JP2008231703A - Irrigation system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an irrigation system which is hardly damaged over a long period of time because a substantial portion of a water storage unit is not directly exposed on the outside, and which facilitates maintenance. <P>SOLUTION: This irrigation system comprises: wholly-spread interlocking blocks 1 (water-retentive blocks); and the water storage unit 5 which is composed of water storage boxes 6 with opened top portions, spread all over an area under the interlocking blocks 1, and a top plate 7 covering an upper portion of the water storage box 7 and having a water passage hole 55 communicating with the water storage box 6. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to an irrigation system laid on, for example, a pavement or a rooftop.

  Urban pavements and building roofs are usually hardened with asphalt and concrete. Therefore, the temperature rises rapidly during the daytime in the summer, and it is a very severe environmental condition to walk on the pavement and spend on the rooftop. In recent years when the global warming phenomenon has become particularly prominent, this heat is dissipated from the asphalt and the rooftop of buildings not only during the daytime but also at nighttime, which is one of the factors that cause the so-called heat island phenomenon. .

In order to alleviate this heat island phenomenon, attempts have been made to plant trees on the side of the road, plant lawns on the rooftops of buildings, or plant various plants and flowers. Is required.
As part of this, a container-like water retention tank is installed under the water-retaining pavement block body as described in Patent Document 1, and rainwater that falls during rainfall is stored in the water retention tank, and this is connected to the capillarity via a nonwoven fabric. Attempts have been made to suck up the water-retaining pavement block, evaporate it from the water-retaining pavement block body, and cool the water-retaining pavement block body by its latent heat of vaporization.

Japanese Patent No. 2885085 (Japanese Patent Laid-Open No. 8-85907)

  However, in the case of the water-retaining pavement block disclosed in Patent Document 1, since the water-retaining pavement block body also serves as a lid for the water-retaining tank, the weight of the pedestrian walking along the pavement on the water-retaining pavement block body corresponding to this lid However, since pedestrians frequently come and go, the water-retaining pavement block main body may be damaged in a relatively short period of time, and there is a problem that maintenance is difficult.

  In view of the above-described problems, an object of the present invention is to provide an irrigation system in which a main part of a water storage unit is not directly exposed to the outside, and therefore is not easily damaged for a long period of time and is easy to maintain.

  In order to achieve the above object, an irrigation system according to claim 1 of the present invention includes a water retention block laid down, a water storage box laid under the water retention block and having an opening at an upper portion thereof, and an opening of the water storage box. And a water storage unit comprising a top plate having a water passage hole communicating with the water storage box.

  Further, the irrigation system according to claim 2 is laid down under the water-retaining block, a water-permeable cushioning inclusion spread under the water-retaining block, and the water-permeable cushioning inclusion. A water storage unit comprising a water storage box having an opening in the upper part and a top plate having a water passage hole that covers the opening of the water storage box and communicates with the water storage box.

  Further, the irrigation system according to claim 3 is laid down under a water-retaining block laid, a water-permeable cushioning inclusion laid under the water-retaining block, and a water-permeable cushioning inclusion. A water storage unit comprising: a water permeable member; a water storage box spread under the water permeable member and having an opening at an upper portion; and a top plate having a water passage hole that covers the opening of the water storage box and communicates with the water storage box. It is characterized by having.

The irrigation system according to claim 4 is the irrigation system according to claim 2 or 3, wherein the water-permeable cushioning inclusion is a sand cushion.
Furthermore, the irrigation system according to claim 5 is characterized in that, in the irrigation system according to any one of claims 1 to 3, there is a gap between the adjacent water storage units in which piping can be installed.

The irrigation system according to claim 6 is the irrigation system according to any one of claims 1 to 3, wherein a gap between the adjacent water storage units is filled with a water permeable filling member. To do.
The irrigation system according to claim 7 is the irrigation system according to claim 3, wherein the water-permeable member is a water-permeable sheet.

In addition, the irrigation system according to claim 8 is the irrigation system according to any one of claims 1 to 3, wherein the bottom plate of the water storage box has a larger area than the area of the cross section of the water storage portion of the water storage box, And it protrudes outside from the side surface of the said water storage box, and the side surface of the said water storage box is provided with the some rib extended from the upper part toward the lower part and continuing to the said baseplate surface, It is characterized by the above-mentioned.
An irrigation system according to a ninth aspect is the irrigation system according to the eighth aspect, wherein the plurality of ribs are ribs whose hems are tapered from an upper part toward a lower part.

  The irrigation system according to claim 10 is the irrigation system according to any one of claims 1 to 3, wherein the four sides of the bottom plate of the water storage box are fitted with fitting holes provided in the bottom plate of the adjacent water storage box. The fitting protrusion which fits and the fitting hole which fits to the fitting protrusion provided in the bottom plate of the said adjacent water storage box are provided in pairs, respectively.

  Furthermore, the irrigation system according to claim 11 is the irrigation system according to any one of claims 1 to 3, wherein the plane of the top plate is wider than the cross section of the water storage part of the water storage box. It is a feature.

In addition, the irrigation system according to claim 12 is the irrigation system according to any one of claims 1 to 3, wherein a fitting continuous protrusion is provided at an upper end of the water storage box, and the lower surface of the top plate A fitting groove into which the fitting continuous protrusion is fitted is provided.
The irrigation system according to claim 13 is the irrigation system according to any one of claims 1 to 3, wherein an upper end of the water storage box is provided with a fitting groove, and the lower surface of the top plate is fitted with the fitting. A fitting continuous protrusion that fits into the groove is provided.

The irrigation system according to claim 14 is the irrigation system according to any one of claims 1 to 3, wherein the maximum width of the water storage box is less than 500 mm.
Further, the irrigation system according to claim 15 is the irrigation system according to any one of claims 1 to 3, wherein the water-conducting member is provided from a water passage hole provided in the top plate toward a bottom surface in the water storage box. It is characterized by drooping.

  Further, the irrigation system according to claim 16 is the irrigation system according to claim 15, wherein the water-conducting member is formed by forming silica powder into a cylindrical shape, and the water-permeable hole is formed in the water passage hole formed in the top plate. The irrigation system according to claim 17, wherein an upper end of the water conveyance member is connected so as to hang down from a lower surface of the top plate toward a bottom surface of the water storage box. Item 15. The irrigation system according to Item 15, wherein the water-conducting member is formed of silica powder in a cylindrical shape, and the water passage hole formed in the top plate and the hole of the water-conducting member are substantially concentric. Thus, the upper end of the water guide member is connected to the water passage hole so as to hang down from the lower surface of the top plate toward the bottom surface of the water storage box.

  According to the present invention thus configured, it is possible to provide an irrigation system in which the main part of the water storage unit is not directly exposed to the outside, and is therefore difficult to be damaged for a long period of time and is easy to maintain.

Hereinafter, an embodiment of the irrigation system of the present invention will be described in detail with reference to the drawings.
FIG. 1 is a schematic cross-sectional view showing a state in which the irrigation system of the present invention is installed on a pavement, and FIG. 2 is an enlarged view of a main part thereof. As shown in FIGS. 1 and 2, the water storage unit, which is an important component of the irrigation system, is provided under a water retention block, specifically, an interlocking block (pavement block with water retention) 1 having water retention. Is laid.
This will be described in more detail below. First, the ground is digged to a predetermined depth, and ground crushed stone 3 or the like is spread on the hardened road bed 2 to a predetermined thickness. Then, sand crushed 3 is covered with sand of a predetermined thickness to form a sand cushion 4. The base was formed.

  Next, a resin water storage unit 5 is spread on the sand cushion 4. This water storage unit 5 includes a water storage box 6 having a water storage space for storing rainwater or the like inside and having an opening at the top, and a top plate 7 covering the opening at the top of the water storage box 6. As will be described later, the top plate 7 is provided with one or a plurality of water passage holes, and rainwater that has permeated from the ground surface enters the water storage box 6 through the water passage holes and is stored in the water storage box 6. It is supposed to accumulate in.

  When the water storage unit 5 is spread over the pavement, water permeability such as joint sand, grain crushed stone or generated soil, and incineration ash from the incinerator as shown in FIG. Filling member 20 is filled. In this embodiment, after filling joint sand as the water-permeable filling member 20, the water-permeable member 8 made of a water-permeable sheet such as a nonwoven fabric having a thickness of about 5 mm is placed on the top plate 7 of the water storage unit 5. It was. For example, the water permeable member 8 diffuses rainwater that has fallen on the surface of the ground on the top plates of the plurality of water storage units 5 and efficiently distributes the rainwater to the water storage boxes 6 of more water storage units 5.

  When the water-permeable member 8 made of a water-permeable sheet is spread, sand is spread again over this to a predetermined thickness to form a sand cushion 9 that is a water-permeable cushioning inclusion. Finally, the above-described interlocking block 1 is spread on the sand cushion 9.

  In FIG. 1, reference numeral 10 denotes a roadway, reference numeral 11 denotes a road shoulder block, and reference numeral 12 denotes a drainage groove formed at the end of the roadway. Reference numeral 13 is an overflow pipe provided as necessary. The overflow pipe 13 is formed such that one end is formed in the water storage box 6 of the water storage unit 5 and the other end is formed between the shoulder block 11 and the pavement. The rainwater that is connected to the drainage groove that has not yet entered the water storage box 6 flows into the drainage groove via the overflow pipe 13. The drainage grooves are connected to the water collecting mass 14 installed at arbitrary intervals in the longitudinal direction of the drainage grooves. In addition, rainwater or the like flows into the water collecting mass 14 via the drainage pipe 15 from the drainage groove 12 on the roadway side. The rainwater collected in the collecting mass 14 finally flows into the sewage main pipe 16 connected by a pipe.

According to the irrigation system of the present invention shown in FIGS. 1 and 2, the rain that has fallen permeates the interlocking block 1 having water retention, the sand cushion 9, and the water permeable member 8, and the top plate 7. To the water storage space of the water storage box 6 through the water passage hole of the top plate 7 and accumulate. If rainwater overflows from the water storage box 6 due to heavy rain or the like, it flows into the drainage channel via the overflow pipe 13 provided as necessary, and is collected in the collecting mass 14 and then flows into the sewage main pipe 16. .
On the other hand, the rain that has fallen on the roadway flows into the drainage groove 12 provided near the road shoulder, is collected by the collecting mass 14, and finally flows into the river etc. from the sewage main pipe 16.

When the rain rises and the daytime temperature rises, the rainwater in the water storage box 6 rises through the sand cushion 9 via the water permeable member 8 and becomes steam from the interlocking block 1 into the atmosphere. Is released. At this time, the interlocking block 1 and the like are cooled by the latent heat of vaporization, and the ambient temperature is lowered.
Note that the above-described overflow pipe 13, the drainage groove into which rainwater flows from the overflow pipe 13, the water collecting mass 14, and the like are not essential requirements of the present invention.
For example, if there is no overflow pipe 13 or drainage groove, rainwater overflowing the water storage box 6 may be infiltrated into the ground through the water permeable member 8.

  According to the irrigation system of the present invention thus configured, since the interlocking block 1 is provided on the water storage unit 5 comprising the water storage box 6 and the top plate 7, the weight of the pedestrian walking on the pavement and when walking Is not directly applied to the water storage unit 5. Therefore, the water storage box 6 and the top plate 7 are not damaged in a short time. In particular, as in the embodiment shown in FIG. 1 and FIG. 2, a cushioning inclusion, specifically a sand cushion 9, and further a non-woven fabric or the like, is provided between the interlocking block 1 and the water storage unit 5. If the water permeable member 8 is provided, the load and impact transmitted from the interlocking block 1 are further alleviated by the water permeable member 8 and the sand cushion 9, and the load and impact applied to the water storage unit 5 are greatly reduced. This is preferable. Of course, these water-permeable members 8 and sand cushions 9 can greatly reduce the influence of vibrations caused by large vehicles passing through the roadway and vibrations caused by earthquakes.

  The water-permeable member 8 and the sand cushion 9 described above are not necessarily required in the present invention, but if there is a water-permeable member 8 such as a nonwoven fabric, the impact transmitted to the water storage unit 5 is reduced as described above. In addition to the cushion effect, rainwater that has permeated through the interlocking block 1 can be uniformly diffused horizontally on the plurality of water storage units 5, and the sand of the sand cushion 9 is provided on the top plate 7. It is also possible to prevent the water storage space in the water storage box 6 from being narrowed by entering the water storage box 6 from the water passage hole and accumulating. That is, it also functions as an earth and sand intrusion prevention member.

  In addition, if the sand cushion 9 is provided, not only the shock applied to the interlocking block 1 is greatly relieved and transmitted to the water storage unit 5 as described above, but also when the interlocking block 1 is arranged on the water storage unit 5, it is laid down. Even if the surfaces of the plurality of water storage units 5 are not completely flush with each other, the sand cushion 9 can adjust the unevenness. Therefore, by arranging a cushioning inclusion such as the sand cushion 9 between the interlocking block 1 and the water storage unit 5, there is also an advantage that the interlocking blocks 1 can be easily arranged.

  3 and 4 show a typical example of the water storage unit 5. 3 is a front view of the water storage unit 5, and FIG. 4 is a perspective view thereof. As shown in these figures, the area of the plane of the top plate 7, that is, the width of the plane, is larger than the width (area) of the cross section of the water storage portion of the water storage box 6, that is, the square box portion in this example. When the water storage unit 5 needs to be exposed for maintenance or the like, earth and sand are difficult to enter the water storage box 6 from the outside.

  In addition, the bottom plate 30 of the water storage box 6 has a width (area) of the cross section of the water storage section of the water storage box 6, specifically, for example, in FIGS. The area is larger than the area of the plane at the position cut horizontally at the half position, and therefore protrudes outward from the side surface of the water storage box 6. A plurality of ribs 31 are provided on each of the four side surfaces of the water storage box 6 from the upper part to the lower part, that is, from the upper part to the surface of the bottom plate 30.

The rib 31 may be a rib having the same width measured from the side surface of the water storage box 6 from the top to the bottom, and as shown in FIG. 3 and FIG. It may be a rib having a taper-shaped hem.
As the number of these ribs 31 is larger, the load resistance of the water storage box 6 can be increased. Therefore, what is necessary is just to determine the number of the ribs 31 provided, the width | variety, etc. in consideration of the environment where the water storage unit 5 is laid.

With such a tapered rib 31, as shown in FIG. 5, when the water storage units 5 are arranged side by side, a gap having an inverted triangular cross section can be created between the adjacent water storage units 5 and 5. . Therefore, a pipe 40 such as a water supply / drainage pipe can be laid between the adjacent water storage units 5 and 5.
It is preferable to lay the pipe 40 at such a position because an external force is not directly applied to the pipe 40, so that damage to the pipe 40 can be prevented for a long period of time. Further, in this case, it is possible to support the pipe 40 with two-point support by the ribs 31 of both the water storage units 5 and 5, and the positioning can be ensured and the pipe 40 can be stably held, which is preferable.
Incidentally, although it is not always necessary to lay the piping 40 such as the water supply pipe here, if the piping 40 is connected in advance and the branch pipes are connected to the respective water storage units 5 in this way, it is insufficient for rain. Thus, when there is no rainwater in the water storage box 6, water can be supplied from the outside to each water storage box 6 using this pipe 40. Therefore, it is preferable that the irrigation system of the present invention can be used even in case of rain shortage such as drought.
By the way, the code | symbol 55 in FIG. 4 is the water flow hole formed in the top plate 7 so that the front and back may be penetrated. The periphery of the pipe 40 is filled with a water permeable filling member 20 made of joint sand or the like.

6 to 8 are modified examples of the water storage box 6 according to the present invention. Specifically, in a state where the top plate 7 is removed from the water storage unit 5, that is, a plan view of the water storage box 6, three types of water storage boxes 6 are shown here.
In each water storage box 6 shown in FIGS. 6 to 8, reference numeral 30 denotes a bottom plate protruding outward from the side wall 33, and each of the side walls 33 is provided with five tapered ribs 31 at equal intervals. ing. Reference numeral 34 denotes the inside of the water storage box 6, that is, the water storage space of the water storage section.
By the way, the water storage box 6 shown in FIG. 6 is characterized by fitting protrusions having the same shape on the four sides of the bottom plate 30, here, a fitting protrusion 35 whose tip is a part of a rectangle or a square, and a fitting protrusion 35. The fitting holes 36 to be paired are provided in pairs.
As a result, when a large number of water storage units 5 are spread on the sand cushion 4, the adjacent water storage boxes 6 are fitted with the mating fitting holes 36 in the fitting protrusions 35 provided on the bottom plates 30 facing each other. Since it is only necessary to fit the mating fitting projection 35 into the mating hole 36, the water storage unit 5 can be positioned reliably and the water storage unit 5 can be installed more easily.

On the other hand, the water storage box 6 shown in FIG. 7 is characterized in that the above-described fitting protrusion 35 and the fitting hole 36 fitted therein are tapered.
Thus, if the fitting protrusion 35 and the fitting hole 36 are made into a taper shape, a mutual fitting becomes easier than what is shown in FIG. 6, and the installation work of the water storage unit 5 becomes simpler, and it is preferable.
Further, the water storage box 6 shown in FIG. 8 is characterized in that a suspension hole 38 is provided in the fitting projection 35 of the water storage box 6 shown in FIG. In this way, when the water storage box 6 is heavy and therefore the water storage box 6 must be suspended and transported with a small crane or the like, it can be suspended through the rope through the suspension hole 38. So convenient.
In FIG. 8, the suspension holes 38 are provided in all the fitting protrusions 35, but the suspension holes 38 may be provided only in any one of the fitting protrusions 35. The number of fitting protrusions 35 to be provided with the suspension holes 38 may be selected as appropriate.

FIGS. 9 and 10 show still another example of the water storage unit 5, and are both longitudinal sectional views of the water storage unit 5.
The feature of the water storage unit 5 shown in FIG. 9 is the fitting portion between the water storage box 6 and the top plate 7. Specifically, in the case shown in FIG. 9, a continuous fitting projection 51 is provided continuously at the upper ends of all four side walls 33 of the water storage box 6, while the fitting is provided on the lower surface of the top plate 7 over four sides. A fitting groove 52 that fits into the continuous projection 51 is provided.
As a result, even if earth and sand try to enter the water storage box 6 from the outside, the intrusion route becomes long and it is difficult to enter.

  On the other hand, the feature of the water storage unit 5 shown in FIG. 10 is that, contrary to that shown in FIG. 9, the fitting grooves 53 are continuously provided at the upper ends of the side walls 33 of all four surfaces of the water storage box 6. On the lower surface of the top plate 7, fitting continuous protrusions 54 that fit into the fitting grooves 53 are also formed continuously on all four sides. Also in this case, as in the case shown in FIG. 9, even if earth and sand try to enter the water storage box 6 from the outside, there is an effect that the intrusion route becomes long and is difficult to enter.

Further, the water storage unit 5 shown in FIG. 9 and FIG. 10 is characterized in that it is connected to a plurality of water passage holes 55 provided in the top plate 7, and the water guide member 56 that hangs down toward the bottom surface in the water storage box 6. There is also.
Even if the water flow hole 55 is simply provided in the top plate 7, the rainwater that has passed through the interlocking block 1, the sand cushion 9, and the water permeable member 8 and reaches the water storage unit 5 passes through the water flow hole 55 and is stored in the water storage box. 6 accumulates in the water storage space 34 and when the external temperature is high, the evaporated water passes through the water passage hole 55 and is finally diffused into the air while cooling the interlocking block 1 and the like. However, in order to increase the efficiency of the rainwater rise and the evaporation of the raised water, the water guide member 56 is connected to the lower surface of the top plate 7 as described above.

The water-conducting member 56 shown in FIG. 9 is obtained by molding silica powder into a cylindrical shape (pipe shape). The water guide member 56 is formed so that the water passage hole 55 formed in the top plate 7 and the hole of the water guide member 56 are substantially concentric and from the bottom surface of the top plate 7 to the bottom surface of the water storage box 6. The upper end is connected to the water passage hole 55 so as to hang downward.
On the other hand, what is shown in FIG. 10 is a product obtained by forming silica powder into a cylindrical shape, and the upper end of the water-conducting member 56 is connected to the water passage hole 55 of the top plate 7. It hangs down toward the bottom.

As described above, since any of the water-conducting members 56 is a porous molded body, the surface tension is easy to work. Especially when the external environment is high temperature, the water-conducting member 6 greatly contributes to an increase in moisture from the inside of the water storage box 6. The effect of cooling the locking block 1 etc. is extremely great.
Needless to say, the water-conducting member 56 is not limited to a molded body made of silica powder, and a water-permeable member such as a non-woven fabric may have a cylindrical shape, a columnar shape, or other shapes. However, it is important that the lower end of the lower end is attached so as to be brought into contact with the bottom surface in the water storage box 6. This is because rainwater can be effectively raised to the end and used up even if the amount of water stored in the water storage box 6 is extremely small.

By the way, as for the size of the water storage box 6, it is preferable that one side is the maximum width, that is, if the plane shape is substantially square as in the above-described embodiment, and if the rectangle is a rectangle, the long side is less than 500 mm at the maximum. This is because, in rare cases, a truck may temporarily ride on a pavement in order to transport luggage to a store adjacent to the pavement or due to an accident or the like. For example, in the case of a 25-ton truck, the installation area of the tire is 200 mm × 500 mm. Therefore, if the maximum width is set to less than 500 mm, the tire does not come to a position that fits completely in the water storage box 6 at worst. That is, since a part of the tire is always located on the side wall 33 of the water storage box 6, a part of the load of the truck can be supported by the side wall 33 and the rib 31 provided on the side wall 33. This is because there is a high possibility of avoiding damage.
Therefore, even in places where there is a high possibility that vehicles such as trucks will ride on the pavement, if the maximum width of the water storage box 6 is 500 mm or less, the truck will be parked on the water storage box 6 in the worst case. This is preferable because the risk of damage to the water storage box 6 can be reduced.

  If both the water storage box 6 and the top plate 7 of the water storage unit 5 are made of resin, the processing of the ribs 31, the fitting protrusions 35, the fitting holes 36 and the like is easy and easy to manufacture. In addition, a recycled material of resin can be used, which is preferable. However, in the water storage unit 5 installed in a particularly heavy load place, either the water storage box 6 or the top plate 7 or all of them can be made of metal.

  As described above, according to the irrigation system of the present invention, since the interlocking block 1 is provided on the water storage unit 5 including the water storage box 6 and the top plate 7, the weight and impact of the pedestrian walking on the pavement are Since it is received primarily by the interlocking block 1, it is not directly applied to the internal water storage unit 5. Therefore, the possibility that the water storage box 6 and the top plate 7 are damaged in a short time is extremely small. In particular, if a water-permeable member 8 such as a sand cushion 9 or a nonwoven fabric is provided between the interlocking block 1 and the water storage unit 5 as in the embodiment shown in FIGS. The impact is further alleviated, and the load and impact applied to the water storage unit 5 can be further reduced. In addition, the effects of vibrations caused by large vehicles passing through the roadway and shaking caused by earthquakes can be greatly reduced by the water-permeable member 8 and the sand cushion 9.

Furthermore, since there is a gap between the adjacent water storage units 5 and each is filled with joint sand 20, the water-retaining pavement blocks directly like the ones described in Patent Document 1 Even if there is an earthquake or a large truck passes through the adjacent roadway and a large vibration is generated and the pavement is shaken, the joint sand 20 will relieve the shaking as compared to the one that is spread while contacting. Willing to. For this reason, the water storage unit 5 is also shaken by the shaking, and it is difficult for a part of the water storage unit 5 to lose its escape and rise.
As described above, in the conventional water-retaining pavement block disclosed in Patent Document 1, the water-retaining pavement block body directly touches the pedestrian, that is, is exposed and easily damaged, or the pavement is shaken by an earthquake or the like, the water retentivity. Although there was a problem that the pavement block is likely to rise, in the above-described irrigation system of the present invention, these problems are solved or greatly reduced.

  By the way, in each said Example, although the example which applied the irrigation system of this invention only to the pavement is shown, the irrigation system of this invention is not limited to a pavement, For example, it can be laid on the roof of a building, and it is in a park etc. The present invention is also applicable to a place where many people gather, especially in the summer when it is desired to lower the ambient temperature. It can also be applied to parking lots, but in that case, sufficient consideration must be given to the mechanical strength of the water storage unit. Specifically, for example, it is necessary to reduce the maximum width of the water storage box, increase the number of ribs provided on the side wall, or increase the width.

  As described above, according to the irrigation system of the present invention, it is possible to provide an irrigation system in which the main part of the water storage unit is not directly exposed to the outside, and thus is not easily damaged over a long period of time and is easy to maintain. .

It is a schematic sectional drawing which shows one Example of the irrigation system of this invention. It is a partially expanded sectional view of the irrigation system shown in FIG. It is a front view which shows an example of the water storage unit which concerns on the irrigation system of this invention. It is a perspective view of the water storage unit shown in FIG. It is a front view which shows the state which laid piping between the water storage units shown in FIG. It is another example of the water storage unit which concerns on the irrigation system of this invention, and is a top view of the water storage box which shows the state which removed the top plate. It is a top view of the water storage box which shows another example of the water storage unit which concerns on the irrigation system of this invention, and shows the state which removed the top plate. It is a top view of the water storage box which shows another example of the water storage unit which concerns on the irrigation system of this invention, and shows the state which removed the top plate. It is a longitudinal cross-sectional view which shows another example of the water storage unit which concerns on the irrigation system of this invention. It is a longitudinal cross-sectional view which shows another example of the water storage unit which concerns on the irrigation system of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Interlocking block 4 Sand cushion 5 Water storage unit 6 Water storage box 7 Top plate 8 Water permeable member 9 Sand cushion 10 Roadway 14 Water collecting mass 20 Water permeable filling member 30 Bottom plate 31 Rib 33 Side wall 34 Water storage space 35 Fitting protrusion 36 Fitting Hole 38 Suspension hole 51 Fitting continuous protrusions 52 and 53 Fitting groove 54 Fitting continuous protrusion 55 Water passage hole 56 Water-conducting member

Claims (17)

  A water storage block comprising a water retention block spread down, a water storage box spread under the water retention block and having an opening at the top, and a top plate having a water passage hole that covers the opening of the water storage box and communicates with the water storage box An irrigation system comprising: a unit;   A water-retaining block laid down, a water-permeable cushioning inclusion laid under the water-retaining block, a water storage box laid down below the water-permeable cushioning inclusion and having an opening at the top thereof, and An irrigation system comprising: a water storage unit comprising a top plate having a water passage hole that covers an opening of the water storage box and communicates with the water storage box.   A water-retaining block laid down, a water-permeable cushioning inclusion laid down under the water-retaining block, a water-permeable member laid down under the water-permeable cushioning inclusion, and the water-permeable member An irrigation system comprising: a water storage box that is spread under and having an opening at the top; and a water storage unit that covers the opening of the water storage box and has a top plate having a water passage hole that communicates with the water storage box. .   4. The irrigation system according to claim 2, wherein the water-permeable cushioning inclusion is a sand cushion.   The irrigation system according to any one of claims 1 to 3, wherein there is a gap in which piping can be laid between the adjacent water storage units.   The irrigation system according to any one of claims 1 to 3, wherein a gap between the adjacent water storage units is filled with a water-permeable filling member.   4. The irrigation system according to claim 3, wherein the water permeable member is a water permeable sheet.   The bottom plate of the water storage box has a larger area than the cross-sectional area of the water storage section of the water storage box, and protrudes outward from the side surface of the water storage box. The irrigation system according to any one of claims 1 to 3, wherein a plurality of ribs extending and connected to the bottom plate surface are provided.   The irrigation system according to claim 8, wherein the plurality of ribs are ribs whose hems are tapered from an upper part toward a lower part.   On the four sides of the bottom plate of the water storage box, a fitting projection that fits into a fitting hole provided in the bottom plate of the adjacent water storage box, and a fitting that fits into a fitting projection provided in the bottom plate of the adjacent water storage box The irrigation system according to any one of claims 1 to 3, wherein the holes are provided in pairs.   The irrigation system according to any one of claims 1 to 3, wherein a flat surface of the top plate is wider than a cross section of a water storage portion of the water storage box.   The fitting continuous protrusion is provided in the upper end of the water storage box, and the fitting groove into which the fitting continuous protrusion is fitted is provided in the lower surface of the top plate. 3. The irrigation system according to any one of 3.   4. A fitting groove is provided at an upper end of the water storage box, and a fitting continuous protrusion that fits into the fitting groove is provided on a lower surface of the top plate. The irrigation system in any one.   The irrigation system according to any one of claims 1 to 3, wherein a maximum width of the water storage box is less than 500 mm.   4. The irrigation system according to claim 1, wherein a water-conducting member hangs down from a water passage hole provided in the top plate toward a bottom surface in the water storage box.   The water-conducting member is formed of silica powder in a cylindrical shape, and the upper end of the water-conducting member extends from the bottom surface of the top plate to the bottom surface of the water storage box in the water passage hole formed in the top plate. The irrigation system according to claim 15, wherein the irrigation system is connected so as to hang downward.   The water-conducting member is formed by forming silica powder into a cylindrical shape, so that the water passage holes formed in the top plate and the holes of the water-conducting member are substantially concentric, and the top plate The irrigation system according to claim 15, wherein an upper end of the water guide member is connected to the water passage hole so as to hang down from a lower surface of the water storage box toward a bottom surface of the water storage box.

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