfall or debris flow, and a shackle 620 to the damping device 600 . The support cable 400 fixed by the can be bound to the anchor (A) fixed in the ground so that an end of the damping member 610 is provided with enough displacement to allow the deformation.

At this time, the damping member 610 of the damping device 600 according to an embodiment may be composed of a guide bar 611 , a guide body 612 , and a plurality of guide pins 613 formed on the guide body 612 . In addition, the attenuator 600 may be bound to both ends of the upper cable 200 and the lower cable 300 so as to be stably fixed in the ground of the slope as well as the support cable 400 .

When the upper cable 200 and the lower cable 300 are configured in plurality to include the upper and lower support cables 210 and 310 and the upper and lower displacement cables 220 and 320, an attenuator ( 600) may be bound and fixed by a shackle to the anchor (A).

In addition, the trapping net (N) of the high energy absorption type rock debris flow protection structure (S) of the present invention is a rhombus-shaped grid made of a steel wire as shown in FIG. It can be manufactured to have sufficient tensile strength by being made of a mesh, and it is also possible to produce a mixed structure thereof.

The high energy absorption type rock and debris flow protection structure (S) of the present invention described above is a plurality of upper and lower cables 200 and 300 and upper and lower mounting portions 130 and 140 formed on the posts 100. The durability of the overall structure can be expected based on the shape and the organic coupling relationship of the support cable 400 and the capture network (N).

On the other hand, below, the construction method (M) of the high energy absorption type rock and debris flow protection structure of the present invention will be described in more detail. As shown in FIG. 8, the construction method (M) of the high energy absorption type rock and debris flow protection structure of the present invention includes a post installation step (S100), a support cable installation step (S200), an upper and lower cable installation step (S300) and capture It includes the network installation step (S500), and will be mainly described with reference to the drawings shown in time series in FIGS. 4A to 4E .

The post installation step (S100) is a step of installing the posts 100 at regular intervals in the lateral direction on the slope. It may include a fixing step (S110) of the lower pedestal for binding through an anchor to a holding step (S120) of fastening the lower end of the upper strut 110 to the lower pedestal 120 so as to be able to move forward and backward. .

The subsequent support cable installation step (S200) is a step of mounting one end of the support cable 400 on the upper mounting part 130 of each post 100 as shown in FIG. 4B and fixing the other end to the rear ground. am. At this time, the support cables 400 are bound to a plurality of the support cables 100 as a center, and the plurality of support cables 400 are fixed symmetrically in a diagonal direction rearward in different directions about the support posts 100 . Stable resistance to torsional loads is possible.

In the next upper and lower cable installation step (S300), the upper cable 200 is sequentially mounted on the upper holder 130 of each post 100, and the lower cable is mounted on the lower holder 140, as shown in FIG. 4c. (300) is sequentially mounted to fix both ends of the upper cable 200 and the lower cable 300 in the lateral direction.

In this case, the upper cable 200 and the lower cable 300 may be configured to include a plurality of cables, respectively. In one embodiment, the upper and lower cables 200 and 300 include upper and lower mounting cables 210 and 310 and upper and lower displacement cables 220 and 320, whereby the upper and lower cables are mounted. A mounting cable mounting step (S310) of sequentially mounting the 210 and 310 to the upper mounting portion 130 and the lower mounting portion 140 of the post 100, and the upper and lower displacement cables 220 and 320 ) may include a displacement cable mounting step (S320) mounted only on the upper cradle 130 and the lower cradle 140 of both end-side posts 100 . Of course, the mounting cable mounting step (S310) and the displacement cable mounting step (S320) may be performed substantially simultaneously.

In addition, it may include a cable fixing step (S330) of fixing the upper and lower mounting cables 210 and 310 and the upper and lower displacement cables 220 and 320 in the ground on both sides. At this time, the cable fixing step (S330) is a damping device 600 having a damping member 610 at the ends of the upper and lower mounting cables 210 and 310 and the upper and lower displacement cables 220 and 320. It can be fastened to the anchor (A) fixed in the ground by fastening it.

As a result, even when an impact force is generated in the trapping net (N) due to rockfall or earth and sand, the upper displacement cable 220 accommodates some displacement based on the degree of freedom and at the same time, the impact force is generated by a plurality of poles 100 arranged in series. By dispersing the bar, even when a high-energy impact force is applied, a technical effect capable of stable absorption is exhibited.

In addition, as shown in FIG. 4D, after the upper and lower cable installation step (S300), the side cables 500 are sequentially attached to the upper and lower mounts 130 and 140 on the posts 100 located at both ends. It may further include a; side cable installation step (S400) for fixing both ends in the lateral underground by mounting.

The side cable 500 is sequentially mounted on the upper mounting part 130 of the upper holding part 110 and the lower holding part 140 of the lower support part 120, and then both ends are lateral to the ground in the front-rear direction. It can be fixed in a state spaced apart by a predetermined interval. The side cable 500 serves to support the torsional load of the holding posts 100 disposed at both ends as well as binding the ends of the trapping net N at the same time.

The subsequent capture network installation step (S500) is a step of binding the upper and lower portions of the capture network N to the upper cable 200 and the lower cable 300 as shown in FIG. 4e, and the upper cable ( 200) and a fastening means providing step (S510) including a fastening means (SC) to the lower cable 300, and a capture network binding step (S520) of binding the capture network (N) to the fastening means (SC); may include

In addition, in the embodiment in which the upper cable 200 and the lower cable 300 include upper and lower mounting cables 210 and 310 and upper and lower displacement cables 220 and 320, respectively, the fastening means In the providing step (S510), the predetermined binding members SC provided on both sides of the upper holder 130 are bound only to the upper displacement cable 220, and on both sides with the lower holder 140 as the center. The provided binding member SC may be bound only to the lower displacement cable 320 .

That is, the upper and lower mounting cables 210 and 310 and the upper and lower displacement cables 220 and 320 are simultaneously bound with the capture network N via the binding member SC, but the upper mounting portion ( 130) and the predetermined binding members SC provided on both sides around the lower holder 140 are bound only to the upper and lower displacement cables 220 and 320, so that a local impact force is generated in the capture network N. Even when the load is not concentrated on the specific post 100, the impact force can be partially distributed by the displacement on the upper displacement cable 220, so a structurally stable high energy absorption type rock and debris protection structure (S) can be provided. have.

Although the description has been focused on the embodiments of the high energy absorbing rock and debris flow protection structure (S) and the construction method (M) of the present invention, those of ordinary skill in the art can use the invention described in the claims. It will be possible to variously modify and change the present invention by adding, changing, deleting or adding elements within the scope not departing from the spirit, and this will also be included in the scope of the present invention.

Furthermore, in describing the embodiments of the present invention, when it is determined that a detailed description of a known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description thereof is omitted. And, the terms used in the above are terms defined in consideration of functions in the embodiment of the present invention, which may vary according to intentions or customs of users and operators. Therefore, the definition should be made based on the content throughout this specification. Accordingly, the detailed description of the present invention is not intended to limit the present invention to the disclosed embodiments, and the appended claims should be construed as including other embodiments.

S: Falling rock and debris flow protection structure N: Capture net
100: holding 110: upper holding part
120: lower support 130: upper mounting portion
131,132: cylindrical guide bar 133: high tension bolt
140: lower mounting portion 141, 142: guide plate
200: upper cable 210: upper mounting cable
220: upper displacement cable 300: lower cable
310: lower mounting cable 320: lower displacement cable
400: support cable 500: side cable
600: attenuation device SC: binding member
M: How to construct a structure for protection against falling rocks and debris
S100: Post installation step S200: Support cable installation step
S300: upper and lower cable installation step S400: side cable installation step
S500: Capture network installation stage

Claims (9)

In the falling rock and debris flow protection structure (S) formed by sequentially mounting the upper cable 200 and the lower cable 300 bound to the upper and lower parts of the trapping net (N) in a sequence on a plurality of posts (100) ,
Each post 100 has a lower end of the upper post part 110 fastened to the lower support part 120 so that it can move back and forth, and an upper holding part 130 is formed on the upper part of the upper post part 110 to allow the upper part. The cable 200 is mounted, the lower holder 140 is formed on the lower support unit 120 , the lower cable 300 is mounted, and one end of the support cable 400 is provided on the upper holder 130 . A pair of guide plates 141 and 142 are formed side by side in front of the lower support part 120, and the lower mounting part 140 has a seating surface 141a ( 142a) is provided, and both ends of the guide plates 141 and 142 are extended to widen the distance therebetween to provide guide surfaces 141b and 142b.
delete According to claim 1,
The upper cable 200 includes an upper mounting cable 210 and an upper displacement cable 220 bound to the capture network N, but only the upper mounting cable 210 and the upper displacement cables 220 at both ends. A high energy absorption type rock and debris protection structure, characterized in that it is mounted on the upper mounting part (130).
4. The method of claim 3,
The upper mounting cable 210 and the upper displacement cable 220 of the upper cable 200 are bound simultaneously with the capture network N via the binding member SC, but both sides centering on the upper mounting part 130 The predetermined binding member (SC) provided in the high energy absorption type rock and debris protection structure, characterized in that it is bound only to the upper displacement cable (220).
According to claim 1,
The lower cable 300 includes a lower mounting cable 310 and a lower displacement cable 320 bound to the capture network N, but only the lower mounting cable 310 and the lower displacement cables 320 at both ends. A high-energy absorbing rock and debris flow protection structure, characterized in that it is mounted on the lower mounting part (140).
6. The method of claim 5,
The lower mounting cable 310 and the lower displacement cable 320 of the lower cable 300 are bound simultaneously with the capture network N via the binding member SC, but both sides around the lower holder 140 . The predetermined binding member (SC) provided in the high energy absorption type rock and debris flow protection structure, characterized in that it is bound only to the lower displacement cable (320).
In the method for constructing a high energy absorption type rock and debris flow protection structure using the invention of claim 1,
Post installation step (S100) of installing the posts 100 at regular intervals in the lateral direction on the slope;
A support cable installation step (S200) of mounting one end of the support cable 400 on the upper mounting portion 130 of each post 100, and fixing the other end in the rear ground;
The upper cable 200 is sequentially mounted on the upper holder 130 of each post 100 , and the lower cable 300 is sequentially mounted on the lower holder 140 , so that the upper cable 200 and the lower cable are sequentially mounted. An upper and lower cable installation step (S300) of fixing both ends of (300) in the lateral underground; and
A capture network installation step (S500) of binding the upper and lower portions of the capture network (N) to the upper cable 200 and the lower cable 300;
A method of constructing a high energy absorption type rock and debris protection structure comprising a.
8. The method of claim 7,
After the upper and lower cable installation step (S300),
A side cable installation step (S400) of sequentially mounting the side cables 500 to the upper mounting part 130 and the lower mounting part 140 to the posts 100 located at both ends and fixing both ends to the lateral underground;
A method of constructing a high energy absorbing rock and debris flow protection structure further comprising a.
8. The method of claim 7,
The capture network installation step (S500) is,
A fastening means providing step (S510) of providing a fastening means (SC) to the upper cable 200 and the lower cable 300; and
a trapping network binding step (S520) of binding the trapping network (N) to the fastening means (SC);
A method of constructing a high energy absorption type rock and debris protection structure comprising a.

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