JPH04161539A - Rain water-permeable structure - Google Patents

Abstract

PURPOSE:To permit rain water to permeate into the ground by preventing blinding by soil and sand by a method in which openings are widewardly formed in blocks to position them in the inside of waterway, and rain water outlets leading from a rain water fluidizing chamber to the underground are formed in the innermost part of the blocks. CONSTITUTION:Rain water flowing in a side ditch 1a goes through a side hole 14 into the opening 31 of the rain water fluidizing chamber 30 of a permeating block 3. The rain water is filtered through filters 5 to remove soil and sand from the rain water, The rain water-deprived of soil is partly directed from rain water outlets 35 through the permeating layer 4 into the ground. The blinding by soil of the rain water-permeating and outlets 35 can thus be prevented and the water permeability of the ground can be kept for long periods.

Description

DETAILED DESCRIPTION OF THE INVENTION (Field of Industrial Application) The present invention relates to a rainwater infiltration structure for infiltrating rainwater into the ground from a waterway such as a side gutter.

(Prior art) Conventionally, as a rainwater infiltration structure that allows rainwater to infiltrate into the ground from a side gutter, for example, there is
Publication No. 59-61382, Publication No. 61382-
Various structures are known, such as those described in Japanese Patent No. 55684 and the like.

In these conventional rainwater infiltration structures, a rainwater outflow hole is formed in the side wall of the gutter, and the rainwater in the gutter infiltrates into the ground through this rainwater outflow hole. However, with conventional rainwater infiltration structures, when rainwater in the gutters percolates into the ground through the rainwater outflow holes, the sediment (fine particles) contained in the rainwater also leaks through the rainwater outflow holes. Since rainwater flows underground, the rainwater infiltration areas and rainwater outflow holes become clogged with sediment, which impairs the permeability of rainwater, making it impractical.

The present invention focuses on the above-mentioned conventional problems, and the present invention
The object of the present invention is to provide a rainwater permeation structure that allows rainwater to permeate into the ground from waterways such as side gutters while preventing clogging caused by fine particles.

(Means for Solving the Problems) In order to achieve the above problems, in the rainwater permeation structure of the present invention, a permeation block whose interior is formed as a rainwater flow chamber is buried in the ground adjacent to a waterway, The opening of the rainwater flow chamber is opened horizontally in the infiltration block so as to face the inner surface of the waterway, and a rainwater outflow hole from the rainwater flow chamber to the ground is formed in the deep part of the infiltration block, and The rainwater flow chamber is provided with a filter.

(Function) In the rainwater infiltration structure of the present invention, rainwater flowing in a waterway such as a side gutter flows into the rainwater flow chamber of the infiltration block from the opening and returns to the waterway from the opening again. Some of the rainwater flowing into the area will seep into the ground through the rainwater outflow holes.

In this case, in the present invention, since a filter is provided in the rainwater flow chamber, when rainwater flows into the rainwater flow chamber, the earth and sand (fine particles) contained in the rainwater are filtered by the filter. Sediment will be removed from rainwater.

Since the rainwater outflow hole from the rainwater flow chamber into the ground is formed deep inside the infiltration block, the rainwater outflow hole is filtered as described above and dirt is removed. of rainwater will run off and seep into the ground.

Therefore, rainwater infiltration areas and rainwater outflow holes are covered with sediment (fine particles).
This prevents clogging and maintains the permeability of rainwater into the ground over a long period of time.

Also, due to the inflow of rainwater, sediment is deposited on the bottom of the rainwater flow chamber, but this sediment is carried away into the waterway by the flow of rainwater returning from the rainwater flow chamber to the waterway. This prevents the accumulation of

(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.

Figures 1 and 2 show the rainwater infiltration structure of the first embodiment,
In the figure, 1a is a side gutter serving as a waterway.

The gutter 1a is formed by a gutter block loa whose bottom surface is open by connecting the upper parts of both ends of the left and right side walls 11.11 by beams 12, 12, and this gutter block 10a is installed on the base concrete layer 21. , a bottom concrete layer 22 is formed on the base concrete layer 21. In addition, 13 is a gutter cover.

Further, a horizontal hole 14 is opened in the side wall 11 of the gutter block 10a at the same level as the upper surface of the bottom concrete layer 22, and a penetration block 3 is disposed connected to this horizontal hole 14.

The infiltration block 3 is a reinforced concrete block in the shape of a horizontal box, with a rainwater flow chamber 30 formed inside and an opening 31 of the rainwater flow chamber 3o opened at the front. A horizontal cylindrical body 32 made of a galvanized iron plate is inserted. The front end protrusion of this horizontal cylindrical body 32 is connected to the horizontal hole 14.
By being fitted into the infiltration block 3, the infiltration block 3 is buried horizontally in the ground so that the opening 31 of the rainwater flow chamber 30 faces the inner surface of the gutter 1a.
A permeable layer 4 is formed of chestnut stone 40. Note that 41 is a crusher run layer.

In addition, on the back wall 34 which is the inner part of the infiltration block 3,
Rainwater outflow hole 3 from rainwater flow chamber 30 to underground (permeation layer 4)
5 is formed.

Further, the rainwater flow chamber 30 is provided with a filter 5.5. The filter 5 has a frame covered with a filtration member such as a net or a water-permeable non-woven mat, and in the embodiment, two filters 5, 5 are arranged so as to partition the inside of the rainwater flow chamber 3o into front and back. It is provided.

Next, the operation of the embodiment will be explained.

In the rainwater infiltration structure of this embodiment, rainwater flowing in the side gutter la passes through the side hole 14 into the rainwater flow chamber 3 of the infiltration block 3.
0 from the opening 31 and returns to the gutter 1a from the opening 31 again, and a part of the rainwater that has flowed into the rainwater flow chamber 30 permeates underground from the rainwater outflow hole 35 through the permeation layer 4. I will continue to do so.

In this case, in this embodiment, the filter 5 is installed in the rainwater flow chamber 30.
, 5 are provided, so when rainwater flows into the rainwater flow chamber 30, the sediment (fine particles) contained in the rainwater is filtered by the filters 5, 5, and by passing through the filters 5, 5, the sediment is removed from the rainwater. will be excluded.

Since the rainwater outflow hole 35 from the rainwater flow chamber 3o to the ground is formed in the back wall 34 of the infiltration block 3, the rainwater outflow hole 35 flows through the filter 5 as described above.
, 5, the rainwater that has been filtered by sand and sand flows out and permeates into the ground.

Therefore, rainwater infiltration areas and rainwater outflow holes are covered with sediment (fine particles).
This prevents clogging and maintains the permeability of rainwater into the ground over a long period of time.

Also, due to the inflow of rainwater, sediment will be deposited on the bottom of the rainwater flow chamber 30, but this sediment will be carried by the flow of rainwater returning from the rainwater flow chamber 30 to the side gutter 1a.
Since the rainwater is carried away inside the rainwater flow chamber 30, accumulation of earth and sand is prevented.

In addition, the rainwater that has flowed into the rainwater flow chamber 30 is drained through the rainwater outflow hole 3.
5 to the permeable layer 4 and propagates through the gaps in the chestnut stones 40 forming this permeable layer 4, the range of permeation into the ground is expanded and efficient permeation is possible.

Next, FIG. 3 shows the rainwater permeation structure of the second embodiment.

In this second embodiment, a side gutter 1b serving as a waterway is formed by a U-shaped side gutter block lob.

In this example, the side wall 1 of the U-shaped gutter block 10b
A horizontal hole 14 formed in 1 is opened upward with a height H from the bottom surface. That is, the rainwater in the side gutter 1b is at a height H
If the rainwater exceeds the height H, the rainwater that exceeds the height H will infiltrate into the ground from the rainwater outflow hole 35 (rainwater infiltration function), and the rainwater below the height H will flow down the side gutter 1b and flow into the river etc. be done (
gutter outflow function).

Therefore, in this rainwater infiltration structure, by providing the height H, the gutter outflow function is normally ensured (below the height H), but when the amount of rainfall is large due to heavy rain (height H or more), the rainwater infiltration function is ensured. This allows rainwater in the gutter lb to permeate into the ground, suppressing rainwater outflow into the river and preventing river flooding.

Further, by providing the height H, the earth and sand flowing at the bottom of the side gutter 1b is stopped by the height H, so that it is possible to prevent the earth and sand from flowing into the rainwater flow chamber 30.

Furthermore, an eaves section 36 is extended at the upper end of the infiltration block 3 so as to cover the infiltration layer 4, and this eaves section 36 prevents earth and sand from collapsing into the infiltration layer 4 from the upper stratum. It is possible to prevent the permeable layer 4 from being clogged with earth and sand, and the load from the road surface can be supported by the eaves 36.

Note that reinforcing bars are embedded inside the eaves portion 36 to ensure strength.

Moreover, a net 7 or a water-permeable sheet is stretched between the permeable layer 4 and the geological layer 6 to prevent landslides from the geological layer 6.

Next, FIG. 4 shows the rainwater permeation structure of the third embodiment.

In this third embodiment, an underdrain 1c serving as a waterway is formed by an underdrain block 10c.

Further, the bottom surface 37 of the rainwater flow chamber 30 is formed to slope upward from the opening 31 toward the back.

Therefore, when rainwater flows into the rainwater flow chamber 30, the dirt contained in the rainwater gradually accumulates on the bottom surface 37 of the rainwater flow chamber 30 as it goes deeper into the rainwater flow chamber 30. are being eliminated. Sediment is removed from the rainwater outflow hole 35 by the slope of the bottom surface 37 as described above, and the rainwater with the sediment removed by the filters 5, 5 flows out and permeates into the ground. As a result, clogging due to earth and sand is further prevented.

Also, a slit hole 39.3 is provided in the upper wall 38 of the penetration block 3.
9 is formed, and by inserting the filters 5, 5 into this slit hole 39, the filters 5.5 can be replaced. In this case, a cylindrical block 8 is installed on top of the infiltration block 3, the interior of the cylindrical block 8 is a work space 80, and a lid 81 is provided on the top surface so as to be flush with the road surface 9. ing.

Therefore, when replacing the filters 5, 5, it is sufficient to remove the lid 81 and replace the filters 5, 5 from the work space 80.

Although 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 embodiments described above.

For example, as shown in the embodiment, the water channel may be a side gutter or a culvert, or the side gutter may be a three-sided gutter cast on site.

In addition, as a filter, water permeable non-woven mats, nets,
Any material may be used as long as it has a filtering function for earth and sand (fine particles), such as a water-permeable sheet, a loofah-like mat made of synthetic fibers, etc. alone or in combination (overlapping, sandwich, etc.). For example, Tijin chemical filter (
Sandfu U type and Keeper), Tijin's polyester yarn water-permeable sheet, Tijin's Endrenmat, etc. can be used. Further, in the case of a water-permeable non-woven fabric mat, the appropriate water permeability coefficient is considered to be 0.1 to 4.0 cm/S, and in the case of a net, the appropriate mesh size is considered to be 20 μ to 2 mm.

In addition, the number of filters installed in the rainwater flow room may be one or two or more, and in the case of multiple filters, each filter should be of the same type (
For example, water-permeable non-woven mats) or different types (for example, water-permeable non-woven mats and nets) may be used.In this case, from the front to the back of the rainwater flow chamber, from the filter with high water permeability to the filter with low water permeability. Arrange filters in order.

Further, the rainwater outflow hole is not limited to the inner wall of the infiltration block, but may be formed in the bottom wall or side wall of the infiltration block as long as it is deep inside the infiltration block.

Also, infiltration blocks may be installed on both sides of the waterway to allow rainwater to infiltrate from both sides of the waterway.

Additionally, a filter material may be installed in the rainwater outflow hole; in this case,
A net, a water-permeable nonwoven mat, or the like may be placed on the inner or outer surface of the back wall of the infiltration block where the rainwater outflow hole is formed.

(Effects of the Invention) As explained above, in the rainwater infiltration structure of the present invention, the rainwater outflow hole is formed in the deep part of the infiltration block,
Before reaching the rainwater outflow hole, the filter filters out the earth and sand (fine particles) contained in the rainwater, allowing the rainwater with the earth and sand removed to permeate into the ground.

In addition, the sediment deposited on the bottom of the rainwater flow chamber is carried away into the waterway by the flow of rainwater returning from the rainwater flow chamber to the waterway, so it is possible to prevent sediment from accumulating within the rainwater flow chamber.

In this way, the rainwater in the waterway filters out the sediment and permeates into the ground, and since there is no accumulation of sediment in the rainwater flow chamber, clogging of the rainwater infiltration area and the rainwater outflow hole by sediment is prevented. The effect is that the permeability of rainwater into the ground can be maintained for a long period of time.

[Brief explanation of the drawing]

FIG. 1 is a longitudinal cross-sectional view showing the rainwater permeation structure of the first embodiment, FIG. 2 is a perspective view of the rainwater permeation structure, FIG. 3 is a cross-sectional view showing the rainwater permeation structure of the second embodiment, and FIG. The figure is a sectional view showing the rainwater permeation structure of the third embodiment. 1a: Side gutter (waterway) ■b = Side gutter (waterway) 1c: Underdrain (waterway) 3: Penetration block 30: Rainwater flow chamber 31: Opening 34: Back wall (back) 35: Rainwater outflow hole 5: Filter

Claims (1)

[Scope of Claims] 1) An infiltration block whose inside is formed as a rainwater flow chamber is buried underground adjacent to a waterway, and the opening of the rainwater flow chamber is arranged so as to face the inner surface of the waterway. A rainwater infiltration system characterized in that a rainwater flow hole is opened horizontally in the infiltration block, a rainwater outflow hole from a rainwater flow chamber into the ground is formed in the deep part of the infiltration block, and a filter is provided in the rainwater flow chamber. structure.