KR20110088785A - Roael drainage system for permeable pavement - Google Patents

Abstract

PURPOSE: A drainage system for a drainage asphalt road is provided to rapidly discharge rainwater absorbed to a permeable asphalt concrete surface layer of an asphalt road to the outside. CONSTITUTION: A drainage system for a drainage asphalt road comprises a drainage asphalt road and a lateral water pipe(10). The drainage asphalt road comprises an impermeable base layer(200) and a permeable asphalt concrete surface layer(300). The lateral water pipe has a bottom part(12) and side parts(13,14). The side parts are extended from both sides of the bottom part along the longitudinal direction of an asphalt road.

Description

Drainage system for drainage pavement {Roael drainage system for permeable pavement}

The present invention relates to a drainage system capable of quickly discharging rainwater absorbed by the permeable asphalt concrete surface layer on the drainage pavement.

The drainage pavement is generally composed of an impermeable base layered with an asphalt mixture on a roadbed and a porous permeable asphalt concrete surface layer on the impermeable base layer. In this drainage pavement, rainwater falling on the road surface in rainy weather is absorbed by the permeable surface layer so that rainwater does not stay on the road surface. The rainwater penetrated into the permeable surface layer is discharged to the outside through a separate component installed in the permeable asphalt concrete surface layer.

1 and 2 illustrate a drainage system already installed and used in a drainage pavement, FIG. 1 is a plan view of a drainage screen for drainage pavement according to the prior art, and FIG. 2 is a line II-II of FIG. A schematic cross section of the drain screen according to the present invention.

The drainage pavement of the prior art is composed of a roadbed 100, an impermeable base layer 200 and a water-permeable asphalt concrete surface layer 300. When rain rain falls on the permeable asphalt concrete surface 300, rainwater is first absorbed by the permeable asphalt concrete surface 300 having excellent porosity, and then the perforated asphalt pipe 310 piped inside the permeable asphalt concrete surface 300 is formed. Collected by means. The rainwater collected by the hole pipe 310 is discharged to the boundary side drain screen 400 installed on both sides of the pavement road along the hole pipe 310. If there is more rainfall than the rainwater that will penetrate into the permeable asphalt concrete surface 300, it flows onto the road surface of the permeable asphalt concrete surface layer 300 to be collected by the drain screen 400 for rain gutters. The rainwater collected by the drain screen 400 may be directly guided to the external water system or may be guided to the external water system through a separate filtration process.

As shown, to bury the perforated asphalt concrete 310 in fluid communication inside the permeable asphalt concrete surface layer 300 in order to discharge the rainwater penetrated into the permeable asphalt concrete surface layer 300 to the outside, for example, the drain screen (400). Bar, the rainwater absorbed into the permeable asphalt concrete surface layer 300 is introduced into the hole tube 310 through a plurality of holes formed on the surface of the hole tube 310. Rainwater introduced into the hole tube 310 is led to the drain screen (400).

Conventional pavement drainage system designed in such a structure is the longer the pipe length of the perforated pipe 310 buried in the permeable asphalt concrete surface layer 300, the more the rainwater absorbed by the permeable asphalt concrete surface layer 300 is collected. can do. However, the piping of the perforated pipe 310 will not only require a considerable work maneuver but also a significant installation cost. In addition, while the rainwater introduced into the perforated pipe 310 may lead to a significant body water phenomenon while being led to the drain screen 400, the drainage time for the body water is also long.

In addition, when used for a long time, the perforated hole in the periphery of the perforated tube 310 is closed with foreign matters to prevent the inflow of rainwater.

Accordingly, the present invention has been made to solve the above-mentioned problems.

An object of the present invention is characterized in that a considerable amount of rainwater absorbed into the permeable asphalt concrete surface layer can be quickly and effectively drained to the side channel.

Conventionally, the present invention removes a plurality of flow tubes installed inside the permeable asphalt concrete surface layer, and instead of the function, the present invention is characterized by improving the existing side aqueduct into a U-shaped drainage channel and installing a drain in the upper side surface of the U-shaped side opening. .

This drain is in fluid communication between the permeable asphalt concrete surface forming the drainage channel and helps the rainwater penetrating the permeable asphalt concrete surface to penetrate the drainage channel toward the side drainage pipe.

According to the description of the present invention, the present invention is provided with a drain hole in the side aqueduct pipe forming a U-shaped drainage channel, the rainwater flowing into the permeable asphalt concrete surface layer is easily discharged to the drainage system consisting of a side channel water pipe through this drain hole It is to be provided.

The present invention can drain rainwater in a short time toward the side aqueduct (U type).

The present invention does not need to bury the perforated pipes that were conventionally installed on the permeable asphalt concrete surface layer has the advantage that can significantly lower the construction cost with the work maneuver during road paving.

In addition, the drainage facility for drainage pavement road according to the present invention can bring about excellent drainage effect by simply forming one or more holes, that is, drainage holes in the upper end of the side aqueduct pipe forming the drainage facility without requiring a separate component, The durability of the maintenance and / or repair of the pavement can be increased.

1 is a plan view of a drain screen for drainage pavement according to the prior art.
FIG. 2 is a schematic cross-sectional view of the drain screen along line II-II of FIG. 1.
3 is a perspective view of a drainage facility for drainage pavement according to the first embodiment of the present invention.
4 is a cross-sectional view of a drainage facility for drainage pavement according to the first embodiment of the present invention.
5 is a cross-sectional view of another drainage system for drainage pavement according to the second embodiment of the present invention.

Now, the drainage pavement drainage system according to the present invention will be described in more detail with reference to the accompanying drawings.

3 and 4 are diagrams schematically showing a drainage facility for drainage pavement according to the first embodiment of the present invention.

As shown, the present invention consists of a boundary side aqueduct 10 and length drainage pavement lengthwise extended to both sides along the longitudinal direction of the pavement to form a boundary of the drainage pavement.

As described, the drainage pavement consists of a roadbed 100, an impermeable asphalt base layer 200, and a permeable asphalt concrete surface layer 300. Such drainage pavements are already well known to those skilled in the art as well known conventional techniques, and detailed descriptions thereof are excluded here for clarity of the features and understanding of the present invention.

In rainy weather, the permeable asphalt concrete surface layer 300 is made of a porous material to quickly absorb rainwater and serves to prevent water film phenomenon on the road surface.

The side aqueduct 10 is formed as a U-shape having a bottom portion 12 and side portions 13 and 14 extending vertically upward from both edges of the bottom portion 12 to act as drainage drainage drains. Helps drainage of excellence. Preferably, the side channel tube 10 further includes a cover 15 covering an upper surface open on the two side portions 13, 14. The cover 15 may prevent the pedestrian or the like from falling into the side aqueduct 10.

Referring to the drawings, the side portions 13 are arranged towards the pavement, while the side portions 14 are arranged towards the road boundary stone 20, for example toward the sidewalk.

The cover 15 may be formed of one or more through holes 151 or a water permeable material. The through hole 151 of the cover 15 may not be completely absorbed by the permeable asphalt concrete surface layer 300, and may direct rainwater flowing through the road surface to the side aqueduct 10.

The side aqueduct 10 is formed on both sides of the drainage pavement is extended long along the longitudinal direction of the pavement. As such, the drainage pavement and the side aqueduct 10 may be disposed adjacent to each other to easily drain the rainwater penetrated or absorbed into the permeable asphalt concrete surface layer 300 of the drainage pavement to the side aqueduct 10.

The present invention was created to drain the rainwater absorbed inside the permeable asphalt concrete surface layer 300 to the side channel waterway 10, for this purpose, the side portion 13 on the top of the side 13 of the side waterway pipe 10 It has a drain hole 131 penetrating. The drain 131 extends along the side portion 13 of the side aqueduct, the length of which extends along the longitudinal direction of the pavement, or arranges a plurality along the longitudinal direction of the side aqueduct 10 on both sides of the drainage pavement. The drain 131 may be spaced at an equal distance as shown, and may be different from each other as needed.

The drain 131 may be formed at the same height as the permeable asphalt concrete surface layer 300, and rainwater received in the permeable surface layer 300 may be introduced into the drain hole 131 to be guided into the side aqueduct 10. In particular, the drain 131 is formed about 5 cm below the top of the side portion (13).

Optionally, the drain 131 is inclined downward at a predetermined angle toward the bottom portion 12 of the side aqueduct 10 to assist inflow into the side aqueduct 10 from the permeable asphalt concrete surface layer 300. Can be.

For reference, the arrow shown in Figure 4 shows the movement path of rainwater, a part of the rainwater is absorbed into the permeable asphalt concrete surface layer 300 is introduced into the side aqueduct 10 through the drain 131 according to the present invention While showing the path, some of the rainwater, that is, the rainwater that has not been absorbed into the permeable asphalt concrete surface layer 300, moves along the road surface of the permeable asphalt concrete surface layer 300 and passes through the through hole or permeable material of the cover 15. It is a diagram illustrating a path flowing into the side channel 10.

5 is a cross-sectional view of another drainage system for drainage pavement according to the second embodiment of the present invention.

Another embodiment of the present invention shown in Figure 5 in the embodiment of the present invention shown in Figure 4 in place of the U-shaped side channel aqueduct 10 of the upper surface is sealed with a ceiling portion 16 covering the upper surface It is similar except that the box-shaped side channel pipe 10 'is provided separately. Accordingly, descriptions of similar or identical components will be omitted herein for the sake of clarity of understanding.

As shown, the side aqueduct 10 'is sealed with a ceiling portion 16 on the upper surface, unlike the side aqueduct 10, it is not necessary to have a cover 15. In addition, the side aqueduct 10 'can be made of the same material (for example, concrete) side and the ceiling to improve the durability.

Optionally, the ceiling 16 may form a plurality of holes (not shown) to induce the stormwater to flow into the side aqueduct.

Drainage for drainage pavement according to the present invention is not limited to the above-described embodiment and the accompanying drawings, it is noted that it can be modified and changed within the scope and scope of the following claims.

10,10 '----- side channel pipe,
20 ----- road boundary stone,
100 ----- roadbed,
131 ----- drain,
200 ----- impermeable substrate,
300 ----- Permeable Asphalt Concrete Surface Layer.

Claims (6)

Drainage pavement roads comprising an impermeable base layer 200 and a permeable asphalt concrete surface layer 300;
A side aqueduct 10 extending longitudinally on both sides along the longitudinal direction of the pavement and having side portions 13 and 14 extending vertically from both edge portions of the bottom portion 12 and the bottom portion 12; In the configured drainage system,
The side part 13 of the side aqueduct 10 has one or more drains 131 along the longitudinal direction of the side aqueduct 10, the drain 131 is the water-permeable asphalt concrete surface layer 300 Drainage for drainage pavement, characterized in that the fluid communication between the side and aqueduct (10).
The drainage system for drainage pavement according to claim 1, wherein the drainage hole (131) is formed at the same height as the permeable asphalt concrete surface layer (300).
The drainage system for drainage pavement according to claim 1, characterized in that the drain hole (131) is inclined downwardly at a predetermined angle toward the bottom portion (12) of the side aqueduct (10).
The drainage system for drainage pavement according to claim 1, wherein the side aqueduct (10) further includes a cover (15) to cover the open upper surface.
5. The drainage system for drainage pavement according to claim 4, wherein the cover (15) forms at least one through hole (151) in its longitudinal direction or is made of a water permeable material.
2. The drainage pavement road according to claim 1, further comprising a box-shaped side channel aqueduct (10 ') integrally provided with a ceiling portion (16) extending between the side portion (14) and the side portion (13). Drainage.

Images