JP2006328640A - Culvert drainage structure and rainwater penetration treating method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a culvert drainage structure applicable to the peripheries of exercise grounds of school gardens and facilities of parks and capable of collecting and rapidly penetrating rainwater into an underground and a rainwater penetration treating method. <P>SOLUTION: This culvert drainage structure is so formed that a plurality of triplet basins 3 comprising two catch basins 1 and 1 and a center basin 2 are installed in a drain passage 5 disposed around an effective use surface 4. In the catch basins 1 and 1 positioned at the front and rear of the triplet basin 3, sand and mud contained in water flowing therein are precipitated to its bottom part 6, and the supernatant is moved to the center basin 2 positioned between the catch basins 1 and 1. An outflow pipe 13 is connected to the side face of the center basin 2, and water flows from the outflow pipe 13 to an underground penetration layer 12 formed under the effective use surface 4. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to an underdrain drainage structure and a rainwater infiltration treatment method that can be applied to, for example, the surroundings of exercise grounds such as school grounds and facilities such as parks, and can collect rainwater and promptly infiltrate it underground.

  Rainwater permeates from the ground surface into the ground in facilities such as exercise grounds such as schoolyards and parks, but underwater drainage with various structures is constructed around it in case of a large amount of rainwater due to typhoons, etc. Yes. That is, such underdrainage has the advantage that it can prevent the formation of mud and water pools in schoolyards and the like even during heavy rain, and can quickly resume the use of schoolyards and the like.

  In addition, by providing such underdrainage and infiltrating or storing rainwater underground, it can contribute to a reduction in the amount of drainage in the waterworks. As a result, for example, clogging of drainage channels, resulting in flooding of main roads, or the amount of water in rivers Flooding due to increase can be prevented.

As mentioned above, constructing drainage drainage around schoolyards, parks, etc. has extremely excellent effects in various areas such as urban environment maintenance, especially when the drainage drainage is huge, for example. There was a problem that it would erode (inhibit) a surface that is effectively used as an exercise ground.
Therefore, an object of the present invention is to propose a culvert drainage structure that can collect rainwater and promptly infiltrate it underground without impeding its effective use.

  The present invention has been proposed in view of the above, and in a drainage channel disposed around the effective use surface, a plurality of triple watersheds composed of two water collecting wells and a central waterhole are installed. The drainage basin located at the front and back is provided with a communication port at a position higher than the bottom of the surface in contact with the central basin, and an effluent pipe is connected to the side of the central basin located between the basins. The present invention relates to a culvert drainage structure characterized by being connected to an underground infiltration layer provided in the basement of the effective use surface.

  In the culvert drainage structure, it is desirable that the outflow pipe is inclined downward toward the underground infiltration layer, the base end side is a non-porous pipe, and the front end side is a perforated pipe.

  The present invention also proposes a rainwater infiltration treatment method using the underdrain drainage structure described above, in which rainwater is caused to flow from the drainage channel into the catchment basin. The sand and mud contained in the ground are settled at the bottom, the supernatant water is overflowed to the central wall located between the water collecting basins, and the underground pipe provided under the effective use surface from the outflow pipe connected to the central basin. Water is allowed to flow into the permeation layer.

The underdrain drainage structure and rainwater infiltration method of the present invention collects rainwater, etc. by a plurality of triple fences installed in drainage channels around the effective use surface of, for example, an exercise ground such as a schoolyard or a park. Water is drained to the base of the effective use surface, and the upper surface (lid part) of the triple fence is only exposed on the ground surface along the drainage channel, so that the effective use surface is obstructed. However, rainwater can be collected and promptly infiltrated into the basement.
In addition, rainwater flowing in from the front and rear of the triple fence is collected in each catchment basin where sand and mud settle, and the supernatant water moves to the central basin. Water can be discharged to the underground infiltration layer by the outflow pipe, and the outflow pipe and the underground infiltration layer are not clogged.

  When the outflow pipe is inclined downward toward the underground infiltration layer, the base end side is a non-perforated pipe, and the tip end side is a perforated pipe, the rainwater sent from the triple basin reaches the perforated pipe when it reaches the perforated pipe. It will flow into the seepage layer and penetrate into the basement.

  The triple fence used in the underdrain drainage structure and rainwater seepage treatment method of the present invention is composed of two drainage tanks and a central tank, and the drainage tank arranged so as to be in contact with the drainage channel is inflowing rainwater. The sand and mud contained in the water is allowed to settle to the bottom, and the supernatant water overflows to the central trough. At the central trough, the water flows out from the outflow pipe to the underground infiltration layer provided on the effective use surface. And method.

  The drainage basin constituting the triple basin is provided with an inflow port at a position higher than the bottom portion on the surface side in contact with the drainage channel, and a communication port is provided at a position higher than the bottom portion on the surface side in contact with the central basin. Therefore, sand or mud contained in rainwater or the like flowing in from the inflow port can be settled to the bottom, and the supernatant water can be overflowed from the communication port and transferred to the central trough.

  Moreover, the above-mentioned connecting port is provided in the front and rear surfaces in contact with the catchment basin, and the outflow pipe is connected to the side surface on the effective use surface (underground permeation layer) side. Therefore, the water overflowed from the two catchment basins can be discharged from the outflow pipe to the underground infiltration layer.

Hereinafter, the underdrainage structure of the present invention will be described based on the illustrated embodiments.
In the underdrain drainage structure of the illustrated embodiment, a triple fence 3 having a structure consisting of a catchment tank 1-a central fence 2-a catchment tank 1 shown in FIG. 1 is used as an effective use surface 4 such as an exercise ground as shown in FIG. A plurality of drainage channels 5 are provided at appropriate intervals in the drainage channel 5 disposed around the.

  As shown in FIG. 1, the triple reed 3 is a precast concrete product having a shape in which three reed portions 1, 2, 1 deeper than the drainage channel 5 are connected in series. Arranged in a shape. That is, the triple water tank 3 is disposed so that the water collecting water bottle 1 is positioned so as to be continuous with the drainage channel 5.

  In the water collecting basins 1 and 1 located at both ends of the triple basin 3, an inlet 7 is provided at a position higher than the bottom 6 on the surface side in contact with the drainage channel 5, and a screen 8 is arranged at the tip of the inlet 7. Has been. In addition, a communication port 9 is provided at a position higher than the bottom 6 on the surface side in contact with the central rod 2, and a screen 10 is arranged in the communication port 9. Further, a grating lid 11 is disposed at the upper end of the opening. The screens 8 and 10 are detachable reticulated materials like the grating lid 11 and function to prevent large diameter stones or dust from entering.

  The central port 2 located at the center of the triple shaft 3 is provided with the connecting port 9 on the front surface and the rear surface in contact with the water collecting rods 1, 1, and on the side surface on the side of the effective use surface 4 (underground permeation layer 12). The outflow pipe 13 is connected. A concrete lid 14 is disposed at the upper end of the opening. A filter (not shown) is attached to the outflow pipe 13 to prevent entry of fine mud or the like.

  The outflow pipe 13 extending from the central trough 2 is disposed so as to incline downward toward the underground infiltration layer 12 formed in the basement of the effective use surface 4 as shown in FIG. 2 and FIG. 13a, the tip side is a perforated pipe 13b. The perforated pipe 13b on the distal end side is disposed so as to be located in the underground infiltration layer 12.

  The structure of the underground infiltration layer 12 is not particularly limited, and may be a simple gravel layer or a layer having a water storage function.

In the underdrain drainage structure having such a configuration, rainwater is infiltrated underground with the following system.
Rainwater penetrates directly into the basement from the effective use surface 4 such as an athletic ground. However, during heavy rain, a large amount of rainwater is guided to the drainage channel 5 by the slope of the ground surface or the like.

  The rainwater guided to the drainage channel 5 flows from the drainage channel 5 into the catchment basin 1 and 1 through the inlet 7 as indicated by an arrow in FIG. In the illustrated embodiment, since the screen 8 is disposed at the tip of the inflow port 7, even if stones, dust, or the like flows together from the ground surface, it does not enter the catchment 1.

  In the water collecting tanks 1, 1, sand and mud contained in the flowing-in water are settled to the bottom part 6, and the supernatant water is allowed to overflow into the central tank 2 from the connection port 9. In the illustrated embodiment, since the screen 10 is arranged at the communication port 9, the leaves of plants floating in the supernatant water do not enter the central basket 2.

  In the central wall 2, water flows out from the outflow pipe 13 to the underground permeation layer 12 provided in the basement of the effective use surface 4. In the illustrated embodiment, since a filter is attached to the base end of the outflow pipe 13, fine mud or the like is not sent to the underground infiltration layer 12.

  And since the rainwater sent to the underground infiltration layer 12 does not contain large stones and trash and fine mud etc., the infiltration into the underground is continued without blocking the underground infiltration layer 12.

  For maintenance, remove the grating lid 11 of the catchment basin 1 and 1 periodically or at an appropriate time to remove solids such as stones, dust and leaves collected on the screens 8 and 10, and sand or mud that has settled to the bottom. Can be removed. It is not necessary to remove the concrete lid 14 of the central ridge 2.

  The present invention has been described based on the embodiments. However, the present invention is not limited to the above-described embodiments, and can be implemented in any manner as long as the configuration described in the claims is not changed.

  It can be used as a culvert drainage structure installed for the purpose of infiltrating rainwater into the ground in facilities such as exercise grounds such as schoolyards and parks.

It is a sectional side view which shows the triple fence used for the underdrain drainage structure of this invention. It is a top view of the underdrain drainage structure which has arranged the triple fence of FIG. It is sectional drawing which shows the arrangement | positioning condition of the outflow pipe extended from a triple fence.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Catchment basin 2 Central gutter 3 Triple gutter 4 Effective use surface 5 Drainage channel 6 Bottom part 7 Inlet 8 Screen 9 Connection port 10 Screen 11 Grating lid 12 Underground penetration layer 13 Outflow pipe 13a Non-perforated pipe 13b Perforated pipe 14 Concrete lid

Claims (3)

  Multiple drainage basins composed of two drainage basins and a central basin are installed in a drainage channel arranged around the effective use surface, and the basins located before and after the triple basin are located at the central basin. A communication port is provided at a position higher than the bottom of the contact surface side, and an outflow pipe is connected to the side surface of the central trough located between the water collecting troughs. Underdrain drainage structure characterized by being connected to the strata.   The underdrain drainage structure according to claim 1, wherein the outflow pipe is inclined downward toward the underground infiltration layer, the base end side is a non-porous pipe, and the tip end side is a perforated pipe.   The underdrain drainage structure according to claim 1 or 2 is installed, rainwater is allowed to flow from the drainage channel into the catchment basin, and in the catchment basin, sand or mud contained in the inflowing water is allowed to settle to the bottom. The rainwater is characterized by overflowing the supernatant water into a central trough located between the water collecting troughs and allowing water to flow out from an outflow pipe connected to the central trough to an underground infiltration layer provided in the basement of the effective use surface Infiltration treatment method.

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