KR101977695B1 - Penetration Gauges Structure - Google Patents

Abstract

The present invention relates to an infiltrating side gutter structure comprising: an infiltrating boundary channel to allow rainwater of a street to flow thereinto to transport the rainwater to a downstream side and infiltrate the rainwater underground; a street tree watering box to transport rainwater transported from an upstream side to a downstream side and infiltrate the rainwater underground to supply the rainwater to a street tree; and a boundary channel collecting well to drain rainwater transported from an upstream side to a rainwater pipe. The infiltrating boundary channel, the street tree watering box, and the boundary channel collecting well are connected to each other to be installed on the borderline of a street and a sidewalk to infiltrate rainwater on the street underground and drain the rainwater to the rainwater pipe. The infiltrating side gutter structure is standardized and manufactured, and is simply assembled and constructed at a site. Since concrete does not need to be poured at the site, the infiltrating side gutter structure and a road side gutter boundary stone can be simply constructed. Since rainwater can be infiltrated underground by the infiltrating boundary channel and the street tree watering box, water can be efficiently supplied to the street tree to restore an ecological environment of soil. A filter installed on the infiltrating boundary channel is conveniently inserted and withdrawn to simplify and facilitate maintenance and management.

Description

Penetration Gauges Structure [0002]

More particularly, the present invention relates to an infiltration countermeasure structure, which is installed on a boundary line between a motorway and a sidewalk in a city center, thereby eliminating the rainwater on the roadway directly along the road slope, And at the same time, the excessive rainwater is quickly drained to the gutter.

As the urbanization progresses recently, the impervious area where the earth surface is covered with asphalt or concrete is increasing rapidly. Particularly, in the case of urban roads packed with impervious surfaces, the rainwater flowing from the road runs down along the shoulder of the road, and the drainage system is drained through the house correction. In addition, rainwater is prevented from penetrating into the ground, resulting in the depletion of groundwater and consequent distortion of the water circulation system, while increasing the damages caused by inundation in the downtown area due to frequent rainfalls due to frequent climate changes. In addition, contaminants that are mixed with rainwater are discharged directly into rivers along with rainwater, thereby causing environmental pollution problems.

Various techniques for solving the above problems are disclosed. In the case of an underground infiltration facility that penetrates rainwater into a basement, which is one example, it is not inefficient because it does not coincide with the road structure, and it is not easy to secure the space and the construction is not easy. In addition, it does not properly implement the flow system of rainwater for the removal of contaminated materials, the penetration of rainwater and the efficient treatment of drainage.

As another example, in the case of the technology for removing pollutants contained in the rainwater, the removal of the pollutants contained in the initial rainwater is inefficient, and the maintenance of the installed pollutant removal device once is difficult.

Therefore, the rainwater generated from the road surface is eliminated more quickly from the road surface, the rainwater is dispersed by the operation of the reservoir and infiltration mechanism to reduce the load on the excellent road, thereby preventing flooding of the road and the city, It is required to develop a technique that can easily remove pollutants and can be easily maintained.

Patent 1: Korean Patent No. 10-1639379

In order to solve the above-mentioned problems, the present invention provides a rainwater collecting apparatus and a rainwater collecting method, which are capable of rapidly collecting rainwater on a road along a transverse slope through a penetrating waterfront structure composed of basic boundary water, infiltration boundary water, It prevents the flooding of the roads and the inner city by discharging the excess rainwater through the gut pipe quickly, and it is possible to prevent the flooding of the roads and the inner city, The present invention provides an infiltration surface structure capable of easily removing accumulated contaminants in the facility, thereby facilitating maintenance.

An infiltration boundary structure according to an example of the present invention is a infiltration boundary water inflowing rainwater of a roadway into a downward direction and infiltrating into the underground. A roadside watering box for transferring the rainwater conveyed from the upstream side to the downstream side and penetrating the underground water to supply rainwater to the roadside water; And a collecting means for collecting the rainwater conveyed from the upstream side by a boundary water which drains the rainwater to a gutter. The infiltration boundary number, the aeration line box, and the boundary water collecting line are connected to each other to be installed on the boundary line between the roadway and the sidewalk, It is possible to infiltrate the rainwater into the underground and drain the rainwater into the excellent pipe at the same time.

The basic boundary water channel is provided on the boundary line between the roadway and the sidewalk, and the infiltration boundary number is set to any one of the rowside watering box and the house waterway correction And the second electrode is connected to the second electrode.

In addition, the basic boundary number is a front wall installed on the front side of the barrier stones installed on the boundary line between the roadway and the sidewalk; A rear wall installed on the rear side of the barrier seat; A bottom wall connecting the front wall and the bottom of the rear wall; An intermediate wall disposed between the front wall and the rear wall and in contact with a rear surface of the barrier seat; An upper wall connecting the upper portion of the front wall and the lower portion of the middle wall, A drain port formed between the front wall, the bottom wall, the rear wall, and the top wall; A roadway inlet formed on the upper surface wall and connected to the drainage passage between the boundary stone and the front wall; And a sidewalk inlet connected to the drainage path between the intermediate wall and the rear wall.

In addition, the infiltration boundary water channel may include a front wall installed on a front side of the boundary stones installed on the boundary line between the roadway and the sidewalk; A rear wall installed on the rear side of the barrier seat; A bottom wall connecting the front wall and the bottom of the rear wall; An intermediate wall disposed between the front wall and the rear wall and in contact with a rear surface of the barrier seat; An upper wall connecting the upper portion of the front wall and the lower portion of the middle wall, A drain port formed between the front wall, the bottom wall, the rear wall, and the top wall; A roadway inlet formed on the upper surface wall and connected to the drainage passage between the boundary stone and the front wall; A sidewalk inlet connected to the drainage path between the intermediate wall and the rear wall; An underground penetrating port formed at an edge portion where the rear wall and the bottom wall meet, and penetrating the rainwater of the drainage path into the underground; A filter insert formed at a rear portion of the drainage passage and extending from an upper portion of the rear wall to the underwater penetration hole; And a filter inserted and installed in the filter insertion path.

Also, the rowside watering box includes a front wall installed on the front side of the barrier stones installed on the boundary line between the driveway and the sidewalk; An intermediate wall disposed rearwardly of the front wall and in contact with a rear surface of the boundary stone; An upper wall connecting the upper portion of the front wall and the lower portion of the middle wall, A pair of bottom walls connected to both lower ends of the front wall; A pair of rectangular boxes protruding rearward from both ends of the rear surface of the intermediate wall; A pair of drainage passages formed between the front wall, the pair of bottom wall walls, the top wall, and the pair of rectangular boxes; And a penetrating tube having through holes formed by connecting the pair of drainage paths.

Further, the rowside watering box may be characterized in that a foundation for supporting the boundary stone is formed instead of the front wall, the intermediate wall, and the upper wall between the pair of rectangular boxes.

In addition, the boundary waterway house correction includes a front wall installed on the front side of the boundary stones installed on the boundary line between the roadway and the sidewalk; A rear wall installed on the rear side of the barrier seat; A bottom wall connecting the front wall and the bottom of the rear wall; An intermediate wall disposed between the front wall and the rear wall and in contact with a rear surface of the barrier seat; An upper wall connecting the upper portion of the front wall and the lower portion of the middle wall, A pair of side walls connecting the upstream and downstream sides of the front wall, the bottom wall, the rear wall, the intermediate wall, and the top wall to form a drain hole; A second drain hole formed in the front wall; And a contaminant removing device formed in the space formed by the front wall, the bottom wall, the rear wall, the intermediate wall, the top wall and the pair of side walls, A pair of shielding plates installed between the rear wall and the rear wall, a screen net installed below the pair of shielding plates, and a water-permeable filter material installed on the screen net, Is led downward by the pair of blocking plates, and the rainwater guided downward passes through the screen net and the water permeable filter, passes through the upper side, and is drained through the second drain port.

The rainwater flowing into the rainwater inflow port on the upper side of the pollutant removing device drops onto the upper side of the water permeable filter medium to thereby remove the contaminant adhered on the lower side. So that drainage of rainwater can be smoothly performed.

In addition, the protruding and engaging portions are formed on one side of the upstream and downstream sides, the other side is formed with a groove coupling portion, and the lower surface of the protrusion coupling portion is formed as a downward sloped surface The lower surface of the groove-joining portion is formed as an upward sloping surface, and the downward sloping surface and the upward sloping surface are tightly coupled to each other to thereby facilitate coupling and separation.

In addition, a through hole is formed at the basic boundary number, the infiltration boundary number, the rowside watering box, and the boundary water collection tank, and is coupled with the fastening member using the through hole.

Through the present invention, various combinations of standardized boundary counts, infiltration boundary counts, athletic watering box, and boundary water collection are arranged in various combinations, whereby the rainfall intensity of the construction site, the slope and width of the road, It is possible not only to quickly and economically construct the penetrating sidewall structure that best suits the situation of the trees, but also to eliminate the rainwater exclusion efficiency of the road by continuously eliminating the road surface generated from the road along the road termination.

In addition, it is possible to use the road space more efficiently than the L-type sidewall drainage system by minimizing the excavation of the roadway and thus, it is easy to construct.

In addition, the infiltration boundary water can penetrate rainwater into the underground by means of the roadside watering box, etc., thereby securing the groundwater, smoothly supplying water to the roadside water, and minimizing the leakage of rainwater, thereby improving the ecological environment and preventing flooding.

In addition, pollution of rivers and the like can be prevented by preventing pollutants from underground penetration or discharging to a gutter by a filter, a pollutant removing device, and the like.

In addition, maintenance is facilitated by easy replacement of the filter and cleaning of the waterway through the walkway inlet.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a plan view showing an arrangement of a penetrating sidewall structure according to an example of the present invention. Fig.
2A is a plan view showing another arrangement of an infusion porting structure according to an example of the present invention.
2B to 2E are cross-sectional views of AA, BB, CC and EE portions in FIGS. 1 and 2A.
FIG. 3A is a plan view showing yet another arrangement of the penetrating sidewall structure according to an example of the present invention. FIG.
3B to 3G are cross-sectional views of the AA, BB, CC, DD, EE and FF portions in FIG. 3A.
Fig. 4A is a perspective view showing a basic boundary water path of the penetrating sidewall structure according to an example of the present invention. Fig.
4B to 4J are cross-sectional views of a plan view, a front view, a rear view, a left side view, AA, BB, CC and DD parts of FIG.
5A is a perspective view showing an infiltration boundary channel of a penetrating sidewall structure according to an example of the present invention.
5B to 5J are cross-sectional views of a plan view, a front view, a rear view, a left side view, AA, BB, CC and DD portions of FIG. 5A.
FIG. 6A is a perspective view showing a state in which a rowside watering box having an infiltration pointing structure according to an embodiment of the present invention is integrally formed. FIG.
6B to 6I are a plan view, a front view, a rear view, a left side view, and sectional views of AA, BB, and CC portions, respectively, of FIG. 6A.
FIG. 7A is a perspective view showing a left connection type in a case where a rowside watering box of an infiltration pointing structure according to an example of the present invention is manufactured as a separate type. FIG.
Figs. 7B to 7H are a plan view, a front view, a rear view, a left side view, a right side view, AA, and a BB sectional view of Fig.
FIG. 8 is a perspective view showing a state of a right connection type in a case where a rowside watering box of an infiltration pointing structure according to an example of the present invention is manufactured as a separate type.
FIG. 9A is an exploded perspective view of the dust collecting apparatus according to an embodiment of the present invention. FIG.
Figs. 9B to 9I are a perspective view, a plan view, a front view, a rear view, a left side view, a right side view, AA and CC partial sectional views of the upper body of Fig.
Figs. 9J to 9O are a perspective view, a plan view, a front view, a left side view, AA, and a BB sectional view of the lower body of Fig.

Hereinafter, some embodiments of the present invention will be described in detail with reference to exemplary drawings. In the drawings, like reference numerals are used to refer to like elements throughout the drawings, even if they are shown in different drawings. In the following description of the embodiments of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the difference that the embodiments of the present invention are not conclusive.

In describing the components of the embodiment of the present invention, terms such as first, second, A, B, (a), and (b) may be used. These terms are intended to distinguish the constituent elements from other constituent elements, and the terms do not limit the nature, order or order of the constituent elements. When a component is described as being "connected", "coupled", or "connected" to another component, the component may be directly connected or connected to the other component, May be " connected ", " coupled " or " connected ".

Hereinafter, the penetrating sidewall structure according to one example of the present invention will be described in detail with reference to Figs. 1 to 9. Fig.

The present embodiment is an infiltration boundary waterway (20) for inflowing rainwater of the roadway (1) and transferring it to the downstream side and penetrating into the underground; A rowside watering box 30 for transferring the rainwater conveyed from the upstream side to the downstream side and penetrating into the underground to supply rainwater to the roadside water; And a water collecting compartment 40 as a boundary water for draining the rainwater conveyed from the upstream side to the gutter. The infiltration boundary waterway 20, the row watering box 30 and the boundary water collecting compartment 40 are connected to each other And is installed on the boundary line between the roadway 1 and the sidewalk 3, it is possible to infiltrate the rainwater on the roadway 1 into the underground and draining it to the excellent roadway at the same time.

The penetrating sidewall structure according to an example of the present invention is installed on the boundary line between the roadway 1 and the sidewalk 3 so as to penetrate the rainwater falling on the roadway 1 into the underground and to be supplied to the trees or infiltrated into the groundwater, Can be drained quickly through the gutter.

The penetrating sidewall structure of the present embodiment may include the penetration boundary waterway 20. The infiltration boundary water passage 20 can infiltrate into the underground after entering the rainwater in the roadway 1 and can transfer the rainwater to the downstream side. The infiltration boundary waterway 20 can be connected to other infiltration boundary counts 20, a basic boundary count 10 to be described later, a tree watering box 30, a boundary water collection collection 40, and the like.

In addition, the penetrating sidewall structure of the present embodiment may include a rowside watering box 30. The rowside watering box 30 can be connected to the basic boundary waterway 10, the infiltration boundary waterway 20, the boundary water collecting waterway 40, and the like. The rowside watering box 30 transfers the rainwater conveyed from the upstream side to the downstream side and penetrates into the underground, so that water can be supplied to the aquatic trees and the like.

In addition, the penetrating sidewall structure of the present embodiment can include a collection water collection unit 40 as a boundary water. The boundary waterway collection fixture 40 may be connected to the basic boundary waterway 10, the infiltration boundary waterway 20, the rowdy watering box 30, and the like. The boundary waterway collecting unit 40 can drain the rainwater transferred from the upstream side through the gutter or infiltrate into the underground. The boundary water channel collectors 40 can be separated and assembled into an upper body and a lower body.

Further, the penetrating sidewall structure of the present embodiment may further include a basic boundary waterway 10. The basic boundary waterway 10 can be connected to other basic boundary waterway 10, infiltration boundary waterway 20, tree watering can water box 30, boundary water collection tank 40, and the like. The basic boundary waterway 10 can transfer the rainwater falling on the roadway 1 to the downstream side.

The penetrating sidewall structure of the present embodiment can be arranged in various combinations of the basic boundary waterway 10, the infiltration boundary waterway 20, the rowside watering can 30, the boundary water collecting water collecting 40, and the like.

FIG. 1A shows a basic boundary waterway 10, an infiltration boundary waterway 20, and a rowside watering box 30 in this order. In this case, the rainwater on the roadway 1 flowing into the basic boundary waterway 10 and the infiltration boundary waterway 20 is infiltrated into the basement through the infiltration boundary waterway 20 and the surplus water is infiltrated into the underground waterway box 30, The water is supplied to ground water or supplied to the surrounding trees, and the remainder can be drained through a brine connected to the rowside watering box 30.

In Fig. 2A, a basic boundary waterway 10 is disposed on both sides of the permeation boundary waterway 20, and a rowside watering box 30 is disposed on the side of the basic boundary waterway 10. Also in this case, the rainwater on the roadway 1 flowing into the basic boundary waterway 10 and the permeation boundary waterway 20 is infiltrated into the basement through the permeation boundary waterway 20, and surplus water is permeated into the underground waterway box 30 ) To be poured into the ground and supplied to the groundwater or to the surrounding trees, and the rest can be drained through the gutter.

FIG. 3A shows an example in which the collector 40 is arranged between the basic boundary waterway 10 and the penetration boundary waterway 20 in the arrangement of FIG. 2A. That is, the rainwater on the roadway 1 flowing into the basic boundary waterway 10 and the infiltration boundary waterway 20 is infiltrated into the basement through the infiltration boundary waterway 20 and the surplus water is introduced into the underground waterway box 30 It can be poured into the ground and supplied to groundwater or supplied to the surrounding trees. Excessive rainwater after infiltration through the infiltration boundary waterway 20 and the irrigation watering box 30 can be drained to the stormwater through the storm waterpipe box 30 and the storm water pipe connected to the storm water purification unit 40 as a boundary water.

That is, in addition to the examples shown in FIGS. 1A, 2A, and 3A, various combinations of the basic boundary waterway 10, the infiltration boundary waterway 20, the rowwater watering box 30, It is possible to apply the characteristics such as the rainfall intensity of the construction site, the inclination and the width of the road, the infiltration ability of the ground, and the condition of the trees.

Since the construction of the penetrating sidewall structure of the present embodiment occupies only a small part of the roadway 1, excessive control of the roadway 1 is not required. In other words, after a small part of the roadway 1 and a part of the sidewalk 3 are excavated, the penetrating sidewall structure of the present embodiment is installed and assembled and the surrounding excavation part is closed to complete the construction work. Therefore, the present embodiment can perform the construction work very quickly and conveniently.

Hereinafter, with reference to Figs. 1 to 9, and particularly to Figs. 4 to 9, the respective constituent elements constituting the penetrating sidewall structure according to an example of the present invention will be described in detail.

Referring to FIG. 4, the basic boundary waterway 10 can be provided with a front wall 11 on the front side of the boundary stones 5 provided on the boundary line between the roadway 1 and the sidewalk 3. A rear wall (12) may be provided on the rear side of the boundary stones (5). A bottom wall 13 is provided under the front wall 11 and the rear wall 12 to connect the front wall 11 and the rear wall 12. [ An intermediate wall 14 may be provided between the front wall 11 and the rear wall 12. The intermediate wall 14 may be provided so as to be in contact with the rear surface of the barrier block 5. A top wall 15 is provided at the top of the front wall 11 and at the bottom of the middle wall 14 to connect the front wall 11 and the intermediate wall 14. The upper surface wall 15 may be provided with an installation groove on which the barrier seat 5 is placed. A recess is formed in the seat groove and a recessed portion is formed in the lower side of the seat seat 5 so as to insert a projection, so that the seat seat 5 can be stably installed. A drainage passage 16 may be formed between the front wall 11, the bottom wall 13, the rear wall 12 and the top wall 15. The rainwater can be flowed to the downstream side through the drainage passage 16. The upper wall 15 is formed with a passage inlet 111 and may be connected to the drainage passage 16 through the boundary wall 5 and the front wall 11. The roadway inlet port 111 can introduce the rainwater on the roadway 1 into the drainage passage 16. A press-in inlet 151 is formed between the intermediate wall 14 and the rear wall 12 so as to be connected to the drainage passage 16. A steel grating or a reinforced concrete cover may be installed at the press-in inlet 151. [ The press-in inlet 151 allows the rainwater on the side of the sidewalk 3 to flow into the drainage passage 16. It is possible to easily clean the drainage passage 16 by removing the steel grating or the reinforced concrete cover.

5, the infiltration boundary waterway 20 can be provided with the front wall 21 on the front side of the boundary stones 5 provided on the boundary line between the roadway 1 and the sidewalk 3. A rear wall (22) may be provided on the rear side of the boundary stones (5). A bottom wall 23 is provided under the front wall 21 and the rear wall 22 to connect the front wall 21 and the rear wall 22. [ An intermediate wall 24 may be provided between the front wall 21 and the rear wall 22 and an intermediate wall 24 may be provided to abut the rear surface of the boundary stone 5. A top wall 25 is provided at the top of the front wall 21 and at the bottom of the middle wall 24 to connect the front wall 21 and the intermediate wall 24. The upper surface wall 25 may be provided with an installation groove on which the barrier 5 is placed. A recess is formed in the seat groove and a recessed portion is formed in the lower side of the seat seat 5 so as to insert a projection, so that the seat seat 5 can be stably installed. A drainage passage 26 may be formed between the front wall 21, the bottom wall 23, the rear wall 22, and the top wall 25. The rainwater can be flowed to the downstream side through the drainage passage (26). The upper wall 25 is formed with a passage inlet 211 and can be connected to the drainage passage 26 between the boundary stone 5 and the front wall 21. Between the intermediate wall 24 and the rear wall 22, a press-in inlet 251 may be formed and connected to the drain passage 26. A steel grating or a reinforced concrete cover may be installed at the press-in inlet 251. The press inflow opening 251 allows the rainwater on the side of the sidewalk 3 to flow into the drainage passage 26. The drainage duct 26 can be easily cleaned by removing the steel grating or the reinforced concrete cover. An underground penetration hole 222 may be formed at a corner where the rear wall 22 meets the bottom wall 23. The underground penetration port 222 can penetrate the rainwater of the drainage passage 26 into the underground.

A filter insertion path 223 may be formed at the rear of the drainage passage 26. The filter insertion path 223 may be formed from the upper part of the rear wall 22 to the underground penetrating port 222. The filter inserting passage 223 is provided with a filter 225 inserted therein so as to be cleaned or replaced, and maintenance is very convenient. Further, the filter 225 may further include a U-shaped filter fixture on the front portion thereof. That is, the filter fixture can be stably fixed to the rear wall 22 after the filter 225 is inserted.

That is, the infiltration boundary waterway 20 can be connected to the other infiltration boundary waterway 20, the basic boundary waterway 10, the aqua regime watering box 30 and the boundary water collecting water well 40, At the same time, foreign matter adhering to the rainwater infiltrating into the underground can be filtered by the filter 225.

The integrated canal watering box will be described with reference to Fig. The integrated canal watering can box can be provided with the front wall 31 on the front side of the boundary stones 5 installed on the boundary line between the roadway 1 and the sidewalk 3. At the rear of the front wall 31, an intermediate wall 34 may be provided so as to contact the rear surface of the barrier stones 5. A top wall 35 is formed at the top of the front wall 31 and at the bottom of the intermediate wall 34 to connect the front wall 31 and the intermediate wall 34. In the upper surface wall 35, an installation groove in which the barrier block 5 is placed may be formed. A recess is formed in the seat groove and a recessed portion is formed in the lower side of the seat seat 5 so as to insert a projection, so that the seat seat 5 can be stably installed. A pair of bottom wall 33 may be connected to the bottom of both ends of the front wall 31. A pair of rectangular boxes 37 may be provided at both ends of the rear surface of the intermediate wall 34 so as to protrude toward the rear side. A pair of drainage paths 36 may be formed between the front wall 31, the pair of bottom wall 33, the top wall 35 and the pair of rectangular boxes 37. The pair of drainage passages 36 may be interconnected by a penetration pipe 38 having through-holes. In other words, the pair of drainage passages 36 at both ends and the penetration pipe 38 connected therebetween can drain the downwardly descending rainwater. At the same time, the infiltration pipe 38 can supply rainwater to the underground through the through-hole to supply rainwater such as a roadside tree located between the pair of rectangular boxes 37. Further, the pair of drains can be connected to a pair of rectangular boxes 37 to supply the rainwater to the rectangular box 37. The lower part of the rowside watering box 30 may be opened or a through hole may be formed. Rainwater can penetrate underground through this opening or through hole. Therefore, the rowside watering box 30 drains to the downstream side of the rainwater, and at the same time, the rainwater can be smoothly supplied to the side water and the underground. In addition, the upper part of the rowside watering box 30 is opened and a steel grating, a reinforced concrete cover, or the like may be installed on the opened surface. In addition, the front wall 31 on the front side of the rowside watering box 30 may be provided with a through hole for connecting a gutter. The through-hole may be formed so as to be partially clogged, and then connected to the bare tube after destruction according to the site conditions (see FIGS. 7A and 7H).

That is, the rowside watering box 30 is connected to the basic boundary waterway 10, the infiltration boundary waterway 20, the boundary water collecting column 40 and the like so that the rainwater conveyed from the upstream side can be flowed to the downstream side At the same time, by infiltrating underground, it is possible to smoothly supply water to roadside trees and soils, thereby helping to restore the ecological environment around the roads.

Referring to Figs. 7 and 8, the separate rowage irrigation water box will be described. The separable rowing irrigation can be omitted in the front wall 31, the intermediate wall 34 and the top wall 35 between the pair of rectangular boxes 37. [ However, the infiltration pipe 38 can connect a pair of rectangular boxes 37. In the case of a separate tree-lined irrigation canal box, bases for supporting the boundary stones 5 may be formed separately and the boundary stones 5 may be provided on the foundation.

9, the front wall 41 may be installed on the boundary line between the roadway 1 and the sidewalk 3, A rear wall 42 may be provided on the rear side of the barrier block 5. A bottom wall 43 is provided under the front wall 41 and the rear wall 42 to connect the front wall 41 and the rear wall 42. An intermediate wall 44 may be provided between the front wall 41 and the rear wall 42 and an intermediate wall 44 may be provided adjacent to the rear surface of the barrier 5. A top wall 45 may be provided at an upper portion of the front wall 41 and a lower portion of the intermediate wall 44 to connect the front wall 41 and the intermediate wall 44. The upper surface wall 45 may be provided with an installation groove in which the boundary stones 5 are placed. A recess is formed in the seat groove and a recessed portion is formed in the lower side of the seat seat 5 so as to insert a projection, so that the seat seat 5 can be stably installed. A pair of side walls connecting the upstream and downstream sides of the front wall 41, the bottom wall 43, the rear wall 42, the intermediate wall 44, and the top wall 45 may be provided. The side wall may be formed with a drain port connected to the adjacent drainage passage. The front wall 41 may be provided with a second drain port 413 for draining the rainwater introduced into the boundary water collecting compartment 40 into the drain pipe 41. That is, the second drain hole 413 can be connected to a gutter.

A pollutant removing device 49 may be formed in the inner space of the boundary water channel collection tank 40. The pollutant removing device 49 is provided with a pair of blocking plates 491 between the front wall 41 and the rear wall 42 on both sides of the second drain port 413 and a pair of blocking plates 491, A screen net 492 may be provided under the screen net 492 and a water permeable filter agent 493 may be provided on the screen net 492. Accordingly, the rainwater introduced through the drain holes on both sides of the boundary water collecting compartment 40 is guided downward by the pair of the blocking plates 491, and the rainwater guided downward is guided through the screen mesh 492 and the permeable filter agent 493 and then drained to the gutter through the second drain port 413. [ The boundary water channel collection tank 40 can be prevented from flooding even when it is raining by draining the rainwater infiltrated by the infiltration boundary water passage 20 and the tree watering box 30 and inflowing the remaining rainwater. In addition, the pollutant removing device 49 can filter pollutants contained in rainwater and prevent the pollutants from being discharged into streams and the like. Further, the contaminant removing device 49 can guide the flow of the rainwater from the lower side to the upper side, thereby preventing clogging by the contaminants.

A drainage inlet 411 may be formed on the upper surface of the contaminant removal device 49. The rainwater on the road surface 1 flows through the inlet port 411 and falls to the upper side of the water permeable filter agent 493 to remove the contaminants adhering to the lower side of the screen net 492 and the water permeable filter agent 493 The drainage of the rainwater can be smoothly performed. That is, when the rain is lowered, the difference between the boundaries of the collection water collection wells 40 before entering the collection water collection well 40 through the basic boundary waterway 10, the infiltration boundary waterway 20, The rainwater falling through the inlet 411 is introduced into the drainage port of the side wall of the collection collector 40 at a later boundary by previously dropping contaminants adhering to the lower side of the screen net 492 and the water permeable filter agent 493 The drainage of rainwater can be facilitated.

The boundary water channel collectors 40 may be separated into upper and lower sections and then joined together. The lower front wall 41 and the rear wall 42 can be formed with hooks. By providing the blocking plate 491, the screen net 492, and the water-permeable filter agent 493 on the latching jaw, the construction can be very convenient.

The protruding engaging portion is formed on one side of the upper and lower sides of the basic boundary number 10, the penetration boundary water passage 20, the side watering can box 30 and the boundary water channel collecting core 40 of the penetrating sidewall structure, An additional portion may be formed. The protruding engagement portion of one side is fitted to and coupled to the recessed engagement portion formed on the other side of another adjacent structure so that the horizontal state can be maintained well even in the case of subsidence of the ground.

In addition, the lower surface of the protruding engaging portion may be formed as a downward inclined surface, and the lower surface of the recessed portion may be formed as an upward inclined surface. Therefore, when the downwardly inclined surface is mounted on the upwardly inclined surface, it slides and is tightly engaged with the upper surface, so that the connection is easy and the separation can be prevented.

In addition, through holes may be formed in the basic boundary waterway 10, the infiltration boundary waterway 20, the aqua regime water box 30, and the boundary water collecting pool 40. It is possible to connect the fastening members, that is, the bolts, the nuts, or the anchors, using the through holes.

In addition, a through hole is formed at one side of the basic boundary waterway 10, the infiltration boundary waterway 20, the aqua regime water box 30, and the boundary water collecting cores 40, The nut is embedded at the corresponding position and fastened with the bolt to be coupled.

As a result, the present invention combines various combinations of the basic boundary waterway 10, the infiltration boundary waterway 20, the irrigation watering box 30, and the boundary waterway collecting 40, (20), the rainwater can be infiltrated into the underground by means of the infiltration boundary water channel (20), the rain water canal box (30), and the like. It is able to smoothly drain the rainwater on the road and to penetrate the underground water smoothly, and it is possible to smoothly drain the rainwater on the road along with securing groundwater, It is possible to prevent flooding, and the filter 225 can be periodically cleaned or replaced, and the drain can be cleaned, thereby providing an easy-to-maintain penetration measuring structure.

While the present invention has been described in connection with what is presently considered to be the most practical and preferred embodiment, it is to be understood that the invention is not limited to the disclosed embodiments. That is, within the scope of the present invention, all the constituent elements may be constituted or operated selectively in combination with one or more. Furthermore, the terms "comprises", "comprising", or "having" described above mean that a component can be implanted unless otherwise specifically stated, But should be construed as including other elements. All terms, including technical and scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs, unless otherwise defined. Commonly used terms, such as predefined terms, should be interpreted to be consistent with the contextual meanings of the related art, and are not to be construed as ideal or overly formal, unless expressly defined to the contrary.

The foregoing description is merely illustrative of the technical idea of the present invention, and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are intended to illustrate rather than limit the scope of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents should be construed as falling within the scope of the present invention.

1: driveway
3: Press
5: Boundary stones
10: By default number of borders
11: Front wall
111: Roadway entrance
12: rear wall
13: Lower wall
14: Middle wall
15: Upper wall
151: Sidewalk inlet
16: drainage
20: Infiltration boundary number
21: Front wall
211: driveway inlet
22: rear wall
222: Underground penetration zone
223: With filter insert
225: Filter
23: Lower wall
24: Middle wall
25: Upper wall
251: Sidewalk inlet
26: drainage
30: Street tree watering box
31: Front wall
33: Lower wall
34: Middle wall
35: Upper wall
36: drainage
37: square box
38: Penetration tube
40: Modify House with Boundary Water
41: Front wall
411: Roadway entrance
413: Second drainage
42: rear wall
43: Lower wall
44: Middle wall
45: Upper wall
48: side wall
49: Contaminant removal device
491:
492: screen net
493: Pitch filter filter agent

Claims (10)

Infiltration boundary water which inflows the rainwater of the roadway to the downstream side and simultaneously penetrates into the underground;
A roadside watering box for transferring the rainwater conveyed from the upstream side to the downstream side and penetrating the underground water to supply rainwater to the roadside water; And
And collecting the rain water transferred from the upstream side into a boundary water for draining the rainwater to the excellent pipe,
The infiltration boundary number is connected to each other and is installed on the boundary line between the roadway and the sidewalk, thereby penetrating the rainwater on the roadway into the underground,
And further includes a basic boundary water channel through which the rainwater of the roadway is introduced and transported,
Wherein the basic boundary number is provided on a boundary line between the roadway and the sidewalk, and is connected to any one of the infiltration boundary number, the rowside watering box,
As the basic boundary number,
A front wall installed on the front side of the barrier seats installed on the boundary line between the driveway and the sidewalk;
A rear wall installed on the rear side of the barrier seat;
A bottom wall connecting the front wall and the bottom of the rear wall;
An intermediate wall disposed between the front wall and the rear wall and in contact with a rear surface of the barrier seat;
An upper wall connecting the upper portion of the front wall and the lower portion of the middle wall,
A drain port formed between the front wall, the bottom wall, the rear wall, and the top wall;
A roadway inlet formed on the upper surface wall and connected to the drainage passage between the boundary stone and the front wall; And
And a sidewalk inlet connected to the drainage path between the intermediate wall and the rear wall.
delete delete Infiltration boundary water which inflows the rainwater of the roadway to the downstream side and simultaneously penetrates into the underground;
A roadside watering box for transferring the rainwater conveyed from the upstream side to the downstream side and penetrating the underground water to supply rainwater to the roadside water; And
And collecting the rain water transferred from the upstream side into a boundary water for draining the rainwater to the excellent pipe,
The infiltration boundary number is connected to each other and is installed on the boundary line between the roadway and the sidewalk, thereby penetrating the rainwater on the roadway into the underground,
As the penetration boundary water channel,
A front wall installed on the front side of the barrier seats installed on the boundary line between the driveway and the sidewalk;
A rear wall installed on the rear side of the barrier seat;
A bottom wall connecting the front wall and the bottom of the rear wall;
An intermediate wall disposed between the front wall and the rear wall and in contact with a rear surface of the barrier seat;
An upper wall connecting the upper portion of the front wall and the lower portion of the middle wall,
A drain port formed between the front wall, the bottom wall, the rear wall, and the top wall;
A roadway inlet formed on the upper surface wall and connected to the drainage passage between the boundary stone and the front wall;
A sidewalk inlet connected to the drainage path between the intermediate wall and the rear wall;
An underground penetrating port formed at an edge portion where the rear wall and the bottom wall meet, and penetrating the rainwater of the drainage path into the underground;
A filter insert formed at a rear portion of the drainage passage and extending from an upper portion of the rear wall to the underwater penetration hole;
And a filter inserted and installed in the filter insertion path.
Infiltration boundary water which inflows the rainwater of the roadway to the downstream side and simultaneously penetrates into the underground;
A roadside watering box for transferring the rainwater conveyed from the upstream side to the downstream side and penetrating the underground water to supply rainwater to the roadside water; And
And collecting the rain water transferred from the upstream side into a boundary water for draining the rainwater to the excellent pipe,
The infiltration boundary number is connected to each other and is installed on the boundary line between the roadway and the sidewalk, thereby penetrating the rainwater on the roadway into the underground,
The rowside watering box comprises:
A front wall installed on the front side of the barrier seats installed on the boundary line between the driveway and the sidewalk;
An intermediate wall disposed rearwardly of the front wall and in contact with a rear surface of the boundary stone;
An upper wall connecting the upper portion of the front wall and the lower portion of the middle wall,
A pair of bottom walls connected to both lower ends of the front wall;
A pair of rectangular boxes protruding rearward from both ends of the rear surface of the intermediate wall;
A pair of drainage passages formed between the front wall, the pair of bottom wall walls, the top wall, and the pair of rectangular boxes;
And a penetration tube having through holes formed by connecting the pair of drainage paths.
The method of claim 5,
The rowside watering box comprises:
Wherein a base for supporting the boundary stone is formed instead of the front wall, the intermediate wall and the upper wall between the pair of rectangular boxes.
Infiltration boundary water which inflows the rainwater of the roadway to the downstream side and simultaneously penetrates into the underground;
A roadside watering box for transferring the rainwater conveyed from the upstream side to the downstream side and penetrating the underground water to supply rainwater to the roadside water; And
And collecting the rain water transferred from the upstream side into a boundary water for draining the rainwater to the excellent pipe,
The infiltration boundary number is connected to each other and is installed on the boundary line between the roadway and the sidewalk, thereby penetrating the rainwater on the roadway into the underground,
The boundary correction to the boundary number may include:
A front wall installed on the front side of the barrier seats installed on the boundary line between the driveway and the sidewalk;
A rear wall installed on the rear side of the barrier seat;
A bottom wall connecting the front wall and the bottom of the rear wall;
An intermediate wall disposed between the front wall and the rear wall and in contact with a rear surface of the barrier seat;
An upper wall connecting the upper portion of the front wall and the lower portion of the middle wall,
A pair of side walls connecting the upstream and downstream sides of the front wall, the bottom wall, the rear wall, the intermediate wall, and the top wall to form a drain hole;
A second drain hole formed in the front wall;
And a pollutant removing device formed in the space formed by the front wall, bottom wall, rear wall, middle wall, top wall and pair of side walls,
The pollutant removing device comprises:
A pair of barrier plates installed between the front wall and the rear wall on both sides of the second drain hole, a screen net provided below the pair of barrier plates, and a water permeable filter material installed on the top of the screen net ,
The rainwater introduced through the drain hole is guided downward by the pair of blocking plates and the rainwater guided downward passes through the screen net and the water permeable filter medium to be discharged upward through the second drain hole Features an infiltration gauge structure.
The method of claim 7,
Further comprising a flow inlet formed on the top wall of the apparatus for removing contaminants,
Wherein the rainwater flowing in through the rainwater inflow port on the upper side of the pollutant removing device drops onto the upper side of the water permeable filter medium to thereby remove pollutants adhering to the lower side to smooth drainage of the rainwater.
The method according to claim 1,
The protruding engaging portion is formed on one side of the upstream and downstream sides and the protruding engaging portion is formed on the other side of the upstream and downstream sides of the corrugated box,
Wherein the lower surface of the projecting engagement portion is formed as a downward sloping surface and the lower surface of the recessed engagement portion is formed as an upward sloping surface so that the downward sloping surface and the upward sloping surface closely contact each other, rescue.
The method according to claim 1,
Through holes are formed at the basic boundary number, the number of penetration borders, the row of watering box and the number of boundaries,
Wherein the through-holes are mutually coupled with the fastening members using the through-holes.

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