JP3363805B2 - Rainwater storage infiltration structure - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a rainwater storage and infiltration structure for storing rainwater underground, and more specifically, it is a public facility such as a building, a road, a waterway, a park, a playground, or a factory. The present invention relates to a rainwater storage and infiltration structure that can be constructed on the site, and even on the site of each household.

[0002]

Most of the conventional rainwater penetrates into the ground,
In addition, it becomes groundwater, and the rainwater is retained in various forms throughout the soil, supplies the water necessary for growing trees, etc., and when it is hot, evaporates from the surface of the soil to regulate the temperature of the surface of the earth, It also had the effect of adjusting the amount of water.

However, with the recent rapid land development and the progress of paving roads, the number of buildings and paved roads has increased,
The amount of exposed soil in sports grounds, factories, etc. is decreasing, and rainwater is discharged into drains and rivers through drainage channels without penetrating into the ground, resulting in the following problems. (1) Reduction and depletion of groundwater, and accompanying ground subsidence. (2) The heat island phenomenon, which occurs because heat from the ground cannot be removed due to the heat of vaporization that accompanies the evaporation of water, becomes noticeable. (3) As a result of storm water concentrating on sewers and rivers at once, floods and floods occur in these rivers and sewers.
Or the necessity of construction such as river improvement and sewer extension to prevent such a situation occurs.

As a method of solving these problems, there is known a method of excavating the ground to dig a hole, provide a rainwater storage and infiltration structure, construct a park or road on the structure, and provide a building. The following two types are known as such rainwater storage and infiltration structures. (B) A tank made of reinforced concrete is formed as the water-blocking material layer, and one side having a void of about 80% is 1.2
The concrete blocks of up to m are stacked and accommodated.
A structure made by the concrete unit construction method in which a soil layer is further provided on top of a lid layer to form a park (Nikkei Construction, March 13, 1998). (B) A tank is formed by using a waterproof sheet as the water-blocking material layer, and the upper surface having about 95% of voids is 360 in the tank.
mm × 360 mm, bottom surface 270 mm × 270 mm, height 260 mm, and pyramidal trapezoidal polypropylene basket-shaped hollow blocks are stacked and accommodated to form a water storage layer, and a lid layer is provided, and then a soil layer is further formed. Shinshin block method to be established (Forest Product Catalog).

However, according to the concrete unit construction method, since the concrete block has a high weight, it is indispensable for the water-impervious material layer to have its foundation made of high-strength reinforced concrete, which is required for construction. It will take a long time. As a result, the construction cost is high as a whole, and a heavy machine is required to store a heavy concrete block when constructing a reservoir, and the heavy machine parking space is required.
It cannot be used for 100% and its rainwater storage capacity is limited.

On the other hand, according to the Shinshin block method, the compressive strength of the polypropylene (PP) cage hollow block is not sufficient, and as described in the above catalog, the PP blocks are stacked with the water storage layer having a depth of more than 3 m. Therefore, rainwater storage capacity per site area will be limited. In addition, the durability of PP in the soil such as microbial deterioration is not so sufficient.

An object of the present invention is to provide a rainwater storage / infiltration structure which is easy to construct, does not require heavy machinery, has an excellent load bearing capacity as a whole structure, has a sufficient depth, and has a large rainwater storage capacity. Especially.

The rainwater stored in the rainwater storage / infiltration structure of the present invention can also be used for fire extinguishing water, drinking water in an emergency by using a purifying device, watering trees, and the like.

[0008]

DISCLOSURE OF THE INVENTION The present invention relates to a water blocking material layer in a recess in the ground, a water storage layer disposed in the water blocking material layer, and this water storage.
A lid layer covering the layer, and covering the lid layer substantially flush with the ground
The soil layer is formed, and the water storage layer is a foamed resin raw material.
And a hard resin foam molded with a foaming agent
With a thick wall surface that has a partial space and is excellent in overload resistance
For multiple water storage blocks with a porosity of 40-70%
The present invention relates to a rainwater storage and infiltration structure composed of

A water storage block made of a hard resin foam and having an internal space has high compressive strength and excellent load resistance, is lightweight, is easy to manufacture, and is low in cost.
Therefore, it is possible to construct the water reservoir deeply, there is no need for a heavy equipment parking space because no heavy equipment is required for construction, and it is possible to construct a rainwater storage infiltration structure with a high rainwater storage capacity per site area. . In particular, it is possible to use the upper surface as a road by taking advantage of its excellent load-bearing capacity, and considering the size of the area, it is possible to store and use an extremely large amount of rainwater, which causes damage due to heavy rainfall. The effect of reducing is also obtained.

The water storage layer is formed by arranging, stacking, and filling water storage blocks, and a large number of small spaces for storing rainwater are formed. The water block has a porosity of 70
% Or less, more preferably 40 to 60%. If it is less than 40%, the rainwater storage capacity is low, and if it exceeds 70%, the compressive strength against the load from above may not be sufficient.

The upper surface of the rainwater storage / infiltration structure of the present invention can be used as a building, road, playground, park, garden, etc. Therefore, as the surface layer, concrete foundation, paved road surface, lawn, tartan truck, soil, etc. Etc. layers are provided. The height of the upper surface of the lid layer is determined by the purpose of use, surrounding conditions, etc., but is generally designed to be almost the same as the surrounding soil layer including the surface layer.

The water-blocking material layer is a layer having a function of preventing stored rainwater from leaking and flowing out, and is made of a material having no water permeability.

Around the rainwater storage and infiltration structure is generally a soil layer, but the structure is not limited to this and may be a structure such as a side wall of concrete or a concrete sheet pile.

In the rainwater storage / infiltration structure of the present invention, it is preferable that the lid layer includes a water permeable material layer.

The lid layer is used to prevent the inflow of earth and sand into the internal space of the water storage block originally contained in the water storage layer, effectively use the land by forming a cover layer as the surface layer, and concentrate stress on the water storage block which is weak against local load. It is equipped with functions such as prevention. Above the water storage block layer, a concrete floor plate, a tile, a steel plate, a natural stone plate or the like is laid as a lid layer, and a soil cover layer as a surface layer is further provided if necessary. It is also possible to form roads as a surface layer.

When a cover layer having no water permeation performance as described above is laid, it is necessary to separately install a water collecting facility such as a water collecting groove in order to introduce rainwater into the rainwater storage / infiltration structure. .

By including the water-permeable material in the cover layer, the rainwater that has fallen on the rainwater storage / infiltration structure is directly introduced into the rainwater storage / infiltration structure, and particularly the rainwater storage / infiltration structure covering a large area. It is possible to drastically reduce the water collection equipment to be installed in the area. Further, even if there is a heavy rainfall, the sediment forming the cover layer on the rainwater storage and infiltration structure will not be washed away by the flow of rainwater to the water collecting facility, which is preferable.
Further, when the road surface is heated, the rainwater stored through the water permeable lid can be evaporated, and the heat of evaporation cools the road surface. As a result, the effect of suppressing the heat island phenomenon is also exhibited.

On the above-mentioned water-permeable lid layer, as a surface layer, earth and sand, a water-permeable concrete floor board, and a sheet or block formed by binding water-permeable particulate or fibrous rubber chips with a binder. It is preferable to lay it. When the soil cover layer is used, it is preferable to have a layered structure having a smaller grain size toward the upper layer such as a coarse crushed stone layer, a gravel layer, and a surface soil layer from the bottom.

[0019]

BEST MODE FOR CARRYING OUT THE INVENTION As a material for forming a water storage block layer used in the present invention, known hard resin foams can be used without particular limitation.
Examples include expanded polystyrene (polystyrene foam). A method for forming these into a water storage block having an internal space is not particularly limited, but a method of charging a foaming resin raw material in a mold having a cavity of a predetermined shape and foaming is most preferable.

In particular, the use of polystyrene foam is low in cost, has little deterioration in soil by hydrolysis and microorganisms, and can be reused because polystyrene is a thermoplastic resin. It is suitable.

The polystyrene foam is produced by a known production method. Specifically, polystyrene beads are impregnated with a low boiling point hydrocarbon such as propane or butane to obtain a foamed resin raw material, which has a cavity of a predetermined shape, and a predetermined amount of this foamed resin raw material is charged into a heated mold. A method of forming a foam by vaporizing a foaming agent at the same time as converting polystyrene into a fluid state is exemplified.

The density of the polystyrene foam varies depending on the mold cavity, the amount of resin charged, the amount of the foaming agent impregnated in the polystyrene resin, etc. and is adjusted according to the purpose. large, it is preferable that the foam has a density in the 10 to 50 kg / m ^3, when the density is less than 10 kg / m ^3, the compressive strength of the blocks is not sufficient, when it exceeds 50 kg / m ³ When the block is used, the weight becomes large and the workability is deteriorated.

The water-permeable material layer in the rainwater storage / infiltration structure of the present invention is preferably a water-permeable polystyrene foam layer, and its permeability is not limited as long as rainwater can pass through. . The water-permeable polystyrene may be one obtained by adhering or fusing foam beads with a gap, or a plate-like body or block by adhering or fusing a strip-shaped foam polystyrene having a diameter of several mm to several tens of mm. May be It is also a preferred embodiment to use a water-permeable sheet together with the water-permeable polystyrene foam layer. A known sheet can be used as the water-permeable sheet, and specifically, a fiber material such as polyester woven cloth or a composite of a fiber material and a resin material can be exemplified.

The material forming the water blocking material layer in the rainwater storage / infiltration structure of the present invention is not particularly limited as long as the stored rainwater does not leak or flow away, and may be resin, metal, or the like. Although concrete and the like are exemplified, a waterproof sheet is particularly preferable. The water storage block used in the rainwater storage / infiltration structure of the present invention is lightweight, and the water-impervious material layer for accommodating the same does not need to use a high-strength material such as concrete, and is at least one waterproof sheet layer. It is enough and the corner of the water storage block does not damage the waterproof sheet. By using a flexible waterproof sheet, construction can be performed according to the shape of the excavated soil layer, and the construction period is short, so construction is easy and the cost is low.

The structure and material of the waterproof sheet, which are generally used as the waterproof sheet, can be used without any particular limitation. Specifically, the thickness obtained by impregnating and coating an organic fiber non-woven fabric with an asphalt-based substance is 4
mm sheet, vulcanized composition of rubber material such as chloroprene rubber, butyl rubber, ethylene propylene rubber (EPDM) and the like, combined with woven or non-woven fabric of natural fiber or synthetic fiber as necessary, to have a thickness of 0.5 mm to A sheet of about 5 mm is preferably used. In addition to the rubber material crosslinked by vulcanization, it is also possible to use a thermoplastic resin or a thermoplastic elastomer in the form of a single sheet or a sheet formed by combining fibers. In particular, a composite sheet of an organic fiber non-woven fabric and an asphalt-based material is preferable because it has good elongation performance, can easily conform to the shape of the recess of the excavated ground, and is low in cost.

An embodiment of the present invention will be described with reference to the drawings. In the examples shown below, polystyrene foam having a density of 25 kg / m ³ was used as the hard resin foam. Use the water storage block with the shape shown in Fig. 5 ,
As the water-permeable polystyrene foam, a water-permeable polystyrene foam board (tammy block, obtained by molding a strip-shaped polystyrene foam into a board having a thickness of 250 mm)
Tamai Environmental System Co., Ltd.) was used.

[0027] Figure 1 the reservoir block and permeable polystyrene foam sequences board, a perspective view of a vertical cross-section, as laminating conditions is known, an example of a vertical cross-section are shown in FIG. 2, bottom vertical 6 m, horizontal It is a rainwater storage and infiltration structure with a depth of 6 m from the ground surface, and the side surface of the reservoir is expanded and formed at an angle of 45 degrees from the bottom surface, and the top surface is formed into a square shape with vertical and horizontal sides of 12 m each. . The rainwater storage and infiltration structure 1 has an inverted truncated pyramid shape, and the thickness of the organic fiber nonwoven fabric and the asphalt-based material provided along the excavated surface of the ground excavated so that the side surface has an inclination angle of 45 degrees and the asphalt-based material Of the composite sheet (trade name: Custom NT, manufactured by Nisshin Special Construction Co., Ltd.) as a water blocking sheet layer, a water permeable polystyrene foam board layer 9 as the lowermost layer, and a water storage block 5 having an internal space. The laminated water storage tank 6 and the water-permeable polystyrene foam board layer are composed of a lid layer 17 composed of two layers 11 and a water-permeable sheet 13, and the crushed stone layer 3 is provided as an upper layer of the lid layer 17.
2, the gravel layer 31 and the soil covering layer 15 are provided to form the surface layer 7.

The rainwater storage / infiltration structure shown in FIGS. 1 and 2 is provided with a pump 18 so that the stored rainwater can be pumped out. When the rainwater storage and infiltration structure is installed higher than the surrounding area like a road, it is possible to use a water discharge means such as a valve instead of the pump. The outside of the water-permeable sheet layer 3 is shown in FIG.
In addition, as shown in FIG. 2, it is preferable to provide a bed sand layer 4.

FIG. 3 is an enlarged view of the structure of the upper end of the rainwater storage / infiltration structure. Rainwater storage infiltration structure 1
Is cut off from the soil around the excavated water by the water-blocking sheet 3, and a water storage layer 6 formed of polystyrene foam blocks 20 as water storage blocks 5 arranged and stacked,
A water-permeable sheet layer 13 and a water-permeable polystyrene foam board layer 11 are provided on the upper part of the lid layer 17 to form a lid layer 17. Further, a crushed stone layer 32, a gravel layer 31, and a soil covering layer 15 are formed on the upper layer thereof, and form the surface layer 7. A space having a triangular cross section formed between the excavated surrounding soil layer and the rectangular water storage block is filled with the water-permeable polystyrene foam board as a filler 34 after being cut into an appropriate shape.

The water barrier sheet 3 may be construction to the upper end about the reservoir 6 formed by the reservoir block 5 and permeable polystyrene foam board 11 is fixed to the soil of the surroundings. The impermeable sheet 3 is fixed in such a manner that the surrounding land is widely excavated in the vicinity of the fixed portion, the impermeable sheet 3 is first laid, and the end portions are, for example, rafters 41 and anchor pins 4.
It is carried out by fixing the water-permeable block 5 and the water-permeable polystyrene foam board 11 and then laying a water-permeable sheet 13 on the water-permeable polystyrene foam board 11 and fixing them appropriately.

It is a preferable mode to use the fixing metal fittings when arranging and stacking the water storage blocks 5, and an example of such fixing metal fittings is shown in FIG. The fixing metal has functions of preventing the water storage block from moving to the left and right, and ensuring the load bearing strength of the water storage layer. The fixing metal fitting of FIG. 4 is manufactured by forming an end portion of a steel plate of an appropriate size in a sawtooth shape and bending it vertically, and the foam portion of the upper and lower polystyrene foam blocks to be laminated. It has a predetermined function by being installed between the teeth and biting the serrated ends. The shape of the fixing metal fitting is not particularly limited as long as it has the above-mentioned function.

FIG. 5 shows an example of the shape of the polystyrene foam blocks 20 used in FIGS. 1 and 2 and the situation in which the polystyrene foam blocks are arranged and laminated using the fixing metal fittings shown in FIG. Is. This polystyrene foam block 20 has a length of 1000 mm and a width of 100.
0 mm, height 250 mm, length 350 mm, width 35
It has four internal spaces 21 of 0 mm vertically penetrating and has a “T” shape when viewed from above. Space partition 2
The foam of No. 3 has a wall thickness of 150 mm, and the peripheral wall 45
The foam has a wall thickness of 75 mm, and the inner spaces are arranged at 150 mm intervals when they are arranged and laminated without a gap. The width of the space partition 23 and the foam forming the surrounding wall 25 is 25 m.
A slit 27 having a height of m and a height of about 100 mm is provided so that rainwater can freely move to the left and right internal spaces.

The shape of the polystyrene foam block is not limited to the above-mentioned shape, and any shape such as a cylindrical shape or a polygonal pillar shape may be used as long as it is a shape that is not destroyed by the load from above. Further, it is not necessary that all the water storage blocks have the same shape, and blocks having different shapes can be freely combined. All the water storage blocks used for the water storage layer do not have to have an internal space, and they may be arranged and laminated with an empty hard resin foam interposed. further,
It is not necessary to arrange and stack the water storage blocks as long as they can withstand the load from above, without gaps. Further, the space for storing water may include, in addition to the internal space provided in the block itself of the water storage block, a space formed by arranging and stacking the water storage blocks.

The internal space of the polystyrene foam block 20, which is the water storage block 5 in FIG. 5, has a shape opened vertically, but it may have a horizontal partition. However, the horizontal partition contributes little to the strength against the load from the upper part and reduces the amount of stored water, and it is preferable that the internal space is vertically opened.

In the construction example shown in FIG. 5, the water storage block 5 is installed by piercing a foam with a fixing metal fitting at the center of the partition 23 in the space "T" of the water storage block located below. The metal fittings are pierced and fixed at the corners of the peripheral walls 25 of the four water storage blocks 5 respectively, and the center of the lower water storage block is located at the contact point of the four corners of the upper water storage block. ing. With such a configuration, it is possible to prevent partial sedimentation from occurring even when a local load is applied to the upper portion of the rainwater storage / infiltration structure, which is preferable.

FIG. 6 shows an example of a rainwater storage / infiltration structure in which a rainwater storage / infiltration layer is provided under the paved road. The paved road is provided with a paved road surface 51, a soil cover layer 15 and a concrete floor plate 52 as a lid layer 17 under the paved road surface, and a water storage layer 6 in which a water storage block 5 is arranged and a waterproof sheet layer 3 under the paved road surface 51. . In order to uniformly receive the load of the concrete floor plate 52, in this example, a normal polystyrene foam block layer 57 is provided as a lower layer of the concrete floor plate 52. A water collecting basin 53 is provided on the shoulder of the road, and a water passage 55 is formed in the water collecting basin 53, and rainwater permeates into the reservoir layer 6 through the water passage 55.

In recent years, water-permeable pavement has been developed,
In the case of such a water-permeable paved road surface, it is possible to use the water-permeable lid as illustrated in FIG. 1 without providing the water collecting tank 53 having the water passage holes 55.

The rainwater storage permeation layer under the paved road shown in FIG. 6 is the same as that illustrated in FIGS. 1 and 2, and the paved road has a width of 7,000 mm. The rainwater storage permeation layer may be formed continuously in the lengthwise direction of the road surface, or a storage layer having a structure like the example of FIG. 6 may be provided intermittently.

Plants and sidewalks are formed on both sides of the paved road, and the surface layer of the sidewalk is a water-permeable pavement layer 5.
9 is provided, and the lower layer is provided with a soil covering layer 15, a gravel layer 31, and a crushed stone layer 32 from the top as in the example of FIG. 2, and a water permeable sheet layer and a water permeable polystyrene foam board layer 11 as a lid layer. Is provided and both rainwater on the road and rainwater on the sidewalk are guided to and stored in the reservoir 6.

FIG. 7 shows the structure of the horizontal cross section at the positions AA and BB of the rainwater storage / infiltration structure shown in FIG.

[Brief description of drawings]

FIG. 1 is a perspective view showing a cross-section of the structure of an example of a rainwater storage / infiltration structure of the present invention so that the construction status of a water storage block and a water-permeable polystyrene foam board can be understood.

FIG. 2 is a diagram showing a cross-sectional structure of the rainwater storage / infiltration structure 1 shown in FIG.

FIG. 3 is an enlarged view showing a structure of an upper end portion of an example of a rainwater storage / infiltration structure of the present invention.

FIG. 4 is an arrangement of water storage blocks, a solid used for stacking.
The figure which showed the example of fixed metal fittings.

FIG. 5 is a reservoir for use in the rainwater storage infiltration structure of the present invention .
The perspective view which shows the shape of the example of a lock.

FIG. 6 is a view showing an example in which the rainwater storage / infiltration structure of the present invention is formed in a lower portion of a road.

FIG. 7 is a view exemplifying a horizontal cross-section structure of a rainwater storage and infiltration structure formed at a lower portion of a road.

   ─────────────────────────────────────────────────── ─── Continued front page       (56) References Japanese Patent Laid-Open No. 9-95999 (JP, A)                 JP-A-9-41470 (JP, A)

Claims (6)

(57) [Claims] 1. A water barrier material layer on the ground recesses, distribution in the water shield material layer
Placed water reservoir, lid layer covering the water reservoir, and the lid
It has a soil cover layer that covers the body layer and is substantially flush with the ground.
The water storage layer is made of a foamed resin raw material and a foaming agent.
Made of high quality resin foam, has an internal space and is resistant to overload
Excellent wall thickness with a thick wall with a porosity of 40-70%
A rainwater storage infiltration structure composed of a number of water storage blocks . 2. The rainwater storage and permeation structure according to claim 1, wherein the lid layer includes a water permeable layer formed of a water permeable material. 3. The rainwater storage / infiltration structure according to claim 1, wherein the hard resin foam is a polystyrene foam. 4. The rainwater storage / infiltration structure according to claim 2, wherein the water-permeable material is a water-permeable polystyrene foam. 5. The polystyrene foam has a density of 10-5.
The rainwater storage and permeation structure according to claim ^3, which has a pressure of 0 kg / m ³ . 6. The rainwater storage / infiltration structure according to claim 1, wherein the water barrier layer is formed of a waterproof sheet.