KR101081564B1 - Using flexible pipes leaking vertical green terraced retaining wall - Google Patents

Abstract

PURPOSE: A vertical drain type environmentally-friendly stepwise retaining wall is provided to ensure easy construction on a cut slope because concrete is placed through flexible pipes and surface water discharge pipes after arrangement of reinforcing bars. CONSTITUTION: A vertical drain type environmentally-friendly stepwise retaining wall(100) comprises a surface water discharge pipe(130), a flexible pipe(140), and a filter(150). The surface water discharge pipe is inserted in the bottom side of a vegetation part(120) of a retaining wall unit(110), and the surface water discharge pipe comprises a guide pipe(132) for inflow of surface water from the bottom of the vegetation part and a branch pipe(134) branched from the bottom of the guide pipe. The flexible pipe connects surface water discharge pipes installed in the retaining wall part. The filter is installed in the upper part of the guide pipe of the surface water discharge pipe in order to prevent the infiltration of soil or other foreign materials filled in the vegetation part.

Description

Using Flexible Pipes Leaking vertical green terraced retaining wall}

The present invention relates to a vertical drainage type eco-friendly stepped retaining wall using a flexible pipe, and more particularly, in the state of connecting a flexible pipe and an induction pipe that function as drainage of infiltration water or surface water after reinforcement of reinforcing bars on the clearance surface of a cut slope. The present invention relates to a vertical drainage type eco-friendly stepped retaining wall using a flexible pipe that allows construction of a stepped retaining wall by pouring concrete after a formwork.

In general, more than 70% of the country's land is mountainous, so cut slopes due to road construction are inevitable. In addition, the construction of roads is rapidly increasing due to recent industrial developments and investment in national infrastructure, and the number of cut slopes is rapidly increasing due to the continuous expansion and linear improvement of existing roads.

In particular, roads that were opened before the 1990s were designed and constructed with unstable elements in the slope due to economic and technical problems. Accidents caused by falling rocks and slopes have been repeated every year due to relaxation, and the re-destruction of cut slopes has emerged as a social problem, and researches have been carried out by institutions and scholars on how to solve them. Is in progress.

On the other hand, since 1990, as a result of interest and research on securing stability of cut slope, many existing slopes have been reconstructed, and new roads are appropriate based on rock characteristics and topographical, geological and hydrological data. Slope countermeasures are being designed.

In particular, when the planar activity is expected due to the discontinuity developed on the cut slope, or when the cut slope instability is expected due to the erosion of the cut slope due to the fracture zone development such as a fault, the activity block is suppressed and the protection function of the cut surface is aimed. As a result, stepped retaining walls are one of the most widely used construction methods for slopes that are expected to have high weathering or disintegration due to directional development and discontinuity.

The prior art of the stepped retaining wall as described above is to clean the surface of the theft slope, and then fill the mold with concrete mortar in the mold in a state made through the formwork to build a stepped retaining wall.

However, the stepped retaining wall according to the prior art as described above is a surface water treatment by rainwater, etc., but there is a problem that no induction of infiltration water and groundwater existing inside the slope (or the surface) behind the retaining wall at all.

On the other hand, the drainage facility of the stepped retaining wall according to the prior art as described above is composed of a drainage channel, such as a kind of U-shaped port at the rear end of the step wall of each layer and a side drainage channel through which the surface water collected through the drainage channel is discharged. .

The drainage facility of the stepped retaining wall according to the prior art, which is formed as described above, is subjected to final induction drainage through a side drain formed on the side of the retaining wall by collecting surface water through the drain.

However, as described above, in the case of the stepped retaining wall according to the prior art, the infiltration water and the groundwater inside the slope, which have a significant influence on the rear slope stability, have not been increased drainage treatment. There is a problem that the pore water pressure of the slope increases, which can pose a great threat to the stability of the slope as well as the retaining wall.

The present invention has been made to solve all the problems of the prior art, the concrete wall through the reinforcement of the flexible pipe and surface water outflow pipe after the reinforcement of the reinforcement on the cut surface of the cut slope to allow the construction of the step retaining wall The purpose is to provide a vertical drainage type eco-friendly step retaining wall using a flexible pipe to make the construction easier.

In addition, the technique according to the present invention is to facilitate the drainage of surface water by allowing the construction of a step retaining wall by placing concrete pipes and pipes through the pipe after the reinforcement of the reinforcement on the clean surface of the cut slope It is to contribute to the stability of the slope as well as the stepped retaining wall.

The present invention configured to achieve the above object is as follows. That is, the vertical drainage type eco-friendly stepped retaining wall using a flexible pipe according to the present invention is a step surface for stepping on a slope, a cut slope, a cut soil or an inclined slope for the rescue of a road, embankment, railroad or tunnel. In a stepped retaining wall composed of a planting portion in which plants are planted on the plant, an insert is installed at the lower portion of each planting portion of the retaining wall, and a branching pipe branching from the lower portion of the induction pipe and the induction pipe through which surface water flows from the lower portion of the planting portion. An integrally formed surface water outlet pipe; A flexible flexible pipe connecting the surface water outlet pipes inserted into each of the retaining wall parts, and connecting the rear end of the branch pipe of the surface water outlet pipe installed under the lower retaining wall and the tip of the branch pipe of the surface water outlet pipe installed under the upper retaining wall; And a filter installed at the upper inner diameter of the induction pipe of the surface water discharge pipe so as to prevent the soil or other foreign substances filled in the planting portion from entering.

In the configuration of the present invention as described above, the branch pipe tip of the surface water outlet pipe installed in the lowermost retaining wall portion of the retaining wall portion may be configured to be exposed to the front or side surface of the lowermost retaining wall portion to allow the surface water to flow out.

In the structure according to the present invention, when the step retaining wall is constructed with n retaining wall parts, the lower retaining wall part may be constructed and then sequentially applied to the lower retaining wall part of the surface water outlet pipe installed on the lower retaining wall part. Connect the flexible flexible tube to the rear end of the engine and expose it to the upper part of the retaining wall.When constructing the upper retaining wall on the lower retaining wall, connect the lower flexible pipe to the tip of the branch pipe of the upper surface water outlet pipe. It can be constructed in such a way that the surface water outlet pipe and the upper surface water outlet pipe are interconnected.

On the other hand, the configuration according to the present invention as described above may be further provided with a plurality of anchors installed in the ground of the slope through the retaining wall portion of the hole means or mating means of the retaining wall portion.

In the structure according to the present invention as described above in the case of the retaining wall portion is installed anchoring planting portion may be formed between the position where the anchor is installed so that interference with the anchor does not occur.

According to the technology of the present invention, after the reinforcement of the reinforcement on the cut surface of the reinforcing bar, the flexible pipe and the guide pipe are piped in a state in which the concrete installation after the formwork to build a step retaining wall to facilitate the drainage of infiltration water or surface water Is done.

In addition, another effect of the technique according to the present invention is to allow the construction of the stepped retaining wall by laying concrete after the formwork in the state of piping the flexible pipe and guide pipe after the reinforcement of the rebar on the clearance surface of the cut slope The drainage of the surface water can be easily performed, so that the slope can be stabilized as well as the construction of the staircase retaining wall.

In addition, the technology according to the present invention constructs an environmentally friendly stepped retaining wall by pouring concrete mortar prepared by mixing sand, gravel and cement through a mixed solution mixed with a solvent, carbon black, a dispersant, an antifoaming agent, graphite, and an oil-based urethane resin. There is a sewer.

1 is a cross-sectional view showing the construction of a vertical drain type eco-friendly step retaining wall using a flexible pipe according to the present invention.
Figure 2 is a plan view showing a plan view of the vertical drainage type eco-friendly step retaining wall using a flexible pipe according to the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the vertical drain type eco-friendly stepped retaining wall using a flexible pipe according to the present invention.
1 is a cross-sectional view showing the construction of a vertical drainage type eco-friendly step retaining wall using a flexible pipe according to the present invention, Figure 2 is a plan view showing a plan view of the vertical drainage type eco-friendly stepped retaining wall using a flexible pipe according to the present invention. It is a block diagram.

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1 and 2, the vertical drainage type eco-friendly step retaining wall using a flexible pipe according to the present invention (hereinafter, referred to as "stepped retaining wall") is a normal, cut slope, cut soil, or collapsed slope (10). The construction surface 12 is constructed. The stepped retaining wall 100 according to the present invention has a configuration of the planting portion 120 is formed in a predetermined depth on the upper surface of the retaining wall portion 110 and the retaining wall portion 110 forming each end.

On the other hand, the stepped retaining wall 100 according to the present invention as described above, in addition to the configuration of the retaining wall portion 110 and the planting portion 120 is inserted into the lower side of the planting portion 120 of each of the retaining wall portion 110, Surface water installed in each of the surface water outlet pipe 130 and the retaining wall part 110 in which the induction pipe 132 through which the surface water is introduced from the planting part and the branch pipe 134 branched from the lower part of the induction pipe 132 are integrally formed. The surface of the surface water outlet pipe 130, which is connected to the outlet pipe 130, but installed below the branch pipe 134 and the upper retaining wall portion 110 of the surface water outlet pipe 130 installed in the lower retaining wall 110, the lower The flexible flexible pipe 140 connecting the tip of the branch pipe 134 and the top surface of the guide pipe 132 of the surface water outlet pipe 130 are installed to prevent the soil or other foreign substances filled in the planting part 120 from entering. It consists of a configuration including a filter (150).

The stepped retaining wall 100 according to the present invention configured as described above is a guide pipe of the surface water outlet pipe 130 below the planting portion 120 where the surface water accumulated on the surface of the retaining wall portion 110 or the planting portion 120 ( 132) It is a structure that is guided to the induction pipe 132 through the filter 150 installed on the inner diameter of the top flows into the branch pipe 134 and then to the outside. At this time, the surface water introduced into the branch pipe 134 through the induction pipe 132 of the surface water outlet pipe 130 installed in the upper retaining wall 110 is the surface water outlet pipe 130 installed in the lower retaining wall 110. It flows into and out of the branch pipe 134 of the lower surface water outlet pipe 130 through the flexible pipe 140 connected to the branch pipe 134.

Looking at the construction process of the stepped retaining wall 100 according to the present invention, first, the surface of the slope 10 to be constructed for the stepped retaining wall 100, and then the lower one stage through the formwork on the retaining wall construction clearance surface 12 Forming the mold to form the retaining wall portion 110 and the planting portion 120 is formed. Subsequently, after forming the mold which forms the one step retaining wall part 110 and the mold which forms the planting part 120, reinforcing steel is reinforced in the inside of a mold.

Next, the surface water outflow pipe 130 in which the induction pipe 132 through which the surface water is introduced and the branch pipe 134 branched from the lower portion of the induction pipe 132 are integrally formed at the lower side of the mold forming the planting part 120. ), And the rear end of the flexible pipe 140 having a flexible structure is connected to the rear end of the branch pipe 134 of the surface water outlet pipe 130 to be exposed and fixed to the upper side of the mold. Subsequently, the concrete mortar is filled in the mold forming the retaining wall 110 to cure for a predetermined time, and then the formwork is removed to construct a one-stage retaining wall 110 of the stepped retaining wall 110 having n steps.

As described above, after constructing the one-stage retaining wall portion 110 of the stepped retaining wall 100 having the n stages, the two-stage retaining wall portion 110 is formed on the upper side of the one-stage retaining wall portion 110. The mold for forming the mold and the planting part 120 is installed, and then the reinforcing bar is placed inside the mold for forming the two-stage retaining wall part 110.

Next, as described above, after the reinforcing bar in the interior of the mold for forming the two-stage retaining wall 110, the induction pipe 132 in which the surface water flows into the lower side of the mold forming the planting portion 120 ) And the surface water outlet pipe 130 formed integrally with the branch pipe 134 branching from the lower portion of the induction pipe 132,

As described above, after the surface water outlet pipe 130 is piped, the flexible pipe 140 exposed to the upper portion of the retaining wall 110 when the first stage retaining wall 110 is constructed, the two-stage retaining wall 110. It is connected to the tip of the branch pipe 134 of the surface water outlet pipe 130 piped in. That is, the rear end of the branch pipe 134 of the surface water outlet pipe 130 piped to the first stage retaining wall 110 and the tip of the branch pipe 134 of the surface water outlet pipe 130 piped to the second stage retaining wall 110. Will be connected through the flexible pipe 140,

Subsequently, as described above, the surface water outlet pipe 130 piped to the second stage retaining wall 110 is the flexible pipe 140 exposed to the upper portion of the retaining wall 110 during the construction of the first retaining wall 110. After the engine 134 is connected to the front end, the other flexible pipe 130 is connected to the rear end of the branch pipe 134 of the surface water outlet pipe 130 piped to the second retaining wall 110 to expose the upper part of the mold.

In addition, as described above, by connecting another flexible pipe 130 to the rear end of the branch pipe 134 of the surface water outlet pipe 130 piped to the two-stage retaining wall 110, the two-stage retaining wall is exposed to the upper part of the mold. The second step retaining wall 110 of the stepped retaining wall 100 consisting of n stages is constructed by filling concrete mortar with curing of the mold to form a part 110 and curing the mold for a predetermined time.

As described above, the construction is performed from the three-stage retaining wall portion 110 to the uppermost n-stage retaining wall portion 110 to the upper side of the two-stage retaining wall portion 110. At this time, the rear end of the branch pipe 134 of the surface water outlet pipe 130, which is piped to the uppermost n-stage retaining wall 110, is closed, and the front end of the branch pipe 134 of the surface water outlet pipe 130 is the n-1 stage retaining wall. It connects through the rear end of the branch pipe 134 and the flexible pipe 140 of the surface water outlet pipe 130 piped to the unit 110.

On the other hand, after constructing the stepped retaining wall 100 from the lowermost single-stage retaining wall 110 to the n-stage retaining wall 110 through the above-described method, the surface water flow formed on each retaining wall 110 is discharged. In the state in which the filter 150 is installed on the upper inner diameter of the induction pipe 132 of the pipe 130, the soil is filled on the planting part 120 to be planted.

When explaining the respective components constituting the stepped retaining wall 100 according to the present invention in more detail. First, the surface water outlet pipe 130 is for discharging the surface water flowing into the inside of the planting part 120 from the upper portion of the retaining wall 110 to the outside, such surface water outlet pipe 130 is shown in FIGS. As shown, the insert is installed at the lower side of the planting part 120 of each of the retaining wall parts 110, and is branched from the induction pipe 132 and the induction pipe 132 in which the surface water flows from the lower part of the planting part 120. Branch pipe 134 has a structure formed integrally.

In the configuration of the surface water outlet pipe 130 as described above, the tip of the branch pipe 134 of the surface water outlet pipe 130 installed at the lowermost retaining wall part 110 of the retaining wall part 110 is the front surface of the lowermost retaining wall part 110. Or is exposed to the side is configured so that the surface water outflow can be made, the rear end of the branch pipe 134 of the surface water outlet pipe 130 is formed on the retaining wall portion 110 of the upper side through the flexible pipe 140 It is connected to the tip of the branch pipe 134 of 130.

In other words, the surface water outflow pipe constituted in the lower retaining wall portion 110 in the structure of the stepped retaining wall 100 formed in a plurality of steps from the lowest retaining wall portion 110 to the n-stage retaining wall portion 110 as in the present invention. The front end of the branch pipe 134 of the surface water outlet pipe 130 formed at the rear end of the branch pipe 134 and the upper retaining wall part 110 of the 130 is connected through the flexible pipe 140 and the upper retaining wall part 110. Surface water) is configured to be discharged to the lower surface water outlet pipe (130).

Next, the flexible pipe 140 constituting the present invention is for interconnecting the upper surface and the lower surface water jujikwan 130, the flexible pipe 140 as shown in Figures 1 and 2 Retaining wall portions 110 connected to the surface water outlet pipes 140 installed in the retaining wall parts 110, respectively, are connected to the rear end of the branch pipe 134 of the surface water outlet pipe 130 installed below the retaining wall part 110. It consists of a structure for connecting the branch pipe front end 134 of the surface water outlet pipe 130 installed in the lower portion. At this time, the flexible pipe 140 interconnecting the surface water outlet pipe 140 inserted into each of the retaining wall parts 110 is formed of a flexible pipe free to bend.

On the other hand, as described above, when the step retaining wall 100 according to the present invention constructs the n retaining wall parts 110, the lower retaining wall part 110 is constructed and then sequentially constructed. At this time, when the lower retaining wall 110 is installed, the flexible flexible pipe 140 is connected to the rear end of the branch pipe 134 of the surface water outlet pipe 130 installed on the lower retaining wall 110 to retain the retaining wall ( The construction is to be exposed to the upper portion of the 110, the lower retaining wall portion 110 on the lower retaining wall portion 110 when constructing the lower side flexible pipe 140 branching pipe 134 of the upper surface water outlet pipe 130 ) Is connected to the front end is constructed in such a way that the lower surface water outlet pipe 130 and the upper surface water outlet pipe 130 are connected to each other.

In addition, the filter 150 constituting the present invention is to prevent the inflow of soil or other foreign matter to the surface water outlet pipe 130 installed under the planting part 120 on the retaining wall 110. 1) is installed in the upper inner diameter of the guide pipe 132 of the surface water outlet pipe 130 as shown in Figure 1 and 2 so that the soil or other foreign matter filled in the planting portion 120 is introduced.

In the configuration of the stepped retaining wall 100 according to the present invention configured as described above in the configuration of the retaining wall 110, planting portion 120, surface water outlet pipe 130, flexible pipe 140 and filter 150 In addition, a plurality of anchors 160 may be further provided to penetrate the retaining wall part 110 of the hole means or the mating means of the retaining wall part 110 and installed on the ground of the slope.

Meanwhile, the plurality of anchors 160 installed as described above transmits the tensile force generated in the retaining wall 110 to the ground 10 so that the retaining wall 110 may be supported by the anchor 160 on the ground 10. To help.

In addition, in the above-described configuration, in the case of the retaining wall part 110 in which the anchor 160 is installed, the planting part 120 is formed between positions where the anchor 160 is installed so that interference with the anchor 160 is not generated. Is better.

In other words, in the case of the retaining wall part 110 in which the aforementioned anchor 160 is installed, the planting part 120 is anchored to the anchor 160 and the anchor 160 so that the anchor 160 to be installed does not penetrate the planting part 120. Form between).

As described above, the technology according to the present invention can facilitate the construction of the retaining wall by constructing the stepped retaining wall 100 through the configuration of the surface water outlet pipe 130, the flexible pipe 140, and the filter 150. Of course, it is possible to easily drain the surface water can contribute to the stability of the slope as well as the stepped retaining wall constructed.

The technology according to the present invention is not limited to the above-described embodiments, but may be variously modified and implemented within the range permitted by the technical idea of the present invention.

10. Fore slope, cut slope, cut soil or collapse slope
12. Retaining wall construction clearance surface
100. Stepped Retaining Wall
110. Retaining Wall
120. Food and Agriculture
130. Surface water outlet
132. Induction pipe
134. Branch pipes
140. Flexible Tube
150. Filter
160. Anchors

Claims (5)

In a stepped retaining wall composed of a retaining wall portion which is formed stepwise on a surface, a cut slope, a cut soil or a collapsed slope for the rescue of a road, a dike, a railroad or a tunnel, and a planting portion in which plants are planted on the step surface of the retaining wall. A surface water outlet pipe integrally formed with an insert installed at a lower side of each planting part of the retaining wall, and having an induction pipe through which inflow of surface water flows from the bottom of the planting part and a branching pipe branched from the lower portion of the induction pipe; The surface water outlet pipes inserted into each of the retaining wall parts may be connected to each other, but the rear end of the branch pipe of the surface water outlet pipe installed below the retaining wall part may be connected to the branch pipe tip of the surface water outlet pipe installed below the retaining wall part of the upper part. Flexible flexible tube; And a filter installed at the upper inner diameter of the induction pipe of the surface water outlet pipe so as not to introduce soil or other foreign substances filled in the planting part,
The tip of the branch pipe of the surface water outlet pipe installed in the lower retaining wall portion of the retaining wall portion is exposed to the front or side surface of the lower retaining wall portion to allow the surface water to flow out, and the stepped retaining wall has a lower portion when the n retaining walls are constructed. After constructing the retaining wall part, construct the upper part sequentially, but connect the flexible flexible pipe to the rear end of the branch pipe of the surface water outlet pipe installed on the lower retaining wall part when the lower retaining wall part is installed to be exposed to the upper part of the retaining wall part. When the upper retaining wall portion is installed on the lower retaining wall portion, the lower flexible pipe is connected to the branch pipe tip of the upper surface water outlet pipe so that the lower surface water outlet pipe and the upper surface water outlet pipe are interconnected. A plurality of anchors are further provided in the ground of the slope through the retaining wall of the hole means or mating means of the retaining wall portion Meanwhile, in the case of the retaining wall portion in which the anchor is installed, the planting portion is formed between positions where the anchor is installed, so that the interference with the anchor does not occur.
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