KR20130025470A - Rainwater permeate and retention module, plants module and module type system - Google Patents

Abstract

PURPOSE: A rainwater permeation and retention module, a vegetation structure and a modular rainwater permeation and retention facility structure using the same are provided to structurally stabilize when comparing to an existing rainwater permeation facility and resolve the inconvenience for the pedestrians such as rain spattering during heavy raining. CONSTITUTION: A rainwater permeation and retention module(100) includes a porous body part(110) and multiple water permeable through hole parts(120) formed through the upper and the lower part of the porous body part. A vegetation structure includes a garden frame forming the upper surface as a terraced type, a partition unit vertically installed in the internal space of the garden frame and multiple divisional spaces separated based on the partition unit in the internal space. A modular rainwater permeation and retention facility structure includes a module assembly vertically or horizontally stacked by multiple modules and a support frame installed to settle the module set.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to rainwater infiltration / storage module, vegetation structure, and module rainwater infiltration /

The present invention relates to a rainwater storage facility structure installed in the vicinity of a road or a house to perform functions of rainwater infiltration, storage, evapotranspiration and purification in order to improve the water circulation inside the city, and components of the facility structure.

The rain on the forest slowly infiltrates into the soil where the ground leaves are deposited, and flows into the sea, creating a steady stream of rivers. Rainwater infiltrates the earth inside the city, not the forest, and goes through the same path. This slowly circulating water allows nature to maintain its purifying action and provide a rich hydrophilic space for all living things. In recent years, the forests have been punctured due to the development of golf courses, ski resorts, and residential areas in mountainous areas. In urban areas, roads occupy 10 to 15% of the surface area. Roads are high in impermeability due to asphalt and concrete front pavement. Therefore, rainwater can not be absorbed into the soil and the outflow rate to the outside is high. The arrival time is fast. This tendency is caused by the lack of underground water in the urban areas, causing the roadside trees to run dry or to deepen the heat island phenomenon. On the other hand, in bottlenecks or low areas, water bottlenecks are generated and damages such as houses and roads are flooded. There is a concern about damage.

In addition, when the river level rises, the exclusion rate tends to slow down and the residential area of the lowlands tends to flood in a short time. Therefore, in the city, many national budgets are consumed by constructing a separate sewage treatment system .

In particular, the drainage of the street area inside the city is becoming the key to road traffic and flooding. It is a horizontal space, and it is a series of space including the structures on both sides of the road and the road. Such lateral space is also required to perform an excellent discharge function. Development of environmentally friendly, efficient, shortened construction time and easy installation of such a drainage structure is required.

In order to solve the above problems, the present invention solves the following problems.

1. In order to solve the problem of the long working time of the human parts due to the difficulty in construction, it is desirable to provide an installation component for standardizing the pitcher block.

2. For this purpose, we developed a modular module of pitcher block to provide a modular rainwater infiltration and storage structure that can be installed at once.

3. On the other hand, in addition to the installation workability for rainwater infiltration and reservoir function, the vegetation structure which effectively enhances the infiltration function is developed and applied to the ground to form aesthetics and to enhance the infiltration function while ensuring stability.

The present invention includes a porous body 110; And a plurality of water permeable cylinder openings (120) formed through the upper and lower portions of the body portion. The rainwater infiltration and storage module body (100)

In addition, the present invention may be applied to an inkjet printer comprising: a bed frame 410 having a top surface formed in a stepped shape; A partitioning part 420 extending downward from a vertical surface of the upper step and vertically installed in the space inside the flower bed frame; And a plurality of compartment spaces 430 separated from the inner space by the partition 420. When the soil is introduced into the compartment space 430, And a rainwater infiltration / storage vegetation structure (400) which is fixed and supported.

Also, the present invention is a rainwater infiltration and storage facility structure installed in a basement, comprising: a module aggregate (200) in which a plurality of modules of claim 1 are stacked horizontally or vertically; And a support frame 300 having a frame 310 formed with a predetermined standard according to the external appearance of the module assembly and having hooking parts 320 mounted on the corners thereof, A modular rainwater infiltration and storage facility structure in which the aggregate is installed so as to be seated, a string is connected to the hook portion of the reception tower to lift the module aggregate together with the reception tower, Lt; / RTI >

The present invention has the following effects.

1. The rainwater infiltration / storage modular body and the module type rainwater infiltration and storage structure according to the present invention are effective because they are structurally stabilized as compared with existing rainwater infiltration facilities.

2. Furthermore, according to the rainwater infiltration / storage module and the module rainwater infiltration / storage structure according to the present invention, since the rainwater flows to the horizontal space or the like, it is possible to solve the inconvenience such as rainwater fogging of pedestrians in the concentrated lakes .

3. When the vegetation structure of the present invention is installed on the upper part of the rainwater infiltration and storage facility structure according to the present invention, the upper surface is configured in a stepped manner, so that the height difference due to the installation of the barrier seats can be reduced.

4. Meanwhile, the precipitation tank is formed inside the vegetation structure according to the present invention, and the rainwater purifying function can be performed by filtering and removing the impurities periodically using the filter box.

5. Also, in the case of using the boundary stones according to the present invention, in particular, in the case of using the boundary stones in which only the settling tank is installed, the rainwater is concentrated to the inside of the settling tank, .

6. In particular, the rainwater infiltration and storage structure according to the present invention can be integrally installed with a module such as a crane after being assembled using a modularized module, so that the constructability is high and the construction time is shortened.

1 is a perspective view of a rainwater infiltration / storage module body according to the present invention.
2 is a perspective view of a vegetation structure for rainwater infiltration and storage according to the present invention.
[Fig. 3] is a front view (a), a lateral side view (b), and a longitudinal side view (c) of the vegetation structure for rainwater infiltration and storage according to the present invention.
4 is an internal structural view of a settling tank for a rainwater infiltration / storage vegetation structure according to the present invention.
5 is a sectional view of a modular rainwater infiltration and storage facility structure according to the present invention.
6 is a perspective view of the installation of the support frame in the modular stormwater infiltration and storage structure according to the present invention.
[7] FIG. 7 is an embodiment of a mounting structure of a support frame in a modular rainwater infiltration and storage facility structure according to the present invention.
FIG. 8 is a sectional view of a facility structure in which a vegetation structure is installed as a modular rainwater infiltration and storage facility structure according to the present invention.
FIG. 9 is an enlarged cross-sectional view depicting a vegetation structure part in a modular rainwater infiltration and storage facility structure according to the present invention.
10 is a cross-sectional view of a boundary trough in which a through hole is formed in the modular stormwater infiltration and storage structure according to the present invention.
11 is an embodiment of a facility structure in which a vegetation structure is installed as a modular rainwater infiltration and storage facility structure according to the present invention.

Ⅰ. Rainwater infiltration and storage Module body (100)

The present invention includes a porous body 110; And a plurality of water permeable cylinder openings (120) formed through the upper and lower portions of the body portion. The rainwater infiltration and storage module body (100)

1 is a perspective view of a rainwater infiltration / storage module body according to the present invention. Hereinafter, the structure of the rainwater infiltration and storage module according to the present invention will be described with reference to the drawings.

1. The body 110,

The module body 100 includes a body 110 and a water permeable cylinder 120. Both of them perform the function of transmitting rainwater. However, in the case of the body portion 110, it is important that the porous body is made of a material suitable for the porosity.

The body portion 110 may have porosity as physical properties, and porous concrete may be used.

Unlike concrete, porous concrete is a porous concrete that forms continuous pores uniformly so that water and air can freely pass through by increasing continuous pores. In order to incorporate a large amount of pores, single-size crushed stones having a uniform particle size of aggregate are required. However, water-tightness is required in that a coarse aggregate and a fine aggregate are usually dispersed in a cement paste. It is also called no-fine concrete because it does not use fine aggregate.

In addition, the material that can have porosity is a mixture of powder and aggregate in a weight ratio of 1: 3 to 7. The non-sintered clay composition or cement powder is used as the powder, and micropores May be used.

2,

The module body 100 may form a permeability hole in a certain space therein. The reason for existence of the permeable water pipe 120 is in the amount of rainwater. Since the body 110 is also porous, it has a permeability, but there is a risk of exceeding the permeability of the body 110 when the rainy season or heavy rain falls. It is preferable to design the permeable water pipe 120 so that the rainwater can be rapidly permeated. This is advantageous in that permeability is ensured in the module body 100 itself and no additional means is required to increase permeability.

One or a plurality of the permeable tubes 120 may be formed in one module 100, and the size and the number of the permeable tubes 120 can be determined flexibly according to the right and left frequencies of the area.

Ⅱ. Rainwater infiltration and storage Vegetation structure (400)

The present invention relates to an inkjet printer comprising: a bed frame 410 having a top surface formed in a stepped shape; A partitioning part 420 extending downward from a vertical surface of the upper step and vertically installed in the space inside the flower bed frame; And a plurality of compartment spaces 430 separated from the inner space by the partition 420. When the soil is introduced into the compartment space 430, The rainwater infiltration / storage vegetation structure (400) is fixed and supported.

The present invention further provides a vegetation structure (400), further comprising a sedimentation tank (440) inserted into and disposed in the lowermost compartment space of the compartment space.

In addition, the present invention is characterized in that the sedimentation tank 440 is provided with a sedimentation box 441 provided so as to form a certain gap with the partitioning part 420, a water permeable material 431 inserted into the sedimentation box, And a grill-shaped lid 443 covering the upper portion of the filter media box. When rainwater is pumped through the lid and stored up to the top of the precipitation box, And the rainwater flows through the gap of the compartment space at the protruding portion so as to be sprayed downward.

3 is a front view (a), a lateral side view (b), and a longitudinal side view (b) of the vegetation structure for storm water infiltration and storage according to the present invention. FIG. 2 is a perspective view of a vegetation structure for rainwater infiltration / Side view (c). Hereinafter, the structure and function of the vegetation structure will be described with reference to these.

1. Flower bed frame 410

The petal frame 410 corresponds to a component constituting the entire shape of the vegetation structure. In general, the upper end of the tubular frame is formed as a stepped layer to form a gentle slope layer.

In the case of installing in a transverse space or between a roadway and a sidewalk, there is usually a height difference between the roadway and the sidewalk. Therefore, in order to gently form such a gap, a flower bed frame composed of the stepped bed can be used.

(A) of FIG. 2 shows the binding of constituent elements of a vegetation structure as a unit of the vegetation structure, and FIG. 2 (b) shows a combination of a plurality of vegetation structures, .

Further, FIG. 3 shows a front view (a), a lateral side view (b), and a longitudinal side view (c) of the vegetation structure.

The inner space of the petal frame is formed as an empty space so that soil or the like necessary for forming a flower bed can be input. It is preferable that the material of the flower bed mold 410 is formed of a material which is not corroded in consideration of being installed in the ground.

2. The partitioning part 420 and the compartment space 430,

And the partition part extends vertically downward from the vertical plane of the upper surface step, and is vertically installed in the space inside the flower bed frame. The partitioning part 420 functions to fix the soil introduced into the inner space of the flower bed mold 410 so as to prevent the soil from flowing along the infiltrated rainwater.

The partitioning part 420 is preferably installed so as to coincide with the vertical surface of the upper step, because it is easy to apply the soil and is effective in the soil pressure and the supporting force.

A plurality of compartment spaces 430 are formed in the inner space of the petal frame by the partitioning part 420. The soil is inserted into each of the compartment spaces and the lower end compartment space is filled with soil A settling tank is also inserted.

3. The settling tank (440)

The settling tank 440 serves to purify the rainwater in the vegetation structure 400. 4 is an internal structural view of a settling tank for a rainwater infiltration / storage vegetation structure according to the present invention. Hereinafter, components of the sedimentation tank 440 will be described.

The sedimentation tank 440 includes a sedimentation box 441 having a size that maintains a predetermined gap with the partitioning space. The reason why the settling box must maintain a gap with a certain interval from the compartment space is that the rainwater flowing down from the protruded filter box can be lowered. That is, most of the inflowed rainwater is mixed with soil, garbage, and leaves, and these impurities are purified by using the filter box of the settling tank to purify contaminants of rainwater.

Also, a filter box 442 is inserted into the settling tank 440, which is installed to be protruded at a predetermined height above the settling box. The functions of the filter box 442 can be seen as a purifying function and a water permeability function.

First, regarding the purifying function, the filtering box 442 is made of a permeable material so that rainwater can be permeated. However, a storage function is implemented in a state where the filtering box is inserted into the filtering box 441. That is, the rainwater is continuously infiltrated into the lower portion of the precipitation box where the precipitation tank is not installed. However, in the portion where the precipitation tank is installed, rainwater is stored by the precipitation box to control the infiltration amount of rainwater. The filter box 442 is made of a water-permeable material, and performs a purifying function through which rainwater is filtered and other impurities are filtered. When the filter box is lifted up and separated from the settling box 441, the process of separating the impurities remaining in the filter box 442 and removing the impurities and then inserting the impurities into the settling box 441 is periodically repeated Function.

Second, since the filter box 442 is installed to protrude from the upper part of the precipitation box, the rainwater stored up to a predetermined water level is also permeated down the precipitation box 441 through the protruding part.

In addition, the sedimentation tank 440 includes a lid portion 443 in the form of a grill covering the protruded upper portion of the filter box 442 as a component. The lid part is provided to constitute a part of the ground on which the vegetation structure 400 of the present invention is installed. In other words, the lid unit 443 is installed to form a part of the stepped top surface of the stage 410 of the sedimentation tank 440. The lid part is formed in the form of a grill to primarily filter impurities such as soil, garbage, and leaves, and to filter the impurities in a small amount secondarily by the inner filter box 442 of the settling tank 440 do.

Ⅲ. Modular stormwater infiltration and storage structure

The present invention relates to a rainwater infiltration and storage facility structure installed in a basement, comprising: a module aggregate (200) in which a plurality of modules of claim 1 are stacked horizontally or vertically; And a support frame 300 having a frame 310 formed with a predetermined standard according to the external appearance of the module assembly and having hooking parts 320 mounted on the corners thereof, A modular rainwater infiltration and storage facility structure in which the aggregate is installed so as to be seated, a string is connected to the hook portion of the reception tower to lift the module aggregate together with the reception tower, Lt; / RTI >

The vegetation structure 400 may be installed on the upper part of the module aggregate 200 so that the upper surface of the vegetation structure 400 is covered with the upper surface of the module assembly 200, The present invention also provides a modular rainwater infiltration and storage facility structure that forms part of the ground.

In addition, the present invention may further comprise a barrier 500 extending in the longitudinal direction so as to be parallel to the upper or lower end of the upper surface of the vegetation structure 400, The penetration portion 510 is formed only in a portion in which the rainwater 400 is installed so that the rainwater is intensively permeated to the lid portion 443 through the penetration portion.

5 is a sectional view of a modular rainwater infiltration and storage facility structure according to the present invention. Hereinafter, the modular rainwater infiltration and storage structure will be described with reference to this.

As shown in FIG. 5, the rainwater infiltration and storage facility structure according to the present invention includes a module aggregate 200 in which a module 100 in which rainwater is permeable to porous material for installation of the module aggregate is stacked, The support frame 300 installed to seat the module assembly is a major component.

The module assembly 200 is formed by stacking the modules 100 in a vertical direction or a left-and-right direction to form one combination. If necessary, the number of modules can be set and used. .

It is preferable that the module assembly 200 is laminated inside the upper part of the support frame 300 prepared in advance.

[Figure 6] is a perspective view of the installation of the support frame in the modular rain storm infiltration and storage facility structure according to the present invention, [Figure 7] is a perspective view of the installation of the support frame in the module rain storm infiltration and storage facility structure according to the present invention FIG.

Referring to FIGS. 6 and 7, it is necessary that the support frame 300 is formed in a predetermined size suitable for the size of the module assembly 200 and prepared in advance. The support frame 300 is composed of a frame part 310 forming a support frame and a hook part 320 installed at each corner of the frame part 310.

Preferably, the frame unit implements a rectangular shape conforming to the standard of the module aggregate. In the case where the frame 310 is elongated in the longitudinal direction of the frame 310, it is possible to additionally provide a frame in the longitudinal direction to maintain the rigidity in the middle. However, it is important to maintain a space other than the frame portion of the support frame so as to be compatible with the water permeability function of the storm penetration installation structure.

In addition, the frame part may be formed only in the transverse direction and the longitudinal direction, or may be formed to have a constant height in the height direction to assist in fixing the module assembly 200. This can confirm the frame in the vertical direction in the support frame 300 of FIG.

The hooking part 320 is installed at each corner of the frame part 310. The hooking part 320 may be formed in a circular shape or a hook shape so that a connection line can be hooked so that the module assembly and the support frame can be lifted at once by a device such as a crane .

In addition, in Fig. 5, an example in which the cover part 600 is further configured to be flush with the paper surface on the module assembly can be identified.

The cover part 600 serves to support the vegetation structure 400 while preventing the soil and the like from leaking out. The cover part 600 is particularly useful for preventing soil or the like from falling through the through hole of the water permeable through hole 120 of the module body 100.

The cover part 600 is preferably made of a water permeable material such as a nonwoven fabric or a porous porous concrete molded article. It is preferable that the cover part 600 is manufactured in accordance with the standard of the module assembly 200.

The upper part of the cover part 600 corresponds to a ground surface such as a horizontal space. However, a method of simply covering the upper part of the cover part 600 with a water permeable packaging composition is also possible. However, in order to create an environmentally- It is also possible to do. Referring to the sectional view of FIG. 5, it can be seen that a vegetation space is provided above the module aggregate 200 and the cover unit 600.

The vegetation space can be installed using the vegetation structure 400 according to the present invention.

8 is a cross-sectional view of a facility structure in which a vegetation structure is installed as a modular rainwater infiltration and storage facility structure according to the present invention, and FIG. 9 is a sectional view of a vegetation structure part in a modular rainwater infiltration and storage facility structure according to the present invention. FIG.

Referring to FIGS. 8 and 9, the vegetation structure 400 is installed on the upper part of the facility structure. The vegetation structure 400 is provided with a settling tank 440, The rainwater purification function can be performed.

In addition, the facility structure may further include a boundary 500 extending in the longitudinal direction so as to be parallel to the upper or lower end of the upper surface of the vegetation structure 400. The boundary may be formed only in a portion where the settling tank 440 is installed The penetration part 510 is formed so that rainwater can be intensively applied to the lid part 443 through the penetration part.

As a result, in the case of the facility structure in which the vegetation structure is installed, the flow of the rainwater is shown in a stepwise manner: (1) the rainwater is concentrated to the cover part through the penetration part of the barrier, (2) is permeated and stored in the settling tank through the cover part, (3) The rainwater is again poured down through the upper protruding portion of the filter box only in the state where impurities and the like are removed by the box, the rainwater is pumped through the module aggregate, and the poured water is stored in the pore tube and moved. can do.

10 is a cross-sectional view of a boundary block 500 in which a penetrating portion is formed in a modular stormwater infiltration and storage structure according to the present invention. Referring to this, it can be seen that the rainwater is concentrated to the portion where the penetration portion is formed in the lateral space, the roadway, or the cargo through the sectional view of the bastion, and it is effective in the concentration management of the rainwater and the concentrated management of the impurities.

The boundary block may be divided into a boundary block 500 having a penetrating portion and a boundary block 500a having no penetrating portion, It is effective to install the rain gutters 500 so as to concentrate the rainwater toward the boundary 500 where the penetration portion is formed. Particularly, the boundary gutters 500 having the penetration portions are preferably provided on the back surface of the cover portion 443 of the vegetation structure.

11 is an embodiment of a facility structure in which a vegetation structure is installed as a modular rainwater infiltration and storage facility structure according to the present invention. Referring to this, it can be seen that a plurality of the vegetation structures are installed horizontally and horizontally in the horizontal space, and a modular rainwater infiltration and storage structure composed of a module is installed under the vegetation structure.

Particularly, the modular rainwater infiltration and storage structure according to the present invention focuses on ease of installation on the installation, but the function of the vegetation structure, that is, the gentle inclination depending on the step type or the precipitation tank, It can be expected that the effect of rainwater infiltration, storage, evapotranspiration and purification of the facility structure will be remarkably enhanced.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art. It is therefore intended that the appended claims cover such modifications and variations as fall within the true scope of the invention.

100: Module body 110: Body part
120: Pitcher tube study 200: Module assembly
300: support frame 310: frame part
320: hook part 400: vegetation structure
410: Flowerpot mold 420:
430: compartment space 440: settling tank
441: Settling box 442: Filter box
443: lid part 500:
600: cover part

Claims (7)

A porous body portion 110; And
A plurality of water permeable cylinder bases (120) penetrating upper and lower portions of the body portion;
(100) for rainwater infiltration and storage.
A flower bed frame 410 having an upper surface formed in a stepped shape;
A partitioning part 420 extending downward from a vertical surface of the upper step and vertically installed in the space inside the flower bed frame; And
A plurality of compartment spaces 430 separated from the inner space by the partition 420;
And the soil is fixed and supported by the partitioning part (420) when the soil is introduced into the compartment space (430).
3. The method of claim 2,
A sedimentation tank 440 installed in the lowest-stage compartment space of the compartment space;
(400). ≪ / RTI >
4. The method of claim 3,
The settling tank 440
A sedimentation box 441 installed to form a certain gap with the partitioning part 420, a permeable material filter box 442 inserted into the sedimentation box and installed to protrude above the sedimentation box at a predetermined height, And a cover portion 443 in the form of a grill covering an upper portion of the box,
Wherein the rainwater flows through the gap of the compartment space at the upper protruding portion of the filter box when the rainwater is pumped through the lid portion and stored up to the upper portion of the precipitation box.
As rainwater infiltration and storage facilities installed underground,
A module assembly (200) in which a plurality of modules of claim 1 are laminated horizontally or vertically; And
A support frame 300 having a frame 310 formed to have a predetermined standard according to the external appearance of the module assembly and having hooks 320 mounted on the corners thereof;
And,
A module configured to mount the module aggregate in the frame part, connect the string to the hook part of the receiver frame to lift the module aggregate together with the receiver frame, Rainwater infiltration and storage facility structure.
The method of claim 5,
The vegetation structure (400) of any one of claims 2 to 4, further comprising:
Wherein the vegetation structure (400) is installed on the module aggregate (200), and the upper surface of the vegetation structure (400) constitutes a part of the ground surface.
The method of claim 5,
A boundary stone 500 extending in the longitudinal direction so as to be parallel to the upper or lower end of the upper surface of the vegetation structure 400;
Further comprising:
The perimeter is formed with a penetrating portion (510) only in a portion where the vegetation structure (400) of the third or fourth aspect is installed, so that rainwater is intensively permeated to the cover portion (443) through the penetrating portion. Rainwater infiltration and storage structure.

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