KR20150002028U - Structure to drain water in slope with s type drain pipe - Google Patents

Abstract

The main purpose of the present invention is to provide a natural slope drainage structure capable of maximizing the drainage effect by burying all the drain pipes under the slope using a new bundle pipe.
In order to accomplish the above object, the present invention provides a slope drainage structure using a multi-pipe, which is installed on one side of a road surface using an S type drain pipe (SDP) on a slope formed by embankment or cut soil A ridge drainage structure is provided, wherein a ridge drainage pipe made of the bundle pipe is embedded below the inclined surface, a road surface drainage pipe made of the bundle pipe is buried under the roadside at one side of the roadside, One or two or more sloped vertical drainpipes, which are the bundle pipes, are embedded in the slopes below the slope so that rainwater flowing in from the ridge drainpipe can be carried to the drainpipe.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a slope drainage structure using a multi-

The present invention relates to a sloped drainage structure using a bundle tube, and more particularly, to a sloped drainage structure using a bundle tube that can provide a more natural and efficient slope drainage structure by replacing a conventional concrete drainage structure with a bundle tube. Drainage structure.

In a structure such as a road formed through embankment or cut, the left and right sides of the road located at the lower part are formed as inclined slopes.

Conventionally, a separate drainage facility is not installed on this inclined surface, and natural drainage is made through an inclined surface. That is, the rainwater on the slope penetrates into the underground of the slope as it is, and the natural drainage to the side drainage of the road at the lower side along the slope has been made. However, during heavy rains or long - term rainfall, rainwater penetrating into the slopes suddenly increased. As a result, the inclination of the slopes weakened the soil support strength from the upper part of the slopes, causing some parts to sink or lose.

In order to solve this problem, a technique of drainage of rainwater on the slope by artificial drainage structure such as concrete was installed on the slope.

Fig. 1 shows a typical shape of an artificial drainage structure provided on such an inclined surface.

First, a ridge 100 is provided at an upper portion of the slope S so that rainwater infiltrating from the upper side is drained through the ridge 100. The mountain ridge 100 is useful for preventing the slope of the slope and the inclined surface from collapsing due to the rainwater flowing down the slope. Ridges 100 are generally installed in a manner that interconnects the concrete structures.

The slope drainage channel 110 is installed perpendicularly along the slope S and communicates with the mountain-mouth gutter 100. Accordingly, the rainwater flowing through the ridge 100 is transported to the road surface 130 below the slope through the slope drain line 110. The sloping drainage canal 110 is also installed in such a way that the concrete structures are connected to each other.

The road surface drainage path 120 is installed on both sides of the road surface 130 positioned at the bottom of the embankment surface or incision surface and the rainwater flowing down the slope surface through the inclined road drainage path 110 passes through the road surface drainage path 120 And finally drained. The road surface drainage channel 120 is also installed mostly as a concrete structure.

The ridge 100, the slope drainage channel 110 and the road drainage channel 120 are generally made of a concrete structure in which the portion turned off in a U shape is directed upward and installed on the slope as described above Thereby forming a total drainage structure. However, it has been found that the slope drainage structure made of such a concrete structure has the following problems.

First, scour phenomenon caused by rainwater or the like occurred on the inclined surface portion contacting the ridge 100 and the inclined surface drainage passage 110. As a result, the rainwater flowing down the slope flowed into the shaved part before flowing into the ridge, and the ridge side and the like could not function properly. Second, due to the open drainage structure, there was a problem of losing soil around the drainage channel during the heavy storm like typhoon or during the rainy season when the water overflowed over the drainage channel. Third, since the artificial structure 100, which is a manmade structure, is installed so as to be exposed to the outside of the slope, it is not only natural in appearance, but also has a problem that the area where the ridge 100 is installed can not be used for other purposes there was.

Fig. 2 shows another conventional artificial slope drainage structure. The ridge girder 100 and the road surface drainage path 120, which are concrete structures, are installed in the same manner as in Fig. However, instead of the conventional slope drainage path, an inclined surface vertical drain pipe 140 in the form of a pipe is embedded below the slope S. A plurality of flow holes 142 are formed on the outer surface of the pipe at regular intervals, and rainwater flowing below the slope flows through the flow holes 142 to flow into the pipe.

If the pipe is used as the inclined-surface vertical drain pipe 140, it can be buried under the inclined surface, thereby preventing scraping and soil erosion around the drainage pipe. In addition, since the artificial structure is not exposed to the outside of the inclined surface, the inclined surface can be formed in a natural-friendly form.

However, this type of slope drainage structure poses another problem due to the structural limitations of the pillar itself. That is, when the pipe is used for a long time, the water collecting property itself is largely deteriorated due to clogging caused by the gravel of the flow hole 142. When the soil is introduced into the pipe through the distribution hole 142, the drainage property is significantly lowered, and the effective drainage cross-sectional area is reduced to 20% of the total cross-sectional area. Due to the limitation of the plastic material, the durability is weak and deformation such as distortion occurs, which also adversely affects drainage. Furthermore, since the concrete structure such as the ridge jig 100 is also used as it is, the above-mentioned problems still arise.

Therefore, in order to solve various problems of the sloped drainage structure of the conventional artificial structure, development of a new type of natural-friendly sloped drainage structure is urgently required.

This design was developed to meet the needs of this industry. It provides a nature-friendly slope drainage structure that can bury all the drain pipes below the slope and maximize drainage effect by using a new multi-pipe. . Further, another object is to improve the overall durability of the retaining wall by maintaining the supporting strength of the soil supported by the retaining wall and the retaining wall.

In order to accomplish the above object, the present invention provides a slope drainage structure using a multi-pipe, which is installed on one side of a road surface using an S type drain pipe (SDP) on a slope formed by embankment or cut soil A ridge drainage structure is provided, wherein a ridge drainage pipe made of the bundle pipe is embedded below the inclined surface, a road surface drainage pipe made of the bundle pipe is buried under the roadside at one side of the roadside, One or two or more sloped vertical drainpipes, which are the bundle pipes, are embedded in the slopes below the slope so that rainwater flowing in from the ridge drainpipe can be carried to the drainpipe.

The bundle tube may be divided into a circular bundle tube and a plate bundle tube according to the shape of the cross section, and the ridge discharge pipe, the road surface discharge pipe, and the inclined plane vertical discharge pipe may all be formed of circular bundle pipes.

On the other hand, one or more slope horizontal drain pipes are installed on the inclined surface so as to intersect with the sloped vertical drain pipes, and the inclined surface horizontal drain pipe may be constituted by a pipe. At this time, when two or more sloped horizontal drain pipes are formed as the pipe, the sloped horizontal drain pipe may be installed to have an increased diameter toward the lower part of the sloped surface.

In the meantime, the bundle tube is divided into a circular bundle tube and a plate type bundle tube according to the shape of a cross section, and one or more inclined plane horizontal discharge pipes are installed on the inclined surfaces so as to intersect with the inclined plane vertical discharge pipes, And may be composed of a plate-type bundle tube. In this case, when two or more sloped horizontal drain pipes are installed, the sloped horizontal drain pipe may be installed to increase in diameter toward the lower part of the sloped surface.

In the meantime, the bundle tube is divided into a circular bundle tube and a plate type bundle tube according to the shape of a cross section, and one or more inclined plane horizontal discharge pipes are installed on the inclined surfaces so as to intersect with the inclined plane vertical discharge pipes, Circular tube bundle. In this case, when two or more sloped horizontal drain pipes are formed as the circular pipe bundle, the sloped horizontal drain pipe may be installed such that its diameter increases toward the lower part of the sloped surface.

In addition, when the inclined-surface vertical drain pipe and the inclined-surface horizontal drain pipe are both circular pipes, the inclined-surface vertical drain pipe and the inclined-surface horizontal drain pipe may be connected to each other by a joint joint.

On the other hand, when a retaining wall is provided on one side of the road surface, an upright drain pipe may be installed on the rear surface of the retaining wall so that rainwater flowing from the inclined surface vertical drain pipe can be carried to the road surface drain pipe. At this time, the bundle tube is divided into a circular bundle tube and a plate type bundle tube according to the shape of the cross section, and the upright type water tube may be composed of either the circular bundle tube or the plate bundle tube.

Another aspect of the present invention is to provide an inclined surface drain structure using a bundle tube, which is installed on one side of a road surface using an S-shaped bundle tube on an inclined surface formed by embankment or cut soil, A ridge drainage pipe made of the bundle tube is embedded in an upper portion of the drainage pipe below the slope and a road surface drainage pipe made of the bundle pipe is buried under the roadside surface on one side of the roadside, And a plurality of inclined surface inclined drain pipes are installed so as to cross each other at an angle so as to simultaneously transport the rainwater flowing from the rainwater and the inclined surface to the road surface drain pipe.

At this time, the inclined surface inclined drain pipe may be constituted by a pipe, a plate-like bundle pipe, or a circular bundle pipe.

According to the slope drainage structure using the multi-pipe according to the present invention constructed as described above, all the structures used in the drainage structure of the slope are buried under the slope, thereby solving various problems of the existing concrete drainage Can be solved. For example, it is possible to prevent the scouring phenomenon caused by rainwater or the like around the drainage channel from occurring, and also to solve the problem that the drainage of the surrounding gravels is lost when the water overflows over the drainage channel during heavy rainfall.

In addition, the use of the bundle tube can solve various problems of the conventional pipe, for example, deterioration of collecting ability due to clogging of the flow hole, decrease in drainage capacity due to the introduction of the soil into the tube, and decrease in durability according to the plastic material By resolving all, it provides the most effective slope drainage system.

In addition, the circular bundle tube is installed as a basic structure, but it can provide the most economical and efficient drainage system by allowing the installation of the pipe tube and the plate bundle tube together in consideration of the inflow of rainwater.

In addition, all the drain pipes used in the sloping drainage structure are buried in the basement so that no artificial structure is exposed to the outside, so that the slope can be formed in a more natural-friendly form.

In addition, since it is not necessary to secure a separate site area in order to expose the artificial structure to the outside, it is possible to reduce the entire construction cost including the land compensation cost.

Further, by maintaining the supporting strength of the soil supported by the retaining wall and the retaining wall, the overall durability of the retaining wall is also improved.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view showing a slope drainage structure using a conventional drain pipe. FIG.
2 is a view showing a slope drainage structure using a conventional pipe.
Fig. 3 is a view for comparing shapes of drain pipes used in the present invention; Fig.
4 is a view showing a basic type inclined surface drainage structure according to the present invention.
5 is a view showing a first embodiment of a matrix type inclined surface drainage structure according to the present invention.
6 is a view showing a second embodiment of a matrix type inclined surface drainage structure according to the present invention.
7 is a view showing a third embodiment of a matrix type inclined surface drainage structure according to the present invention.
8 is a view showing a fourth embodiment of a matrix type inclined surface drainage structure according to the present invention.
9 is a view showing a fifth embodiment of the matrix type inclined surface drainage structure according to the present invention.
10 is a view showing a retaining wall drainage structure according to the present invention.

Hereinafter, a preferred embodiment according to the present invention will be described in more detail with reference to the accompanying drawings.

Before describing the slope drainage structure according to the present invention, the shape of the multi-tube, which is the most important component of the present invention, will be briefly described with reference to FIG.

The S type drain pipe (hereinafter referred to as "the multi-tube") is formed by bundling a plurality of pipes having an S-shaped cross section (see the circle in FIG. 3 (a) It is a collecting tube bundle. Since this bundle tube has many continuous line collecting ports and drainage spaces, it is less clogged and the soil does not flow completely into the pipe, and therefore the collecting and draining effect is more excellent than the general pipe. For example, while the effective drainage cross-sectional area of the general pore tube accounts for only 20% of the total cross-sectional area, the effective drainage cross-sectional area of the circular pipe tube described later accounts for more than 60% of the total cross-sectional area. In addition, since several S-shaped pipes are bundled, they are durability against external pressure and can be used semi-permanently. For example, a general pipe has a pressure resistance of 1.2 ton / m, whereas a circular pipe has a pressure resistance of 2.4 ton / m.

3 (a) shows a circular tube bundle 10 having a circular cross-sectional shape. The circular tube bundle 10 is formed by concentrating a plurality of S-shaped tubes 12 in a circular shape. The circular bundle tube 10 is buried in the form of a geosynthetic fiber 14 for filtering, draining and separating functions. The circular tube bundle (10) has the same circular cross-section as the general drain pipe, so it is easy to install. Further, the pressure resistance is uniform in all the circumferential directions, and exhibits excellent durability from the earth pressure in any direction. For this reason, in the present invention, the circular tube bundle 10 is mainly used as a basic drain pipe.

FIG. 3 (b) shows a plate-shaped tube mat 20 having a rectangular cross section. The plate-shaped tube bundle 20 is formed by arranging the S-shaped tube 22 in one or two or more rows. The plate-shaped bundle tube 20 is buried in the form of a geosynthetic fiber 24 for filter, drainage and separation functions. The plate-shaped bundle tube 20 can be deformed into various shapes in its width and height, so that it can not be deeply used or is effectively used to receive a large area of water. For this reason, in the present invention, the plate bundle pipe is mainly used as an inclined horizontal pipe which requires a large collecting area.

FIG. 3 (c) shows the general pipe structure 30 used in the conventional drainage structure as described in FIG. The oil pipe flows rainwater or the like flowing into the underground through the flow hole (32) formed on the outer surface into the pipe and discharges it. The perforated pipe 30 is often used as a drain pipe such as rainwater due to the drainage function of the outside water. However, the pore tube 30 is disadvantageous in that it has lower collecting ability, drainage ability, and durability than the bundle tubes 10 and 20. However, it is still in use because it is inexpensive to produce. For this reason, in the present invention, the above-described pillar pipe is mainly used as a sloping horizontal drain pipe requiring a relatively low collecting and drainage capability.

In the present invention, as shown in FIG. 3 (c), the pores refer not only to the flow holes 32 formed at regular intervals, but also to the mesh holes in which the flow holes are formed in the form of a net.

Fig. 4 shows a basic type slope drainage structure according to the present invention.

The present invention relates to an inclined drainage structure installed on an inclined plane (S) formed by embankment or cut with a S type drain pipe (S.D.P) on one side of a road surface.

For this, a ridge drainage pipe 40, which is a bundle pipe, is embedded in the upper part 80 of the slope below the slope, and a road surface drainage pipe 50 of the bundle pipe is installed at one side of the roadside 90 And a slope vertical drain pipe (60) formed of the bundle pipe is embedded in the slope below the road surface so that rainwater flowing from the ridge drain pipe (40) can be conveyed to the road surface drain pipe One or more of them are buried.

Basically, the present invention is configured such that all the drains 40, 50, 60 constituting the drainage structure are buried beneath the slopes and are not exposed to the outside. As a result, the drain pipe, which is an artificial structure, is not exposed to the outside of the inclined surface, so that a more environmentally friendly drainage structure can be constructed.

The ridge drain pipe 40 corresponds to a ridge jig installed as a concrete structure in the conventional inclined surface drainage structure shown in Figs. 1 and 2. The present invention replaces a conventional U-shaped open-end ridge-jig with a ridge drainage pipe (40), which is composed of a bundle tube and buried underground. As a result, all the problems of the conventional ridge jig were solved.

In other words, the problem of scouring due to rainwater or the like on the slope part contacting with the ridge side, and the flow of the rainwater to the scraped part before the rainwater flows into the side of the ridge, the ridge side can not function properly. The drainage structure that was opened to the outside solved the problem of overflowing the water over the drainage line at the concentrated lake and losing the soil around the drainage line. Furthermore, it solves the problem of securing separate land area by the outwardly exposed ridge side.

As shown in FIG. 2, although a drain pipe vertically installed on a slope has been buried in the ground, there has never been a case where a mountain-mouth slope provided on the slope has been buried underground. The inventor of the present invention paid attention to this point and realized the problem of the open-ended concrete structure by using the bundle pipe to realize the underground burial ridge.

This technical configuration has become feasible by selecting a bundle as a drain pipe. In other words, as described above, the bundle pipe has a better collecting ability, drainage ability and durability than the existing pipe, and even if it is buried in the underground, it can satisfy the high drainage ability required as a ridge.

On the other hand, a road surface water pipe 50 made of the bundle tube is embedded at one side of the road surface 90 below the road surface. This road surface water pipe 50 corresponds to a road surface water pipe having a "U" -shaped open form, which is installed as a concrete structure in the conventional inclined water drainage structure shown in Figs. The present invention replaces a conventional U-shaped drainage path of a "U" shape with a drainage pipe 50 formed of a bundle tube and buried underground. As a result, all the problems of the conventional road surface drainage are solved. This problem is almost similar to the problem of the above-described ridge line gauge, and thus a detailed description thereof will be omitted.

On the other hand, the inclined-surface vertical drain pipe 60 is composed of a bundle pipe and corresponds to the pipe used in the conventional slope drainage structure of FIG. This design replaces the drainage pipe that transports rainwater from the upper part of the slope to the lower part of the existing pipe. As a result, all the problems of the conventional pipe are solved.

That is, if the pipe is used for a long time, the problem of clogging due to the soil of the distribution hole is solved. It also solved the problem that drainage is significantly lowered when the soil is introduced into the pipe through the distribution hole. Further, the durability, which is the limit of the plastic material, causes deformation such as distortion, and this solves the problem of adverse effect on the drainage property. This is due to the physical characteristics of the bundle tube in preparation for the pore tube, and the details thereof have been described in detail with reference to FIG. 3, which will be referred to here.

Basically, the bundle of the present invention may be any of the circular bundle bundle 10 or the plate bundle bundle 20 described above with reference to Fig. 3 above. However, as shown in Fig. 4, the ridge drain pipe 40, the road surface drain pipe 50, and the slope vertical pipe 60 constituting the basic form of the inclined surface drainage structure are all formed of the circular pipe bundle 10 More preferable.

This is because the above three drain pipes require maximum drainage ability in order to smoothly drain the rainwater and prevent the sliding of the slope even in heavy rainfall. Therefore, it is preferable to use a circular bundle tube having a relatively low internal inflow rate due to soil and an excellent drainage ability as compared with the plate bundle tube. In addition, since it is difficult to repair the slope drainage line once installed, it is preferable to use a circular drainage pipe having excellent pressure resistance against external pressure in all directions for semi-permanent use.

As described above, the basic form of the slope drainage structure using the multi-pipe according to the present invention is a concrete structure that was conventionally used as a ridge side and a road surface drainage path, or a pore pipe that was buried vertically on an inclined surface, All of these problems have been solved by replacing them with excellent multi-tube pipes.

The inventor of the present invention has further developed the basic slope drainage structure shown in FIG. 4 to develop a matrix type slope drainage structure. In the following, various types of matrix type slope drainage structures will be described in order.

Fig. 5 shows a first embodiment of the matrix type slope drainage structure according to the present invention.

A ridge drainage pipe 40 buried in the slope upper portion 80, a road surface drainage pipe 50 buried in one side of the road surface, and a road surface drainage pipe 50 buried under the slope S from the ridge drainage pipe 40, The inclined vertical drain pipe 60 for conveying the rainwater is provided with a bundle pipe, particularly a circular pipe bundle 10, which is the same as the basic type inclined drainage structure according to the present invention described with reference to FIG.

According to the present embodiment, one or more sloping horizontal drain pipes 70 are provided on the sloped surface S so as to intersect with the sloped vertical drain pipes 60. The sloped horizontal pipe 70 is constituted by a pipe 30 do.

Since the inclined-surface vertical drain pipes 60 are installed at regular intervals, the rainwater seeps under the inclined surface and is naturally drained. However, when the amount of precipitation suddenly increases as in the case of heavy rainfall, the amount of the rainwater spontaneously drained sharply increases, so that the supporting strength of the soil is weakened, and a part of the rainwater sinks or is lost.

The slope horizontal drain pipe 70 according to the present invention is installed to cover an area between the slope vertical drain pipes 60. That is, the rainwater that permeates down the slope and is naturally drained is drawn into the sloped horizontal drainage pipe 70 and is transported horizontally. The rainwater is transported vertically to the sloped vertical drainage pipe 60 and then transported vertically through the drainage pipe 50 Respectively.

Unlike the ridge drain pipe 40, the road surface drain pipe 50, and the sloped vertical pipe 60, which constitute the basic drainage structure for the entire inclined surface, the inclined surface horizontal drain pipe 70 has a constant area It is possible to have relatively low collecting and draining ability. Therefore, in this embodiment, the most economical drainage system is realized by using the relatively low-cost pipe 30 as the sloping horizontal drain pipe 70.

Here, the inclined-surface vertical water pipe 60 and the inclined-surface horizontal water pipe 70 do not mean that they are mathematically installed vertically and horizontally exactly and intersect at right angles to each other. That is, the inclined plane vertical drainage pipe 60 and the inclined plane horizontal drainage pipe 70 are installed substantially vertically and horizontally with respect to the inclined plane S, It may be installed at a slight slope. This applies equally to other embodiments of the matrix-shaped inclined plane drainage structure described below with reference to FIGS. 6-8.

Fig. 6 shows a second embodiment of the matrix type inclined surface drainage structure according to the present invention.

The ridge drainage pipe 40, the road surface drainage pipe 50 and the inclined-surface vertical drainage pipe 60 are installed as a bundle pipe, in particular, a circular pipe bundle 10, as shown in FIG. 4, .

According to the present embodiment, one or more sloping horizontal drain pipes 70 are installed on the sloped surface S so as to intersect with the sloped vertical drain pipes 60. The sloped horizontal pipe 70 is connected to the plate- . That is, the present embodiment replaces the pillar tube 30 with the plate-shaped tube bundle 20 in the first embodiment described with reference to Fig.

As described above, the plate-shaped tube bundle 20 can be deformed into various shapes in width and height, and thus can not be deeply used or can be effectively used to receive a large area of water. This embodiment is used where a wide catchment area is required by taking advantage of the characteristics of such a plate-shaped bundle tube. Therefore, this embodiment is suitable for application to an inclined plane which is located in a region with high precipitation during the rainy season and requires a large catchment area.

Fig. 7 shows a third embodiment of the matrix type slope drainage structure according to the present invention.

The ridge drainage pipe 40, the road surface drainage pipe 50 and the inclined-surface vertical drainage pipe 60 are installed as a bundle pipe, in particular, a circular pipe bundle 10, as shown in FIG. 4, .

According to the present embodiment, one or more sloping horizontal drain pipes 70 are installed on the sloped surface S so as to intersect with the sloped vertical drain pipes 60. The sloped horizontal pipe 70 is connected to the circular pipe bundle 10, . That is, this embodiment replaces the plate bundle 20 with the circular bundle tube 10 in the second embodiment described with reference to FIG.

As described above, since the circular tube bundle 10 has the same circular cross-section as that of the general drain pipe, it is easy to install. Compared with the plate-type drain pipe, the degree of the dirt is less than that of the drain pipe. Further, the pressure resistance is uniform in all the circumferential directions, and exhibits excellent durability from the earth pressure in any direction. Therefore, the present embodiment is suitable for application to a slope where high durability is required, or where a high drainage capability is required instantaneously in a heavy rainfall area.

The inclined plane vertical drain pipe 60 and the inclined plane horizontal drain pipe 70 are connected to each other by a connecting joint 72 when the inclined plane vertical drain pipe 60 and the inclined plane horizontal drain pipe 70 are both circular pipe bundles 10 Can be mutually coupled. 7, a connection joint 72 of various shapes such as a T-shape or a Y-shape is used according to the shape in which the inclined plane vertical drain pipe 60 and the inclined plane horizontal drain pipe 70 meet with each other .

Fig. 8 shows a fourth embodiment of the matrix type inclined surface drainage structure according to the present invention.

According to the present embodiment, when two or more sloping horizontal drain pipes 70 are installed on the sloped surface S, the diameter of the sloped horizontal drain pipe 70 can be increased so as to increase to a lower portion of the sloped surface. 8 shows a case where the circular bundle tube 10 is installed as the inclined plane horizontal drain pipe 70. However, when the pipe tube 30 is installed as the inclined plane horizontal drain pipe 70 as shown in FIG. 5, 20 may be installed such that the diameter thereof increases toward the lower portion of the inclined surface even when the inclined surface horizontal drain pipe 70 is installed.

The rainwater permeating into the slope moves to the lower part of the slope depending on the gravity. Therefore, the flow rate to the underground increases with the lower part of the slope. In consideration of this point, a more effective drainage system is realized by disposing the inclined-surface horizontal drain pipe 70 having a larger diameter at the lower part of the inclined surface.

Fig. 9 shows a fifth embodiment of the matrix type inclined surface drainage structure according to the present invention.

The ridge drainage pipe 40 and the roadside drainage pipe 50 are provided as a bundle pipe, particularly a circular pipe bundle 10, which is the same as the basic type slope drainage structure according to the present invention described with reference to Fig.

According to the present embodiment, instead of the inclined-surface vertical drain pipe 60 included in all of the above-described embodiments, a plurality of inclined-surface inclined drain pipes 65 and 75 are installed so as to cross each other. 9 shows an embodiment in which a plurality of inclined surface inclined drain pipes 65 and 75 provided in a zigzag form are provided in one row on an inclined plane. However, the present invention is not limited thereto and may be arranged to be arranged in two or more rows.

The inclined tilted drain pipes 65 and 75 are installed to transport the rainwater flowing from the ridge discharge pipe 40 and the rainwater flowing from the sloped surface to the road surface drain pipe 50 at the same time. In the above-described embodiment, the sloped vertical drain pipe 60 mainly carries the rainwater flowing into the ridge drain pipe 40 to the drainage pipe 50 on the road surface, and the sloped horizontal drain pipe 70 penetrates mainly below the slope And carried the rainwater to the drainage pipe 50 on the road surface. In this embodiment, the oblique tilted drain pipes 65 and 75 are provided so as to cross each other in an inclined manner so that the oblique surface vertical drain pipe 60 and the sloped horizontal drain pipe 70 can perform the same role.

According to the present embodiment, the inclined tilted drain pipes 65 and 75 can be configured as the most economical pipe tube 30. In addition, the inclined tilted drain pipes 65 and 75 may be formed of a plate-shaped bundle 20 having the largest collecting area per unit cost. In addition, the inclined tilted water distribution pipes 65 and 75 may be formed of a circular tube bundle 10 having the best collecting / draining ability.

Finally, FIG. 10 shows a retaining wall drainage structure according to the present invention.

When the embankment surface or the cut surface has a high degree of slope or the risk of topsoil degradation is high, a retaining wall P is provided at a portion where the inclined surface of one side of the road surface starts. When the retaining wall is provided on one side of the road surface, the upright drainage pipe (65) is installed on the rear surface of the retaining wall so that the rainwater flowing from the inclined surface vertical drain pipe (not shown) .

When the retaining wall P is installed on one side of the road surface, the inclined surface vertical drain pipe embedded along the inclined surface extends only to the upper end of the retaining wall. Therefore, the gap between the sloped vertical water pipe located at the upper end of the retaining wall and the road surface water pipe 50 located at the lower end of the retaining wall is spaced by the height of the retaining wall. In the present embodiment, one or more upright drain pipes 65 are provided on the rear surface of the retaining wall to allow rainwater flowing from the inclined surface vertical drain pipes to be conveyed to the road surface drain pipe 50. At this time, the upright drain pipe 65 may be either the circular pipe bundle 10 or the plate type pipe bundle 20, and may be selected selectively considering the required collecting / draining area, drainage capacity, durability, Can be used.

By providing the upright drainage pipe 65 on the rear surface of the retaining wall as described above, not only the amount of rainwater permeated into the retaining wall is reduced, but also the rainwater permeating into the soil supported by the retaining wall is drained quickly, I will. As a result, the overall durability of the retaining wall is also improved.

On the other hand, a filter material 92 may be filled in the periphery of the road surface water pipe 50, such as quartz, crushed stone, and gravel.

As described above, the present invention has been described with reference to particular embodiments, such as specific elements and the like, with limited examples and drawings. However, the present invention is not limited to the above embodiments, And various modifications and changes may be made thereto by those skilled in the art to which the present invention belongs.

Therefore, the spirit of the present invention should not be limited to the embodiments described, and all of the equivalents or equivalents of the claims, as well as the following claims, fall within the scope of the present invention .

10: round bundle tube 20: plate bundle tube
30: Pipe pipe 40: Ridgeline pipe
50: road surface drain pipe 60: inclined surface vertical drain pipe
65: inclined surface inclined water pipe 70: inclined surface horizontal water pipe
75: inclined surface inclined water pipe 80: inclined surface upper surface
90: road surface S: slope surface
P: Retaining wall

Claims (8)

An inclined drainage structure installed on an inclined plane (S) formed by embankment or cut with a S type drain pipe (SDP) on one side of the road surface,
A ridge drain pipe (40), which is a bundle pipe, is embedded in the upper part of the inclined surface below the inclined surface,
A road surface drain pipe (50), which is a bundle pipe, is embedded in one side of the road surface below the road surface,
One or more sloped vertical drain pipes 60, which are the bundle pipes, are embedded in the slopes below the slope so that the rainwater flowing from the ridge drain pipe 40 can be carried to the drain pipe 50,
One or more inclined horizontal drain pipes (70) are installed on the inclined surfaces so as to intersect with the inclined vertical water pipes (60)
The ridge discharge pipe 40, the road surface discharge pipe 50 and the inclined surface vertical discharge pipe 60 are formed in a circular shape in which a plurality of S-shaped pipes 12 are roundly bundled and wrapped with geoscientific fibers 14, A bundle tube 10,
The inclined-surface horizontal drain pipe 70 is composed of a pipe 30,
Wherein the inclined plane horizontal drain pipe (70) increases in diameter toward the lower side of the inclined plane when two or more inclined plane horizontal drain pipes (70) are formed as the perforated pipe (30). An inclined drainage structure installed on an inclined plane (S) formed by embankment or cut with a S type drain pipe (SDP) on one side of the road surface,
A ridge drain pipe (40), which is a bundle pipe, is embedded in the upper part of the inclined surface below the inclined surface,
A road surface drain pipe (50), which is a bundle pipe, is embedded in one side of the road surface below the road surface,
One or more sloped vertical drain pipes 60, which are the bundle pipes, are embedded in the slopes below the slope so that the rainwater flowing from the ridge drain pipe 40 can be carried to the drain pipe 50,
One or more inclined horizontal drain pipes (70) are installed on the inclined surfaces so as to intersect with the inclined vertical water pipes (60)
The ridge discharge pipe (40), the road surface discharge pipe (50) and the inclined surface vertical discharge pipe (60) are formed in a circular shape in which a plurality of S-shaped pipes (12) are circularly bundled and wrapped with geoscientific fibers A bundle tube 10,
The inclined-surface horizontal drainage pipe 70 is composed of a plate-shaped bundle pipe 20, which is filled with a plurality of S-shaped pipes 12 into one or two or more rows and is wrapped with geosynthetic fibers 14,
Wherein the inclined plane horizontal drain pipe (70) increases in diameter toward the lower side of the inclined plane when two or more inclined plane horizontal drain pipes (70) composed of the plate type bundle pipe (20) are installed. rescue. An inclined drainage structure installed on an inclined plane (S) formed by embankment or cut with a S type drain pipe (SDP) on one side of the road surface,
A ridge drain pipe (40), which is a bundle pipe, is embedded in the upper part of the inclined surface below the inclined surface,
A road surface drain pipe (50), which is a bundle pipe, is embedded in one side of the road surface below the road surface,
One or more sloped vertical drain pipes 60, which are the bundle pipes, are embedded in the slopes below the slope so that the rainwater flowing from the ridge drain pipe 40 can be carried to the drain pipe 50,
One or more inclined horizontal drain pipes (70) are installed on the inclined surfaces so as to intersect with the inclined vertical water pipes (60)
A plurality of S-shaped pipes 12 are concentrated in a circular shape, and the geomorphic pipes 14, the road surface water pipe 50, the sloped surface vertical water pipe 60 and the sloping horizontal water pipe 70, And a circular tube bundle (10) embedded in a wrapped circular form,
In the case where two or more sloping horizontal drain pipes 70 made of the circular pipe bundle 10 are installed, the diameter of the sloping horizontal pipe 70 increases toward the lower part of the sloped surface, And the horizontal drain pipes (70) are connected to each other by a connecting joint (72). The method according to any one of claims 1 to 3,
When the retaining wall P is provided on one side of the road surface, an upright drainage pipe 65 is provided on the retaining wall P so that the rainwater flowing from the inclined-surface vertical drainage pipe 60 can be carried to the roadside drainage pipe 50. [ Lt; RTI ID = 0.0 >
Wherein the upright drain pipe (65) comprises the circular pipe bundle (10). An inclined drainage structure installed on an inclined plane (S) formed by embankment or cut with a S type drain pipe (SDP) on one side of the road surface,
A ridge drain pipe (40), which is a bundle pipe, is embedded in the upper part of the inclined surface below the inclined surface,
A road surface drain pipe (50), which is a bundle pipe, is embedded in one side of the road surface below the road surface,
A plurality of inclined surface inclined water pipes 65 and 75 are installed on the inclined surface so as to cross each other in an oblique direction so as to simultaneously transport the rainwater flowing from the ridge discharge pipe 40 and the rainwater flowing from the inclined surface to the road surface water pipe 50
The ridge discharge pipe 40 and the road surface discharge pipe 50 are constituted by a circular bundle tube 10 in which a plurality of S-shaped pipes 12 are circularly bundled and embedded in a circular shape wrapped with geoscientific fibers 14 Wherein the sloping drainage structure is constructed by using a bundle tube. The method of claim 5,
Wherein the inclined surface inclined water draining pipes (65, 75) are formed of a perforated pipe (30). The method of claim 5,
Wherein the inclined tilted drain pipes (65, 75) are formed of a plate-shaped bundle pipe (20). The method of claim 5,
Wherein the slope inclined drain pipes (65, 75) are formed of a circular pipe bundle (10).

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