JPH05280029A - Soil drainage structure for planting - Google Patents

Abstract

(57) [Summary] [Structure] The foamed resin plate member 4 for drainage is provided below the customer soil layer 2 with the water-permeable sheet 3 for civil engineering interposed. On the upper surface of the drainage foamed resin plate-like body 4, there is provided a projection pillar 9 for providing a space between the water-permeable sheet 3. [Effects] The voids formed by the protruding columns 9 are filled with moisture due to the evaporated water of the excess water accumulated in the drainage foam resin plate-shaped body 4, and the roots of the plants on the upper side of the water-permeable sheet 4, or Oxygen and water or nutrient water can be supplied to the roots that have penetrated through the water-permeable sheet 4 and thus can provide a favorable growth environment to the roots. As a result, it is possible to improve water retention and wettability while ensuring weight reduction and drainage, and to secure a total growth environment for plants.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention provides a foamed resin plate material for drainage on the lower side of soil through, for example, a water-permeable sheet when planting and greening on an artificial ground such as a roof of a building or a terrace. It is related to the soil drainage structure for planting.

[0002]

2. Description of the Related Art In recent years, as part of urban greening, soil has been laid on the roof of a building or on an artificial ground such as a terrace and planted. In this case, the slab has a load limit and is required to be lightweight. In addition, drainage is required for rainwater and watering. Furthermore, since the roof of a building is a place with strong winds, the soil is easily dried and water retention is required. Further, since the roots of plants need to take in oxygen, air permeability is also required. These conditions make it preferable for plant roots to take in oxygen, water, and nutrients from a moist air layer.

In consideration of the above points, in the conventional soil drainage structure for planting, gravel or crushed stone is used as a drainage layer, and in recent years, perlite (obsidian, etc. is light-weighted by firing and foaming to reduce weight). The aggregate) forms an underground drainage layer to promote drainage.

However, this type of underground drainage layer is usually
Because it is formed to a thickness of 10 to number 10 cm, weighs about by crushed stone 1.8 t / m ^3, about in pearlite 0.2t / m ³
Becomes Therefore, when loading materials on the roof,
Further weight reduction is required because it causes time and cost. On the other hand, crushed stone and perlite have a problem that it is difficult to spread them to a uniform thickness, which impedes water flow and cannot expect uniform drainage.

In order to solve such a problem, for example, in Japanese Examined Patent Publication No. 63-54084, as shown in FIG. 8, a drainage pipe 52 having a mesh-like or perforated structure is buried in a subsoil layer 51. A foamed resin plate 54 provided with a large number of water holes 53 is provided above the subsoil layer 51, and a planting 57 is applied to a topsoil layer 56 laid above the foamed resin plate 54 via a water permeable layer 55. It is disclosed to do.

In Japanese Utility Model Laid-Open No. 51-18404, for example, as shown in FIG. 9, an upper wall 62 having a large number of through holes 61 and a lower wall 63 having no holes are arranged in parallel. Disclosed is a plastic drain plate 65 which is supported by the ribs 64 to be an integrally molded product.

The foamed resin plate 54 and the plastic drain plate 65 improve the problems of weight reduction, drainage and breathability.

[0008]

However, in the conventional soil drainage structure for planting described above, although the weight reduction and the drainage performance can be achieved, the water retention property of the foamed resin plate 54 is from the front surface to the back surface. Since the water passage hole 53 that penetrates through is formed, the lower wall 6 of the plastic drain plate 65 is also formed.
Since 3 also does not have a function of collecting excess water,
None of them have a water retention function and still have problems. Further, although the air permeability is improved, the air layer is insufficient in a wet state, and there is still a problem.

The present invention has been made in view of the above-mentioned conventional problems, and an object thereof is to improve water retention and wettability while ensuring weight reduction and drainage, and to achieve total plant protection. The purpose of the present invention is to provide a soil drainage structure for planting that can secure a stable growth environment.

[0010]

In order to solve the above-mentioned problems, the soil drainage structure for planting of the invention according to claim 1 has a foamed resin plate for drainage through a water-permeable sheet below the soil for planting. In the soil drainage structure for planting provided with a strip-shaped body, the upper surface of the foamed resin plate body for drainage is characterized in that a convex portion for forming a gap between the sheet and the water-permeable sheet is formed. There is.

In the soil drainage structure for planting according to the second aspect of the invention, in order to solve the above problems, a foamed resin plate for drainage is provided below the planting soil via a water permeable sheet. The soil drainage structure for planting is characterized in that a recess for a water pool is formed on the upper surface of the drainage foamed resin plate.

In order to solve the above problems, the soil drainage structure for planting according to a third aspect of the present invention is a drainage soil for planting, in which a foamed resin plate for drainage is provided under the planting soil. In the structure, the drainage foamed resin plate-like body is composed of a plurality of blocks, and a water storage groove for overflowing drainage is formed at a joint portion between the blocks.

[0013]

According to the first aspect of the present invention, since the convex portion for forming the gap between the water-permeable sheet and the water-permeable sheet is formed on the upper surface of the drainage foamed resin plate, the convex portion is formed. The created voids are filled with moisture due to the evaporated water of the excess water accumulated in the drainage foamed resin plate. For this reason,
The void portion can supply oxygen and water or nutrient water to the root of the plant on the upper side of the water-permeable sheet, or the root that has penetrated through the water-permeable sheet, and thus can provide a preferable growth environment for the root. .. Therefore, it is possible to improve the water retention and wettability while ensuring the weight reduction and the drainage, and to secure the total growth environment for the plant.

Further, according to the second aspect of the present invention, since the recess for the water pool is formed on the upper surface of the drainage foamed resin plate, the planting soil is formed by the evaporative water from the water pool of the recess. Water can be supplied to the bottom and roots of.
In addition, the root that has penetrated through the water-permeable sheet can directly absorb water from the water pool in the recess. Therefore, it is possible to improve the water retention and wettability while ensuring the weight reduction and the drainage, and to secure the total growth environment for the plant.

According to the structure of claim 3, the foamed resin plate for drainage is composed of a plurality of blocks, and a water storage groove for overflowing drainage is formed at the joint between the blocks. Therefore, when the water is drained, the water is once stored in the water storage groove and then overflows and is drained. Therefore, even if the lower side of the foamed resin plate for drainage is in a dry state, since water is stored in the water storage groove, water is supplied by this water storage. As a result, the drying of the planting soil above the drainage foamed resin plate can be delayed. Therefore, it is possible to improve the water retention and wettability while ensuring the weight reduction and the drainage, and to secure the total growth environment for the plant.

[0016]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The following will describe one embodiment of the present invention with reference to FIGS. As shown in FIG. 1, the soil drainage structure for planting of the present embodiment is, for example, as shown in FIG. 1, a soil layer 2 as a soil for planting, which is provided on the upper side of a waterproof concrete concrete frame 1 on the roof of a building. It is applied to drainage structure. A foamed resin plate member 4 for drainage is laid under the above-mentioned soil layer 2 through a water-permeable sheet 3 for civil engineering as a water-permeable sheet for preventing the outflow of soil.

The soil layer 2 is, for example, artificial soil made of lightweight soil or natural soil. Moreover, the water-permeable sheet 3 for civil engineering is, for example, polypropylene, polyethylene,
Sheets of polyester, nylon, etc., or commonly referred to as "geotextile", for example Unitika Ltd.
It is made of a non-woven fabric for civil engineering such as a product name "21102 / BVG" manufactured by the company.

The material of the foamed resin plate 4 for drainage is preferably, for example, foamed polystyrene excellent in durability and compressive strength, but foamed polyethylene, polypropylene,
In addition to resins such as polyamide, vinyl chloride, epoxy, urea and polyurethane, it is also possible to use synthetic rubber and resin concrete. The foamed resin plate member 4 for drainage
A bead-molded article obtained by pre-foaming expandable resin particles such as polystyrene, polyethylene, and polypropylene containing a foaming agent and foam-molding this in a molding die with a heating medium such as steam is preferably used. For example, the density of an expanded polystyrene bead molded product having an expansion ratio of 40 times is about 0.025.
It is g / cm ³ . Therefore, in the foamed resin plate member 4 for drainage in which the porosity of the molded product is, for example, 40%, the density is about 0.015 t / m ³ , so that an ultralight structure can be obtained.

Further, as shown in FIG. 2, the drainage foam resin plate member 4 is composed of a plurality of blocks 4a ... For the convenience of handling, the size of each block is, for example, a square whose one side is 0.3 to 2.0 m,
The thickness is preferably about 2 to 30 cm.

As shown in FIG. 1, the upper surface of one block 4a of the drainage foamed resin plate member 4 is an inclined surface 5 in one direction, so that a water gradient is formed.
The two adjacent blocks 4a, 4a are arranged such that the upper and lower comers of the slope are adjacent to each other, and that the combination is laid side by side in the front-rear direction (the XY direction in FIG. 2). Is becoming Although the upper surface of one block 4a in this embodiment is the inclined surface 5 in one direction, the present invention is not limited to this, and for example, as shown in FIG. 3, on the upper surface of one block 4a, While it is possible to form the inclined surfaces 6 in two directions, as shown in FIG. 4, one block 7a has one apex 7 ... On the upper surface, and from this apex 7 to each side. It is also possible to use the descending slope 24.

As shown in FIGS. 1 and 2, the upper surface of the block 4a is formed in a wave shape and has a large number of recesses 8 for accumulating surplus water such as rainwater and sprinkling water. .. It is not always necessary to form the recesses 8 ... In a wavy shape on the upper surface of the block 4a, but it is also possible to form a large number of holes 8a on the upper surface of the block 4a, for example, as shown in FIG.

On the other hand, on the inclined surface 5 of the block 4a, projection pillars 9 are formed as projections for forming a space between the block 4a and the water-permeable sheet 3 for civil engineering. This protruding pillar 9 ...
As shown in FIG. 1, the upper surface of each of the projecting pillars 9 ... Is formed so as to be flush with each other, and the water-permeable sheet 3 for civil engineering provided on the upper side can be laid parallel to the surface of the concrete skeleton 1. .. Therefore, the length in the height direction of each protruding column 9 is long at the lower part of the inclined surface 5 and short at the upper part of the inclined surface 5.

.. are formed at the bottom of each block 4a. This leg 10 is shown in FIG. 6 (b).
As shown in (c), both end portions and the central portion in the horizontal direction have an E shape projecting downward in a cross section and are capable of withstanding a compressive load. The leg length is preferably about 5 to 100 mm. That is,
In the continuous space formed between the legs 10 ... and the concrete frame 1, the surplus water of the soil layer 2 is added to the concrete frame 1.
It is a drainage space for rapid drainage according to the water gradient of the above and for providing ventilation.

Further, as shown in FIG. 7, a water storage groove 11 for overflowing the drainage is formed at the joint between the blocks 4a ... That is, FIG.
As shown in (a) and (b), the water storage grooves 11, 11 are formed on one side of each block 4a ... And on the side next to it, and the bank 13 is formed at each edge.・ 13 is formed. The bank portions 13 and 13 are formed to have a height lower than that of the inclined surface 5, while the bank portions 13 and 13 are provided with horizontal water channels 20 on the upper surface thereof for passing overflow water. In addition, at both ends of the upper surface of the bank portion 13,
The protrusions 22 are provided, and the blocks 4a are connected to each other by fitting with the fitting grooves 23 formed on the back surface of the eaves portion 12 of the other blocks 4a described later. It has become.

Further, as shown in FIG. 7, the side portions in the other two directions of the blocks 4a, etc. substantially cover the water storage grooves 11 of the other blocks 4a when the blocks 4a are joined to each other, The eaves portion 12 that abuts the upper surface of the bank portion 13 is formed, and a plurality of vertical water channels 14 are formed in the vertical direction on the surface of the other block 4a facing the bank portion 13.

Further, when the blocks 4a ... Are joined to each other, a gap 13 is formed above the water storage groove 11, and drainage flows into the water storage groove 11 through the gap 13 to temporarily store the water. After that, it overflows from the horizontal water channels 20 and is drained downward through the vertical water channels 14.

As described above, in the soil drainage structure for planting of the present embodiment, the projection pillars 9 are provided on the upper surface of the drainage foam resin plate-like body 4 for providing a space between the drainage foam sheet 3 for civil engineering. Are formed, the voids formed by the projecting pillars 9 are filled with moisture by the evaporated water of the drainage.
Therefore, the void portion can supply oxygen and water or nutrient water to the root of the plant on the upper side of the civil engineering permeable sheet 3 or the root that has penetrated through the civil engineering permeable sheet 3, On the other hand, it functions as a moist aeration layer and a water retention layer that provide a favorable growth environment. Further, since the drainage foamed resin plate-shaped body 4 is made of a foamed resin plate, the height of each of the projection pillars 9 ... Is so that the upper surfaces of the projection pillars 9 ... Direction length, slope 5
It is easy to make it long at the lower part of the above and short at the upper part of the inclined surface 5.

Further, since the recesses 8 for accumulating water are formed on the upper surface of the drainage foamed resin plate body 4,
Moisture can be supplied to the bottom and roots of the soil layer 2 by the evaporated water from the water pool of the recesses 8 ... Further, the roots that have penetrated through the water-permeable sheet 3 for civil engineering have entered the recesses 8 ...
Water can be directly absorbed from the pool.

Further, the drainage foamed resin plate member 4 is composed of a plurality of blocks 4a ... And a water storage groove 11 for overflowing the drainage is formed at the joint between the blocks 4a. At this time, the water is once stored in the water storage groove 11 and then overflows and is drained. Therefore, even if the lower side of the drainage foamed resin plate body 4 is in a dry state, the water is stored in the water storage groove 11, so that the water is supplied by this water storage. As a result, it is possible to delay the drying of the soil layer 2 on the upper side of the drainage foamed resin plate member 4.

Further, since the upper surface of the drainage foamed resin plate body 4 has the inclined surface 5, it becomes possible to guide the excess water to the water storage grooves 11 formed on the side portions of the blocks 4a. There is.

Further, since the legs 10 are formed at the bottom of each block 4a, the continuous space formed between the legs 10 and the concrete skeleton 1 allows the drainage layer to have a constant thickness. Can be easily secured. Therefore, the excess water can be rapidly drained, the drainage performance can be improved, and the air permeability can be improved.

As a result, it is possible to improve the water retention, the air permeability and the wettability while ensuring the weight reduction and the drainage, and to secure the total growth environment for the plants.

[0033]

As described above, the soil drainage structure for planting according to the first aspect of the present invention has the following features:
This is a configuration in which a convex portion for forming a void portion is formed between the water-permeable sheet.

As a result, the voids formed by the protrusions are filled with moisture by the evaporated water of the excess water accumulated in the drainage foamed resin plate. Therefore, the void portion can supply oxygen and water or nutrient water to the root of the plant on the upper side of the water permeable sheet, or the root that has penetrated through the water permeable sheet, thus giving a preferable growth environment to the root. be able to. Therefore, it is possible to improve the water retention and wettability while ensuring the weight reduction and the drainage, and to secure the total growth environment for the plant.

The soil drainage structure for planting according to the invention of claim 2 is
As described above, the recess for retaining water is formed on the upper surface of the drainage foamed resin plate.

Thus, the water can be supplied to the bottom and roots of the planting soil by the evaporated water from the water pool in the recess. In addition, the root that has penetrated through the water-permeable sheet can directly absorb water from the water pool in the recess. Therefore, it is possible to improve the water retention and wettability while ensuring the weight reduction and the drainage, and to secure the total growth environment for the plant.

The soil drainage structure for planting according to the invention of claim 3 is
As described above, the foamed resin plate for drainage is composed of a plurality of blocks, and the water storage groove for overflowing the drainage is formed at the joint between the blocks.

As a result, when the water is drained, the water is once stored in the water storage groove and then overflows and is drained. Therefore, even if the lower side of the foamed resin plate for drainage is in a dry state, since water is stored in the water storage groove, water is supplied by this water storage. As a result, the drying of the planting soil above the drainage foamed resin plate can be delayed. Therefore, it is possible to improve the water-retaining property and the wettability while ensuring the weight reduction and the drainage property, and it is possible to ensure the total growth environment for the plant.

[Brief description of drawings]

FIG. 1 is a cross-sectional view showing a soil drainage structure for planting according to an embodiment of the present invention.

FIG. 2 is a perspective view showing the soil drainage structure for planting.

FIG. 3 is a front view showing a structure of another upper surface portion of the drainage foamed resin plate-like body used for the above-described planting soil drainage structure.

FIG. 4 is a perspective view showing the structure of still another upper surface portion of the drainage foamed resin plate-like body used for the above-described planting soil drainage structure.

FIG. 5 is a front view showing the structure of another concave portion of the drainage foamed resin plate-like body provided in the above-described soil drainage structure for planting.

FIG. 6 shows a structure of a block of a foamed resin plate for drainage, which is provided in the above-mentioned soil drainage structure for planting,
(A) is a plan view, (b) is a front view, and (c) is a bottom view.

FIG. 7 is a cross-sectional view showing a connection structure of each block of the drainage foamed resin plate-like body provided in the above-mentioned planting soil drainage structure.

FIG. 8 is a cross-sectional view showing a conventional soil drainage structure for planting.

FIG. 9 is a perspective view showing a drain plate used in another conventional soil drainage structure for planting.

[Explanation of symbols]

 1 Concrete skeleton 2 Soil layer (soil for planting) 3 Water-permeable sheet for civil engineering (water-permeable sheet) 4 Foamed resin plate for drainage 4a Block 5 ・ 6 Sloping surface 8 Recess 9 Recessed pillar (convex) 10 Leg 11 Reservoir groove 12 Eaves 13 Embankment

Claims (3)

[Claims] 1. A soil drainage structure for planting, in which a foamed resin plate body for drainage is provided below a soil for planting through a water-permeable sheet, wherein the upper surface of the foamed resin plate body for drainage comprises: A soil drainage structure for planting, characterized in that a convex portion for forming a void is formed between the water permeable sheet and the water permeable sheet. 2. A soil drainage structure for planting, in which a foamed resin plate body for drainage is provided below a soil for planting through a water-permeable sheet, wherein the upper surface of the foamed resin plate body for drainage is: A soil drainage structure for planting, characterized in that a recess for a water pool is formed. 3. A soil drainage structure for planting, in which a foamed resin plate for drainage is provided below the planting soil, wherein the foamed resin plate for drainage comprises a plurality of blocks,
A soil drainage structure for planting, wherein a water storage groove for overflowing drainage is formed at the joint between the blocks.