JP2000226835A - Water permeable soil block - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a water permeable soil block capable of exhibiting water permeability while holding strength, capable of exhibiting temperature adjusting performance and humidity adjusting performance by evaporating inside water, capable of exhibiting a soundproof effect and a vibration control effect by a water permeable soil material layer and the inside bubbles and harmonizable with nature by the water permeable soil material layer when laid as a revetment and a forestry road. SOLUTION: A water permeable soil block 11 is composed of a strength holding material layer 12 and a water permeable soil material layer 13 formed on the strength holding material layer 12. In that case, in this water permeable soil block 11, a water permeable intermediate layer 14 excellent in water permeability more than the water permeable soil material layer 13 is desirably arranged between the strength holding material layer 12 and the water permeable soil material layer 13 to further improve water permeability. Then, the water permeable soil material layer 13 is formed by mixing and solidifying a porous material, earth and a soil stabilizer.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention is used in ground stabilization works for harmonizing with nature, such as revetment blocks constituting rivers and coastal embankments and surface pavement blocks on forest road ground. Permeable soil blocks.

[0002]

2. Description of the Related Art Conventionally, surface pavement of this kind of ground has been
It was done with asphalt and concrete. In this case, there is a problem that water accumulates on the surface pavement and is not easily drained. Further, there is also a problem that dust and oil or the like adhering to the surface emerge on the surface water, and a vehicle or the like running on the surface causes slippage. However, in recent years, asphalt having water permeability, and a high-pressure press-molded product of a mixture of sand, cement, and a pigment have been developed, and the above-mentioned problems are being solved.

[0003]

However, in the above-mentioned conventional water-permeable asphalt or high-pressure press-formed product,
In order to increase water permeability, the strength is reduced by forming many gaps inside, and when laid for revetment or forest road etc., there is a possibility that it will be easily destroyed by external forces applied from various directions there were.

In addition, when the conventional asphalt or high-pressure press-formed product is laid and used in a more natural environment, its temperature and humidity are significantly different from the surrounding environment, and severe noise and vibration are generated. Therefore, it was difficult to create an environment in harmony with nature.

The present invention has been made by focusing on the problems existing in the prior art as described above. The purpose is to lay for revetment, forest road, etc.
An object of the present invention is to provide a water-permeable soil block capable of exhibiting water permeability while maintaining strength, and exhibiting temperature control performance and humidity control performance by evaporating water inside. The other purpose is a water-permeable soil block that can exhibit soundproofing and vibration-proofing effects by the water-permeable soil material layer and the air bubbles inside it, and can be harmonized with nature by the water-permeable soil material layer. Is to provide.

[0006]

In order to achieve the above object, a water-permeable soil block according to claim 1 comprises a strength retaining material layer and a water-permeable soil material layer formed on the strength retaining material layer. It is composed of

[0007] The permeable soil block according to the second aspect,
A water-permeable intermediate layer having better water permeability than the water-permeable soil material layer is provided between the strength retaining material layer and the water-permeable soil material layer according to claim 1.

[0008] The permeable soil block according to claim 3 is:
The permeable soil material layer according to claim 1 or 2 is formed by mixing a porous material, soil, and a soil stabilizer.

[0009]

Embodiments of the present invention will be described below in detail with reference to the drawings. As shown in FIG. 1A, the first permeable soil block 11 includes a strength holding material layer 12 and a strength holding material layer 1 on the strength holding material layer 12.
2 is a square plate-like molded body composed of a water-permeable soil material layer 13 formed in a shape corresponding to 2. As the first permeable soil block 11, for example, the vertical and horizontal lengths are 1 to 1.5 m, and the thickness of the strength holding material layer 12 is 20c.
m, the thickness of the permeable soil material layer 13 is formed as a flat molded body having a thickness of 20 cm. Further, the ratio of the thicknesses of the layers 12 and 13 is preferably 1: 1.

The strength retaining material layer 12 is formed of concrete or reinforced concrete without reinforcing bars. This strength retaining material layer 12 is made of the permeable soil block 11.
The main purpose is to maintain the strength, and there is almost no water permeability and water retention.

The permeable soil material layer 13 is formed of a mixture of a porous material, soil and a soil stabilizer. The permeable soil material layer 13 has a large number of pores therein so that water such as rainwater accumulated on the upper surface can pass therethrough and the water can be retained for a certain period of time. Have. Further, the permeable soil material layer 13 has a strength that is not crushed by heavy objects such as vehicles.

The porous material forms a gap inside the permeable soil material layer 13 for passing water such as rainwater. The porous material preferably has a large number of continuous pores and has a strength not to be crushed by heavy objects such as vehicles.

The pore diameter of the pores of the porous material is preferably 5 μm to 5 mm, more preferably 100 μm to 2 μm.
mm. When the pore diameter is less than 5 μm, the water permeation rate is low, the water permeability of the water-permeable soil block 11 is reduced, and sufficient drainage cannot be performed. On the other hand, if it exceeds 5 mm, the water retention capacity of the water-permeable soil material layer 13 is reduced, and the gap is increased, the strength of the water-permeable soil material layer 13 is reduced, and the water-permeable soil material layer 13 is easily crushed by heavy objects such as vehicles.

Further, the particle size of the porous material is preferably in the range of 3 to 15 mm, more preferably 3 to 5 mm. When the particle size is less than 3 mm, there is almost no gap between the particles of the porous material, and it is not possible to form a continuous gap through which water can appropriately pass. Conversely 15
If it exceeds mm, a large gap is formed between the particles of the porous material, and water is quickly discharged through the gap, so that the water retention capacity is reduced. Examples of such a porous material include charcoal waste, pumice stone, brick and the like.

Coal waste is a cinder generated by coal boilers such as bottom ash and clinker ash, and usually has a particle size of 10 mm or less, a water content of 20.8% by weight and a wet density of 0.68 g / cm ³ . is there. Pumice is a volcaniclastic material that is made porous by the gas that expands during rock formation, has few crystals, and is mainly composed of siliceous components and bubbles. Brick is obtained by firing a mixture of low-grade clay as a main raw material, a mixture of river sand and lime added thereto, and when used as a porous material, preferably has a particle size of 3 to 15 mm. Used after being crushed.

As the soil, clay or clay soil, sludge cake, Kira clay and the like are preferably used. Soil having a clay content contains 15% or more of soil particles having a particle size of 75 μm or less, which are regarded as fine particles according to the Japanese Unified Classification System. Sludge cake is an industrial waste generated when limestone is washed with water, and is also clayey. Kira clay is discarded when silica sand and elutriation clay are obtained by washing natural silica sand produced near Seto City in Aichi Prefecture with water, for example, and is a white clay mixed with fine sand.

In addition, as the soil constituting the permeable soil material layer 13, if the soil at the construction site has clay or clay, it can be effectively used. On the other hand, when the soil at the construction site does not have clay or clay content, commercially available soil such as sludge cake or clay sand, or soil having clay content produced elsewhere is used at the construction site. Can be used as a mixture.

As the soil stabilizer, a general soil stabilizer containing at least one of quick lime, slaked lime, cement, gypsum and blast furnace slag can be used. However, cement contains a large amount of impermeable gel in the soil, so that it is not preferable to include a large amount as a constituent of the soil stabilizer. On the other hand, quicklime, slaked lime, and gypsum generate ettringite or the like in the form of needle-like crystals, and bind the soil and the porous material with lines or points.
3 is preferable as a component of the soil stabilizer to be mixed. Further, the blast furnace slag is preferable as a component of the soil stabilizer to be mixed with the water-permeable soil material layer 13 in order to generate a solidified product having a high porosity due to alkali stimulation of quicklime and slaked lime. Therefore, it is preferable that the soil stabilizer does not contain a large amount of cement and mainly contains at least one of quick lime, slaked lime, gypsum and blast furnace slag.

As the soil stabilizer other than those described above, for example, dust collected in a lime production step is preferably used. The main component of the dust is slaked lime or quicklime. Also, since quick lime generates heat by reacting with moisture in the soil to accelerate the solidification reaction of the permeable soil material layer 13, it is very effective in rapidly solidifying the permeable soil material layer 13. . Further, as is generally practiced, gypsum or cement is appropriately added to the soil stabilizer so as to compensate for the deficient components in the soil at the construction site, so that the quality of the permeable soil material layer 13 is improved. It is preferred that

Among the materials constituting the water-permeable soil material layer 13, the porous material is preferably 50
To 400% by weight, more preferably 150 to 300% by weight. If the amount is less than 50% by weight, desired water permeability cannot be exhibited.
On the other hand, when the content exceeds 400% by weight, the strength of the water-permeable soil material layer 13 is reduced, which may cause the soil to be easily broken, and may hinder the solidification of the soil by the soil stabilizer.

The soil stabilizer is preferably added in the range of 3 to 20% by weight, more preferably 3 to 10% by weight, particularly preferably 5 to 10% by weight, based on the soil.
It is blended in the range of 10% by weight. 3% by weight
If it is less than the strength, the strength of the permeable soil material layer 13 may be reduced, and it may be easily broken. On the other hand, if it exceeds 20% by weight, the water permeability of the water-permeable soil material layer 13 is significantly reduced.

The second permeable soil block 11 is shown in FIG.
As shown in (b), between the strength holding material layer 12 and the water-permeable soil material layer 13, a square flat plate having a water-permeable intermediate layer 14 having better water permeability than the water-permeable soil material layer 13 is formed. It is a molded object of. The strength retaining material layer 12 and the permeable soil material layer 13 constituting the second permeable soil block 11 are the same as those of the first permeable soil block 11.

As the second permeable soil block 11, for example, the length and width are 1 to 1.5 m, the thickness of the strength retaining material layer 12 is 20 cm, and the thickness of the permeable intermediate layer 14 is 10
cm, and the thickness of the water-permeable soil material layer 13 is 20 cm. Further, the thickness ratio of the strength retaining material layer 12, the water-permeable intermediate layer 14, and the water-permeable soil material layer 13,
The ratio is preferably 2: 1: 2.

The permeable intermediate layer 14 is formed of porous concrete made of a mixture of cement and gravel. Further, the water-permeable intermediate layer 14 has a large number of gaps formed therein by mixed gravel so that water such as rainwater that has passed through the water-permeable soil material layer 13 can pass through. This gap is formed larger than the gap formed inside the permeable soil material layer 13, and has better water permeability than the permeable soil material layer 13.

The grain size of the gravel constituting the water-permeable intermediate layer 14 is preferably 30 to 50 mm. When the particle size of the gravel is less than 30 mm, the gap formed in the permeable intermediate layer 14 is small, so that it is not possible to reliably secure the flow path of water such as rainwater, and the drainage capacity of the permeable soil block 11 is reduced. descend. Conversely, if it exceeds 50 mm, the gap formed in the water-permeable intermediate layer 14 may be crushed by a heavy object such as a vehicle, and the water-permeable soil material layer 13 and the water-permeable intermediate layer 14 may collapse.

The second water-permeable soil block 11 constructed as described above is solidified by pouring the material constituting the strength retaining material layer 12 into a bottomed rectangular box-shaped forming form. Next, the material constituting the water-permeable intermediate layer 14 is poured into the upper portion of the strength retaining material layer 12 and solidified. Finally,
The material constituting the permeable soil material layer 13 is poured into the upper portion thereof, solidified while applying pressure as necessary, and then taken out of the forming mold and used. On the other hand, when manufacturing the first permeable soil block 11, the process of forming the permeable intermediate layer 14 may be omitted. It is also possible to reverse the order in which the materials constituting these layers 12, 13, and 14 are poured into a molding frame and solidified.

Next, the operation of the first and second permeable soil blocks 11 will be described. The first and second permeable soil blocks 11 are mainly laid for revetment on rivers and coastal embankments, and for forest roads for paving roads in mountains and forests.

When a large amount of rain falls on the upper surface of the first permeable soil block 11, the water is formed inside the permeable soil material layer 13 as shown by the arrow in FIG. After gradually moving downward through the gap, it moves in the horizontal direction and is discharged from the side surface of the permeable soil block 11.

When a large amount of rain falls on the upper surface of the second permeable soil block 11, the water is first formed inside the permeable soil material layer 13 as shown by the arrow in FIG. Gradually moves downward through the gap, and
Reach 4 Next, it quickly moves in the horizontal direction through a gap formed inside the water-permeable intermediate layer 14 and is discharged from the side surface of the water-permeable soil block 11.

Therefore, it is difficult for water pools to be formed on the surfaces of the first and second permeable soil blocks 11. Further, since the water-permeable soil material layer 13 has water retention by the gap formed therein, water is appropriately stored in the gap even after the rain stops. In the case of a small amount of rainwater, the water is stored in gaps formed inside the permeable soil material layer 13 of the first and second permeable soil blocks 11. Therefore, also in this case, similarly to the case of the large amount of rainwater, it is difficult for water pools to be formed on the surface of these permeable soil blocks 11.

At the place where the first and second permeable soil blocks 11 are laid, for example, on a very hot day in the summer, the blocks are stored in the gaps inside the permeable soil material layer 13 as described above. Water evaporates by removing heat of vaporization from the surface of the permeable soil material layer 13 and maintains the surface at an appropriate temperature. Further, at this time, water is appropriately supplied to the surface of the permeable soil material layer 13 to prevent the surface from cracking due to drying.

When a heavy object such as a vehicle passes over the first and second permeable soil blocks 11, air bubbles mainly in the gaps formed inside the permeable soil material layer 13 are generated from the vehicle and the like. Noise can be absorbed. further,
The air bubbles in the water-permeable soil material layer 13 can act like a shock absorbing material, and can absorb vibration generated by a vehicle or the like.

The surface of the first and second permeable soil blocks 11 has a permeable soil material layer 13 mainly composed of soil.
It can grow plants that do not take root deep in the ground. By the action of these plants, the water permeability of the first and second water-permeable soil blocks 11,
Water retention, temperature control performance, humidity control performance, soundproofing and vibration-proofing effects are further improved, and can be harmonized with nature.

Next, the effect of the permeable soil block 11 of the above embodiment will be described. The first and second permeable soil blocks 11 of the embodiment
In the first embodiment, a water-permeable soil material layer 13 having high water permeability is formed on the strength holding material layer 12 having high strength. Therefore, the strength retaining material layer 12 supports the entire permeable soil block 11 and can maintain its strength at a high level, and allows water such as rainwater to pass through the permeable soil material layer 13, and The water can be discharged from the side surface of the permeable soil block 11 and water pools can hardly be formed on the surface of the permeable soil block 11. Therefore, when laid for revetment, forest road, or the like, it is possible to provide an easily usable ground that can exhibit water permeability while maintaining strength.

According to the first and second permeable soil blocks 11 of the embodiment, by making the thickness ratio of the strength retaining material layer 12 and the permeable soil material layer 13 approximately 1: 1, The balance between the strength and the water permeability of the water-permeable soil block 11 can be improved.

According to the first and second permeable soil blocks 11 of the embodiment, since the permeable soil material layer 13 has a water retention property, the permeable soil material layer 13 is formed of water such as rainwater. Can be stored over a long period of time, and the water evaporates to exhibit temperature control performance and humidity control performance. That is, for example, on a hot summer day, the water evaporates, so that the surface temperature of the permeable soil block 11 can be prevented from rising excessively, and can be maintained at an appropriate temperature. Drying of the surface can be suppressed, and cracking can be prevented.

According to the first and second permeable soil blocks 11 of the embodiment, since there is a gap inside the permeable soil material layer 13, noise generated from a vehicle or the like is reduced. In addition to being able to be absorbed by the bubbles in the gap, it is possible to absorb the shock due to the vibration generated by the vehicle or the like.

According to the first and second permeable soil blocks 11 of the embodiment, since the soil is used as the material forming the permeable soil material layer 13, organisms such as plants grow. It can be harmonized with the surrounding natural environment when laid for revetment and forest roads. Furthermore, when a plant is growing, the effect of the plant can further improve the water permeability, water retention, temperature control performance, humidity control performance, soundproofing effect, and vibration damping effect.

The first and second permeable soil blocks 11 of the embodiment are different from the conventional asphalt or concrete ground pavement, and the plurality of permeable soil blocks 11 are different from each other.
Are laid in such a way that their sides are in contact with each other.
Therefore, at least a small gap is formed on the side face of each block, and water such as rainwater can be discharged from the side face of the block facing the gap. For this reason, it is not necessary to provide a drainage channel, and even if a concave portion is formed due to local land subsidence or the like, a water pool is hardly formed.

According to the first and second permeable soil blocks 11 of the embodiment, by mixing the porous material into the permeable soil material layer 13, the permeable soil material layer 13 has In addition, a gap capable of exhibiting water retention can be reliably formed. Furthermore, by setting the pore diameter of the porous material to 5 μm to 5 mm and the particle diameter to 3 to 15 mm, the balance between water permeability and water retention can be improved, and the strength of the water-permeable soil material layer 13 can be improved. The drop can be prevented. In addition, by using charcoal as a porous material, waste treatment can be performed simultaneously, which is economical.

According to the first and second permeable soil blocks 11 of the embodiment, as the soil constituting the permeable soil material layer 13, clay or clay-containing soil, sludge cake, Kira clay, etc. By using, the strength of the permeable soil material layer 13 can be maintained at an appropriate level. Furthermore, by using sludge cake or Kira clay, industrial waste treatment can be performed at the same time, which is economical. In addition, when using the soil at the construction site, the cost of transportation and the like can be reduced, which is economical.

According to the first and second permeable soil blocks 11 of the embodiment, general soil stabilization mainly comprising at least one of quick lime, slaked lime, cement, gypsum and blast furnace slag as a soil stabilizer. By using the agent, it is possible to form the permeable soil material layer 13 that can maintain the strength at an appropriate level. Furthermore, by using at least one of quick lime, slaked lime and gypsum, a crystal such as ettringite can be generated inside the permeable soil material layer 13, so that the strength of the permeable soil material layer 13 is further improved. In addition, water permeability and water retention can be improved.

Also, by using blast furnace slag and quicklime or slaked lime, a solidified product having a high porosity can be generated, so that the permeability and water retention of the permeable soil material layer 13 can be improved. . In addition, by using quick lime, since it reacts with moisture in soil to generate heat, the solidification reaction of the permeable soil material layer 13 can be promoted. On the other hand, by using dust collected as a soil stabilizer, industrial waste treatment can be performed at the same time, which is economical.

According to the first and second permeable soil blocks 11 of the embodiment, as the material constituting the permeable soil material layer 13, 50 to 400% by weight of the porous material and 3 to It contains 20% by weight of a soil stabilizer. Therefore, the water-permeable soil material layer 13 can reliably exhibit desired water permeability and water retention while maintaining appropriate strength.

According to the second permeable soil block 11 of the embodiment, the strength retaining material layer 12 and the permeable soil material layer 13
By forming the water-permeable intermediate layer 14 having a very good water permeability between these steps, the water permeability of the water-permeable soil block 11 can be further improved. Further, by making the water-permeable intermediate layer 14 approximately half the thickness of the water-permeable soil material layer 13, sufficient water-permeability can be exhibited, and the water-permeable soil block 11 can be formed as thin as possible. Is possible.

According to the second permeable soil block 11 of the embodiment, by mixing the gravel to form the permeable intermediate layer 14, a size that allows water to quickly pass between the gravel particles. As a result, a gap is formed, and the water permeability of the water-permeable soil block 11 can be further improved. Further, by setting the particle size of the gravel to 30 to 50 mm, it is possible to impart strength that is not crushed by heavy objects such as vehicles while maintaining high water permeability of the water-permeable soil block 11.

[0047]

EXAMPLES Examples of the above embodiment will be described below. (Examples 1 to 3) In Examples 1 to 3, the porous material
The soil and soil stabilizer were mixed in the mixing ratio shown in Table 1 and
mx 1m width, using a bottomed square box-shaped mold
A water-permeable soil material layer 13 of 0 cm was formed. The permeability coefficient (cm / sec), the uniaxial strength (kg · f / cm ² ), and the surface temperature (° C.) at an outside air temperature of 35 ° C. were measured for these permeable soil material layers 13, and are shown in Table 1.

In this embodiment, as the porous material, the particle size is 3.0 to 5.0 mm, the water content is 20.8% by weight,
Boiler bottom ash with a wet density of 0.68 g / cm ³ was used. The soil has a particle size of 0.5 mm or less and no moisture.
Dry clay having a wet density of 0.91 g / cm ³ -1% by weight was used. As a soil stabilizer, cement (commercially available Portland cement), slaked lime (Kawai Lime Industry Co., Ltd., particle size 0.075 mm or less, wet density 1.46 g / c)
m ³ ), a mixture of gypsum (commercially available anhydrite) and water in a weight ratio of 2: 7: 1: 40 was used.

The test method was performed in accordance with the standards set by the Japan Society of Geotechnical Engineers.
T311, JSF T for uniaxial compressive strength test
511 was performed. Regarding the measurement of the surface temperature, the permeable soil material layer 1 was installed for a while in a place exposed to direct sunlight during the summer day when the outside air temperature was 35 ° C.
The surface temperature of No. 3 was measured. (Comparative Example 1) Cement, sand, gravel, and water were mixed to produce a concrete block having a length of 1 m, a width of 1 m and a thickness of 20 cm according to a conventional method. Sec), the uniaxial strength (kg · f / cm ² ), and the surface temperature (° C.) at an outside air temperature of 35 ° C. were measured. Table 1 shows the results.

[0050]

[Table 1] From the results in Table 1, the permeable soil material layers 13 of Examples 1 to 3 were obtained.
Has a higher water permeability than the concrete block of Comparative Example 1, indicating that the water permeability was good. In addition, the permeable soil material layer 13 of Examples 1 to 3 has an outside air temperature of 35 ° C. as compared with the concrete block of Comparative Example 1.
The surface temperature of the sample was low, indicating that the temperature control performance was good.

On the other hand, the permeable soil material layer 13 of Examples 1 to 3
Although the uniaxial strength is slightly lower than that of the concrete block of Comparative Example 1, it was shown to be a sufficiently practical value. The permeable soil block 11 composed of the permeable soil material layer 13 has a strength retaining material layer 12 typified by the concrete block of Comparative Example 1 formed below the permeable soil material layer 13. Therefore, it is judged that there is almost no problem in strength in practical use.

The above embodiment can be modified as follows. In the first permeable soil block 11 of the embodiment, as shown in FIG. 2A, the shape of the upper surface of the strength holding material layer 12 is a curved surface shape such that the vicinity of the center is raised, or the vicinity of the center is increased. Be composed of such inclined surfaces.

With such a configuration, the drainage capacity of the permeable soil block 11 can be further improved, and the formation of a water pool can be made difficult. In the second permeable soil block 11 of the embodiment, as shown in FIG. 2B, the upper surfaces of the strength retaining material layer 12 and the permeable intermediate layer 14 are formed into a curved surface shape such that the vicinity of the center rises, or the center. Construct from an inclined surface that makes the neighborhood higher.

With such a configuration, the drainage capacity of the permeable soil block 11 can be further improved, and the formation of water pools can be suppressed. In the second permeable soil block 11 of the embodiment, as shown in FIG. 2 (c), the upper surface of the strength retaining material layer 12 has a curved surface shape such that the vicinity of the center is raised or the vicinity of the center is raised. Be composed of inclined surfaces.

With such a configuration, the drainage capacity of the permeable soil block 11 can be further improved, water pools can be hardly formed, and temperature control performance and humidity control performance can be exhibited uniformly. .

In the first and second permeable soil blocks 11 of the embodiment, a drain pipe is formed in which the strength holding material layer 12 is vertically penetrated. With this configuration,
It is possible to further improve the drainage capacity of the permeable soil block 11 and make it difficult for water pools to be formed.

In the second water-permeable soil block 11 of the embodiment, a plurality of water-permeable intermediate layers are provided between the strength holding material layer 12 located at the bottom and the water-permeable soil material layer 13 located at the top. 14 and the permeable soil material layer 13 are alternately laminated.

With this configuration, the temperature control performance and humidity control performance of the permeable soil block 11 can be further improved. The first and second permeable soil blocks 11 of the embodiment
In the above, planting a plant on the surface of the permeable soil block 11. For example, making the surface of the permeable soil block 11 a lawn.

With this configuration, it is possible to improve at least one of the water permeability, the water retention, the temperature control performance, the humidity control performance, the soundproof effect, and the vibration-proof effect of the water-permeable soil block 11. Moreover, when laying the permeable soil block 11 planted with lawn for revetment, it can be harmonized with the surrounding natural environment and can be effectively used as a plaza for people to relax.

The first and second permeable soil blocks 11 of the embodiment have a planar shape of a polygon such as a rectangle, a triangle, a pentagon, a hexagon, an octagon, a dodecagon, a circle or an ellipse. .

Next, the technical ideas that can be grasped from the above embodiment will be described below. (1) The pore diameter of the pores of the porous material is 5 μm to 5 m
The permeable soil block according to claim 3, wherein m is m.

With this configuration, it is possible to reliably exhibit water permeability and water retention, as well as to reliably exhibit temperature control performance and humidity control performance by evaporating water inside.

(2) The particle size of the porous material is 3 to 15
The permeable soil block according to claim 3 or (1). With such a configuration, it is possible to reliably exhibit water permeability and water retention.

(3) The permeable soil block according to claim 2 or 3, wherein the permeable intermediate layer is formed by mixing cement and gravel, and the grain size of the gravel is 30 to 50 mm.

In the case of such a configuration, more excellent water permeability can be exhibited.

[0066]

Since the present invention is configured as described above, it has the following effects. According to the permeable soil block according to claim 1, when laid for revetment, forest road, etc., it is possible to exhibit water permeability while maintaining strength, and to evaporate water in the inside to control temperature. And can exhibit humidity control performance. Furthermore, the sound-permeable effect and the vibration-proof effect can be exhibited by the water-permeable soil material layer and the air bubbles therein, and the water-permeable soil material layer can be harmonized with nature.

According to the water-permeable soil block of the second aspect, in addition to the effect of the first aspect of the invention, further excellent water-permeability can be exhibited. According to the permeable soil block of the third aspect, the effects of the invention of the first aspect can be reliably exhibited.

[Brief description of the drawings]

FIGS. 1A and 1B are perspective views showing a state in which a part of a first and a second permeable soil block of an embodiment is broken.

FIGS. 2A, 2B and 2C are perspective views each showing a permeable soil block other than the embodiment.

[Explanation of symbols]

11: permeable soil block, 12: strength retaining material layer, 13
... a permeable soil material layer, 14 ... a permeable intermediate layer.

──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI Theme coat ゛ (Reference) C09K 17/10 C09K 103: 00 (72) Inventor Akihiko Yokoseki 681 Ishigami, Kawabe-cho, Kamo-gun, Gifu Prefecture (72) Inventor Hideki Niwa 1-49-2 Emucho, Nishi-ku, Nagoya-shi, Aichi F-term (reference) 2D018 EA02 2D051 AA02 AA06 AD07 AF01 AF03 AF05 AF14 DA01 DB02 4G052 AB24 AB29 AB42 4H026 CA01 CA02 CA04 CA06 CC06

Claims (3)

[Claims] 1. A water permeable soil block comprising a strength holding material layer and a water permeable soil material layer formed on the strength holding material layer. 2. The permeable soil block according to claim 1, further comprising a water-permeable intermediate layer having better water permeability than the water-permeable soil material layer, between the strength retaining material layer and the water-permeable soil material layer. 3. The permeable soil material layer is formed by mixing a porous material, soil and a soil stabilizer.
Or the permeable soil block according to claim 2.