JPH03290540A - Rainwater penetrative structure - Google Patents

Abstract

PURPOSE:To expand a penetrating range of rainwater by forming a rainwater outflow port in a puddling block in the midway of a side groove, installing a rainwater penetrating layer continuously in the ground in surface form, and forming an impermeable layer in space between the rainwater penetrating layer and its upper layer. CONSTITUTION:An asphalt layer 11 for a rod surface 10 is formed on a bedding layer 12 of a pavement 1, while a puddling block 3 is installed in the midway of an L-shaped side groove 20 installed in the shoulder, and a rainwater inflow port 30 is installed on the top, closing the bottom surface. In addition, a lower side water storage part 31 is set down to a stepped cylindrical block made up of widening an upper side inflow part 32, thereby installing a grating cover 33 in the inflow port 30. Then, a side rainwater outflow port 35 is installed in a side wall 34 of the lower layer storage part 31, and a concrete layer 60 as an impermeable layer is formed in an interval between a rainwater penetrating layer 4, where macadam 40 is laid down in surface form on an underground penetrative bedding layer 7, and its upper layer. With this constitution, the extent of penetrability in the rainwater is maintainable over a long period of time.

Description

DETAILED DESCRIPTION OF THE INVENTION (Industrial Application Field) The present invention relates to a structure for allowing rainwater to permeate into the ground from a basin block disposed in the middle of a side gutter.

(Prior art) Conventionally, as a rainwater infiltration structure that allows rainwater to infiltrate into the ground from a basin block placed in the middle of a side gutter, for example, there is a structure described in Japanese Utility Model Application Publication No. 171981/1981. something is known.

This conventional source shows a rainwater infiltration structure in which a rainwater outlet is formed at the bottom of the basin block.

Therefore, in this rainwater infiltration structure, rainwater flowing into the basin block permeates into the ground through the rainwater outlet at the bottom.

(Problem to be solved by the invention) However, in the conventional rainwater infiltration structure, the infiltration range is within the opening area of the rainwater outlet, so the infiltration does not spread, and the rainwater infiltration range is narrow. There was a problem that it became.

Therefore, in order to widen the range of rainwater infiltration, it is possible to form a rainwater infiltration layer in the ground in a planar shape, but in this case, the rainwater infiltration layer is caused by the soil from the upper stratum collapsing into the rainwater infiltration layer. The problem arises that the layers become clogged.

As a means for preventing clogging of the rainwater infiltration layer due to falling of earth and sand, for example, Japanese Patent Application Laid-Open No. 59-15084
As described in Publication No. 0, there is a technique of providing a water-permeable sheet between a rainwater permeation layer and the stratum above it.

However, although this permeable sheet can certainly prevent soil from collapsing from the upper strata, it literally
Because it has water permeability, rainwater flowing through the rainwater permeable layer will flow between the upper stratum and the upper stratum through this water permeable sheet.

In this way, when rainwater flows between the rainwater infiltration layer and the stratum above it, when the rainwater that has flowed from the rainwater infiltration layer to the upper stratum flows back into the rainwater infiltration layer, the amount of water contained in the rainwater increases. Fine earth and sand will be carried into the rainwater infiltration layer from the upper strata, and in the long term, this problem will cause the rainwater infiltration layer to become clogged.

This problem cannot be solved as long as rainwater flows between the rainwater infiltration layer and the stratum above it, and conventional permeable sheets have always had the problem of clogging of the rainwater infiltration layer. It was left behind.

Therefore, in order to repair the clogging of this rainwater permeation layer, it is necessary to dig up the ground and rebuild the rainwater permeation layer, spending a lot of money, effort, and time, and to prevent clogging of this rainwater permeation layer. The major challenge for practical application is to do so.

The present invention focuses on the conventional problems as described above.

The object of the present invention is to provide a rainwater infiltration structure which can widen the infiltration range and completely prevent clogging of the rainwater infiltration layer by earth and sand in the upper stratum.

(Means for Solving the Problems) In order to achieve the above-mentioned problems, in the rainwater infiltration structure of the present invention, a rainwater outflow port is formed in a basin block arranged in the middle of a side gutter, and the rainwater outflow port is A rainwater infiltration layer is formed in a planar shape in the ground continuously, and an impermeable layer is formed between the rainwater infiltration layer and the stratum above it.

(Function) In the rainwater permeation structure of the present invention, rainwater that has flowed into the basin block flows into the rainwater permeation layer through the rainwater outlet.

The rainwater that flows into the rainwater infiltration layer from the rainwater outlet is
Rainwater permeates into the ground while propagating through this rainwater permeation layer. In this case, since the rainwater permeation layer is formed into a planar shape underground, the range of permeation into the ground becomes significantly wider.

Therefore, rainwater can permeate through the rainwater permeation layer evenly and permeate into the ground over a wide area.

An impermeable layer is formed between the rainwater infiltration layer and the stratum above it, so this impermeable layer prevents soil from falling down from the stratum above it, and this impermeable layer also prevents rainwater from falling. This is because the flow of rainwater between the permeable layer and the strata above it is blocked.

Sediment from the upper stratum is not carried into the rainwater permeation layer by rainwater, and clogging of the rainwater permeation layer by sediment from the upper stratum can be completely prevented.

(Example) Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

First, the configuration of the embodiment will be explained.

FIG. 1 shows the rainwater infiltration structure of the first embodiment, and 1 in FIG. 1 is a paved road.

The paved road 1 has an asphalt layer 1 forming a road surface 10.
1 is formed on the base layer 12, a 1-shaped gutter 20 is provided on the shoulder of the road, and a sump block 3 is provided in the middle of the curvature-shaped gutter 20. Note that the road surface 10 is formed with a slight downward slope from the center toward both sides.

The base layer 12 serves as a roadbed for the asphalt layer 11, and is formed by laying a crusher run under the asphalt layer 11 and compacting it. Note that this base layer 12 is formed on a base layer that is used in a normal road structure, such as forming an upper base course by crusher run on a lower base base made of incised crushed stone or granular crushed stone to form two layers. Ru.

The basin block 3 is formed into a stepped cylindrical block with a rainwater inlet 30 formed on the upper surface, a closed bottom surface, and a lower water storage section 31 wider than the upper inflow section 32. . Incidentally, the rainwater inlet 30 is provided with a grating lid 33.

Further, a side rainwater outlet 35 is formed in the side wall 34 of the lower water storage part 31 of the basin block 3 in the middle in the depth direction, and a rainwater infiltration layer is formed continuously to the side rainwater outlet 35. 4 is formed in the ground in a plane shape, so that rainwater in the basin block 3 flows into the rainwater permeation layer 4 through the side rainwater outlet 35. In addition, the side rainwater outlet 3
5 is covered with the filter 5 from the inner surface side of the side l1134.

The rainwater permeation layer 4 is formed by laying crushed stones 40 (approximately 20 m to 50 m) in a planar shape on the underground permeation layer 7, and is formed over almost the entire area under the road.

Moreover, a concrete layer 60 as an impermeable layer is formed between the rainwater permeable layer 4 and the base layer 12 which is the upper stratum.

The concrete layer 60 is cast on-site on the rainwater permeation layer 4, and this concrete layer 60 prevents soil from collapsing from the base layer 12 to the rainwater permeation layer 4, and also prevents the rainwater permeation layer 4 and the base layer from collapsing. The flow of rainwater between 12 and 12 is cut off.

Next, the operation of the embodiment will be explained.

In the rainwater infiltration structure of this embodiment, rainwater that has flowed into the basin block 3 from the single-character side gutter 20 is stored in the lower water storage section 31, and when it reaches the side rainwater outflow port 35, the rainwater flows into the filter 5.
The rainwater flows into the rainwater infiltration layer 4 from the side rainwater outflow port 35 through the rainwater.
removed by

The rainwater that has flowed into the rainwater infiltration layer 4 from the side rainwater outflow outlet 35 penetrates into the underground infiltration layer 7 through this rainwater infiltration layer 4. In this case, the rainwater infiltration layer 4 is underground. Since it is installed in a planar manner, its penetration range is wide. Furthermore, since the rainwater permeation layer 4 is formed of crushed stones 40, the voids are large, and rainwater can smoothly propagate through the rainwater permeation layer 4.

Therefore, the rainwater permeates through the rainwater permeation layer 4 evenly, and the rainwater can permeate into the permeation layer 7 in the ground over a wide range.

In addition, the rainwater permeation layer 4 and the base layer 12 which is the geological layer above it.
Since the concrete layer 60 as an impermeable layer is formed between the base layer 12 and the rainwater infiltration layer 4, it is possible to prevent soil from collapsing from the base layer 12 to the rainwater permeation layer 4.

Note that if the concrete layer 60 is not provided or if a permeable layer is provided instead of the concrete layer 60, the rainwater flowing through the rainwater permeation layer 4 will flow through the rainwater permeation layer 4.
From there, it also penetrates into the underlying layer 12, which is the upper stratum. In this way, if rainwater permeates into the base layer 12, the rainwater that returns from the base layer 12 to the rainwater permeation layer 4 will contain the soil in the base layer 12, so in the long run, the rainwater permeation layer 4 becomes clogged with the earth and sand of the base layer 12, resulting in a problem that rainwater permeation function cannot be obtained.

On the other hand, when an impermeable layer is formed by the concrete layer 60 as in this embodiment, the concrete layer 60 blocks the flow of rainwater between the rainwater permeation layer 4 and the base layer 12, Since rainwater does not permeate into the base layer 12, the rainwater does not contain the earth and sand of the base layer 12.

Therefore, clogging of the rainwater permeation layer 4 due to the earth and sand of the base layer 12 can be prevented.

Next, FIG. 2 shows the rainwater permeation structure of the second embodiment.

In this second embodiment, a basin block 3 is provided in the middle of the U-palm side groove 21, the bottom of this basin block 3 is opened as a bottom rainwater outlet 36, and the rainwater flows continuously to the bottom rainwater outlet 36. This is an example in which a permeable layer 4 is formed, and a synthetic resin sheet 61 as an impermeable layer is provided between the rainwater permeable layer 4 and a base layer 12 which is a geological layer above the rainwater permeable layer 4.

Therefore, rainwater flowing into the storage block 3 from the U palm side groove 21 flows into the rainwater permeation layer 4 from the bottom rainwater outlet 36, and permeates into the underground permeation stratum 7 through the rainwater permeation layer 4.

Further, the collapse of earth and sand from the base layer 12 to the rainwater permeable layer 4 and the flow of rainwater between the rainwater permeable layer 4 and the base layer 12 are prevented by the synthetic resin sheet 6l as an impermeable layer.

Note that the other configurations and operations are the same as those of the first embodiment, so the reference numerals in the drawings are the same and the explanation thereof will be omitted.

The embodiments of the present invention have been described above with reference to the drawings.

The specific configuration of the present invention is not limited to the above embodiments.

For example, in addition to crushed stone, the rainwater infiltration layer can also be made of sand, chestnut stone, weed, etc.
It may be formed from coral, other well-drained soil, etc.

Further, the impermeable layer is not limited to a concrete layer or a synthetic resin sheet, but may also be a concrete plate 1, a synthetic resin plate, or other sheets or plates that do not have water permeability.

Further, the rainwater permeation structure of the present invention may be formed entirely or partially underground under a paved road, or may be formed not only under a paved road but also on an unpaved road, parking lot, ground, park, etc. can be formed underground.

(Effects of the Invention) As explained above, in the rainwater infiltration structure of the present invention, the rainwater infiltration layer is formed in a planar shape underground.
Although it is a structure in which rainwater infiltrates from a narrow area called a sump block, it can allow rainwater to penetrate into a much wider area than conventional rainwater infiltration structures.

In addition, in order to deal with the problem caused by installing the rainwater permeation layer underground, that is, the clogging of the rainwater permeation layer by the sediment in the stratum above the rainwater permeation layer, Since an impermeable layer is formed in the area, it is possible to prevent soil from collapsing from the upper stratum to the rainwater permeation layer, and it is also possible to prevent soil from the upper stratum from being carried into the rainwater permeation layer by rainwater. Therefore, it is possible to prevent clogging of the rainwater permeable layer caused by the earth and sand in the upper stratum, and it is possible to maintain the permeability of the rainwater permeable layer over a long period of time.

[Brief explanation of drawings]

Figure 1 is a sectional view showing the rainwater infiltration structure of the first embodiment;
The figure is a sectional view showing the rainwater permeation structure of the second embodiment. 12: Base layer (upper stratum) 20: 1-shaped side gutter (side gutter) 3: Reservoir block 35: Side rainwater outlet (rainwater outlet) 4: Rainwater permeation layer 60: Concrete layer (impermeable layer) 21: U Palm side gutter (side gutter) 36: Bottom rainwater outlet (rainwater outlet) 61: Synthetic resin sheet (impermeable layer)

Claims (1)

[Claims] 1) A rainwater outflow outlet is formed in a sump block placed in the middle of the side gutter, and a rainwater infiltration layer is formed in the ground in a planar shape continuous with the rainwater outflow outlet, and the rainwater infiltration layer and its A rainwater infiltration structure characterized by an impermeable layer formed between the upper stratum.