KR101705885B1 - Constructing method and shock absorbing apparatus for rockfall preventing net - Google Patents

Abstract

The present invention relates to a movable-type shock-absorbing device for preventing rock from falling and a construction method thereof. The movable-type shock-absorbing device for preventing rock from falling comprises: a fixation part which is formed in the shape of a plate, includes a front side unit and joining units which are bent from both end portions of the front side unit and have second through-holes; a pair of movable-type U bolts which comprise a body unit, bent in the shape of a groove, and screw units having screws on outer circumferences of both end portions of the body unit and have both end portions inserted from the outside of the fixation part through the second through-holes of the joining units; compression springs which are arranged, in the fixation part, in the shapes covering an outer circumferential side of the body unit and are joined to the movable-type U bolts; a spring pressing plate which is separated from the fixation part, is arranged between the compression spring and the screw units, and is formed in the shape of a plate having first through-holes to allow both end portions of the movable-type U bolts to be inserted; joining nuts which are screw-joined to the screw unit from a side opposite to the compression springs with respect to the spring pressing plate as the center to prevent the spring pressing plate from escaping, and form a joining ring on one side; and tension springs which join the joining nuts which are installed on both end portions of the movable-type U bolts and face each other. Therefore, it is possible to increase the tension to enable a wire rope to be extended when rock falls. In addition, the wire rope can be prevented from being easily broken.

Description

TECHNICAL FIELD [0001] The present invention relates to a shock absorber for preventing rockfall and a method for constructing the shock absorber,

More particularly, the present invention relates to a shock absorber for preventing rockfall and a method of constructing the shock absorber, and more particularly, to a shock absorber and a method of constructing a shock absorber that absorbs impact energy elastically in stages according to the magnitude of impact energy applied to a wire rope .

Typically, rockfall protection networks or rockfall prevention measures are installed to prevent rocks that have been detached from rocks existing on the slope of the road or the side of the guards from penetrating into roads or sidewalks.

Such a rockfall prevention net reinforces the slope surface by fixing the net made of synthetic resin on the slope surface using a fixing fastener or the like. However, such a rockfall prevention network has a problem that it is easily torn or broken due to impact caused by rockfall of a certain weight or more.

In recent years, a buffer for preventing rockfall has been developed and used so as to more flexibly absorb the impact energy applied to the rockfall prevention network as a solution to the above-mentioned problems.

1 is a view showing an elastic contact type rockfall preventing network according to the prior art.

The conventional resilient compression type rockfall preventing network according to the related art includes a wire rope 20 disposed on the surface of a fall-preventing prevention network 10 and a fixing member 31 fixed to the sloped surface in a state of pressing the fall- A plate 30 and a compression spring 40 for elastically connecting the connection plate 30 and the wire rope 20.

However, in the conventional resilient pressing rockfall preventing network according to the related art, the wire rope 20 is connected to the binding plate 30 through the compression spring 40, so that the wire rope 20 The number of the compression springs 40 is increased because the wire rope 20 connected to the compression springs 40 is supported only by the elastic force of the compression springs 40, The wire ropes 20 can not be firmly supported.

KR 10-0859209 B1 (2008.09.18.)

The present invention has been conceived to solve the above-mentioned conventional problems, and it is an object of the present invention to provide a shock absorber of anti-rocking type which absorbs impact energy step by step according to the magnitude of impact energy applied to a wire rope, The purpose is to provide.

Another object of the present invention is to provide a floating type shock absorber which is made of a simple structure and can reduce the working time required for assembly and disassembly.

It is still another object of the present invention to provide a shock absorber and a method of constructing a bridge type anti-rocking type in which neighboring wire ropes are elastically supported together so that the wire rope can be more firmly and safely installed.

In order to achieve the above-mentioned objects, the anti-rocking fluid type buffer according to the present invention is in the form of a plate, and includes a front portion and a coupling portion bent at one side from both ends of the front portion, A fixture in which a through hole is formed; A pair of floating U-bolts formed of a body portion bent in a groove shape and a threaded portion formed on the outer periphery of both ends of the body portion, both ends of which are inserted from the outside of the fixing hole through a second through hole of the coupling portion; A compression spring which is respectively assembled to the pair of the floating type U bolts in such a manner as to enclose the outer periphery of the body within the fixture; A spring presser plate disposed between the compression spring and the threaded portion in a state of being separated from the fixture and having a first through hole for inserting both ends of the flow U-bolt; A fastening nut for fastening the spring pressing plate to the threaded portion on the opposite side of the compression spring to prevent the spring pressing plate from coming off and forming a connecting ring on one side; And a tension spring for connecting opposite coupling nuts provided at both ends of the pair of the floating type U bolts.

And the second through hole is formed in a vertical shape so that the body can be linearly moved in a direction in which the coupling portion is bent.

And the second through hole is formed of two holes that are respectively divided into one side and the other side of the coupling portion to correspond to the two round bar structures of the bent body portion.

A fastening hole is formed in the front portion of the fixture to receive the anchor body, and a fixing pin is provided between the fastening hole and the anchor body.

 A method for constructing a rockfall preventing network using a rockfall preventive flow type shock absorber according to the present invention is a method for constructing a rockfall preventing network using a compression spring, the method comprising: laying a rockfall preventing network on a slope; Disposing a wire rope in a rhombic shape on the fall-preventing network; and disposing a fixture in a perforation hole formed in a slope; Passing a wire rope through a flow U-bolt coupled to the outside of the fixture; Assembling the U-bolt by inserting the compression spring, the spring-biasing plate, and the fastening nut sequentially in a state in which the bent both ends of the U-bolt are inserted through the second through hole from the outside of the fastener; Tightening a tension spring to elastically connect the floating U-bolts disposed in a direction opposite to each other; And fixing the fixture using an anchor body inserted into the perforation hole.

 A method of constructing a rockfall prevention network using a rockfall preventive flow type shock absorber according to the present invention is a method of constructing a rockfall prevention network using compression springs, comprising the steps of: Disposing a wire rope in a stock rock preventive stockholder, disposing the wire rope in a rhombic shape, and disposing a fixture at a rhombic crossing point; Passing a wire rope through a flow U-bolt coupled to the outside of the fixture; Assembling the U-bolt by inserting the compression spring, the spring-biasing plate, and the fastening nut sequentially in a state where the bent both ends of the U-bolt are coupled to the fastener; Tightening a tension spring to elastically connect the floating U-bolts disposed in a direction opposite to each other; And a step of laying a synthetic resin network on the wire rope.

According to the present invention having the above-described structure, by constituting the anti-rocking motion type buffer that includes the tension springs connecting between the floating U-bolts so that the relative movement between the floating U-bolts can be performed, The tensile force that can be increased can be further increased, and also the phenomenon that the wire rope is easily broken can be prevented.

In addition, since the second through-hole formed in the fixture has a vertical slotted structure, it can actively cope with the sloped surface having a groove structure and can be installed, and impact energy applied to the wire rope The moving range of the U-bolt can be maximized so that the U-bolt can be moved up and down and left and right depending on the position and size of the U-bolt.

1 is a view showing an elastic contact type rockfall preventing network according to the prior art.
FIG. 2 is a view showing an anti-rocking flow type buffer according to an embodiment of the present invention.
3 is a plan view of Fig.
4 is a side view of Fig.
Fig. 5 is a view showing the action of the linear U-bolt of Fig. 2 moving linearly in the vertical direction.
Fig. 6 is a view showing the action of the floating U-bolts of Fig. 2 relative to each other. Fig.
7 is a view showing an elasticity adjusting member and a spring pressing plate according to another embodiment of the present invention.
8 is a schematic view showing a state in which the anti-rocking flow type buffer according to the embodiment of the present invention is installed on a slope having a groove structure.
9 is a view showing a state in which a rockfall preventing net is installed using an anti-rocking fluid type buffer according to an embodiment of the present invention.
10 is a flowchart showing a construction method of FIG.
FIG. 11 is a view showing a state in which a rockfall preventing network is installed using a rockfall preventing flow type buffer according to another embodiment of the present invention.
12 is a flowchart showing the construction method of Fig.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying FIGS. 2 to 12. FIG.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the anti-rockfall type buffer and method of construction according to the present invention will be described in detail with reference to the accompanying drawings. It is to be understood that the terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms and that the inventor should properly interpret the concepts of the terms to best describe their invention It should be construed as meaning and concept consistent with the technical idea of the present invention based on the principle that it can be defined. In addition, since the embodiments described in the present specification and the configurations shown in the drawings are only the most preferred embodiments of the present invention and do not represent all the technical ideas of the present invention, It is to be understood that equivalents and modifications are possible.

As shown in the drawings, the anti-rocking fluid type buffer according to the present invention includes a fluid type U bolt 10, a compression spring 20, a spring pressure plate 30, a fastener 40, a fastening nut 60 and a tension spring 70 .

First, the floating type U bolt 10 comprises a body portion 12 formed by a round bar and folded into a U-shaped groove, and a threaded portion 14 having a thread formed on the outer periphery of both ends of the body portion 12. Such a floating type U bolt 10 is made of a steel material having excellent strength and rigidity.

The compression spring 20 is assembled in the longitudinal direction in which the body 12 of the floating U-bolt 10 extends in the linear direction in the form of wrapping the outer periphery of the body 12 of the floating U-bolt 10.

Specifically, the compression spring 20 is installed in a state of being coupled to the body 12 of the floating type U bolt 10, and one end in the longitudinal direction is supported by the engaging portion 42 of the fixture 40 And the other end is held in a state of being supported by a spring pressing plate 30 to be described later.

The compression spring 20 is disposed symmetrically about the bent portion of the body 12.

Alternatively, the compression springs 20 are provided as a pair and are inserted into the body 12 through the opposite ends of the floating U-bolt 10, respectively, so that the compression springs 20 are symmetrically symmetrical about the bent portion of the body 12 . The compression springs 20 are provided in pairs so as to be respectively fitted to the body 12 of the flow type U bolts 10 so that the wire rope W is moved in accordance with the direction and size of the external force applied to the wire rope W, Can be more effectively supported elastically.

The compression spring 20 according to the present invention allows the floating U-bolt 10 to move in a linear direction from the elastic force of the compression spring when the impact energy is generated by the rockfall, thereby buffering the falling rock impact energy And provides an effect of further improving.

Here, the compression spring 20 and the spring pressing plate 30 are installed in the fixture 40.

This is for the purpose of facilitating the interaction between the compression spring 20 and the spring pressing plate 30 by using the engaging portion 42 formed on the fixture 40.

The spring pressing plate 30 is coupled to the body 12 of the floating U-bolt 10 to which the compression spring 20 is coupled so that the elastic compression action of the compression spring 20 is stably performed .

Here, the spring pressing plate 30 is fixed to the spring plate 30 so that the body 12, which is located between the compression spring 20 and the threaded portion 14 of the floating U-bolt 10, And a through hole (36).

The first through hole 36 is preferably formed by two split holes corresponding to the diameters of the body 12 divided into the bent state of the floating U-bolt 10, But may be formed in a single structure having a size capable of accommodating both of the body portions 12. [

The fastener 40 is formed of a rectangular plate and includes a front portion 41 and a coupling portion 42 that is bent at one side from both ends of the front portion 41. The bent coupling portion 42 has a fluid type U And the second through hole 42a is formed so that the threaded portion 14 of the bolt 10 is fitted and assembled. At this time, the second through-hole 42a has the same or similar structure as that of the first through hole 36 described above, and is formed so as to correspond to the two round bar structures of the body portion 12, The body portion 12 may be formed with two holes each of which is divided into the other side and formed so as to be relatively wider than the diameter of the body portion 12 so that the body portion 12 can flow left and right laterally.

The second through hole 42a is formed by a vertical slot extending in a direction in which the coupling portion 42 is bent so that the body portion 12 can be linearly moved. .

In other words, the second through-hole 42a is formed in a vertically extending shape having a larger space for moving the body 12 in a vertical direction than a space in which the body 12 can move laterally.

The second through-hole 42a provides a moving space through which the body 12 can flow in the left-right direction as well as up and down directions. Thus, as shown in FIG. 8, the slit- The U-bolt 10 can be moved up and down and left and right depending on the position and size of the impact energy applied to the wire rope W when a rockfall occurs. It is possible to further improve the buffering effect on impact energy (see FIGS. 5 and 6).

A fastening hole 44 is formed at the center of the front portion 41 of the fastener 40 and an anchor body 50 inserted and fixed in the perforation hole formed in the slope of the road or the side surface of the guide portion, Respectively.

A fixing pin 51 is provided between the coupling hole 44 and the anchor body 50 so that the fixing hole 40 can be firmly fixed to the slope of the road or the side surface .

The clamping nut 60 is screwed to the threaded portion 14 from the opposite side of the compression spring 20 with respect to the spring pressing plate 30 so as to be inserted into the floating U- (20) and the spring pressing plate (30).

A connection ring 61 is formed at one side of the outer surface of the coupling nut 60 to connect a tension spring 70, which will be described later.

The connection ring 61 is preferably formed in an annular shape, but is not limited thereto. The connection ring 61 may be formed in various polygonal shapes such as a hollow triangle, a quadrangle, or the like, as well as a hook structure having a hook shape You may.

The tension spring 70 connects the mutually facing coupling nuts 60 provided at both ends of the pair of the floating type U bolts 10 so that the floating type U bolts 10 can elastically move relative to each other, It provides a buffering effect.

That is, the tension spring 70 connects the floating U-bolts 10 so that they can be elastically moved relative to each other. When the impact energy is generated by the falling rock, the floating U-bolts 10 are connected to the wire ropes W 10 of the wire rope W is moved by a predetermined distance to further perform elastic resistance against the tensile force of the wire rope W, thereby preventing the wire rope W from being broken.

7 (a), an elastic tune member 35 for adjusting the elastic force of the compression spring 20 is additionally provided between the spring biasing plate 30 and the lock nut 60. As shown in Fig.

That is, the elasticity adjusting member 35 is fastened to the threaded portion 14 so that the distance that the floating U-bolt 10 can elastically move can be effectively adjusted according to the ground state of the slope face.

In other words, even if a sloped surface having a certain area is used, the ground strength of one side may be different from that of the other side, so that the elasticity of the wire rope can be set variously correspondingly.

7 (b), the spring pressing plate 30 may be formed into a cylindrical shape or a hemispherical shape to house the compression spring 20 in a state of enclosing the spring.

This is to prevent the compression action from being deteriorated due to weakening of corrosion or durability when the compression spring 20 is exposed to the outside for a long time.

At this time, it is a matter of course that a through hole 42b corresponding to the shape of the spring pressing plate 30 is formed in the engaging part 42 so that the spring pressing plate 30 can slide.

Hereinafter, with reference to FIGS. 1, 9, and 10, a construction method using the anti-rocking flow type buffer according to one embodiment of the present invention will be described.

(S1) of laying a slope prevention gate (G) on a slope surface; and arranging a wire rope (W) in a rhombic form on the slope prevention network (G) A step S3 of passing a wire rope W through a floating U-bolt 10 which is coupled to the outside of the fixture 40, a step S2 of moving the bent U- (S4) assembling the compression spring (20), the spring pressure plate (30), and the lock nut (60) successively in a state of being coupled to the U-bolt (10) A step S5 of tightening the tension spring 70 so as to elastically connect the wire ropes W to the floating U-bolts 10 projecting outwardly of the fastener 40, And fixing the fixture 40 using the anchor body 50 inserted into the perforation hole (S6).

The rockfall prevention network G may be a synthetic resin material such as a PVC net made of polyvinyl chloride or a metal mesh or a mixed mesh net coated with PVC around the surface of an iron mesh.

1, 11, and 12, a construction method using a shock absorber of a floating type according to another embodiment of the present invention will be described.

(S10) of installing a rockfall preventing main shoe B on the bottom surface L of the main shaft B and a wire rope W placed on the main shaft of the anti-rocking measure B to arrange the wire rope W in a rhombic shape (S30) of passing a wire rope (W) through a floating U-bolt (10) coupled to the outside of the fixture (40) A step (S40) of assembling the compression spring (20), the spring pressure plate (30) and the fastening nut (60) in succession while assembling the bent ends of the U bolt (10) to the fastener (40) A step (S50) of tightening a tension spring (70) so as to elastically connect the floating U-bolts (10) arranged in the direction of the wire (10) (S60) of passing the wire rope (W) through the wire rope (W) It consists of.

The synthetic resin mesh (M) is mainly made of iron mesh coated with a synthetic resin such as PVC (polyvinyl chloride).

According to the present invention constructed as described above, by constituting the anti-rocking motion type buffer including the tension spring 70 connecting between the floating U-bolts 10 so that the relative movement between the floating U-bolts 10 can be performed It is possible to further increase the tensile force by which the wire rope W can be increased in the event of a fall, and to prevent the wire rope W from being easily broken.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, Will be apparent to those of ordinary skill in the art.

10: Fluid type U bolt 20: Compression spring
30: spring platen 40: fastener
50: anchor bolt 60: fastening nut
70: Tension spring

Claims (6)

A fixture having a plate shape and including a front portion and a coupling portion bent to one side from both ends of the front portion, wherein the coupling portion has a second through hole, respectively;
A pair of floating U-bolts formed of a body portion bent in a groove shape and a threaded portion formed on the outer periphery of both ends of the body portion, both ends of which are inserted from the outside of the fixing hole through a second through hole of the coupling portion;
A compression spring which is respectively assembled to the pair of the floating type U bolts in such a manner as to enclose the outer periphery of the body within the fixture;
A spring presser plate disposed between the compression spring and the threaded portion in a state of being separated from the fixture and having a first through hole for inserting both ends of the flow U-bolt;
A fastening nut for fastening the spring pressing plate to the threaded portion on the opposite side of the compression spring to prevent the spring pressing plate from coming off and forming a connecting ring on one side; And
And a tension spring for connecting opposing clamping nuts provided at both ends of the pair of the floating type U bolts,
Wherein the second through hole comprises a vertical slot extending in a lateral direction so as to allow the body to move left and right and to be linearly movable in a vertical direction.
delete The method according to claim 1,
Wherein the second through-hole is formed of two holes each of which is divided into one side and the other side of the coupling portion to correspond to the two round bar structures of the bent body portion.
The method according to claim 1,
Wherein a fastening hole is formed in a front portion of the fixture so that the anchor body is inserted, and a fixing pin is provided between the fastening hole and the anchor body.
A method of constructing a rockfall preventing network using a compression spring, which is assembled to a pair of floating type U bolts in a manner of enclosing the outer periphery of the body inside the fixture according to any one of claims 1 to 3,
Installing a rockfall prevention net on a slope;
Disposing a wire rope in a rhombic shape on the fall-preventing network, and then disposing a fixture in a perforation hole formed in a slope;
Passing a wire rope through a flow U-bolt coupled to the outside of the fixture;
Assembling the U-bolt by inserting the compression spring, the spring-biasing plate, and the fastening nut sequentially in a state in which the bent both ends of the U-bolt are inserted through the second through hole from the outside of the fastener;
Tightening a tension spring to elastically connect the floating U-bolts disposed in a direction opposite to each other;
And fixing the fixture by using an anchor body inserted into the perforation hole.
A method of constructing a rockfall preventing network using a compression spring, which is assembled to a pair of floating type U bolts in a manner of enclosing the outer periphery of the body inside the fixture according to any one of claims 1 to 3,
Installing a rockfall prevention measure shareholder on the floor surface;
Disposing a wire rope in a stock rock preventive stockholder, disposing the wire rope in a rhombic shape, and disposing a fixture at a rhombic crossing point;
Passing a wire rope through a flow U-bolt coupled to the outside of the fixture;
Assembling the U-bolt by inserting the compression spring, the spring-biasing plate, and the fastening nut sequentially in a state where the bent both ends of the U-bolt are coupled to the fastener;
Tightening a tension spring to elastically connect the floating U-bolts disposed in a direction opposite to each other;
And a step of laying a synthetic resin network on the wire rope.

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