JP6076055B2 - Artificial grass laying structure - Google Patents

Description

  The present invention relates to an artificial grass laying structure such as a park, a soccer ground, a baseball field, an athletic field, and the like.

Because it is extremely easy to care for, artificial grass turf ground is increasing in place of natural turf ground.
However, the artificial turf ground has a higher surface temperature due to solar heat than natural turf ground and bear ground, and there is a risk that the ground user may suffer from heat stroke, especially under hot weather in summer.
In particular, the artificial turf mat may be laid on asphalt provided so as to cover the ground. In such a case, the above problem is significant.

Artificial grass, on the other hand, is filled with fine sand fillers such as silica sand and rubber granules to reduce the burden on the user's legs and to prevent injuries (patents) There is literature 1).
Fine-grained fillers, especially sand layers, have water retention. In such artificial grass-like structures, if water is sprayed and retained in the sand layers, the cooling effect of the retained water by the evaporative heat is retained. Can keep the ground cool.

JP 11-229314 A

However, the amount of water retained in the sand layer is not so large, and the effect can be expected only for a short time of about 1 to 2 hours under hot weather.
Moreover, since water will float on the artificial turf mat when water is sprinkled too much, it is necessary to pay attention to the control of the watering amount, and the watering operation is difficult.

  In view of the above circumstances, the present invention can maintain the artificial turf fine particle filler in a water retention state for a long time, and does not float on the artificial turf mat even when it is sprinkled with water or in heavy rain. The purpose is to provide an artificial grass laying structure.

In order to achieve the above object, the artificial turf laying structure according to the present invention (hereinafter referred to only as “the laying structure of the present invention”) has a large number of turf leaf-like bodies from the base cloth part in which the water-permeable holes are formed. An artificial turf mat formed so as to be erected is an artificial turf laying structure in which the artificial turf mat is laid directly on the base layer portion from below, wherein the base layer portion directly receives the artificial turf mat. A water retention layer made of porous concrete, which is made of an aggregate having a particle size larger than that of the aggregate constituting the water retention layer, continuously provided below the water retention layer However, the gap between the turf-like body and the turf-like body of the artificial turf mat is filled, and part of the filled fine-grain filler enters the water-permeable holes and is retained in the water retaining layer. Before water can be sucked up by meniscus effect It is characterized in that in contact with the moisture-holding layer.

The fine filler can be appropriately determined according to the use of the artificial turf, but preferably has an average particle size of 1.5 mm or less because of its high meniscus effect, such as silica sand, recycled sand, and recycled chips. Is preferred. These fine-grain fillers may be used alone or in combination with other fine-grain fillers.
Further, the filling thickness of the fine-grain filler is appropriately selected depending on the shape, length, material, etc. of the turf foliate, and is not particularly limited. preferable.

Although the diameter of a water permeable hole is not specifically limited, 3 mm-8 mm in diameter are preferable.
That is, if the water permeability hole is too small, the water permeability effect is insufficient, and if it is too large, the fine-grain filler tends to flow out to the water retention layer side.
The number of water permeable holes is not particularly limited, but is preferably 1 to 4 per 100 cm ^{2 in} the range of 3 mm to 8 mm in diameter.

The strength and thickness of the base layer portion are selected according to the use of the artificial turf, but it is necessary to have a water retaining layer at the upper end.
The water-retaining layer is not particularly limited as long as it is formed of porous concrete having a meniscus pumping effect within a range that does not impede water permeation. It is preferable to use it.
That is, for the pumping effect, the porosity of the porous concrete is small (in the range of about 15 to 35%, the smaller the porosity, the higher the pumping height is slightly), and the aggregate particle size ( Depends on the average void diameter.

Incidentally, according to the knowledge of the inventor, in the case of porous concrete (porosity 25%) using No. 9 crushed stone (particle size 0.6 to 1.2 mm) as aggregate, a pumping height of about 20 cm is obtained. In the case of porous concrete (porosity 25%) using No. 8 crushed stone (particle size 1.2 to 2.5 mm), a pumping height of about 15 cm is obtained, and No. 6 crushed stone (particle size 5 to 13 mm) is obtained. In the case of the used porous concrete (porosity 25%), a pumping height of about 5 to 10 cm is obtained.
Moreover, in order to control the pumping height, coarse aggregate and fine aggregate may be mixed.
However, when an aggregate having a diameter smaller than that of No. 9 crushed stone is used, the moving speed of the internal water decreases, which is not desirable.
Further, in the laying structure of the present invention, the base layer portion is provided with a water retaining layer having a thickness capable of pumping by the meniscus effect, and has a high water permeability under the water retaining layer, so that it is placed on the artificial turf during a heavy rain. It is preferable to provide a water storage layer that temporarily stores rainwater flowing down through the water-retaining layer and prevents flooding by preventing a rapid inflow of rainwater into the river.
The water storage layer is not particularly limited, but porous concrete having an aggregate particle size of 5 mm or more, a porosity of 25 to 35%, a continuous porosity of 20% or more, and a water permeability of 1 to 10 cm / s is preferable.

In other words, when the aggregate particle size is less than 5 mm, it becomes difficult for the water level in the reservoir to flow toward the lower water level, and during heavy rain, it becomes difficult for rainwater, etc., that falls on the artificial turf to penetrate through the water retention layer. There is a risk that water may float on the mat, making it impossible to exhibit a sufficient water storage effect.
If the porosity is less than 25% or the continuous porosity is less than 20%, a sufficient water storage volume may not be secured. If the porosity exceeds 35%, although it is desirable from the water permeability and water storage function, it is manufactured and constructed. And it tends to be difficult to manage.
If the permeability coefficient is less than 1 cm / s, the penetration is slow and the level required for flood countermeasures may be insufficient.
When the water permeability coefficient exceeds 10 cm / s, although it is desirable from the water permeability function, workability is lowered, and therefore, one aspect appears that makes manufacture, construction and management difficult.

In the present invention, the particle size of the aggregate is measured using JIS A 1102 (Aggregate screening test method).
The porosity and continuous porosity are based on the volume pressure method (The Architectural Institute of Japan, Vol.75, No.650, p1043-1050, July 2008), JCI (Concrete Engineering Association) proposed standard ( It is measured using the volume method described in Porous Concrete Porosity Test Method (Draft)).
The permeability coefficient is measured using the permeability test method described in the above-mentioned JCI standard draft (Porosity concrete permeability test method (draft)).
The compressive strength test method is measured using JIS A 1108 (Concrete compressive strength test method).

The laying structure of the present invention may be provided with a cavity serving as a water storage space in the base layer.
The water storage space is obtained, for example, by embedding a perforated pipe in a porous concrete layer that constitutes the foundation.
The water storage space may be provided in a continuous tunnel shape in the base layer portion or may be provided intermittently.
The perforated pipe is not particularly limited as long as it has the necessary water-permeable through holes and can withstand the load applied from the surroundings during use. However, the perforated pipe made of a synthetic resin such as vinyl chloride resin or polyethylene, FRP, etc. And a perforated cylindrical body such as a perforated pipe made of a composite material, a perforated steel pipe, a perforated fume pipe, and the like.
The number of the water permeable through holes is not particularly limited as long as the space forming member can secure the strength that the peripheral wall is not damaged by the load applied from the surroundings, but considering the water permeability of rainwater into the hollow portion, it should be provided as much as possible. preferable.

In the laying structure of the present invention, the base layer portion is surrounded by a hardly water permeable layer or a non-permeable layer except for the upper surface, one end faces the drainage path, and the other end is the non-permeable layer or the non-permeable layer. The drainage pipe is provided with an open / close valve that passes through the water permeable layer and faces the base layer, and is connected to a perforated pipe to control drainage of rainwater in the base layer. The amount of water stored in the base layer may be controlled so as to control drainage.
Examples of the hardly water permeable layer or the non-water permeable layer surrounding the base layer portion include concrete walls and curbs.

As described above, the artificial turf mating structure according to the present invention is such that the artificial turf mat formed so that a large number of turf leaf-like bodies are erected from the base cloth part in which the water-permeable holes are perforated directly on the base layer part. An artificial turf laying structure laid in a state of being received from below, wherein the base layer portion is provided continuously with a porous concrete water retaining layer that directly receives the artificial turf mat, and below the water retaining layer. A porous concrete water storage layer made of an aggregate having a particle size larger than that of the aggregate constituting the water-retaining layer, and the fine-grain filler is a gap between the turf-like body and the turf-like body of the artificial turf mat A part of the filled fine particle filler enters the water-permeable hole and is in contact with the water retention layer so that the water retained in the water retention layer can be sucked up by the meniscus effect .

Therefore, by keeping water in the water retaining layer, the water retained in the water retaining layer is sucked up into the fine particle filler layer by the meniscus effect as the water retained in the fine particle filler layer evaporates.
That is, since the fine-grain filler layer is kept moist for a long time, the surface temperature of the artificial turf mat can be kept at a low temperature for a long time by the evaporation heat of water, and the artificial turf surface can be kept in a comfortable environment. Can do.

  And since the artificial turf mat is provided with a water permeable hole, the excessive rain water falling on the artificial turf mat permeates the water retention layer through the water permeable hole, so that the rain water can be effectively used. Moreover, even if it sprinkles excessively, since excess water osmose | permeates a water retention layer, a watering operation | work becomes easy.

Furthermore, if a water reservoir and a water storage space are provided below the water retention layer, rainwater slowly flows through the water retention layer, and a part of the water is retained in the water retention layer. Then, the rainwater that has slowly permeated the water retaining layer is temporarily stored in the water reservoir or the water storage space. Therefore, it has the effect of reducing the amount of rainwater runoff during heavy rain, etc., and draining it with a time difference from the rain, thereby preventing a sudden increase in the river and preventing flooding.
Moreover, by providing a reservoir and a reservoir space as described above, the water stored in the reservoir and reservoir space is replenished to the reservoir, and the fine filler layer is kept in a moist state for a longer time. be able to.

It is sectional drawing which cut | disconnects and shows 1st Embodiment of the laying structure of this invention in the direction parallel to the pipe axis of a perforated pipe | tube. FIG. 2 is a cross-sectional view obtained by cutting in a direction orthogonal to the tube axis of the perforated tube having the laying structure of FIG. 1. It is an expanded sectional view of FIG. It is sectional drawing which cut | disconnects and shows 2nd Embodiment of the laying structure of this invention in the direction orthogonal to the pipe axis of a perforated pipe. It is sectional drawing which cut | disconnects and shows 3rd Embodiment of the laying structure of this invention in the direction parallel to the pipe axis of a perforated pipe. It is a principal part expanded sectional view showing 4th Embodiment of the laying structure of this invention. It is a graph showing the coarseness and water retention of the aggregate of a porous concrete layer.

Hereinafter, the present invention will be described in detail with reference to the drawings showing embodiments thereof.
1 to 3 show a first embodiment of a laying pavement structure according to the present invention.

As shown in FIGS. 1 to 3, the laying structure A includes a base layer portion 1 a and an artificial turf mat 2.
As shown in FIG. 3, the base layer portion 1 a includes a water retention layer 11, a water storage layer 12, and a water storage space 13.

Further, the base layer portion 1a has a bottom surface excavating the ground, and a poorly permeable or non-permeable modified road bed formed by mixing a hydraulic material such as cement with the road bed on the bottom surface of the digging portion. 3 and the side peripheral surface is surrounded by a non-permeable or non-permeable side wall 4 such as a concrete wall.
In the present invention, the poor water permeability means that the water permeability coefficient is 0.1 cm / s or less.

The water retention layer 11 includes, for example, No. 9 crushed stone as aggregate, is made of porous concrete having an airport rate of 15 to 30%, and the height dimension thereof is within 20 cm.
The water storage layer 12 is made of porous concrete containing, for example, No. 6 crushed stone as an aggregate and a porosity of 20 to 35%.

As shown in FIG. 2, the water storage space 13 is formed by embedding the perforated pipe 14 having a plurality of water permeable through holes 14 a in parallel in the water storage layer 12 while being received by the reformed road bed 3. Has been.
The perforated pipe 14 is connected so that one end of the perforated pipe 14 joins the other perforated pipe 14, and then, as shown in FIG. 1, the drain pipe 5 provided so as to penetrate the side wall 4 in contact with the drain path 6. It is connected to the.
Note that the other end of the perforated tube 14 may be open or closed in the base layer portion 1a.

Further, the water permeable through hole 14a of the perforated pipe 14 is covered with a net for preventing the aggregate and the cement component constituting the water reservoir 12 from entering the perforated pipe 14 although not shown. Yes. The mesh of the mesh is preferably as rough as possible unless the aggregate and the cement component enter the perforated pipe 14.
The drain pipe 5 has a valve 51. As shown in FIG. 1, the valve 51 is arranged in a gutter 52 provided with a lid 52 a, and can be opened and closed from the ground side using a jig (not shown) by removing the lid 52 a.

The artificial turf mat 2 includes a base cloth part 21, a turf leaf-like body 22 provided in a standing state on the base cloth part 21, and a silica sand layer 23. The base cloth part 21 is received by the water retention layer 11 from below. It is laid to be able to.
In addition, the base fabric portion 21 has 1 to 4 water-permeable holes 21a having a diameter of about 3 to 8 mm per 100 cm ² .
The silica sand layer 23 is formed by filling silica sand (0.6 to 1.2 mm) between the turf leaf-like body 22 and the turf leaf-like body 22, and is one of the silica sands constituting the silica sand layer 23. The part enters the water permeable hole 21 a and is received by the water retention layer 11.

Since this laying structure A is configured as described above, it has the following excellent effects.
(1) Since the base layer portion 1a is provided, water that cannot be retained in the silica sand layer 23 such as rainwater or water sprinkled on the artificial turf mat 2 permeates the water retaining layer 11 side through the water permeation holes 21a. In addition, the water is stored in the water storage layer 12 and the water storage space 13.
And since the silica sand layer 23 is received by the water retention layer 11 at the water permeable hole 21a portion, the water retained in the water retention layer 11 by the meniscus effect is sucked up by the silica sand layer 23 as the water of the silica sand layer 23 evaporates. The silica sand layer 23 can be kept moist for a long time.
On the other hand, when the weather recovers and the artificial turf mat 2 is exposed to sunlight, the water retained in the silica sand layer 23 evaporates, and the surface temperature of the artificial turf mat 2 is kept low by the heat of evaporation.
That is, even under hot weather, the surface temperature on the artificial turf mat 2 can be kept at a temperature lower by 10 to 20 ° C. for a long time than the case where water is not retained by the water retained by the silica sand layer 23. Can maintain a comfortable state and prevent heat stroke and the like.
(2) Since the base layer portion 1a is formed of porous concrete having a high porosity, it can maintain high water permeability and drainage, and is strong as a support board for artificial turf, and can maintain flatness for a long time.
(3) Since the water storage layer 12 and the water storage space 13 are provided, rainwater or the like that has permeated into the base layer portion 1 a through the water retention layer 11 can be stored in the water storage layer 12 and the water storage space 13. Therefore, it can be a measure for preventing flood damage caused by guerrilla heavy rain.
(4) The water stored in the water storage layer 12 can be replenished to the water retention layer 11, and the quartz sand layer 23 can be kept moist for a longer time via the water retention layer 11.
That is, the water retention layer 11 also functions as a pumping layer for rainwater or the like stored in the water storage layer 12 and the water storage space 13, and the temperature on the artificial turf mat 2 is increased for a long time by evaporation of water from the silica sand layer 23. The temperature can be kept low, and the artificial grass mat 2 can be kept in a comfortable temperature environment for a long time by the athlete.
(5) Since the water retention layer 11 is provided, when water is sprayed, excess water sprayed on the artificial turf mat 2 is retained on the water retention layer 11 side. Therefore, since it can be performed without hesitation even when watering, the temperature can be rapidly lowered.
(6) Since the base layer portion 1a is formed of porous concrete, rainwater that has fallen on the artificial turf mat 2 can be stored on the downstream side of the base layer portion 1a even in an inclined portion (such as a slope).
(7) Since the drainage pipe 5 is provided, the drainage pipe is used in the case of heavy rain every day when the water retention layer 11, the water storage space 13 and the water storage layer 12 are filled with water, and rainwater overflows on the upper surface of the artificial turf mat 2. The water level in the water storage space 13 can be drained and the water level on the artificial turf mat 2 can be reduced by opening the 5 valve 51 at a necessary opening according to the situation. That is, the amount of water stored in the base layer 1d can be controlled by opening and closing the valve 51 of the drain pipe 5.

In addition, the said laying structure can be constructed as follows, for example.
(1) Excavate the ground at the artificial turf laying position, spray cement improver, etc. on the bottom of the excavation part, mix the bottom soil and cement improver, etc., and then roll to improve the roadbed 3 and the side wall 4 is formed by mortar or the like.
Moreover, a cement film is formed on the modified road bed 3 as necessary.
(2) The perforated pipe 14 is arranged on the reforming road bed 3 and is connected to the drain pipe 5.
(3) After pouring the porous concrete to be the water reservoir 12 so that the perforated pipe 14 is embedded, the porous concrete to be the water retention layer 11 is placed on the water reservoir 12.
(4) The artificial turf mat 2 is laid on the water retention layer 11.
(5) Place No. 9 silica sand on the artificial turf mat 2 so as to form a silica sand layer 23 having a thickness of 0.5 to 3.0 cm. The artificial turf mat 2 can be fixed so as not to move with the weight of the silica sand layer 23, but before the silica sand layer 23 is provided as necessary, the artificial turf mat 2 is directed from the base cloth portion 21 of the artificial turf mat 2 toward the water retention layer 11. Then, the artificial turf mat 2 may be fixed to the water retention layer 11 by driving a fixing nail.
That is, since the water retention layer 11 is formed of porous concrete made of fine aggregate, it can be firmly fixed by the fixing nail, and is a particularly useful function on a slope or the like.

FIG. 4 shows a second embodiment of the laying structure of the present invention.
As shown in FIG. 4, this laying structure B is the above laying except that it is formed by a water storage space 13 formed by arranging perforated tubes 14 in the base layer portion 1b in the vertical direction as well as in the horizontal direction. It is the same as the structure A.
According to this laying structure B, the total volume of the water storage layer 12 and the water storage space 13 can be increased to increase the water storage amount.

FIG. 5 shows a third embodiment of the laying structure of the present invention.
As shown in FIG. 5, this laying structure C is provided such that the water reservoir 12 of the base layer portion 1 c is partly flush with the upper surface of the water retention layer 11 and exposed to the outside. Except that the upper surface of the exposed portion is covered with the grating 7, it is the same as the laying structure A described above.
Although not shown, the grating 7 is installed in a concrete frame provided so as to be in contact with the edge of the artificial turf mat 2 so as not to move.

  In this laying structure C, as described above, since a part of the water reservoir 12 through which water easily passes is exposed to the outside through the grating 7, rainwater quickly permeates into the water reservoir 12 from the exposed portion. Even if the permeation rate of the water from the permeation hole 21 a to the water retention layer 11 is slow, part of the rain water that has fallen on the artificial turf mat 2 quickly penetrates into the water storage layer 12 through the exposed portion of the water storage layer 12. That is, even during a temporary heavy rain such as a sunset, it is possible to prevent water from floating on the artificial grass mat 2 as much as possible.

FIG. 6 shows a fourth embodiment of the laying structure of the present invention.
As shown in FIG. 6, in this laying structure D, the base layer portion 1d includes a water retention layer 15 and a water storage layer 16, and no water storage space is provided.

The water retaining layer 15 includes crushed stone having a particle diameter of 1 to 15 mm as an aggregate, is made of porous concrete having a porosity of 15 to 30%, and has a thickness of 1 to 5 cm.
The water storage layer 16 includes crushed stone having a particle size of 5 to 30 mm as an aggregate, is made of porous concrete having a porosity of 20 to 35%, and has a thickness of 5 to 100 cm.
In FIG. 6, 8 is a fixing nail 8 for fixing the artificial turf mat 2 to the water retention layer 15.

In this laying structure D, since the water retention layer 15 is formed of porous concrete made of fine aggregate, workability at the time of construction is good, and unevenness of the upper surface that receives the artificial turf mat 2 can be eliminated well.

(Experimental example 1)
A water retention layer sample (porosity 25%) made of cylindrical porous concrete having a diameter of 10 cm and a height of 20 cm, in which No. 6 crushed stone (particle size of 5 to 13 mm) was blended as an aggregate was obtained.

(Experimental example 2)
A water retention layer sample (porosity 25%) made of cylindrical porous concrete having a diameter of 10 cm and a height of 20 cm, in which No. 7 crushed stone (particle size 2.5 to 5 mm) was blended as an aggregate was obtained.

(Experimental example 3)
A water retention layer sample (porosity 25%) made of cylindrical porous concrete having a diameter of 10 cm and a height of 20 cm, in which No. 8 crushed stone (particle size: 1.2 to 2.5 mm) was blended as an aggregate was obtained.

(Experimental example 4)
No. 6 crushed stone (particle size 5-13 mm) and No. 8 crushed stone (particle size 1.2-2.5 mm) were mixed at a ratio of 3: 1 by weight, and the mixed material was blended as an aggregate, diameter 10 cm A water retention layer sample (porosity 25%) made of cylindrical porous concrete having a height of 20 cm was obtained.

The water retention layer samples obtained in the above experimental examples 1 to 4 were each submerged in water for 24 hours, and then examined for mass changes during natural drying from the state where they were taken out of the water and lightly drained, and the results are shown in FIG. 7 shows.
From FIG. 7, it can be seen that the water retention function of porous concrete (the function of retaining moisture in the internal voids) depends on the aggregate particle size of the porous concrete, and the smaller the particle size, the higher the water retention. That is, the amount of water stored in the interior increases, and the time until draining and drying becomes longer. This is thought to be due to the fact that as the particle size decreases, the total surface area increases exponentially, moisture adheres to it, the average void diameter decreases, and the pumping (meniscus) effect due to surface tension increases relatively. It is done.

The present invention is not limited to the above embodiment. For example, in the above embodiment, nothing is filled in the water storage space, but a water absorbent material filled with a water absorbing polymer in a bag-like body made of a nonwoven fabric may be arranged in the water storage space. That is, in this way, rainwater that has entered the water storage space is once absorbed by the water-absorbing polymer and held in the water storage space. And when it rains and it becomes good weather, the water absorbed by the absorptive polymer is gradually evaporated and released from the surface layer.
In the above-described embodiment, the reservoir is directly received by the reformed roadbed, but the impermeable film made of a substantially impermeable thin concrete layer or an epoxy resin between the reservoir and the reformed roadbed. A conductive layer may be provided.
Further, in the above embodiment, the base layer portion is a multilayer, but it is also possible to configure it as a single layer having the most appropriate particle size.
In the above embodiment, the perforated pipe is received on the reforming roadbed and is arranged at the bottom of the water storage tank. However, if the drainage performance can be ensured, it can be embedded in the intermediate position of the water reservoir. I do not care.

A, B, C, D Laying structure 1a, 1b, 1c, 1d Base layer 11 Water retention layer (pumped water layer)
DESCRIPTION OF SYMBOLS 12 Reservoir 13 Reservoir space 14 Perforated pipe 15 Non-land adjustment water retention layer 16 Reservoir 2 Artificial turf mat 21 Base cloth part 21a Permeation hole 22 Turf frond body 23 Silica sand layer 3 Reformed road floor 4 Side wall 5 Drain pipe 51 Valve 6 Drainage channel 7 Grating 8 Fixing nail

Claims (7)

An artificial turf mat constructed so that a large number of turf leaf-like bodies are erected from the base cloth part where the water permeable holes are perforated, and is laid in a state where it is received directly from below at the base layer part. There,
The base layer portion is a porous concrete water retaining layer that directly receives the artificial turf mat, and a porous material that is continuously provided below the water retaining layer and is made of an aggregate having a larger particle size than the aggregate constituting the water retaining layer. Concrete water reservoir,
The fine-grain filler is filled in the gap portion between the turf-leaf-like body and the turf-leaf-like body of the artificial turf mat, and a part of the filled fine-grain filler enters the water-permeable hole and the water retaining layer. The artificial grass laying structure is characterized in that the water retained in the water is in contact with the water retention layer so that the water retained by the meniscus effect can be sucked up .
The artificial grass laying structure according to claim 1, wherein the fine-grain filler is silica sand of 0.6 to 1.2 mm .
  The artificial grass laying structure according to claim 2, wherein a filling thickness of the fine-grain filler is 0.5 to 3.0 cm.   The artificial grass laying structure according to any one of claims 1 to 3, wherein the fine-grain filler is at least one selected from the group consisting of silica sand, recycled sand, and recycled chips.   The artificial turf laying structure according to any one of claims 1 to 4, wherein the base layer portion includes a water storage space for entering the base layer portion.   The artificial grass laying structure according to claim 4, wherein the water storage space is formed by embedding a perforated pipe in the base layer.   The base layer portion is surrounded by a non-permeable layer or a non-permeable layer except for the upper surface, and one end faces the drainage path, and the other end penetrates the non-permeable layer or the non-permeable layer and enters the base layer portion. The artificial turf laying structure according to claim 6, further comprising a drainage pipe connected to the perforated pipe and provided with an open / close valve for controlling drainage of rainwater in the base layer.