JP4125834B2 - Gutter, gutter lid member, and boundary block - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a side groove provided on a side edge of a water-permeable pavement capable of penetrating rainwater into a roadbed, a side groove cover member, and a boundary block.
[0002]
[Prior art]
On paved roads such as general roads, expressways, and parks, a gutter is provided as a drainage facility in order to prevent rainwater from accumulating on the road surface due to rain. For example, a concrete side groove (hereinafter referred to as a U-shaped side groove) provided with a U-shaped water channel is representative. This U-shaped side groove has a U-shaped side groove main body having a substantially U-shaped cross section with a large opening on the upper surface and a drain empty space inside, and a rainwater introduction hole penetrating from the upper surface to the lower surface. The U-shaped side groove is connected to be embedded in a boundary portion between the paved road surface and the sidewalk.
[0003]
In general, when constructing U-shaped side grooves, foundation crushed stones and foundation concrete are respectively placed on the roadbed, and mortar is provided, and then U-shaped side grooves are buried so as to be connected to the paved road. Further, a paved road is generally formed by providing a paved roadbed as a foundation on a roadbed and constructing an asphalt layer on its surface layer. In recent years, by using relatively large aggregates in the asphalt layer, continuous gaps or holes are formed between the aggregates, thereby allowing water permeability or water permeability (hereinafter simply referred to as water permeability). The one using water-flowing asphalt equipped with is becoming popular. That is, the surface layer has water permeability and quickly infiltrates rainwater into the ground, and rainwater that cannot be permeated is poured into a drainage facility such as a gutter having a U-shaped or circular water channel for wastewater treatment.
[0004]
[Problems to be solved by the invention]
However, on the paved road provided with the water-permeable surface layer described above, a water-impermeable underlayer is usually used as a surface layer having water permeability in consideration of durability. For this reason, there has been a problem that when there is a large amount of rain or snow, rainwater or the like cannot be smoothly penetrated into the basement. That is, when there is a large amount of rainfall, there is a problem that rainwater gradually accumulates from the boundary portion between the water-permeable surface layer and the water-impermeable underlayer.
[0005]
In order to solve this problem, the side wall of the gutter body is provided with a through-hole for guiding rainwater from the water-permeable surface layer of the paved road into the drainage channel of the gutter body, and the rainwater stored in the surface layer is drained. It is possible to do.
[0006]
However, with this configuration, in order to increase drainage efficiency, it is necessary to increase the diameter of the water guide hole. On the other hand, if the diameter of the water guide hole is increased, there is a problem in that the strength of the side groove body decreases. In addition, when used for many years, foreign substances such as dirt and earth and sand are clogged in the water guide hole, and there is a problem that the drainage capacity of rainwater is reduced.
[0007]
In addition, the water-permeable concrete has 15-30% of voids in a practical range and has a specific function that rainwater can easily permeate, but is disadvantageous in terms of strength because of the large number of voids. For this reason, the combined use with non-permeable concrete with big intensity | strength is needed.
[0008]
However, simply combining non-permeable concrete and permeable concrete makes the boundary unclear because the cement paste of the non-permeable concrete enters the voids of the permeable concrete, and the concrete cannot be expected to be permeable or strong. In addition, it becomes difficult for rainwater to pass smoothly through the boundary between the two concretes.
[0009]
Therefore, the present invention prevents the rainwater that has permeated into the water-permeable roadbed in the water-permeable pavement having a water-permeable surface layer on the water-impermeable underlayer from being quickly drained and retained in the roadbed. An object of the present invention is to provide a side groove, a side groove cover member, and a boundary block that can maintain the ability of wastewater treatment over a long period of time.
[0010]
[Means for Solving the Problems]
  The present invention has been proposed in order to achieve the above-mentioned object, and the one according to claim 1 is a side groove embedded in a water-permeable pavement in which a water-permeable surface layer is formed on a water-impermeable base layer. The side groove is composed of a bowl-shaped side groove main body with a side wall standing from the left and right side edges of the bottom, and a plate-like lid member that closes the upper surface opening of the side groove main body. A non-permeable concrete having a water permeable wall portion at a portion, and a lid support portion for supporting the lid member in a state where the upper surface of the lid member is substantially the same height as the upper end of the side wall is formed on the upper side wall. The wall is a paved roadSurfaceThe lid member is formed by bonding a permeable concrete layer to a top surface of a non-permeable concrete layer having a through-hole penetrating from the upper surface to the lower surface through a binder layer, and In the state in which the lid member is supported by the support portion, the binder layer is configured to be lower than the water permeable wall portion.
[0011]
  What is claimed in claim 2The lid member is provided with a plurality of through-holes along the longitudinal direction in the water-impermeable concrete layer, and a concave groove is formed along the longitudinal direction in the state including the through-holes on the bottom surface of the water-permeable concrete layer. 2. The side groove according to claim 1, wherein a grating having a rain water passage portion for allowing rain water to pass from the outside to the inside is fitted in the concave groove.
[0012]
  What is claimed in claim 3In the lid member for opening the opening in the longitudinal direction of the upper surface and closing the opening of the side groove body formed in the longitudinal direction of the drainage communicating with the opening, the lid member is made of a water-impermeable concrete layer. A permeable concrete layer is bonded to the upper surface of the permeable concrete layer via a binder layer, and a boundary step wall is erected on one side of the non-permeable concrete layer higher than the upper surface of the permeable concrete layer. A plurality of through-holes penetrating from the upper surface to the lower surface are provided along the longitudinal direction, the upper surface is inclined downward toward the through-hole, and the water-permeable concrete layer includes the through-hole on the bottom surface along the longitudinal direction. Permeable pavement in which a grating having a rain water passage portion for passing rain water from the outside to the inside is fitted in the recessed groove, and a permeable surface layer is formed on the non-permeable base layer. Buried in the road In a state where the opening of the lateral gutter body is closed, the binder layer is disposed below the boundary between the surface layer and the foundation layer of the pavement, and rainwater from the water permeable surface layer side is disposed in the longitudinal direction of the water permeable concrete layer. A side groove lid member characterized in that the side groove is infiltrated into the inside from a side surface and guided into the drainage empty portion of the side groove main body through the through hole of the non-permeable concrete layer to perform drainage treatment.
[0013]
  What is described in claim 4In the boundary block laid along the boundary between the water-permeable paved road and the sidewalk in which a water-permeable surface layer is formed on the water-impermeable base layer, this boundary block is formed on the upper surface of the water-impermeable concrete layer via a binder layer. The permeable concrete layer is combined, and a boundary step wall is erected on one side of the non-permeable concrete layer so as to be higher than the upper surface of the permeable concrete layer, and the binder layer and the permeable surface layer of the paved road are impermeable to water. A grating having a rainwater passage portion for forming rain grooves along the boundary step wall portion and allowing rainwater to pass from the outside to the inside of the side surfaces. Is a boundary block characterized in that the upper surface of the water-impermeable concrete layer is inclined downward toward the concave groove side.
[0018]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a sectional view of a first embodiment of a side groove 1 according to the present invention, and FIG. 2 is a perspective view of the side groove 1.
In FIG. 1, reference numeral 3 is a road bed, 4 is a paved roadbed, 5 is a non-permeable base layer made of non-water-permeable asphalt, and 6 is a water-permeable surface layer made of water-permeable asphalt or the like. Further, below the side groove 1, a basic crushed stone layer 7, a basic concrete layer 8, and a mortar layer 9 are formed.
[0019]
The side groove 1 includes a bowl-shaped side groove main body 12 in which a side wall 11 is erected upward from the left and right side edges of the bottom portion 10, and a plate-like lid member 13 that closes an upper surface opening of the side groove main body 12.
[0020]
The side groove main body 12 is molded into a bowl shape having a substantially U-shaped cross section with an upper surface opened by non-permeable concrete, and a drainage empty portion 14 (drainage) is surrounded by a bottom portion 10 and left and right side walls 11. And a bulging portion bulging outward is formed at the upper end portion of the side wall 11, and a stepped lid support portion 15 is formed inside the bulging portion, and is formed at one upper edge of the bulging portion. The water permeable wall portion 16 is formed of water permeable concrete. The lid support portion 15 is formed at a position where the upper surface of the lid member 13 and the upper end surface of the side wall 11 are substantially flush with each other when the opening is closed by the lid member 13. Further, the thickness (vertical dimension) of the water permeable wall portion 16 is set to be thicker than the thickness of the water permeable surface layer 6 of the water permeable paved road 2. For example, since the thickness of the water-permeable surface layer 6 is 50 mm, the thickness of the water-permeable wall portion 16 is preferably set to 60 mm.
[0021]
The lid member 13 includes a plate-shaped water-impermeable concrete layer 21 in which a plurality of through holes 20 penetrating from the upper surface to the lower surface are formed, and a plate-shaped water-permeable concrete layer formed on the water-impermeable concrete layer 21. 22 and a resin-based binder layer 23 that is interposed between both layers 21 and 22 and bonds the water-impermeable concrete layer 21 and the water-permeable concrete layer 22, and when the opening of the side groove main body 12 is closed. The resin binder layer 23 is configured to be positioned below the boundary between the water permeable wall portion 16 and the water-impermeable concrete. That is, the thickness of the water permeable concrete layer 22 is set larger than the vertical dimension of the water permeable wall portion 16.
[0022]
In addition, the through-hole 20 is formed as a tapered hole whose diameter is expanded downward (drainage channel), and this taper functions as a draft when removing the mold, and when foreign matter such as earth and sand enters. It also functions as a hole clogging that smoothly falls off.
[0023]
The resin binder that forms the resin binder layer 23 is, for example, a resin binder mainly composed of 80 to 90% bisphenol A liquid epoxy resin, or a resin binder mainly composed of a modified aliphatic polyamine. It is widely used for bonding each other. The water-impermeable concrete is desirably fluid concrete with a low water content in order to increase the bonding strength with the resin binder layer 23.
[0024]
Permeable concrete is bonded with a cement-based binder in a state where voids are continuously formed between the aggregates, and the voids formed between the binder and the aggregates prevent rainwater. Ensures the function of soaking into the inside from the top surface of permeable concrete.
[0025]
In order to mold the lid member 13, first, a water-permeable concrete in which a binder mainly composed of cement, an aggregate, and water are mixed is poured into a mold and pressure-molded, and the surface of the water-permeable concrete is formed. A resin-based binder is applied to the resin, fluid concrete which is water-impermeable concrete is poured onto the resin-based binder layer 23, and a through-hole mold for forming the through-hole 20 is set in the water-impermeable concrete layer 21. Mold.
[0026]
As described above, since the resin-based binder layer 23 is interposed between the water-permeable concrete layer 22 and the water-impermeable concrete layer 21, it is difficult for the water-impermeable concrete to penetrate into the voids of the water-permeable concrete layer 22. A smooth layer can be formed by the system binder layer 23. That is, if the resin-based binder layer 23 is not interposed, the non-permeable concrete penetrates into the voids of the permeable concrete layer 22, the boundary surface is not smoothed, and the drainage into the through-hole 20 is hindered. Because.
[0027]
A resin-based binder layer may be provided between the water-permeable concrete layer 22 and the water-impermeable concrete layer 21 constituting the water-permeable wall portion 16 of the gutter body 12. However, in this case, it is preferable to use fluidized concrete as the non-permeable concrete.
[0028]
In order to construct the side groove 1 having the above-described configuration on the permeable paved road 2, first, the permeable wall portion 16 side of the side groove body 12 is directed toward the permeable paved road 2, and the upper surface of the side groove body 12 is permeable. The pavement road 2 is adjusted and buried so as to be substantially flush with the upper surface of the pavement road 2, and the lid member 13 is attached to the gutter body 12. In this state, the side groove 1 is positioned such that the lower surface of the water permeable wall portion 16 is lower than the lower surface of the water permeable surface layer 6 of the water permeable pavement 2, and the resin-based binder layer 23 of the lid member 13 is further lower than the lower surface of the water permeable wall portion 16. The upper surface is located low. Therefore, the rainwater that has penetrated into the water-permeable surface layer 6 of the water-permeable pavement road 2 during the rain passes through the water-permeable wall portion 16 of the side groove main body 12 from the side surface of the water-permeable surface layer 6 and the water-permeable concrete layer 22 of the lid member 13. The water-permeable concrete layer 22 flows through the resin-based binder layer 23 and drains from the through hole 20 formed in the water-impermeable concrete layer 21 into the drainage empty portion 14 of the side groove main body 12. Is done.
[0029]
Since the permeable wall portion 16 of the side groove main body 12 and the permeable concrete layer 22 of the lid member 13 are formed over a wide range over the entire length of the side surface of the permeable surface layer 6, smooth drainage treatment is possible even if the amount of rainwater is large. In addition, since the rainwater passage region is formed over a wide range, even if it passes for a long time, there is little deterioration in the function of water permeability due to clogging of earth and sand.
[0030]
For this reason, it is possible to prevent rainwater from staying on the water permeable surface layer 6 of the water permeable paved road 2 over a long period of time, and to prevent deterioration of the water permeable surface layer 6 and the non-water permeable base layer 5.
[0031]
Further, since the resin binder layer 23 is formed on the lower surface of the water permeable concrete layer 22 of the lid member 13, this boundary surface becomes smooth, and drainage guidance to the through hole 20 can be performed smoothly. When the resinous binder layer 23 is inclined downward toward the through hole 20, that is, when a water gradient is formed at the boundary surface between the water-impermeable concrete layer 21 and the water-permeable concrete layer 22, rainwater moves toward the through-hole 20. This makes it easier to flow and enhances wastewater treatment capacity.
Further, since the diameter of the through hole 20 is increased toward the drainage empty portion 14, dust or the like is not clogged in the through hole 20.
[0032]
Next, a second embodiment of the side groove 1 of the present invention will be described. FIG. 3 is a cross-sectional view of the side groove 1.
[0033]
The side groove 1 has the same configuration as the side groove 1 of the first embodiment described above, but has a characteristic part in the lid member 13. The lid member 13 has a plurality of through holes 20 along the longitudinal direction of the central portion in the width direction of the water impermeable concrete layer 21, and the upper surface of the water impermeable concrete layer 21 is inclined downward toward the through hole 20. Thus, a water gradient is formed, whereby the resin-based binder layer 23 is inclined toward the through-hole 20, and the permeable concrete layer 22 has a concave groove along the longitudinal direction with the through-hole 20 included in the bottom surface. 24, and a grating 25 is embedded in the concave groove 24.
[0034]
The grating 25 is, for example, a long material formed by bending a stainless steel plate or the like downward in a U-shape, and has a water introduction hole 26 such as a long hole on the upper surface, and rain water is provided from the outside of the side surface to the lower portion of both side surfaces. A cutout portion 27 is formed as a rainwater passage portion through which rainwater from above passes through the water introduction hole 26 and rainwater from the side passes through the cutout portion 27 to the inside.
[0035]
Therefore, the rainwater that has permeated into the water-permeable concrete layer 22 of the lid member 13 from the water-permeable wall portion 16 of the side groove 1 or the rainwater that has directly poured into the water-permeable concrete layer 22 is a resin binder that is inclined downward toward the through hole 20. Rainwater that has been guided to the upper surface of the layer 23, smoothly guided into the through hole 20 through the notch 27 of the grating 25, and has flowed over the permeable surface layer 6 to the top of the grating 25 during heavy rain. Flows down on the water-impermeable concrete layer 21 through the water introduction hole 26 opened on the upper surface of the grating 25, is guided into the through hole 20, and drains into the drainage empty portion 14 of the gutter body 12. It is processed. Therefore, a large amount of rainwater can be drained in a short time.
[0036]
In the side groove main body 12 of the above-described embodiment, the water permeable wall portion 16 is formed on one of the side walls 11, but the present invention is not limited thereto, and water permeable wall portions may be formed on both side walls 11. The grating 25 may have any configuration as long as it can pass rainwater, and is not limited to the bent stainless steel plate. For example, the steel strip plate material may be assembled in a lattice shape.
[0037]
Next, the lid member 13 of the side groove 1 according to the present invention will be described. FIG. 4 is a cross-sectional view of another embodiment of the side groove 1. The side groove body 12 has a U-shaped cross section in which the side walls 11 are erected from the left and right side edges of the bottom portion 10, and the upper surface has a large opening, below the opening portions, that is, the bottom portion 10 and the left and right side walls 11. The interior drainage space 14 surrounded by is used as a drainage channel.
[0038]
The lid member 13 is used in a state of closing the opening of the side groove main body 12, and has a plate-like impermeable concrete layer 21 in which a plurality of through holes 20 penetrating from the upper surface to the lower surface are formed, and the impermeable water Plate-like permeable concrete layer 22 formed on permeable concrete layer 21, and resin-based binder layer 23 that is interposed between both layers 21 and 22 and bonds non-permeable permeable concrete layer 21 and permeable concrete layer 22 to each other. On the lower surface of the water-impermeable concrete layer 21, a fitting convex portion 30 that fits into the opening of the gutter body 12 is formed. The thickness of the water-permeable concrete layer 22 is set to be thicker than the thickness of the water-permeable surface layer 6 of the water-permeable paved road 2, and for example, the thickness of the water-permeable surface layer 6 is 50 mm as a standard thickness. The thickness of the water permeable concrete layer 22 is preferably 60 mm.
[0039]
The resin-based binder layer 23 is positioned below the boundary between the water-permeable surface layer 6 and the water-impermeable base layer 5 of the water-permeable paved road 2 when the opening of the side groove main body 12 is closed with the lid member 13. It is formed to do. The through-hole 20 is formed in a cylindrical shape whose diameter is expanded downward (drainage), and the longitudinal side surface of the lid member 13 is formed so as to be substantially flush with the outer surface of the side wall 11 of the side groove body 12. Yes.
[0040]
In order to embed the side groove 1 using the lid member 13 having such a configuration in the permeable paved road 2, the side groove main body 12 so that the upper surface of the lid member 13 is substantially flush with the surface of the permeable paved road 2. And the lid member 13 is put on the side groove main body 12. In this state, since the upper surface of the resin binder layer 23 of the lid member 13 is located lower than the lower surface of the water permeable surface layer 6 of the water permeable paved road 2, rainwater that has penetrated into the water permeable surface layer 6 of the water permeable paved road 2 is It penetrates into the water-permeable concrete layer 22 of the lid member 13 from the side surface of the water-permeable surface layer 6, flows on the resin binder layer 23, and flows down from the through holes 20 formed in the water-impermeable concrete layer 21 to the drainage empty space 14. Wastewater treatment.
[0041]
For this reason, it is possible to prevent rainwater from staying in the water-permeable surface layer 6 of the water-permeable paved road 2.
Further, since the resin binder layer 23 is formed on the lower surface of the water permeable concrete layer 22 of the lid member 13, this boundary surface becomes smooth, and drainage guidance to the through hole 20 can be performed smoothly.
[0042]
Moreover, since the said water-permeable surface layer 6 and the water-permeable concrete layer 22 are surface-contacted along the longitudinal direction of the cover member 13 in the constructed state, that is, the surface layer 6 and the water-permeable concrete layer 22 which have a water-permeable function mutually. Are continuously connected in the longitudinal direction, so that rainwater flowing out from the surface layer 6 can be passed over a wide range of the entire side surface of the permeable concrete layer 22, drainage efficiency can be increased, earth and sand, etc. There is little clogging by. Furthermore, since the diameter of the through hole 20 increases toward the drainage channel, dust or the like is not clogged in the through hole 20.
[0043]
Further, since the lid member 13 is a type supported on the upper end surface of the side wall 11 of the side groove main body 12, the versatility is high. For example, even if the side groove 1 is already embedded in the permeable paved road 2. In addition, the lid member 13 of the present invention can be replaced. In addition, the material of water-permeable concrete, a resin-type binder, and the manufacturing method of the cover member 13 are the same as the cover member 13 of the side groove 1 in description of embodiment of the side groove 1 mentioned above.
[0044]
Next, another embodiment of the lid member 13 will be described. FIG. 5 is a cross-sectional view of another embodiment of the side groove 1.
[0045]
The lid member 13 of the side groove 1 has the same configuration as the lid member 13 of the side groove 1 of the first embodiment described above, but is characterized by drainage treatment of rainwater penetrating from the permeable surface layer 6 of the permeable pavement 2. There is a part. The lid member 13 has a plurality of through-holes 20 along the longitudinal direction of the central portion in the width direction of the water-impermeable concrete layer 21, and the surface of the water-impermeable concrete layer 21 is inclined downward toward the through-hole 20. A water gradient is formed, and the resin-based binder layer 23 is provided to be inclined toward the through-hole 20, and a concave groove is formed along the longitudinal direction in the permeable concrete layer 22 including the through-hole 20 on the bottom surface. 24 and a grating 25 is fitted into the concave groove 24. The grating 25 has the same configuration as that of the above embodiment, and a plurality of water introduction holes 26 are opened on the upper surface, and a notch 27 is formed on the lower portion of the side surface.
[0046]
For this reason, rainwater that has penetrated into the water-permeable concrete layer 22 from the water-permeable surface layer 6 of the water-permeable paved road 2 is guided toward the through-hole 20 by the upper surface of the resin-based binder layer 23 inclined downward, and the notch of the grating 25 is When flowing into the concave groove 24 through the portion 27, the drainage treatment is smoothly performed from the through hole 20 into the drainage empty portion 14 of the side groove main body 12. In addition, rainwater that has flowed along the surface of the permeable paved road 2 and rainwater that has fallen on the lid member 13 is also collected in the concave groove 24 and drained from the through hole 20. Therefore, high wastewater treatment capacity can be expected.
[0047]
Further, as shown in FIG. 6, the side groove main body 12 having a long and narrow opening along the longitudinal direction on the upper surface and having a circular drainage cavity 14 ′ communicating with the opening as a drainage channel can also be used. By forming the shape of the fitting convex part 30 formed in the water-permeable concrete layer 21 in accordance with the opening, the lid member 13 adapted to the side groove main body 12 can be obtained.
[0048]
Next, another embodiment of the lid member 13 according to the present invention will be described. FIG. 7 is a cross-sectional view of another embodiment of the side groove 1.
[0049]
Although the lid member 13 of the side groove 1 is common to each of the embodiments described above, the water-permeable concrete layer 22 is formed on the water-impermeable concrete layer 21 via the resin binder layer 23. The boundary stepped wall 31 is erected higher than the surface of the water-permeable concrete layer 22 from one side of the bottom of the wall 21 and has a substantially L-shaped cross section. Is inclined downward toward the boundary step wall 31.
[0050]
The boundary step wall portion 31 of the water-impermeable concrete layer 21 functions as a boundary block that clearly partitions the roadway and the sidewalk 32 and is made of water-impermeable concrete, so that sufficient strength can be obtained. In the lid member 13, as with the lid member 13 shown in FIG. 5, rainwater from the water-permeable surface layer 6, which is a roadway, passes smoothly through the water-permeable concrete layer 22 into the drainage empty space 14. The drainage treatment can be performed, and also the rainwater flowing from the sidewalk 32 can be permeated into the water-permeable concrete layer 22 to be drained from the through hole 20 into the drainage empty space 14.
[0051]
In addition, the lower surface of the water-impermeable concrete layer 21 is formed with a fitting convex portion 30 that fits into the upper surface opening of the side groove main body 12, and the fitting convex portion 30 depends on the size of the side groove main body 12. For example, when used in the side groove main body 12 having a circular drainage channel, it is formed narrow so as to correspond to the width of the elongated opening.
[0052]
Further, the embodiment shown in FIG. 8 has a long and narrow opening along the longitudinal direction on the upper surface, and is used for the side groove main body 12 in which a circular drainage cavity 14 ′ communicating with the opening is formed as a drainage channel. The fitting convex part 30 formed in the non-permeable concrete layer 21 is formed narrowly in accordance with the opening, the through hole 20 penetrating the fitting convex part 30 is provided, and the water permeable concrete is formed. A concave groove 24 is formed in the layer 22 so that the through hole 20 is located on the bottom surface, and a grating 25 is fitted into the concave groove 24, and a boundary step is formed on one side of the non-permeable concrete layer 21. The wall 31 is erected higher than the permeable concrete layer 22. The grating 25 is the same as that used in the embodiment.
[0053]
The lid member 13 having such a configuration can be used for the side groove main body 12 of the circular waterway, and rainwater that has permeated the water-permeable surface layer 6 of the roadway into the grating 25 through the water-permeable concrete layer 22. The water can be drained from the through hole 20 to the circular drainage space 14 ′, and the rainwater flowing on the sidewalk 32 and the water permeable surface layer 6 can be drained into the water permeable concrete layer 22 and the water introduction hole 26 of the grating 25. Can be introduced into the grating 25 and drained from the through hole 20 into the circular drainage space 14 '.
[0054]
Next, the boundary block according to the present invention will be described. FIG. 9 is a sectional view of the boundary block 40.
The water-permeable paved road 2 has a water-permeable surface layer 6 formed on a water-impermeable base layer 5.
[0055]
This boundary block 40 is formed with a non-permeable concrete layer 21 having a substantially L-shaped cross section, that is, a boundary step wall portion 31 is erected from one side of the bottom, and a through hole 20 is formed at the bottom. The water-permeable concrete layer 22 is bonded via the resin-based binder layer 23, and the resin-based binder layer 23 is inclined downward toward the boundary stepped wall portion 31, and the boundary stepped wall portion 31 is formed into the water-permeable concrete layer. It is formed higher than 22. The water permeable concrete layer 22 is set to be thicker than the thickness of the water permeable surface layer 6.
[0056]
When the boundary block 40 is laid, the upper surface of the water-permeable concrete layer 22 is substantially flush with the surface of the water-permeable surface layer 6 of the road 2 that is a roadway, and the resin binder layer 23 is paved. The lower permeable surface layer 6 and the non-permeable base layer 5 are arranged below the boundary between the water-permeable surface layer 6 and the water-impermeable base layer 5 so that the upper end of the boundary step wall portion 31 is substantially flush with the surface of the sidewalk 32.
[0057]
When laid in this way, rainwater that has permeated into the water-permeable surface layer 6 permeates into the inside from the longitudinal side surface of the water-permeable concrete layer 22 of the boundary block 40 and penetrates into the ground through the through-hole 20 of the water-impermeable concrete layer 21. Wastewater treatment. Therefore, it is possible to prevent rainwater from staying on the roadway.
[0058]
FIG. 10 is a cross-sectional view of another embodiment of the boundary block 40.
The boundary block 40 bonds the water-permeable concrete layer 22 to the upper surface of the water-impermeable concrete layer 21 via the resin binder layer 23, and the water-permeable concrete on one side of the bottom of the water-impermeable concrete layer 21. The boundary step wall 31 is erected higher than the upper surface of the layer 22 to form the water-impermeable concrete layer 21 in a substantially L-shaped cross section, and the concave groove 24 is formed along the boundary step wall 31 to form the concave shape. A grating 25 is fitted into the groove 24, and the upper surface of the bottom of the water-impermeable concrete layer 21 is inclined downward toward the concave groove 24 side. In addition, the water-permeable concrete layer 22 is formed thicker than the thickness of the water-permeable surface layer 6 like the said embodiment.
[0059]
When the boundary block 40 having such a configuration is laid between the roadway (road 2) and the sidewalk 32, water collecting basins (not shown) are arranged at appropriate intervals, and the boundary is directed toward the water collecting basin. The block 40 is laid down with a series of downward slopes, that is, with a water gradient. When laid in this manner, rainwater that has penetrated into the water-permeable surface layer 6 of the roadway 2 penetrates into the inside from the side surface of the water-permeable concrete layer 22 and flows on the resin-based binder layer 23, gathers in the grating 25, Rainwater that flows from the water-permeable surface layer 6 onto the water-permeable concrete layer 22 or the grating 25 or from the sidewalk 32 over the boundary step wall 31 also gathers in the grating 25. These rainwaters that flow into the grating 25 flow toward the drainage basin in the concave groove 24 by a water gradient applied in the laying direction of the boundary block 40, and are drained into the sewer by the drainage basin.
[0060]
【The invention's effect】
As described above, according to the present invention, the following effects can be obtained.
Since the side groove according to claim 1 is configured such that the lid member that closes the opening of the side groove main body is joined to the upper surface of the non-permeable concrete layer having a through hole, and the permeable concrete layer is bonded via the binder layer. When the binder layer is disposed below the boundary between the water-permeable surface layer of the paved road and the non-water-permeable base layer, the rainwater from the water-permeable surface layer side of the water-permeable paved road is permeable concrete layer of the lid member. It can be made to permeate into the inside from the side surface in the longitudinal direction and be guided from the through hole of the water-impermeable concrete layer into the drainage space of the gutter body to be drained. Therefore, a higher drainage efficiency and a higher drainage treatment capacity can be expected as compared with a conventional side groove in which a through water guide hole is provided in the side wall of the side groove body.
[0061]
In addition, rainwater flowing out from the side surface of the permeable surface layer of the permeable pavement can be passed over the entire side surface of the adjacent permeable concrete layer. Permeability is unlikely to deteriorate due to clogging with dust. Therefore, water permeability can be maintained over a long period of time, and the durability is excellent.
[0062]
Furthermore, since the binder layer is formed on the lower surface of the water-permeable concrete layer of the lid member, this boundary surface becomes smooth and drainage guidance to the through hole can be performed smoothly.
[0063]
The side groove according to claim 2, the side groove is composed of a bowl-shaped side groove body in which side walls are erected from the left and right side edges of the bottom portion, and a plate-like lid member that closes the upper surface opening of the side groove body. The main body is made of non-permeable concrete having a permeable wall portion at the upper edge of the side wall, and the upper portion of the side wall is a lid support that supports the lid member in a state where the upper surface of the lid member is substantially the same height as the upper end of the side wall. The permeable wall is formed thicker than the thickness of the surface layer of the paved road, and the lid member is formed on the upper surface of the non-permeable concrete layer having a through-hole penetrating from the upper surface to the lower surface through a binder layer. Since the binder layer is configured to be below the permeable wall with the lid member supported by the lid support portion, the permeable concrete layer is bonded to the permeable surface layer of the permeable paved road. The rainwater that has permeated penetrates the lid member through the permeable wall. Permeates the sex concrete layer, is drained into the drainage path by the through holes formed in the water-impermeable concrete layer. Therefore, it is possible to effectively suppress the retention of rainwater on the water-permeable surface layer of the water-permeable paved road, and to maintain the water permeability over a long period of time and to expect excellent durability. Further, although the configuration of the side groove main body is different, since the shape is the same as that of the conventional side groove main body, the design and construction standards can be applied as usual.
[0064]
In addition, rainwater derived from the water-permeable surface layer is guided to the water-permeable concrete layer of the lid member through the water-permeable wall portion, so there is no need to open a water passage hole penetrating the side wall, and the strength of the side groove body Can be prevented.
[0065]
The lateral groove according to claim 3 is provided with a plurality of through holes along the longitudinal direction in the non-permeable concrete layer of the lid member, and along the longitudinal direction in a state in which the through hole is included in the bottom surface of the permeable concrete layer. Since the concave groove is formed and the grating is fitted in the concave groove, rainwater can be introduced also from the grating. Therefore, the drainage capacity can be further increased.
[0066]
The lid member according to claim 4 is configured by bonding a water-permeable concrete layer to a top surface of a water-impermeable concrete layer having a through-hole penetrating from the top surface to the bottom surface via a binder layer. When the binder layer is disposed below the boundary between the surface layer and the foundation layer of the pavement with the opening of the side groove body embedded in the water-permeable pavement formed with a water-permeable surface layer on the formation layer, Rain water from the surface side of the water-permeable concrete layer can permeate into the inside from the longitudinal side surface of the water-permeable concrete layer, and can be drained by being guided from the through hole of the water-impermeable concrete layer into the drainage space of the side groove main body. Therefore, it can be used also for the existing gutter body, is versatile, and is easy to construct.
[0067]
Further, since the binder layer is formed on the lower surface of the water-permeable concrete layer of the lid member, this boundary surface becomes smooth, and drainage guidance to the through hole can be performed smoothly.
Furthermore, since the water-permeable surface layer and the water-permeable concrete layer are in surface contact with each other along the longitudinal direction of the lid member in the installed state, the surface layer and the water-permeable concrete layer having a water-permeable function are arranged in the longitudinal direction. Thus, the rainwater flowing out from the surface layer can be absorbed by the entire side surface of the permeable concrete layer, and the drainage efficiency can be increased.
[0068]
The lid member according to claim 5 is provided with a plurality of through-holes along the longitudinal direction in the non-permeable concrete layer, and the upper surface is inclined downward toward the through-hole to form the permeable concrete layer on the bottom surface. Since a concave groove is formed along the longitudinal direction in a state including the through-hole, and the grating is fitted into the concave groove, rainwater can be introduced from the grating, and higher drainage capacity can be expected.
[0069]
In the lid member according to claim 6, since the boundary step wall portion is erected on one side of the non-permeable concrete layer so as to be higher than the upper surface of the permeable concrete layer, the boundary between the sidewalk and the roadway is clearly defined. It can be expected to have a high drainage function.
[0070]
The boundary block according to claim 7, wherein the water-permeable concrete layer is bonded to the upper surface of the water-impermeable concrete layer having a through hole penetrating from the upper surface to the lower surface via a binder layer, and Since the boundary step wall is erected on one side higher than the upper surface of the permeable concrete layer, the binder layer is laid so that it is below the boundary between the permeable surface layer and the non-permeable base layer of the paved road. Then, the rainwater from the water-permeable surface layer side can permeate into the inside from the longitudinal side surface of the water-permeable concrete layer, and can penetrate into the ground through the through-hole of the water-impermeable concrete layer to be drained. Accordingly, the amount of rainwater drained into the sewer can be reduced, and rainwater can be permeated into a wide area of the ground where the boundary block is laid, so that the drainage capacity is higher than the conventional underground penetration structure.
Moreover, the construction of the boundary block that divides the roadway and the sidewalk and the wastewater treatment facility can be constructed at the same time, and the work efficiency can be improved.
[0071]
The boundary block according to claim 8, the water permeable concrete layer is bonded to the upper surface of the water-impermeable concrete layer via a binder layer, and is formed on one side of the water-impermeable concrete layer from the upper surface of the water-permeable concrete layer. A boundary step wall is erected higher, a concave groove is formed along the boundary step wall, a grating is fitted into the concave groove, and the upper surface of the non-permeable concrete layer is directed toward the concave groove. Therefore, rainwater can be introduced into the concave groove even from the grating, so that a high wastewater treatment capacity can be expected.
[Brief description of the drawings]
FIG. 1 is a cross-sectional view of a first embodiment of a side groove according to the present invention.
FIG. 2 is a perspective view of a side groove.
FIG. 3 is a cross-sectional view of a second embodiment of a side groove.
FIG. 4 is a cross-sectional view of another embodiment of a side groove according to the present invention.
FIG. 5 is a cross-sectional view of another embodiment of a side groove.
FIG. 6 is a cross-sectional view of an embodiment of a gutter having a circular drainage cavity.
FIG. 7 is a cross-sectional view of another embodiment of a side groove.
FIG. 8 is a cross-sectional view of another embodiment of a side groove having a circular drainage cavity.
FIG. 9 is a cross-sectional view of a boundary block.
FIG. 10 is a cross-sectional view of another embodiment of a boundary block.
[Explanation of symbols]
1 Side groove
2 Permeable paved road
3 Roadbed
4 Paved roadbed
5 Non-permeable base layer
6 Permeability surface layer
7 Basic crushed stone layer
8 Foundation concrete layer
9 mat mortar
10 Bottom
11 Side wall
12 Gutter body
13 Lid member
14 Drainage space
14 'circular drainage empty space
15 Lid support part
16 Permeable wall
20 Through hole
21 Non-permeable concrete layer
22 Permeable concrete layer
23 Resin binder layer
24 concave groove
25 Grating
26 Water introduction hole
27 Notch
30 Fitting projection
31 Boundary step wall
32 Sidewalk
40 boundary block

Claims (3)

In the gutter embedded in the water-permeable pavement with a water-permeable surface layer formed on the water-impermeable underlayer,
This side groove is composed of a bowl-shaped side groove body with side walls erected from the left and right side edges of the bottom, and a plate-like lid member that closes the upper surface opening of the side groove body,
The gutter body is made of non-permeable concrete having a permeable wall portion at the upper edge of the side wall, and supports the lid member at the upper part of the side wall in a state where the upper surface of the lid member is substantially the same height as the upper end of the side wall. Forming a lid support,
The water permeable wall is formed thicker than the surface layer of the paved road, and the lid member is made of water permeable concrete via a binder layer on the upper surface of the non-permeable concrete layer having a through hole penetrating from the upper surface to the lower surface. Composed of layers,
A side groove characterized in that the binder layer is configured to be lower than the water-permeable wall portion in a state where the lid member is supported by the lid support portion.   The lid member is provided with a plurality of through holes along the longitudinal direction in the non-permeable concrete layer, and a concave groove is formed along the longitudinal direction in the state including the through holes on the bottom surface of the water permeable concrete layer. The side groove according to claim 1, wherein a grating having a rain water passage portion for allowing rain water to pass from the outside to the inside is fitted in the concave groove. In the lid member for opening the opening in the upper surface longitudinal direction and closing the opening of the gutter body formed in the inner longitudinal direction with a drainage cavity communicating with the opening,
This lid member is constructed by bonding a water-permeable concrete layer to a top surface of a water-impermeable concrete layer via a binder layer,
On one side of this non-permeable concrete layer, a boundary step wall portion is erected higher than the upper surface of the permeable concrete layer, and a plurality of through holes penetrating from the upper surface to the lower surface are provided along the longitudinal direction. The upper surface is inclined downward toward the through hole, and a concave groove is formed in the water permeable concrete layer along the longitudinal direction in a state including the through hole on the bottom surface. It is fitted with a grating that has a rainwater passage to pass through,
With the opening of the side groove body embedded in the water-permeable pavement formed with a water-permeable surface layer on the water-impermeable base layer, the binder layer is placed below the boundary between the surface layer and the base layer of the pavement. It is arranged so that rainwater from the water permeable surface layer permeates into the inside from the longitudinal side surface of the water permeable concrete layer and guides it into the drainage space of the gutter body from the through hole of the water impermeable concrete layer so as to drain the water. A gutter lid member characterized by the above.

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