KR100981434B1 - Eco-friendly reinforcing material for greening slope and method for greening slope using this - Google Patents

Abstract

PURPOSE: An environment-friendly vegetative slope reinforcing member and a vegetating method for a slope using the same are provided to evenly plant on a slope by installing a vegetative frame according to the quality of soil on the slope. CONSTITUTION: An environment-friendly vegetative slope reinforcing member comprises a water pressure plate(10) and a vegetative frame(20). A water pressure plate is formed on a slope and supports an anchor(2). The water pressure plate comprises a precast block(11), a sleeve(13) for a slope and an anchor plate(12). The vegetative frame is combined on the circumference of the water pressure plate for the vegetation of slope.

Description

ECO-FRIENDLY REINFORCING MATERIAL FOR GREENING SLOPE AND METHOD FOR GREENING SLOPE USING THIS}

The present invention relates to an eco-friendly slope greening reinforcement and a slope greening method using the same, and more specifically, to manufacture a hydraulic plate to the optimum cross-sectional standard by the structural analysis by the design tensile load, and can be attached to the green soil in conjunction with the hydraulic plate The present invention relates to an environment-friendly slope greening reinforcement that can record a slope by installing a rusted frame, and a slope greening method using the same.

In general, the hydraulic plate is used for the purpose of dispersing and transmitting the tensile force of the anchor on the slope, and thus the reaction force of the anchor tension member should be transmitted equally to the ground, and refers to a block-type structure made of reinforced concrete as the main material.

Here, the anchor method is introduced as an alternative method for the support of earth walls, and is mainly applied to the unsupported opening method. Recently, the anchor method is used for earth walls, surface protection, steep slope collapse prevention, ground accident prevention, underground structure injury prevention, and other construction. .

And, the hydraulic plate used for the incision site, the slope is mainly used on-site reinforced concrete hydraulic plate.

However, in-site reinforced concrete hydraulic plate is the most commonly used hydraulic plate is easy to manufacture and inexpensive advantages, but the strength of the reinforced concrete is limited in order to support the required anchor bearing pressure, the thickness and area of the member There was a growing problem.

Due to this, the weight of the hydraulic plate is increased, the size of the equipment used for the lifting construction is required in the field, the installation cost is excessive in the field, and the quality of the aggregate used in the concrete is gradually deteriorating, so that durability as a permanent structure is increased. There was a problem of deterioration.

In addition, it is difficult to maintain a constant thickness at the time of installation of green soil, and thus it is impossible to obtain a homogeneous quality of construction.

In addition, even ground reaction force cannot be expected due to the occurrence of a gap between the hydraulic plate and the slope.

The present invention is to solve the problems as described above, the hydraulic plate is manufactured by precast reinforced concrete at the factory with the optimal cross-sectional specifications by the structural analysis by design tension load, and can be attached to the rust soil in conjunction with the hydraulic plate The purpose of the present invention is to provide an eco-friendly slope greening reinforcement that can record slopes with a uniform thickness according to the soil quality (rock quality) and a slope greening method using the same.

Another object of the present invention is to ensure an even ground reaction force by preventing a gap between the hydraulic plate and the slope.

Eco-friendly slope greening reinforcement according to the present invention for achieving the above object, the precast block is formed in the form of a staircase in which the cross-sectional area is increased toward the lower side according to the pressure distribution and the anchor insertion hole therein, the precast Acupressure plate, which is pre-installed at the upper inlet side of the anchor insertion hole of the block, is inserted into the anchor insertion hole of the precast block so that the lower portion protrudes out of the precast block, and is inserted into the anchor hole formed on the slope to insert the precast block. A hydraulic plate comprising a sleeve for supporting the slope to support the slope; The roots of the greening seeds or trees are formed in the sliding net in the frame-shaped frame so as to slide on the slope, characterized in that it comprises a rusted frame coupled to the periphery of the hydraulic plate.

Environmentally friendly slope greening reinforcement according to the present invention, the pressure plate is installed on the slope, the step of tensioning the anchor hole into the anchor hole of the slope; Installing a rusted frame provided with a sliding network on the periphery of the hydraulic plate; It characterized in that it comprises the step of attaching the rust soil to the slid network of the rust texture.

According to the eco-friendly slope greening reinforcement according to the present invention and the slope greening method using the same, the hydraulic plate is manufactured by high strength precast with the optimal cross-sectional specification by the structural analysis for each design tensile load. Can be saved.

In addition, even when a gap is generated between the hydraulic plate and the slope according to the conditions of the slope, the hydraulic plate is firmly adhered to the slope by grouting between the hydraulic plate and the slope so that the tension of the anchor can be effectively transmitted to the slope.

In addition, when the sleeve for the slope mounting formed on the hydraulic plate is inserted into the anchor hole, the hydraulic plate does not slip on the slope and can maintain the state at the time of construction (before being fixed by the tension force of the anchor) so that the crane can be efficiently used. Can shorten.

In addition, by connecting the rust frame to the circumference of the hydraulic plate to record the circumference of the hydraulic plate, the slope of the slope is easy to record, and by mounting the rust soil according to the thickness of the rust frame for each soil of the slope, the slope is taped to a uniform thickness. It can prevent the loss of green soil.

1 is an exploded perspective view of an environment-friendly slope greening reinforcement according to the present invention.
Figure 2 is a cross-sectional view of the hydraulic plate applied to the eco-friendly slope greening reinforcement according to the present invention.
Figure 3 is a side view of the installation state of the environment-friendly slope greening reinforcement according to the present invention.
Figure 4 is another exemplary view of the sleeve for the slope applied to the environment-friendly slope greening reinforcement according to the present invention.
Figure 5 is another illustration of the rusted frame applied to the eco-friendly slope greening reinforcement according to the present invention.
6a to 6d is a slope greening process using the eco-friendly slope greening reinforcement according to the present invention.

As shown in FIGS. 1, 3, 6a, and 6b, the eco-friendly slope greening reinforcement according to the present invention is mounted on the slope 1 and supports the hydraulic plate 10 and the hydraulic plate 10 supporting the anchor 2. It is coupled to the periphery of the) and consists of a green frame 20 for the greening of the slope 1, each component will be described in detail below.

As shown in FIG. 1 and FIG. 2, the hydraulic plate 10 includes a precast block 11, a pressure plate 12, and a sleeve 13 for slope mounting.

The precast block 11 is made of concrete in the factory and then transported to the construction site. The precast block 11 has a cross-sectional area toward the bottom of the precast block 11 based on the installation state in accordance with the distribution of acupressure stress applied to the precast block 11. It may be in the form of being enlarged, eg, in the form of stairs or in the form of a taper, as in the figure.

The precast block 11 is formed with an anchor insertion hole (11a).

The pressure plate 12 is installed at the inlet of the anchor insertion hole 11a of the precast block 11 to support the anchor 2, and may be fixed to the precast block 11 through fasteners, or precast. When the concrete 11 of the block 11 is embedded in concrete may be fixed.

The precast block 11 is supported on the slope 1 by the force applied to the pressure plate 12 through the anchor 2, and the precast block 11 is suspended by a crane or the like until the anchor 2 is installed. Even if the precast block 11 is not separated from the slope 1, the sleeve 13 is applied.

The sloped sleeve 13 is in the form of a pipe through which the anchor 2 can pass, and the anchor insertion hole 11a of the precast block 11 to be fitted into the anchor hole 3 of the slope 1. It is inserted and fixed inside.

Slope mounting sleeve 13 may be installed in all the portions of the anchor insertion hole (11a) can serve to prevent the collapse of the anchor insertion hole (11a).

The sloped sleeve 13 must functionally protrude to the bottom of the precast block 11, and a portion of the sloped sleeve 13 protrudes below the precast block 11 so that the When stacking for storage and transport, there is inconvenience in that the sleeve 13 for stacking should be laminated with the protruding bottom upward, and to solve this problem, as shown in FIG. 11 is inserted into the anchor hole 3 of the slope 1 while being fastened to the fixing part 13a, the fixing part 13a fixed to the inside of the fixing part 13a, and protruding to the outside of the precast block 11. It can be separated into (13b).

The slope 1 is flattened in advance for reinforcement and greening of the slope 1, but a gap is generated between the bottom of the precast block 11 and the slope 1. The gap prevents the precast block 11 from being firmly supported on the slope 1, so that, for example, the ground force is concentrated only on a part of the precast block due to the pressure applied to the anchor 2, so that the hydraulic plate is broken. Can not maintain the correct anchor installation angle.

The present invention allows grouting between the bottom of the precast block 11 and the slope 1 so that the precast block 11 is in close contact with the slope 1 regardless of the exposed surface state of the slope 1. It is composed together.

The precast block 11 is provided with one or more grouting holes 14.

The grouting hole 14 is a flow path in which two places are opened for the injection and discharge of the grout material.

The hydraulic plate 10 is mounted on the slope 1 using equipment such as a crane, and is provided with a lifting hole 15 to which the equipment is connected.

The lifting hole 15 penetrates the precast block 11 in the lateral direction so that the lifting ring or the wire is connected to both sides.

The lifting hole 15 may communicate with the grouting hole 14 as shown in the drawing, and at this time, openings on both sides of the lifting hole 15 so that the grout material introduced into the grouting hole 14 does not leak through the lifting hole 15. There is a blocking cap (15a) is coupled.

As shown in FIG. 1, the rust frame 20 is provided with a sliding network 21 to allow roots to slide and is coupled to a circumference of the hydraulic plate 10 to couple a block to record a slope 1. The part 22 is formed.

Rust frame 20 may have a structure in which the sliding network 21 is coupled to the frame (23). The frame 23 may allow the inner frame 23a and the outer frame 23b to be connected through the connection 23c to couple the sliding network 21 between the inner frame and the outer frame.

1 shows that the rusted frame 20 is in the form of a rectangular frame surrounding the hydraulic plate 10, as shown in Figure 5, a plurality of units surrounding the hydraulic plate 10 of the rectangular frame as shown in FIG. It may also form. In FIG. 5, four unit frames are illustrated, but two or more unit frames may be provided.

In the case of the rusted frame 20 composed of four unit frames, since the two unit frames are placed on the hydraulic plate 10, the two unit frames do not flow down the slope of the slope 1, but the two unit frames are disposed below the hydraulic plate 10. The unit frame can flow down the slope of the slope 1 (of course, if all the rust frame 20 is installed to support each other does not flow), and a plurality of unit frame under the hydraulic plate 10 does not flow down The unit frame can be connected to each other via a wire or the like.

Rust frame 20 is composed of two or four unit frame, it can be installed by changing the direction of one unit frame is easy to manufacture, store and transport.

Rust frame 20 is made of a synthetic resin and the like to reduce the weight and workability.

The frame 23 forms a mounting space of the rusted soil 30, and the thickness of the rusted soil 30 may be varied according to the rock quality (soil) of the slope 1 to enable firm and constant mounting thickness construction of the rusted soil 30.

Hereinafter, a slope greening process using an environment-friendly slope greening reinforcement according to the present invention will be described with reference to FIGS. 6A to 6.

(S10) slope excavation.

As shown in Figure 6a, for the reinforcement and greening of the slope, the yarn surface is first excavated in accordance with the slope plan to form the slope (1). The slope 1 may be formed in a step shape as shown in FIG. 6B, and for example, slope clearance and anchors may be installed while descending from the top to the bottom in a top-down manner.

(S20) Hydraulic plate installation and anchor installation.

As shown in FIG. 6B, a plurality of anchor holes 3 are drilled on the slope 1 along the longitudinal direction, and the hydraulic plate 10 is provided in the anchor holes 3.

Hydraulic plate 10 is provided with a sleeve for the slope mounting 13, the lifting ring of the crane is connected to the lifting hole 15, and then the hydraulic plate 10 is lifted to the slope (1), the sleeve for slope mounting (13) is fitted to the anchor hole (3).

When the sleeve 13 is configured to be separated into the fixing part (13a) and the inserting portion (13b) is connected to the inserting portion (13b) on the ground and then installed by lifting the hydraulic plate (10).

When only one grouting hole 14 is configured when the hydraulic plate 10 is installed, the grouting hole 14 is disposed at an upper portion thereof.

When the mounting of the hydraulic plate 10 is completed, the grouting hose is connected to the grouting hole 14 and the grout material is injected. The grout material may be shotcrete and is filled in the gap between the bottom face and the slope 1 of the hydraulic plate 10 through the grouting hole 14. That is, since there is no gap between the bottom of the hydraulic plate 10 and the slope 1, the hydraulic plate 10 can be firmly installed on the slope 1, so that the pressure can be transmitted to the ground evenly and anchor installation It can keep the angle accurately.

The anchor 2 is inserted into the anchor hole 3 before or after installation of the hydraulic plate 10, and when the installation of the anchor 2 is completed, the anchor 2 is tensioned to reinforce the slope 1.

Since the installation process and the tension process of the anchor 2 are the same as before, a detailed description thereof will be omitted.

(S30) Rust frame installation.

As shown in FIG. 6C, the green frame 20 is installed at the circumference of the hydraulic plate 10.

In the case where the rusted frame 20 has a rectangular frame shape, the block coupling part 22 of the rusted frame 20 is fitted to fit the hydraulic plate 10, and the rusted frame 20 is composed of a plurality of unit frames. The mold is installed by fitting each other to the circumference of the hydraulic plate 10.

(S40) Installation of green soil.

The green soil 30 is mounted on the sliding network 21 of the green framework 20 (green soil spray, green mat mat seating, etc.).

By mounting the rust soil 30 in accordance with the thickness of the rust mold 20, all the rust soil 30 can be mounted at the same height.

1: slope, 2: anchor
3: anchor hole, 10: hydraulic plate
11: precast block, 12: pressure plate
13: Slope Mount Sleeve, 14: Grouting Hole
15: salvage hall, 20: green frame
21: active network, 22: block coupling portion
23: frame, 30: green soil

Claims (7)

A precast block 11 is formed in the form of a staircase or taper having a larger cross-sectional area toward the lower portion and has an anchor insertion hole 11a formed therein, and an acupressure plate 12 installed at an upper inlet side of the anchor insertion hole of the precast block. For slope mounting, the lower end portion is inserted into the anchor insertion hole of the precast block so as to protrude out of the precast block and inserted into the anchor hole 3 formed in the slope 1 to support the precast block on the slope. Hydraulic plate 10 consisting of a sleeve (13);
Roots of the green seed or tree is formed in the sliding net 21 in the frame-shaped frame 23 so as to slide on the slope, and the rusted frame 20 is coupled to the periphery of the pressure plate; Eco-friendly sloped greening reinforcement.
The method according to claim 1,
And a grouting hole (14) penetrating up and down the precast block to guide grouting between the bottom and the slope of the precast block. The eco-friendly slope greening reinforcement according to claim 1 or 2, characterized in that an inlet hole (15) is provided for the lifting of the hydraulic plate. The method according to claim 3,
The green frame, eco-friendly slope greening reinforcement, characterized in that the two or more unit frame is formed by being coupled to the periphery of the hydraulic plate. The method of claim 4, wherein the sleeve for mounting the slope is fixed to the anchor insertion hole of the precast block (13a) so as not to protrude to the outside of the precast block, the fixing portion to the outside of the precast block Eco-friendly slope greening reinforcement, characterized in that configured to be separated so as to protrude into the insertion portion (13b) inserted into the anchor hole of the slope. Drilling a plurality of anchor holes in the longitudinal direction on the slopes arranged in the yarn surface to insert the anchor into the interior of the anchor hole, the cross-sectional area is formed in the form of a step toward the bottom of the inlet of the anchor hole toward the bottom and the anchor inside A precast block 11 having an insertion hole 11a formed thereon, a pressure plate 12 provided at an upper inlet side of the anchor insertion hole of the precast block, and an anchor of the precast block such that a lower end thereof protrudes out of the precast block. Inserted into the insertion hole and inserted into the anchor hole (3) formed in the slope 1 to install a hydraulic plate (10) consisting of a sleeve 13 for the slope mounting to support the precast block on the slope, the anchor Inserting an anchor into the ball to tension the first step;
The first step of forming the rusted frame 20 is formed in the sliding network 21 in the frame 23 of the frame shape so that the roots of the green seed or tree to slide on the slope, and is coupled to the periphery of the hydraulic plate A second step of installing at the circumference of the hydraulic plate installed in the;
Slope greening method using the eco-friendly sloped greening reinforcement, characterized in that it comprises a third step of attaching the rusted soil 30 to the sliding net of the rusted frame installed in the second step. The slope according to claim 6, wherein, in the second step, the green frame is composed of a plurality of unit frames each having a sliding net, and the unit frame is installed at the periphery of the hydraulic plate. Greening technique.

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