JP2021123999A - Vegetation base and concrete placing method - Google Patents

Abstract

To provide a vegetation base having excellent water retention and strength.SOLUTION: A vegetation base 1 of an embodiment comprises: a concrete base having through holes; particles having a water absorption rate of 10% or more filled in the through holes; a groove formed on the upper surface of the concrete base; a water pipe placed in the groove; and a water guide layer integrally formed to include the groove on the upper surface of the concrete base. The water guide layer is composed of a crushed product of a porous material having a particle size of 3 mm or less and particles having a water absorption rate of 10% or more.SELECTED DRAWING: Figure 1

Description

The present invention relates to a greening base and a concrete placing method.

For example, in Patent Document 1, a water supply conduit is provided in a pipe groove formed in a paved base, and a first water guide sheet that wraps around the lower part of the water supply conduit and reaches the edge surface portion of the pipe groove is described above. Along with laying only in the portion along the pipe groove, a second water guiding sheet that completely covers the surface of the paved base is laid from above the first water conducting sheet, and is laid on the second water conducting sheet. A wet pavement system characterized by the construction of a permeable pavement layer is disclosed.

Japanese Unexamined Patent Publication No. 2005-351026

An object of the present invention is to provide a greening base having excellent water retention and strength.

The greening base according to the present invention has a concrete base provided with through holes and particles filled in the through holes and having a water absorption rate of 10% or more.

Preferably, the particles are crushed products of a porous material and have a particle size of 3 mm or less.

Preferably, it further has a groove formed on the upper surface of the concrete base, a water sprinkler pipe arranged in the groove, and a water guiding layer integrally formed including the groove on the upper surface of the concrete base. The water conducting layer is composed of particles having a water absorption rate of 10% or more.

Preferably, the concrete base has sufficient strength and thickness to allow a vehicle to enter.

Preferably, the concrete base includes a plurality of concrete bases having different strength and water retention.

Further, the concrete placing method according to the present invention includes a step of pouring concrete to form porous concrete and a step of pouring particles and water having a water absorption rate of 10% or more into the through holes of the porous concrete.

Preferably, the step of pouring the particles and water is carried out within 48 hours of pouring the concrete.

Preferably, the step of pouring the particles and water is carried out from the start of setting of the concrete to the completion of solidification of the concrete.

According to the present invention, a greening base having excellent water retention and strength can be obtained.

It is sectional drawing which illustrates the greening base 1 in embodiment. It is a flowchart which illustrates the concrete placing method (S10) in the greening base 1. It is sectional drawing which illustrates the modification of the greening base 1 of embodiment.

Hereinafter, embodiments according to the present invention will be described with reference to the drawings. However, the scope of the present invention is not limited to the illustrated examples.
First, the configuration of the greening base 1 in this embodiment will be described.
FIG. 1 is a cross-sectional view illustrating the greening base 1 in the embodiment.
As illustrated in FIG. 1, the greening base 1 is constructed on the paved base F. The greening base 1 has a water guide layer 10, a water retention layer 20, and a drainage control sheet 40 in this order from the lawn and the lawn floor soil side to the paved base F side, and these are laminated. Further, the lawn floor soil is laminated on the greening base 1, and the lawn is planted on the lawn floor soil. As the roots of the planted lawn grow, they extend to the water conveyance layer 10, the water retention layer 20, the drainage control sheet 40, and the paved base F of the greening base 1, and in this figure, the roots of the lawn are covered. The state of extending to the pavement base F is illustrated.

The water-conducting layer 10 is a layer containing water-retaining particles (water-retaining particles 5), and the water-conducting layer 10 of this example is mainly composed of water-retaining particles 5. The water conveyance layer 10 is laminated on the upper surface of the water retention layer 20 described later with a thickness of, for example, 5 mm or more and 5 cm or less, in this example, 1 cm or more and 5 cm or less, and is tightened by applying pressure from the lawn and the lawn floor soil side. It is in a solidified state. The water-retaining particles 5 constituting the water-conducting layer 10 are crushed or crushed products of a porous material, and are particles having a water absorption rate of 10% or more, and in this example, a water absorption rate of 10% or more and 20% or less. For example, the water-retaining particles 5 are fine particles obtained by crushing diatomaceous earth, chamotte, roof tiles, bricks, etc., pumice stones, or fine particles obtained by crushing lava. That is, the water-retaining particles 5 are fine particles of a porous material. The water-retaining particles 5 of this example are fine particles obtained by crushing a roof tile. The particle size of the water-retaining particles 5 is, for example, 0.1 mm or more and 10 mm or less, and in this example, 1 mm or more and 3 mm or less.
Further, the water-retaining particles 5 are also filled in a plurality of grooves 22 formed on the upper surface of the water-retaining layer 20 described later, and cover the irrigation pipe 8 arranged in the grooves 22. That is, a part of the water conveyance layer 10 covers the irrigation pipe 8.

The water retention layer 20 is a layer located between the water conveyance layer 10 and the drainage control sheet 40, and is a base layer made of concrete having a plurality of through holes (hereinafter, referred to as continuous voids). The water retention layer 20 of this example is made of porous concrete. The continuous voids in the water retention layer 20 are filled with the water retention particles 5.
Further, a plurality of grooves 22 are formed on the upper surface of the water retention layer 20. The groove 22 is a groove for arranging the irrigation pipe 8 described later. Here, the irrigation pipe 8 is an example of a sprinkler pipe according to the present invention, and is a pipe for supplying water mainly to plants. A plurality of grooves 22 are arranged at equal intervals at intervals of 40 cm or more and 60 cm or less. Each groove 22 is filled with a part of the water conveyance layer 10 with the irrigation pipe 8 arranged. As a result, a part of the water guide layer 10 filled in the groove 22 and the water guide layer 10 located on the upper surface of the water retention layer 20 are integrated. Further, the water retention layer 20 has a strength and a thickness sufficient for a vehicle to enter, and is, for example, 7 cm or more and 15 cm or less in thickness. The water retention layer 20 is an example of a concrete base according to the present invention.

The drainage control sheet 40 is a sheet for adjusting the amount of water discharged from the water retention layer 20. The drainage control sheet 40 may have a gap sufficient to temporarily retain the water that has passed through the water retention layer 20, or may be in a state where there is substantially no gap. For example, from the viewpoint of discharging excess water in the event of heavy rain, the drainage control sheet 40 may have a gap sufficient to temporarily retain the water that has passed through the water retention layer 20. From the viewpoint of efficiently retaining water, the drainage control sheet 40 may be in a state where there is substantially no gap. The drainage control sheet 40 of this example is a sheet having a gap that can be temporarily retained. As a result, the drainage control sheet 40 can temporarily retain water in the continuous voids of the water retention layer 20. Therefore, the water-retaining particles 5 constituting the water-retaining layer 20 and the water-conducting layer 10 can efficiently retain water. Although the drainage control sheet 40 of this example is provided on the lower surface of the water retention layer 20, the drainage control sheet 40 is not limited to this and may be omitted.
In this way, the greening base 1 can efficiently retain water by forming the water-retaining layer 10 with the water-retaining particles 5 and filling the voids of the water-retaining layer 20 with the water-retaining particles 5. .. As a result, the lawn can grow roots more in search of water retained not only in the water-conducting layer 10 but also in the water-retaining particles 5 inside the water-retaining layer 20.

Next, a concrete placing method in the greening base 1 of the embodiment will be described.
FIG. 2 is a flowchart illustrating a concrete placing method (S10) in the greening base 1.
As illustrated in FIG. 2, in step 100 (S100), the operator arranges the drainage control sheet 40 on the paved base F. If the drainage control sheet 40 is not required, this step can be omitted.
In step 102 (S102), the operator arranges a formwork for driving porous concrete. In addition, the operator arranges a formwork for forming the groove 22 at a position where the groove 22 is formed. In addition, a buried tree may be used instead of the formwork.

In step 104 (S104), the operator cleans the transport device for transporting the porous concrete, the driving equipment, and the area surrounded by the formwork. At this time, if there is water in the mold, remove it. Then, after cleaning, the worker pours the unsolidified porous concrete into the formwork.

In step 106 (S106), the operator confirms whether or not the porous concrete poured into the formwork has begun to solidify, and whether or not the so-called porous concrete is condensed. When the operator determines that the porous concrete has begun to condense (Yes), the process proceeds to the process of S108, and when it is determined that the porous concrete has not condensed (No), the operator returns to the work process of S106 and the porous concrete. Wait for the concrete to begin to set. If it is difficult to confirm the presence or absence of condensation of the porous concrete, the work process of S108 may be started about 8 to 10 hours after the porous concrete is poured into the mold.

In step 108 (S108), the operator puts the water-retaining particles 5 on the porous concrete in a state where it has started to condense and has not hardened in the mold, and water is poured into the formwork. In the work of pouring water, the worker sprinkles water using, for example, a watering hose or a high pressure washer. When the operator sprinkles water, the water-retaining particles 5 flow into the continuous voids of the porous concrete together with the water. Since the water-retaining particles 5 that have flowed into the continuous voids of the porous concrete stay in the continuous voids in a water-retaining state, water can be supplied from the inside of the porous concrete. As a result, the water retained in the water-retaining particles 5 can be supplied to the cement during the hydration reaction of the porous concrete. In this way, in the initial stage of hardening of the porous concrete, water can be efficiently supplied to the porous concrete by supplying water from the inside of the porous concrete and curing the porous concrete with water. .. As a result, the strength of the porous concrete can be increased, and cracks due to lack of water can be prevented.
Since the porous concrete is generally hardened after 1 to 2 days, it is preferable that the worker carries out the work process of S108 within 48 hours from the work of pouring the porous concrete (S104). In this example, it is carried out from the start of setting of the porous concrete to the completion of hardening and solidification, in other words, within 8 to 24 hours from the pouring work of the porous concrete.

In step 110 (S110), the worker removes the formwork after confirming that the solidification of the porous concrete has been completed (so-called formation of the water retention layer 20).
In step 112 (S112), the operator arranges the irrigation pipe 8 in the groove 22 formed on the upper surface of the solidified water retention layer 20. Then, the operator puts the water-retaining particles 5 on the upper surface of the water-retaining layer 20. At this time, the operator puts the water-retaining particles 5 into the groove 22 in which the irrigation pipe 8 is arranged so as to fill the groove 22. After charging the water-retaining particles 5, the operator rolls the water-retaining particles 5 using a compactor. As a result, the water-conducting layer 10 in which the water-retaining particles 5 filled in the groove 22 and the water-retaining particles 5 located on the upper surface of the water-retaining layer 20 are integrated can be formed.

In step 114 (S114), the worker plantes a plant such as a lawn in the planting area on the upper surface of the headrace layer 10, for example, in a nursery filled with soil.
In this way, the worker can obtain the greening base 1. In this example, the case where the plant is planted in S114 after removing the formwork in S110 is taken as a specific example, but the present invention is not limited to this, and the work of planting the plant in S114 is not limited to this. Later, the work of removing the mold of S110 may be performed. Specifically, the formwork is set higher than the top of the water-retaining layer 20, a water-conducting layer 10 is formed in the formwork, water is sprinkled and filled, a lawn is planted, and the lawn is fixed to the water-retaining layer 20. The formwork may be removed.

As described above, according to the greening base 1 in the present embodiment, by filling the continuous voids of the porous concrete with the water-retaining particles 5, water can be supplied at the time of the hardening action of the porous concrete. A strong porous concrete layer can be obtained.
Further, according to the greening base 1, the water supplied from the irrigation pipe 8 is allowed to be retained by the water-retaining particles 5, so that the water can permeate into the entire water-conducting layer 10.
Further, since the greening base 1 can retain water and nutrients to be supplied to the plants planted on the upper surface of the water retention layer 10, the frequency of watering and nutrient supply can be reduced. Further, by supplying water from the irrigation pipe 8 to the water conveyance layer 10 and the water retention layer 20 by automatic water supply by a timer, the operator can reduce the frequency of watering work.
Further, according to the greening base 1, since a part of the water guide layer 10 filled in the groove 22 contacts and covers the irrigation pipe 8, the water supplied from the irrigation pipe 8 is efficiently applied to the entire water guide layer 10. It can be distributed.
Although the embodiments according to the present invention have been described above, the present invention is not limited to these, and various changes, additions, and the like can be made without departing from the spirit of the invention. For example, the construction is not limited to permeable pavement, and may be constructed indoors such as buildings, rooftops, elevated roads, or artificial ground.

Next, a modification of the above embodiment will be described. In the modified example, elements having substantially the same function and configuration as those in the above embodiment are designated by the same reference numerals, so that duplicate description will be omitted.
[Modification example]
In the above embodiment, the case where only the water retention layer 20 is used as the concrete base layer is taken as a specific example, but the present invention is not limited to this, and a plurality of concrete base layers may be provided.
FIG. 3 is a cross-sectional view illustrating a modified example of the greening base 1 of the embodiment.
As illustrated in FIG. 3, the greening base 1 includes a water guide layer 10, a water retention layer 20, a drainage control sheet 40, and a reinforcing layer 30 in this order from the lawn and lawn floor soil side to the paved base F side. Further, these are laminated.
The reinforcing layer 30 is a layer located between the water retention layer 20 and the drainage control sheet 40, and is a base layer made of concrete having a plurality of continuous voids. Like the water-retaining layer 20, the reinforcing layer 30 of this example is made of porous concrete, and the plurality of continuous voids in the reinforcing layer 30 are filled with water-based particles 5.
Further, the reinforcing layer 30 has a strength and water retention different from those of the water retaining layer 20. For example, from the viewpoint of increasing the strength, the reinforcing layer 30 may have a higher strength than the water-retaining layer 20 by containing an aggregate having a higher strength than the aggregate used for the water-retaining layer 20. Further, the reinforcing layer 30 may have a higher strength than the water retaining layer 20 by reducing the continuous voids of the porous concrete.
Further, for example, from the viewpoint of increasing the water retention, the reinforcing layer 30 can increase the amount of the water retention particles 5 to be filled in the continuous voids by increasing the number of the continuous voids of the water retention layer 20. As a result, it may have higher water retention than the water retention layer 20.

1 Greening base 5 Water-retaining particles 8 Irrigation piping 10 Water-conducting layer 20 Water-retaining layer 40 Drainage control sheet 30 Reinforcement layer

Claims (8)

A concrete base with through holes and
A greening substrate having particles having a water absorption rate of 10% or more filled in the through holes. The greening substrate according to claim 1, wherein the particles are crushed products of a porous material and have a particle size of 3 mm or less. The groove formed on the upper surface of the concrete base and
The sprinkler pipe arranged in the groove and
On the upper surface of the concrete base, the water conducting layer including the groove and integrally formed is further provided.
The greening base according to claim 2, wherein the water conveyance layer is composed of particles having a water absorption rate of 10% or more. The greening base according to claim 3, wherein the concrete base has strength and thickness sufficient for vehicles to enter. The greening base according to claim 4, wherein the concrete base includes a plurality of concrete bases having different strength and water retention. The process of pouring concrete to form porous concrete,
A concrete placing method including a step of pouring particles and water having a water absorption rate of 10% or more into the through holes of the porous concrete. The concrete placing method according to claim 6, wherein the step of pouring the particles and water is carried out within 48 hours from the pouring of the concrete. The concrete placing method according to claim 6, wherein the step of pouring the particles and water is carried out from the start of setting of the concrete to the completion of solidification of the concrete.

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