JPH11100804A - Permeable plate block - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a permeable plate block attractive with designed appearance, high in mechanical strength and excellent in drainage performance and water permeability. SOLUTION: This permeable plate block 10 consists of an impermeable surface layer 11, and a permeable lower layer 12 with open pores at the porosity of 15-50%. In this case, a large number of water conveying grooves 13 reaching the inside of the lower layer 12 from the surface of the surface layer 11 and opened from one side to the other side are formed in the plate block 10. It is desirable that granular material of grain size not impeding water conveyance is filled in the water conveying grooves 13. It is also desirable that the surface layer is formed of nonporous concrete and that the lower layer 12 is formed of porous concrete with aggregate jointed to each other with cement.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a water-permeable flat block used for pavement of a street, curbstone, and the like.

[0002]

2. Description of the Related Art To prevent floods and floods by infiltrating rainwater that has fallen on the road surface of a street to prevent flooding and flooding, and to improve the aesthetic appearance of the street, instead of using asphalt or concrete, a large number of pavements on the street have to be replaced. Pavement in which a water-permeable flat block is laid on a subgrade is desirable.

Heretofore, as this kind of permeable flat plate block, a permeable flat plate block made of porous concrete or porous resin concrete is known. For example, Japanese Utility Model Publication No. 4-37921 discloses a water-permeable floor plate obtained by hardening a large number of small particle size aggregates with a binder to form a porous plate-like body, and cutting and polishing the surface thereof smoothly. Have been.

[0004] Since such a water-permeable floor plate has a porous and monotonous surface as a whole, it has some design effects due to ordinary joints generated when it is laid on a subgrade.
It doesn't look good. In addition, since the entire body is porous, the mechanical strength is slightly reduced. In addition, the porous holes may be easily blocked by dust, dirt, or mud, and the water permeability may be reduced.

[0005] When the surface is cut and polished smoothly, the cut and polished surface of the aggregate is exposed to the surface to improve the cosmetic property, but the appearance of the design is still insufficient.

In order to improve such disadvantages, for example, Japanese Patent Application Laid-Open No. Hei 9-131716 discloses that a large number of drainage holes which are composed of a surface layer of decorative concrete and a lower layer of water-permeable concrete, and which reach the lower layer from the surface of the surface layer. A formed permeable concrete block has been proposed.

[0007] The water-permeable concrete block proposed above makes the surface of the decorative concrete exhibit cosmeticity (aesthetics) and mechanical strength, and allows rainwater to permeate through a large number of drain holes in the surface to the lower layer of the water-permeable concrete. It is intended to penetrate the ground from there.

[0008]

However, the large number of drain holes formed in the surface layer only guide the surface rainwater vertically to the lower layer, and when the amount of rainfall is relatively large, the rainfall is reduced. The water overflows from the drain holes to the surface, and the drainage performance and water permeability are not sufficient.

According to the surface layer of the decorative concrete,
Even if the surface has cosmetic properties, a three-dimensional design effect cannot be obtained. Also, even if a large number of drain holes are formed in the surface layer of decorative concrete, even if the size and arrangement of such drain holes are changed, there is a limit in obtaining a design appearance,
Appearance is inadequate.

The present invention solves the above problems,
It is an object of the present invention to provide a water-permeable flat plate block having a good design appearance, good appearance, high mechanical strength, and excellent drainage performance and water permeability performance.

[0011]

In order to achieve the above-mentioned object, the present invention provides a water-permeable flat plate block having a water-impermeable surface layer and a water-permeable lower layer having continuous pores having a porosity of 15 to 50%. A flat block comprising: a flat block formed from a surface of the surface layer into a lower layer, and formed with a number of water guiding grooves opened from one side to the other side. (The invention of claim 1).

According to the present invention, in the water-permeable flat plate block according to the present invention, the water guide groove is filled with a granular material having a particle size that does not impede water transfer.

Further, according to the present invention, in the water-permeable flat plate block of each of the above-mentioned inventions, the surface layer is made of non-porous concrete, and the lower layer is made of porous concrete in which aggregates are joined with cement. 3 invention).

[0014]

According to the water-permeable flat block of the present invention, since it has a water-impermeable surface layer, the mechanical strength is improved as a whole. In addition, a three-dimensional design effect is exhibited on the surface by the size, shape, and arrangement of the many water guide grooves formed in the surface layer.

[0015] Further, the above-mentioned many water guiding grooves extend from the surface of the surface layer into the lower layer, whereby rainwater is guided vertically in the groove, and not only from the bottom of the groove but also from the side of the lower layer. Since water is also permeable, the surface area of the permeable portion is greatly increased, and the permeable performance is significantly improved.

Moreover, since the large number of water guiding grooves are open from one side of the flat block to the other side, when the rainfall is relatively large, the rainwater flows horizontally through the water guiding grooves. Then, the water flows out to the ordinary joints generated when laid on the roadbed, and the drainage performance is remarkably improved.

If the large number of water guiding grooves are filled with granular material having a particle size that does not impede water transmission, dust, dirt and mud are blocked by the granular material and penetrate into lower continuous pores. It becomes difficult to prevent a decrease in water permeability due to clogging.

Further, the surface layer is made of non-porous concrete, and the lower layer is made of porous concrete in which aggregates are joined together with cement. It can be easily manufactured by the method.

[0019]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to embodiments shown in the drawings. FIG. 1 is a partially cutaway perspective view showing an example of a water-permeable flat plate block of the present invention.
FIG. 2 is a partially cutaway perspective view showing another example of the water-permeable flat plate block of the present invention, and FIG. 3 is a cross-sectional view showing one example of a method of molding the water-permeable flat plate block of the present invention.

1 and 2, reference numeral 10 denotes a water-permeable flat plate-shaped block of the present invention, 11 denotes a water-impermeable surface layer, 12 denotes a water-permeable lower layer, and the water-impermeable surface layer 11 generally comprises a curable material. It is composed of a non-porous cured product obtained by mixing and curing a binder and an aggregate. In addition, the water-permeable lower layer 12 is generally made of a porous cured body having continuous pores in which aggregates are joined with a binder.

As the curable binder, a curable inorganic binder such as Portland cement or a curable organic binder such as unsaturated polyester or epoxy resin is usually used. Inorganic aggregates such as sand, gravel, crushed stone, granite, and marble are used. The aggregate having a particle size of about 2 to 10 mm is preferably used.

The porosity of the continuous pores of the water-permeable lower layer 12 is 15 to 50%. When the porosity is less than 15%, the water permeability is reduced. On the contrary, when the porosity is more than 50%, the mechanical strength is reduced and the porosity is not practical.

Here, the porosity is measured by the following method. First, a specimen of the lower layer portion was prepared, the test specimen was the weight was dried weighed W _1, was then which was boiled in water for 3 hours or more saturated with water in the gap continuous cooling pores to room temperature , which its weight was weighed and W ₂ hanging in the water, and finally out the water-saturated test specimen from the water, and weighed Nuguisa' excess moisture well squeezed compress the surface and the weight W
_{Assume 3} . Then, the porosity is calculated as follows: (W ₃ −W ₁ ) / (W ₃ −W ₂ ) × 100 (%).

The impermeable surface layer 11 and the permeable lower layer 1
2 form a plate-shaped block 10. This plate-shaped block 10 is generally formed into a rectangular plate shape, but may be formed into an appropriate shape such as a polygonal plate shape. When formed into a rectangular plate shape, for example, the length and width of the entire flat plate block is about 100 to 600 mm, the thickness of the entire flat block is about 50 to 100 mm, and the thickness of the surface layer is about 5 to 20 mm. It is.

Further, the flat block 10 is formed with a number of grooves 13 for guiding water. The large number of water guiding grooves 13 guide the rainwater accumulated on the surface of the block into the grooves 13 and serve to flow the grooves 13 in the vertical and horizontal directions, and to exert a design effect on the surface of the block. In general, a large number are formed linearly or curvedly in one direction in parallel with each other, or are formed in a lattice shape.

The plurality of water guiding grooves 13 must extend from the surface of the surface layer 11 to the lower layer 12 through the boundary and open from one side to the other side. In the case where the water guiding groove 13 is formed only from the surface of the surface layer 11 to the boundary surface with the lower layer 12, rainwater permeates only from the bottom surface of the groove 13 to the lower layer 12, and cannot permeate from other lower layers. Therefore, the water permeability is insufficient.

When the water guiding groove 13 is not open from one side to the other side like a large number of independent drain holes as in the prior art, when the rainfall is relatively large, the rainwater is discharged from the surface layer. It cannot flow in the horizontal direction along the groove, does not flow out to a normal joint that occurs when laid on the roadbed, but overflows to the surface, and the drainage performance deteriorates.

The width and depth of the water guiding groove 13 are generally about 3 to 10 m in view of a balance between water permeability and strength.
m, those having a depth of about 10 to 40 mm are preferred,
It is not limited to this. In particular, as shown in FIG. 2, the water guiding groove 13 is preferably filled with a granular material 14 having a particle size as small as possible without impeding water conveyance, for example, silica sand having a particle size of 2 to 5 mm. is there.

The above-mentioned granular material 14 is provided in the water guiding groove 13.
When the particles are filled, dust, dirt, and mud are blocked by the particulate matter 14 and are less likely to enter the continuous pores of the lower layer 12 from the groove 13, thereby preventing clogging of the continuous pores of the lower layer 12, There is no danger of performance degradation.

When the water-conducting groove 13 is filled with the granular material 14, the water-permeable flat block 10 may be individually filled before being applied to the roadbed, or may be filled in a large number after being applied to the roadbed. May be filled all at once.
Also, after application to the subgrade, the granules 14 can be periodically replaced with new granules.

In particular, the permeable plate-like block 10 in which the surface layer 11 is made of non-porous concrete and the lower layer 12 is made of porous concrete in which aggregates are bonded to each other with cement has a low raw material cost and a low mechanical cost. There is strength,
Moreover, it is preferable because it can be easily manufactured by a molding method in which a molding die is filled with a concrete material in two layers.

Hereinafter, a method of manufacturing the concrete permeable flat block 10 will be described with reference to FIG. FIG. 3 is a cross-sectional view illustrating an example of a method for manufacturing the water-permeable flat block 10. In FIG. 3, reference numeral 20 denotes a steel mold, on the bottom surface of which a large number of ridges 21 for forming a large number of grooves 13 for water introduction are provided at desired dimensions and intervals. ing. The mold 2
0 may be such that the side frame and the bottom frame can be divided.

First, a block material 11a for the surface layer 11 and a block material 12a for the lower layer 12 are prepared as block materials. The block material 11a of the surface layer 11 is composed of a mixture of sand and gravel and, if necessary, aggregate made of pebbles with beautiful colors, white Portland cement, and, if necessary, a coloring pigment, and water. These mixing ratios are the same as the mixing ratios when producing a nonporous ordinary concrete product. Aggregate is usually 65
Accounts for ~ 80%.

On the other hand, the block material 12a of the lower layer 12 is
For example, the particle size is about 2 to 10 mm, preferably 2.5 to 5
mm, aggregate consisting mainly of sand, gravel and crushed stone, ordinary Portland cement in an amount required to cover the surface of the aggregate (about 1/3 to 1/5 weight of the aggregate), and ordinary Portland cement A mixture of about 1/40 of the cement adjuvant and about 1/3 of the water of ordinary Portland cement.

As the binding aid, a polymer (for example, Movinyl DM200 manufactured by Hoechst Gosei Co., Ltd.) is used.
A thickener (for example, Tylose M manufactured by Hoechst Gosei
A binding aid to which H) has been added is used.

Next, a retarder for cement coagulation (for example, 100-R manufactured by Nisso Master Builders Co., Ltd.) is applied to the bottom surface of the mold 20 and the surfaces of the numerous ridges 21, or such a retarder is used. Is spread on a delay paper, and the block material 11a of the surface layer 11 is poured into the bottom of the paper at a desired thickness, and is pressed evenly. A layer of the block material 11a is formed.

Thereafter, the block material 11 of the surface layer 11 is formed.
On the layer a, the block material 12a of the lower layer 12 is poured into a desired thickness and spread, and the compacted by a compacting machine 30 to perform vibration compaction. A block material having a two-layer structure including the layer of the block material 12a is formed.

In this case, the block material 11a of the surface layer 11
The layers of the block material 12a are solid with no voids, while each aggregate has been hardened with a sufficient amount of cement, while the layer of the block material 12a of the lower layer 12 has each aggregate joined at its contact point. And voids are formed in other portions.

The block material having the double-layered structure in which the molding is performed as described above is allowed to cure for a suitable time or for 24 hours in a room, and then is released from the molding die 20 to form a flat block. The cement content on the block surface of which solidification has been delayed is removed with a brush or the like, and curing is performed if necessary. The curing of the flat block is, for example, 70 to 1
Steam curing may be performed in a steam room at about 00 ° C. Further, the surface of the surface layer 11 may be finally polished if necessary.

Thus, the water-permeable flat block 10 of the present invention as shown in FIG. 1 is manufactured, and the water-permeable flat block 10 is a non-water-permeable layer whose surface layer 11 is made of non-porous concrete. The lower layer 12 is made of porous concrete in which aggregates are joined together with cement, and has a porosity of 15 to
It is a water-permeable layer having 50% continuous pores, and further has a number of water-guiding grooves formed from the surface of the surface layer 11 into the lower layer 12 and open from one side to the other side. .

The water-permeable flat block 10 of the present invention is laid on a roadbed and paved by a known method. It is also used as a curb. Usually, a sand layer is formed on a rubble stone or gravel layer to form a subgrade, and the permeable flat plate block 10 is laid on the subgrade to be paved. In particular, a nonwoven fabric made of glass fiber or synthetic fiber or When laid on the subgrade through a woven cloth, the water-permeable flat plate block 10 is easily flattened without becoming uneven, and construction can be easily performed.

The water-permeable flat block 10 of the present invention
Can be used not only for pavements and curbs on streets, but also for flooring of buildings, flooring of kitchens and baths, and the like.

[0043]

As described above, the water-permeable flat block of the present invention is a flat block comprising a water-impermeable surface layer and a water-permeable lower layer having continuous pores having a porosity of 15 to 50%. The flat block has a large number of water guiding grooves extending from the surface of the surface layer into the lower layer and being open from one side to the other side, so that a design-like appearance is obtained and appearance is obtained. It is good, has high mechanical strength, and has good drainage performance and water permeability.

Further, when a large number of the above water guiding grooves are filled with particulate matter having a particle size that does not hinder water transmission, it is possible to prevent a decrease in water permeability due to clogging. Further, a material whose surface layer is made of non-porous concrete and whose lower layer is made of porous concrete in which aggregates are bonded to each other with cement is low in material cost and can be easily manufactured by a molding method, so that the product can be inexpensive.

[Brief description of the drawings]

FIG. 1 is a partially cutaway sectional view showing an example of a water-permeable flat plate-shaped block of the present invention.

FIG. 2 is a partially cutaway sectional view showing another example of the water-permeable flat plate-shaped block of the present invention.

FIG. 3 is a cross-sectional view illustrating an example of a method for manufacturing a water-permeable flat block according to the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 10 Water-permeable flat block 11 Non-water-permeable surface layer 12 Water-permeable lower layer 13 Water guide groove 14 Granular material

Claims (3)

[Claims] 1. A flat block comprising a water-impermeable surface layer and a water-permeable lower layer having continuous pores having a porosity of 15 to 50%, wherein the flat block has a lower layer from the surface of the surface layer. A water-permeable flat plate-shaped block, wherein a number of water-guiding grooves are formed in the layer and open from one side to the other side. 2. The water-permeable flat block according to claim 1, wherein the water guide groove is filled with a granular material having a particle size that does not impede water transfer. 3. The surface layer is made of non-porous concrete,
The permeable flat block according to claim 1 or 2, wherein the lower layer is made of porous concrete in which aggregates are joined with cement.