KR100947248B1 - A stone structure for the protection of slope and constructing method thereof - Google Patents

Abstract

PURPOSE: A stone structure for slope protection and a construction method thereof are provided to protect a slope by securing fixing force in the soft ground or a steep slope. CONSTITUTION: A stone structure for slope protection comprises a block(10), an anchor(20), a support member(70), and a connection member(60). The block is composed of natural block or imitation stone. The anchor is inserted in one side of the block. The support member is inserted into the ground to secure fixing force. The connection member connects the support member with the anchor.

Description

A stone structure for the protection of slope and constructing method

The present invention relates to a stone structure for protecting the slope is installed on the top of the slope to protect the slope and a construction method thereof, and more specifically, a block made of natural or artificial stone; An anchor press-installed on one side of the block; A support member press-fitted into the ground to secure a fixing force; A connection member connecting the support member and the anchor; Including the soft ground, steep slopes and fast flow velocity, it is possible to protect the slope by showing a firm fixing force, and the support member press-installed in the ground to secure the fixing force of the block has a 'V' shape in the ground. It relates to a slope protection stone structure and its construction method characterized in that the earth can be faithfully filled in the upper portion of the support member as well as to maintain.

As industrialization and urbanization are rapidly progressing, land use in river basins is also increasing, and many slope protection works have been carried out on slopes around rivers such as flood control to prevent flooding or landscapes around rivers.

Conventional construction for the protection of the slope was used a method of concrete block the entire slope of the river using an artificial concrete structure, but due to the disadvantages that are not environmentally friendly, there are a lot of problems in the construction recently.

As an alternative to solve this problem, a method of constructing a stone net utilizing natural stones and the like is used. FIG. 1 is a reference view showing a cross section of a conventional stone net installed on a slope, and FIG. It is a reference diagram showing the state that the stone is fixed to the wire mesh.

1 and 2, in the case of the conventional method for installing the stone net on the slope, first to secure the stone (a) using the anchor bolt (b) to the wire mesh (d), such as a net proceeds in the factory It is then transported along with other materials to the construction site. At this time, if necessary, the vegetation mat (c) for inducing seed germination is further included in the upper portion of the wire mesh (d). After the transportation is completed, the construction site unfolds the wire mesh (d) on which the stone (a) is fixed to the slope, and then connects each wire mesh (d) using a wire such as a wire to complete the construction.

However, the conventional stone net construction method constructed in the above manner, first, each of the wire mesh (d) to which the stone (a) is fixed must be transported to the construction site by using a vehicle (anchor bolt (b)) Although it is not possible to perform the fixing of the used stone (a) to the wire mesh (d) at the construction site, it is not possible to perform the fixing work as described above. Since the anchor bolt (b) must be fixed at the bottom, it is difficult for the unskilled workers (construction workers at the construction site), and the work efficiency at the actual site is remarkably weak compared to that performed by skilled workers in the factory. Since it is more inefficient than efficiency, it is fixedly assembled at the factory and transported to the site), and due to the volume of the stone (a), the wire mesh (d) cannot be wound and transported and (A) Due to the weight and volume of a fixed wire (d) there were many problems in terms that are more time and cost of transport can not carry a large quantity in a single vehicle.

In addition, since the wire mesh (d) and the wire mesh (d) must be bundled together using a wire such as a wire, work is complicated and disadvantageous in terms of time and cost,

In particular, the fixing of the stone (a) by using an anchor bolt (b) is a method of directly fixing the stone (a) to the wire mesh (d) because the weight of the stone (a) is the wire mesh (d) There is no power to support the fixing force of the whole stone net except for pressurizing force, so even if the construction is completed, it can be expected to have a solid coupling force or fixing force between the slope and the stone net until long time passes and the stabilization according to the plant's activity is completed. There is no problem.

Therefore, there is an urgent need for a new construction method that can improve the inefficiency of transportation by improving the conventional stone net construction method as described above, and achieve the ultimate purpose of slope protection by exerting a firm fixing force with a simple construction method. It is becoming.

The present invention has been made to solve the above problems,

The object of the present invention is to solidify even in soft ground or steep slopes, high-speed revetment by connecting the support member and the block integrally installed on the ground to secure the fixing force of the block made of natural or artificial stone installed to protect the slope It is to provide a slope protection stone structure and its construction method that can protect the slope by applying a fixed force.

Another object of the present invention to provide a slope protection stone structure and its construction method which can be optimally maintained by maintaining the 'V' shape in the ground to be press-installed in the ground to secure the fixing force of the block will be.

Another object of the present invention is to prevent the play of the support member is completed, as well as to maximize the holding force of the earth is filled with the earth is faithfully filled in the upper portion of the support member in the process of press-installed on the ground support member for securing the fixing force of the block It is to provide a slope protection stone structure and its construction method.

Another object of the present invention is to enable the construction of blocks that can protect the slope without a net, such as a separate net, so that the construction of the slope protection stone structure that can reduce the time and cost required to transport the material and its construction To provide a way.

Still another object of the present invention is to further arrange the slope protection stone structure by additionally arranging a grid formed in the shape of a net under the block installed to protect the slope, as well as to transmit the pressing force by the block evenly across the slope. It is to provide a slope protection stone structure and its construction method.

Still another object of the present invention is to connect the grid and the grid mutual by binding the grid to each other by a binding member formed by a simple structure including a support portion formed parallel to both sides and a head portion bent at the support portion and interconnecting the support portion. It is to provide a slope protection stone structure and its construction method that can quickly and simply construct the binding of the liver.

Still another object of the present invention is to further include a coir mat including a seed layer to which plant seeds are attached, and the slope protection stone structure that can stabilize the slope by inducing rapid plant sliding on the slope protected by the block and its It is to provide a construction method.

Slope protection stone structure and its construction method for achieving the above object of the present invention includes the following configuration.

Slope protection stone structure according to an embodiment of the present invention is a block made of natural or artificial stone; An anchor press-installed on one side of the block; A support member press-fitted into the ground to secure a fixing force; A connection member connecting the support member and the anchor; Including, soft ground or steep slopes, it is characterized by being able to protect the slope by showing a firm holding force even in a high velocity of high velocity.

According to another embodiment of the present invention, the slope protection stone structure according to the present invention further comprises a grid formed in the bottom of the block and formed in the net shape, by integrating the slope protection stone structure as well as by the block It is characterized in that the pressing force can be evenly transmitted throughout the slope.

According to another embodiment of the present invention, the stone structure for protecting the slope according to the present invention further comprises a binding member that can bind the grid and the grid between each other, the binding member and the support is formed parallel to both sides and It is formed by a simple structure including a head portion bent at the support portion and interconnecting the support portion, it is characterized in that the binding between the grid and the grid can be quickly and simply construction.

According to another embodiment of the present invention, the slope protection stone structure according to the present invention is characterized in that it further comprises a coir mat located at the bottom of the grid and including a seed layer to which plant seeds are attached.

According to another embodiment of the present invention, in the stone structure for protecting the slope according to the present invention, the support member includes a folding portion in the center of the support member so that the support member can be folded in the process of press-installed on the ground It is done.

According to another embodiment of the present invention, in the stone structure for protecting the slope according to the present invention, the support member is folded in order to secure the optimal holding force by maintaining the V-shaped support member in the process of being press-installed on the ground It characterized in that it comprises a shape maintaining portion on the left and right sides relative to the portion.

According to another embodiment of the present invention, in the stone structure for protecting the slope according to the present invention, the support member includes a through hole formed through the one surface, the earth and sand through the through hole in the process of press-installed in the ground The earth and sand is faithfully filled in the upper portion of the support member installed by press-fitting into the ground to prevent the play of the support member as well as to maximize the fixing force.

Construction method of the slope protection stone structure according to an embodiment of the present invention comprises a support member installation step of press-installing the support member with the connection member is bonded to the ground using a hammer drill; An anchor installation step of press-fitting an anchor on one side of a block made of natural stone or artificial stone; Connection fixing step for connecting the connection member to the anchor; including, soft ground or steep slopes, even in a fast flow velocity is characterized by being able to protect the slope by a solid holding force.

According to another embodiment of the present invention, the construction method of the slope protection stone structure according to the present invention is a coir mat installation step of additionally installing a coir mat including a seed layer to which the plant seed is attached before the connection fixing step Wow; Installing a grid formed in a mesh shape on top of the coir mat, and using a binding member to install and connect the grid and the grid to each other; In addition, the binding member is formed by a simple structure including a support portion formed in parallel on both sides, and the head portion bent at the support portion interconnecting the support portion, thereby quickly and simply binding between the grid and the grid It can be constructed.

According to another embodiment of the present invention, in the construction method of the slope protection stone structure according to the present invention, the support member includes a folding portion in the center of the support member so that the support member can be folded in the process of press-fitting the ground Characterized in that.

According to another embodiment of the present invention, in the construction method of the slope protection stone structure according to the present invention, the support member can secure the optimal fixing force by maintaining the V-shaped shape in the process of being press-installed on the ground A shape maintaining unit formed on each of the left and right sides of the folding unit so as to be formed; In the process of press-fitting the ground, the earth and sand can be moved through the through hole so that the soil is filled in the upper part of the supporting member press-fitted into the ground to prevent the play of the support member and to penetrate to one side to maximize the fixing force. Through holes are formed; It is characterized in that it further comprises.

The present invention can obtain the following effects by the configuration, combination, and use relationship described above with the present embodiment.

The present invention by connecting the support member and the block is press-installed on the ground integrally to secure the fixing force of the block made of natural stone or artificial stone is installed to protect the slope to provide a solid holding force even in soft ground or steep slopes, fast drafts It provides slope protection stone structure and its construction method that can be used to protect the slope.

The present invention provides a slope protection stone structure and its construction method that can support the optimal holding force by maintaining the 'V' shaped form in the ground press-installed in the ground to secure the fixing force of the block.

The present invention is to prevent the play of the support member is installed is completely filled with earth and sand in the upper portion of the support member in the process of the support member for securing the fixing force of the block press-fitted to the ground, as well as the stone protection structure for slope protection to maximize the fixing force And a construction method thereof.

The present invention provides a surface protection stone structure and a construction method that can reduce the time and cost required to transport the material by enabling the construction of blocks that can protect the slope without a net, such as a separate net body. .

The present invention provides a slope protection stone that is capable of integrating the slope protection stone structure by additionally arranging a grid formed in a mesh shape in the lower portion of the block to be installed to protect the slope, as well as the pressure applied by the block to the entire slope. Provide structure and construction method thereof.

The present invention provides a fast connection between the grid and the grid by binding the grids with each other by a binding member formed by a simple structure including a support part formed parallel to both sides and a head part bent at the support part and interconnecting the support parts. The present invention provides a surface protection stone structure and its construction method which can be easily and simply constructed.

The present invention further comprises a coir mat comprising a seed layer to which the plant seeds are attached to provide a slope-protecting stone structure and a construction method which can stabilize the slope by inducing rapid plant sticking to the slope protected by the block. do.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the stone structure and the construction method for the slope protection according to the present invention will be described in detail.

Figure 3 is a reference diagram showing a cross-section of the state the slope protection stone structure constructed on the slope, according to the present invention, Figure 4 is a partial plan view showing a plane of the state of the slope protection stone structure constructed on the slope, Figure 5 is a reference diagram showing the actual construction of Figure 4, Figure 6 is a perspective view of the stone structure for protecting the slope according to an embodiment of the present invention, Figure 7 is a process of constructing the support member of Figure 6 on the ground 8 is a reference perspective view illustrating a process of constructing a support member on ground according to another embodiment of the present invention, and FIG. 9 is a reference showing a cross section of a state in which the support member of FIG. 8 is constructed on ground. It is also.

3 to 9, the slope protection stone structure according to an embodiment of the present invention is a block 10 made of natural or artificial stone; An anchor 20 which is press-fitted on one side of the block 10; A support member 70 press-fitted into the ground to secure a fixing force; A connection member 60 connecting the support member 70 and the anchor 20; It can be installed in the field without a net such as a separate mesh to improve the inefficiency in material transportation, and it can protect the slope by showing a firm fixing force even on soft ground, steep slopes, and high-speed revetment. It is characterized by being.

The block 10 is installed on the upper portion of the slope to be protected to perform a function to substantially protect the slope, the stone structure for the protection surface according to the present invention can be used as a natural stone or artificial stone as the block 10. . As shown in Figure 6, the block 10 is a natural stone or artificial stone, such as crushed stone, amber stone formed in a circular to rectangular shape as a whole, the size is 250 ~ 800 mm in diameter in consideration of the softness and construction conditions of the slope It is mainly used inside and outside, and can be used by changing the type and color according to the region. In particular, the block 10 may be installed in various modifications, such as processed into a step shape or a shape that can be used as a walkway to suit the purpose and landscape of the slope as needed. One surface of the block 10 may be formed with an anchor insertion groove 110 that can be inserted, fixed anchor 20 to be described in detail below.

The anchor insertion groove 110 is a part formed by being embedded in one surface of the block 10, preferably the block 10 is in contact with the slope, the following anchor 20 to be described later is inserted, fixed To be able to be embedded in a shape corresponding to the shape of the anchor 20 to be formed. Typically, the size of the inner diameter of the anchor insertion groove 110 is preferably formed to be smaller than the outer diameter of the anchor 20 so that the anchor 20 can be fixed by pressing.

The anchor 20 is press-fitted on one side of the block 10, and is fixed to the anchor insertion groove 110 formed on one surface of the block 10. The anchor 20 easily binds the support member 70, which is press-fitted to the ground, and a connecting member 60 connecting the block 10 to the block 10 to provide a fixed force to the block 10. In order to ensure that the connection member 60, which will be described later, is difficult and inefficient to directly bind to the block 10, the anchor 20 is first press-fixed to one surface of the block 10. After the connection member 60 is bound to the anchor 20, the support member 70 and the block 10 can be easily and quickly connected to each other by using the connection member 60. To this end, the anchor 20 may include an anchor body 210 inserted into the anchor insertion groove 110 and a connecting ring 220 to which the connecting member 60 is coupled.

The anchor body 210 is a portion that is inserted and fixed in the anchor insertion groove 110 formed on one surface of the block 10, as described above, the anchor to be press-fitted to the anchor insertion groove 110 It is formed to have an outer diameter larger than the size of the inner diameter of the insertion groove 110, the distal groove is formed at the side end that is inserted into the anchor insertion groove 110 to prevent the separation after being inserted into the anchor insertion groove (110). To be able to double the fixing force, the other end of the connecting ring 220 to be described later may be threaded to be screwed.

The connecting ring 220 is connected to one end of the anchor body 210 is a portion to which the connecting member 60 is bound, but does not limit its position or shape as long as the connecting member 60 can be bound, Preferably, as shown in Figure 6 and the like is preferably formed in an annular shape so that the connection member 60 can be engaged while screwing to one end protruding from the anchor insertion groove 110 of the anchor body 210. . In such a case, since the connecting ring 220 is screwed to one end of the anchor body 210 and then the upper and lower positions can be adjusted after binding the connecting member 60 in a ring shape, the block 10 and The connection member 60 interconnecting the support member 70 can be kept taut without being loose, so that the fixing force of the support member 70 can be effectively transmitted to the block 10, as well as the connection member 60. ) To bind to the connecting ring 220 can be more easily carried out.

The connection member 60 is a configuration for connecting the support member 70 and the anchor 20 to be described later, the block through the anchor 20 to the fixing force of the support member 70 is pressed into the ground fixed (10) to perform the function. To this end, the connection member 60 may be used a wire or iron wire used in the anchoring method, it is not limited to the material as long as it has a durability that can efficiently transfer the fixing force of the support member (70). As shown in FIG. 6, the connection member 60 extends upward through the support member 70 embedded in the ground, and is press-fitted and fixed to the block 10 positioned on the upper surface of the anchor 20. Specifically, the coupling ring 220 is bound.

The support member 70 is configured to be press-fitted into the ground to secure the fixing force of the stone protection stone structure is installed on the upper surface to protect the slope, the support member 70 is a ground (㉡) It can be formed into various shapes as long as it can be press-installed to exert a fixing force, and in particular, as illustrated in the embodiment in FIG. It is preferable to be formed in a shape that is deformed into a 'V' shape, but it will be revealed that any modification is possible as long as it is deformed into a 'V' shape to increase the fixing force in the process of being press-fitted into the ground. When the support member 70 is formed in a plate shape having a predetermined size as shown in FIG. 6 and the like, a folding portion is formed at the central portion so that the support member 70 can be accurately folded in the process of being press-fitted into the ground. 710 may be formed, and the folding member 710 may be formed so that the support member 70 maintains a 'V' shape in order to secure an optimal fixing force in the process of being press-fitted into the ground. As a reference, it may include a shape maintaining part 720 formed on each of the left and right sides, and a through hole 730 formed through the surface so that the earth and sand move in the process of being pressed into the ground.

The folding portion 710 is formed in the central portion of the support member 70 so that the support member 70 can be folded in a precise 'V' shape or the like during the press-installed on the ground (㉡) to be. The folding portion 710 is formed as a cutting groove as shown in Figure 6 and the like can be induced to be accurately folded along the cutting groove in the process of press-installed in the ground (㉡), another example is the support member ( Various modifications may be utilized, such as may be formed by installing a hinge at the center of the 70). When the foldable part 710 is formed in the center portion of the support member 70 in a predetermined direction or is formed as a cut groove or the like partially cut, the support using a hammer drill 80 or the like as illustrated in FIG. 7. When press-fitting the member 70 to the ground, the hammer drill 80 press-fits the press-formed portion where the folding part 710 is formed, thereby supporting the support member 70 based on the folding part 710. Can be easily folded.

The shape maintaining part 720 is configured to maintain the 'V' shape without being excessively folded in the support member 70 in the process that the support member 70 is press-installed in the ground (㉡). . As described above, when the support member 70 is press-fitted into the ground while pressing the folding portion 710 using the hammer drill 80, the support member 70 is once When the left and right sides start to be folded based on the folding part 710, the hammer drill 80 is pressed by the force and the soil is pushed up by the force of the hammer drill 80 in the process of being continuously pressed into the ground. The member 70 is excessively folded to be fully folded in extreme cases, in which case the support member 70 may not be able to exert the desired fixing force. Accordingly, the shape maintaining part 720 is formed to solve the above problems, and the shape maintaining part 720 is formed on the left and right sides of the folding part 710 as illustrated in FIG. 8. A member of a shape (more preferably, a triangular shape) may be formed to face each other. In this case, the support member 70 is pressed against the hammer drill 80 as shown in FIG. 9. When folded about the folding portion 710 in the process of being pressed into the ground by the shape, the shape maintaining portion 720 formed to face each other on the left and right sides with respect to the folding portion 710 is in contact with each other In addition, the shape maintaining portion 720 in contact with each other afterwards exerts an opposing force against the force that the support member 70 is to be continuously folded to prevent the support member 70 from being folded anymore. The support member It is possible to maintain the 'V' shape of the 70 so that the maximum holding force can be exerted. For reference, the shape of the shape maintaining part 720 shown in FIGS. 8 and 9 is only one embodiment, and the shape maintaining part 720 is not particularly limited as long as the shape maintaining part 720 exhibits the above functions.

The through hole 730 is configured to allow the earth and sand to move to the upper portion of the support member 70 in the process of the support member 70 is pressed into the ground, the one surface of the support member 70 It can be formed through. As described above, the role of the support member 70 in the present invention is to provide a fixing force for the slope protection stone structure for protecting the slope to be firmly and stably fixed, the support member 70 In addition to maintaining the 'V' shape in order to exhibit a firm fixing force, the earth and sand must be faithfully filled in the upper portion of the support member 70, there is no play in the upper portion of the support member 70, the support member 70 is upward Since the fixing force is firmly fixed without migrating into the ground, the earth and sand must be faithfully filled in the upper portion of the supporting member 70 in the process of being pressed into the ground. Accordingly, the through hole 730 is formed through one surface of the support member 70 (preferably left and right sides of the folding portion 710, respectively), thereby supporting the support member as shown in FIG. In the process in which 70 is pressed into the ground in the ① direction, the earth and sand in the ground move in the A and B directions through the through holes 730 so that the upper portion of the support member 70 can be faithfully filled. Therefore, there is no play in the upper portion of the support member 70, the press-fit fixed is completed, the support member 70 can be firmly fixed in the ground (㉡).

Slope protection stone structure according to an embodiment of the present invention is connected to the support member and the block integrally installed on the ground in order to secure the high force of the block even in soft ground or steep slopes, high speed revetment Not only can protect the slope by showing the firm fixing force, but also the support member installed by press-fitting on the ground can maintain the 'V' shape in the ground to show the optimal holding force, and the support member in the process of press-installing on the ground Tossa faithfully filled in the upper portion of the can be maximized the fixing force of the completed supporting member. In addition, unlike conventional stone nets, it is possible to construct a slope without the need for a separate net such as a net, thereby reducing the hassle of transporting a fixed net of stone to the construction site. Can be reduced.

FIG. 10 is an exploded perspective view illustrating a coupling relationship between a grid and a binding member used in a slope protection stone structure according to another embodiment of the present invention. FIG. 11 is a perspective view illustrating a state of a grid in which a binding is completed using a binding member. 12 is a cross-sectional view of the grid where the binding is completed using the binding member.

3 to 5 and 10 to 12, the slope protection stone structure according to another embodiment of the present invention is disposed in the bottom of the block 10 and the grid 30 is formed in a mesh shape, the grid 30 By further including a coir mat 50 including a seed layer 510 attached to the plant seeds 520 attached to the bottom of the), as well as integrating the slope protection stone structure as well as the total pressure applied by the block It can be delivered evenly and characterized by inducing slope stabilization by the adhesion of plants.

The grid 30 is a mesh of a mesh shape having a predetermined area is usually used, such as a wire mesh, it is possible to cover the entire slope to be protected by continuing to connect the grid 30 to the construction. Therefore, if the block 10 is placed on the grid 30 after covering the entire slope to be connected by connecting a plurality of the grid 30, the pressing force by the block 10 causes the grid 30 to be removed. Through this, the pressing force can be evenly transmitted throughout the slope. In the present invention, the block 10 is securely fixed by receiving a fixed force by the support member 70 as described above, the grid 30 is the bottom of the block 10 of the block 10 itself Since it is naturally pressurized and fixed by the weight and the pressing force, it is possible to reduce the hassle of separately binding the block 10 and the grid 30, unlike the conventional case.

In the present invention, a unique binding member 40 is used to bind the grid 30 and the grid 30 to each other. The binding member 40 includes a support part 410 formed to be parallel to both sides. By being formed by a simple structure including a head portion 420 interconnecting the support portion 410 while being bent at the support portion 410, the binding between the grid 30 and the grid 30 quickly and simply construction It can be characterized by. Conventionally, in tying a mesh similar to the grid 30, a method of tying a plurality of points together using a wire or the like has been used. In the case of the conventional method, a lot of time and manpower are required due to the complicated work. Of course, there was a problem that the durability of the wire, such as used in the binding is poor, the present invention uses the binding member 40 as described above to solve this problem.

The support part 410 is two rod-shaped portions arranged in parallel and spaced apart at regular intervals as shown in FIG. 10, and the grid member 40 is used to bind the grid 30 to each other. 30) the insertion portion is started, and after the binding is completed, as shown in FIG. 12, the lower portion of the grid 30 is positioned so that the support member 70 is separated upward by an external force or the like. It will perform a function that prevents it.

As shown in FIG. 10, the head part 420 is bent from the support part 410 spaced apart from each other at a predetermined interval and connected to the support part 410, and the support part 410 is connected to each other. When the binding member 70 is rotated 90 degrees after being inserted into the grid 30 by a predetermined depth, as shown in FIGS. 11 and 12, only the head part 420 is positioned above the grid 30. The grid 30 performs the function of maintaining the binding between each other.

When the binding member 40 formed as described above is used to bind the grids 30 to each other, the troublesome work of tying the grids 30 together using conventional wires is eliminated, and the binding member By inserting and rotating the 40, the grid 30 can be quickly and simply bound to each other, resulting in cost and time savings.

The coir mat 50 is positioned below the grid 30 and has a vegetation mat structure including a seed layer 510 to which plant seeds 520 are attached. As shown in FIG. It is located in the lower portion of the 30 is in close contact with the slope (㉡). The coir mat 50 is made of coconut fiber such as coconut shell, and the seed layer 510 to which the plant seed 520 is attached may be formed in the middle. In this case, the coir mat serves as a vegetation base material to allow the plant seed 520 to germinate well.

Since the coir mat 50 is uniformly transmitted to the entire slope by receiving the force pushed by the block 10 from the lower portion of the grid 30 through the grid 30, the When the plant seed 520 of the seed layer 510 germinates, the palm fiber of the coir mat 50 is effectively planted on a slope so that the slope is recorded by quickly recording the entire slope. It can be stabilized more. For reference, after the construction of the slope protection stone structure according to the present invention is completed, in order to induce the smooth germination and lubrication of the plant seed 520 may further proceed to fill the soil between and the top of the block (10). have.

Hereinafter, with reference to the drawings with respect to the construction method of the slope protection stone structure according to the present invention to be described in detail. Figure 13 is a block diagram showing a construction method of the slope protection stone structure according to the present invention.

3 to 13, the construction method of the slope protection stone structure according to an embodiment of the present invention is to press-install the support member 70, the coupling member 60 is bonded to the ground using a hammer drill (80) Support member installation step (S1); An anchor installation step (S3) of press-fitting the anchor 20 to one side of the block 10 made of natural stone or artificial stone; Coir mat installation step of additionally installing a coir mat 50 including a seed layer 510 to which the plant seed 520 is attached before connecting the connecting member 60 to the anchor 20 ( S5); Grid installation and connection step of installing the grid 30 formed in the mesh shape on the top of the coir mat 50, using the binding member 40 to bind the grid 30 and the grid 30 mutually (S7); Connection fixing step (S9) for connecting the connecting member 60 to the anchor (20); including, soft ground or steep slopes, even in the fast flow velocity fast solid holding force is characterized by protecting the slope It is done.

Looking in detail with respect to the support member installation step (S1), as shown in FIG. 8, after connecting the connecting member 60 to the support member 70, the hammer drill (80) having a predetermined width While pressing the folded portion 710 of the support member 70 is pressed into the ground (㉡). When the press-fitting starts, the support member 70 is continuously pressed into the ground while the left and right are folded around the folding portion 710, in this case the support member 70 as shown in FIG. ) Until the shape retaining portion 720 is in contact with each other, and then the shape retaining portion 720 is in contact with each other, so that the shape retaining portion 720 is not folded any more and is continuously pressed into the ground while maintaining the 'V' shape. At this time, the earth and sand in the ground (지지) through the through hole 730 of the support member 70 is moved in the A, B direction so that the earth and sand is faithfully filled in the upper portion of the support member (70). In this manner, when the support member 70 is press-fitted to the ground (㉡) is completed, the support member 70 is able to exert a firm fixing force.

The anchor installation step (S3), as shown in Figure 6, first to form an anchor insertion groove 110 into which the anchor 20 can be inserted into one surface of the block 10, and then the anchor insertion The anchor body 210 of the anchor 20 is press-fitted into the groove 110. The anchor installation step (S3) by screwing the connecting ring 220 to the anchor body 210 using a thread profile formed at one end of the anchor body 210 after the anchor body 210 is press-fit and fixed Will complete.

The coir mat installation step (S5) comprises a coir mat 50 including a seed layer 510 to which a plant seed 520 is attached prior to connecting the connecting member 60 to the anchor 20. It is completed by unfolding to cover the entire upper part of the slope. Since the coir mat 50 may be evenly pressed by the grid 30 positioned on the upper portion thereof, the coir mat 50 does not need to be separately connected to each other.

The grid installation and connection step (S7) is installed a plurality of grid 30 formed in the mesh shape on the top of the coir mat 50, using the binding member 40 the grid 30 and grid 30 Binding to each other, the grid 30 and the grid 30 disposed by using the binding member 40 after the plurality of grids 30 are arranged on the coir mat 50 above Will be overlapped to some extent.

The method of binding the grid 30 and the grid 30 to each other by using the binding member 40 is as shown in FIGS. 10 to 12. First, the support 410 of the binding member 40 is fixed. In the simple manner of rotating the binding member 40 by 90 ° at the time when the head portion 420 of the binding member 40 comes into contact with the grid 30 after being inserted through the partially overlapped grid 30. In this way, the support portion 410 is in close contact with the lower surface of the grid 30, the head portion 420 is in close contact with the upper surface of the grid 30, even if an external force is applied to the grid without loosening the grid (30) It will be possible to firmly connect with each other.

The connection fixing step (S9) is to connect the connecting member 60 to the anchor 20, one end of the connecting member 60 is connected to the support member 70 is press-fit fixed to the ground (㉡) The other end of the) is made in such a way to connect to the connecting ring 220 of the anchor 20, which is press-fit fixed to the block (10). When connecting the other end of the connecting member 60 to the connecting ring 220, the connecting member 60 should be connected as tight as possible so as not to loosen, and after the connection is completed, the connecting ring 220 is finally connected. It is to be screwed to the anchor body 210 to move upward to connect the support member 70 and the block 10 in the state that the connection member 60 is kept as tight as possible.

When the construction of the slope protection stone structure according to the present invention by the construction method described above is completed on the slope, and additionally between the block 10 and the top may be carried out to fill the soil, which is the coer mat This is to induce rapid germination and rooting of the plant seed 520 in the 50.

In the above, the Applicant has described preferred embodiments of the present invention, but these embodiments are merely one embodiment for implementing the technical idea of the present invention, and any changes or modifications may be made as long as the technical idea of the present invention is implemented. Should be interpreted as being within the scope.

1 is a reference diagram showing a cross section of a state in which the conventional stone net is installed on the slope

2 is a reference diagram showing a state in which the stone is generally fixed to the wire mesh

Figure 3 is a reference diagram showing a cross-section of the stone structure for the slope protection according to the present invention constructed on the slope

4 is a partial plan view showing a plane in a state in which the stone structure for protecting the slope according to the invention constructed on the slope

5 is a reference diagram showing the actual construction drawing of FIG.

Figure 6 is a perspective view of the slope protection stone structure according to an embodiment of the present invention

7 is a reference picture showing a process of constructing the support member of Figure 6 on the ground

8 is a reference perspective view showing a process of constructing a support member on ground according to another embodiment of the present invention;

9 is a reference view showing a cross section of the support member of FIG.

10 is an exploded perspective view showing the coupling relationship between the grid and the binding member used in the slope protection stone structure of another embodiment of the present invention

11 is a perspective view showing a state of the grid where the binding is completed using the binding member.

12 is a cross-sectional view of the grid in which the binding is completed using the binding member.

Figure 13 is a block diagram showing the construction method of the slope protection stone structure according to the present invention

* Explanation of the main symbols used in the drawings

10: block 110: anchor insertion groove

20: anchor 210: anchor body 220: link

30 grid 40 binding member 410 support portion 420 head portion

50: coir mat 510: seed layer 520: seed

60: connecting member

70: support member 710: folding portion 720: shape holding portion 730: through hole

80: hammer drill

Claims (11)

A block made of natural or artificial stone; An anchor press-installed on one side of the block; A support member press-fitted into the ground to secure a fixing force; A connection member connecting the support member and the anchor; Include, The support member is a folding portion formed in the center of the support member so that the support member can be folded in the process of press-fitting the ground, and the support member in the process of press-fitting the ground to maintain the V-shaped shape to secure the optimal holding force Including a shape maintaining portion formed on each of the left and right sides on the basis of the folding portion, Slope protection stone structure, characterized by the ability to protect the slope by showing a firm holding force even in soft ground, steep slopes, high-speed lakes. The method of claim 1, wherein the slope protection stone structure Slope protection stone structure, characterized in that it further comprises a grid formed in the net shape formed in the lower portion of the block, to integrate the slope protection stone structure as well as to transmit the pressing force by the block throughout the slope. The method of claim 2, The slope protection stone structure further includes a binding member that can bind the grid and the grid mutually, The binding member is formed by a simple structure including a support portion formed parallel to both sides and a head portion bent at the support portion and interconnecting the support portion, so that the binding between the grid and the grid can be quickly and simply constructed. Slope protection stone structure characterized in that. According to claim 3, wherein the slope protection stone structure Slope protection stone structure characterized in that it further comprises a coir mat located at the bottom of the grid and comprising a seed layer to which plant seeds are attached. delete delete The method of claim 1, wherein the support member By including a through hole formed through one surface, so that the earth and sand through the through hole in the process of press-installed in the ground so that the earth is faithfully filled in the upper portion of the support member press-installed in the ground to the play of the support member Slope protection stone structure, characterized in that to maximize the fixing force as well as preventing. A support member installation step of press-fitting and installing the support member on which the connection member is bound to the ground using a hammer drill; An anchor installation step of press-fitting an anchor on one side of a block made of natural stone or artificial stone; And a connection fixing step of connecting the connection member to the anchor. The support member has a folding portion formed in the center of the support member so that the support member can be folded in the process of press-fitting the ground, and the support member in the process of press-installing the ground to maintain the V-shaped shape for optimal holding force The shape retaining portion is formed on the left and right sides based on the folding portion to ensure the sediment, and the earth and sand are faithfully filled in the upper portion of the support member press-fitted into the ground to allow the earth and sand to move through the through-hole in the process of press-fitting the ground Including a through hole formed through the one surface to prevent the play of the support member as well as to maximize the fixing force, Slope protection stone structure construction method characterized in that it can protect the slope by showing a firm holding force even in soft ground, steep slopes, high-speed lakes. The method of claim 8, wherein the construction method of the stone structure for protecting the slope A coir mat installation step of additionally installing a coir mat including a seed layer to which plant seeds are attached before the connection fixing step; Installing a grid formed in a mesh shape on top of the coir mat, and using a binding member to install and connect the grid and the grid to each other; Additionally, The binding member is formed by a simple structure including a support portion formed parallel to both sides and a head portion bent at the support portion and interconnecting the support portion, so that the binding between the grid and the grid can be quickly and simply constructed. Slope protection stone structure construction method characterized in that. delete delete

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