KR102529317B1 - Rainwater storage supply system for tree growth and construction method thereof - Google Patents

Abstract

The present invention relates to a rainwater storage and IoT fusion non-point pollution removal water supply system for tree growth and a construction method thereof.
Rainwater retention and IoT fusion non-point pollution removal type water supply system for tree growth of the present invention is spaced apart from the tree at a predetermined interval, buried in all directions of the tree to collect rainwater, and a house having a plurality of first through holes formed on the outer surface. fisherman; A three-way elbow storage that is connected to the lower part of the collecting part, receives the rainwater collected in the collecting part, has a plurality of second through-holes formed on the outer surface, and has three openings communicating with each other and orthogonal to each other; Both ends are connected to the three-way elbow tubes spaced apart from each other to connect the three-way elbow tubes, receive the rainwater from the three-way elbow tubes, and have a plurality of third through-holes formed at the top, provided to be flexible corrugated tube; A wick inserted into the first through hole, the second through hole, and the third through hole, respectively, wherein the three-way elbow storage tube and the corrugated pipe store the rainwater, and the wick stores rainwater inside the water collecting unit or the three-way water collecting part. It is characterized in that the rainwater inside the elbow pipe or the rainwater inside the corrugated pipe is transferred to the soil on the tree side.

Description

Rainwater storage and IoT fusion non-point pollution removal water supply system for tree growth and its construction method {Rainwater storage supply system for tree growth and construction method thereof}

The present invention allows rainwater to flow in, retains the inflowed rainwater, transfers the rainwater to the soil on the tree side to prevent the tree from drying out, and promotes the generation of fine roots by supplying oxygen by securing air permeability to the roots of the tree. It relates to a rainwater storage and IoT convergence non-point pollution removal water supply system and its construction method for tree growth that can reduce the cost of tree management by recycling rainwater.

Street trees (trees) are planted between the road and the sidewalk or at the edge of the sidewalk.

Roadside trees (trees) delight people by giving them a beautiful taste, cool them down by providing shade in hot summer, and function to reduce noise and reduce air pollutants and fine dust on roads with many cars.

However, all ground in the city is paved with asphalt, sidewalk blocks, concrete, etc., and rainwater infiltration and ventilation are not secured. The water supply to these street trees (trees) is mainly dependent on the water cannon.

However, it is difficult to supply a sufficient amount of water consistently in the water supply using a water sprinkler, and maintenance costs are high.

In particular, due to the lack of water during the dry season, there was a problem that trees withered due to lack of water.

In order to solve this problem, there is a conventional water supply system for tree growth, entitled "Street water supply and feeding and ventilation device" (hereinafter referred to as the prior art) of Korean Patent Registration No. 10-1437121.

However, in the case of this prior art, there was a problem in that sufficient water could not be supplied to the tree because water could only be delivered to a part of the side of the tree.

In addition, when a plurality of water supply devices are installed in order to supply sufficient water to the tree, there is a problem in that a lot of cost is consumed and a space for installing the plurality of water supply devices around the tree must be secured.

On the other hand, in urban areas, most of the ground surface is covered with asphalt or concrete, making it difficult for rainwater to penetrate the foundation.

Therefore, when the amount of rainwater exceeds the design value of rainwater pipes or sewage pipes due to heavy rain or localized heavy rain, backflow and surface subsidence of rainwater occur. There were problems that arose.

The present invention was invented to solve the above problems, and an object of the present invention is to temporarily store rainwater to prevent damage caused by heavy rain and torrential rain, and to absorb rainwater in the dry season and slowly into the soil on the tree side. It relates to rainwater retention and IoT fusion non-point pollution removal water supply systems and their construction methods for the growth of trees that can be supplied.

Another object of the present invention relates to a rainwater storage and water supply system for tree growth capable of supplying sufficient water to trees by supplying water to the entire periphery of the tree by connecting each catchment part in the ground and a method of constructing the same.

In order to achieve the above object, the rainwater storage and IoT convergence non-point pollution removal type water supply system for tree growth of the present invention is spaced apart from the tree at a predetermined interval and buried on all sides of the tree to collect rainwater, and a plurality of a water collecting unit having a first through hole; A three-way elbow storage that is connected to the lower part of the collecting part, receives the rainwater collected in the collecting part, has a plurality of second through-holes formed on the outer surface, and has three openings communicating with each other and orthogonal to each other; Both ends are connected to the three-way elbow tubes spaced apart from each other to connect the three-way elbow tubes, receive the rainwater from the three-way elbow tubes, and have a plurality of third through-holes formed at the top, provided to be flexible corrugated tube; A wick inserted into the first through hole, the second through hole, and the third through hole, respectively, wherein the three-way elbow storage tube and the corrugated pipe store the rainwater, and the wick stores rainwater inside the water collecting unit or the three-way water collecting part. It is characterized in that the rainwater inside the elbow pipe or the rainwater inside the corrugated pipe is transferred to the soil on the tree side.

The water collecting part is fixed to the upper part of the three-way elbow storage pipe and has a plurality of first through holes formed on the outer surface, a collecting pipe inserted into the collecting pipe, and a lower part inserted into the upper part of the collecting pipe, and the upper and lower parts It is opened and has a grating through which rainwater flows in, and includes a water collecting cover that is gradually narrowed toward the bottom in a tapered shape, and the filter is to filter out foreign substances contained in rainwater flowing in through the water collecting cover. to be characterized

The water collector is buried in the ground, the upper end is exposed to the ground, a plurality of first through-holes are formed on the outer surface, and the upper and lower surfaces are opened and inserted into the hollow first penetration tube and the hollow inside the first penetration tube, It is formed to be relatively higher than the upper end of the first infiltration tube and includes a hollow first collection tube having an upper and lower surface opened, and the lower end of the first infiltration tube is connected to the upper part of the three-way elbow storage tube, The first water collection pipe communicates with the three-way elbow pipe, the inner wall of the first water collection pipe and the outer wall of the first water collection pipe are spaced apart by a predetermined distance, and flows in between the inner wall of the first water collection pipe and the outer wall of the first water collecting pipe. The rainwater that falls into the surrounding soil penetrates into the surrounding soil through the first through hole, and the rainwater flowing into the first collection pipe is discharged into the three-way elbow storage pipe, and the cross section of the first collection pipe is at the lower end of the first infiltration pipe. A hooking end formed to correspond to is formed, and the lower end of the first collecting pipe is seated on the hanging end, so that rainwater flowing between the inner wall of the first infiltration pipe and the outer wall of the first collecting pipe and the first collecting pipe are seated. The rainwater flowing into the inside is configured not to mix with each other, the first infiltration pipe is formed to become narrower toward the lower end, a water stop material is installed at the lower end, and a primary inlet end is formed at the upper end of the first infiltration pipe, , A secondary inlet end is formed at the upper end of the first collection pipe, and the first collection pipe is an upper end of the first infiltration pipe for allowing rainwater overflowing from the upper surface of the first infiltration pipe to have a water quality higher than a certain standard. It is characterized in that it has a height difference with.

The water collector is opened vertically, has an internal space, has a plurality of first through-holes formed on an outer surface, and is buried in the ground to penetrate rainwater into the ground through the first through-hole. , It is coupled to the upper opening of the infiltration pipe, the lower part is open and communicates with the inner space of the infiltration pipe, the upper end is exposed to the ground, and a plurality of inlet holes are formed on the upper surface through which rainwater flows in An inlet cap and a filtration unit inserted into the inlet pipe and coupled to the lower opening of the inlet pipe, the lower part connected to the upper part of the three-way elbow storage, and filtering rainwater flowing through the inlet hole, When the level of rainwater filtered by the filtering unit and drained into the three-way elbow pipe rises beyond the upper end of the three-way elbow pipe, the rainwater flowing through the inlet hole penetrates into the ground through the first through hole. to be characterized

It is characterized in that it further comprises a wet cloth wrapping the outer circumferential surface of the corrugated pipe and dispersing water delivered from the wick inserted into the third through hole.

It is characterized in that the lower part of the three-way elbow storage is formed in a concave shape upward to form a collecting portion for collecting foreign substances contained in the rainwater.

In order to achieve the above object, the construction method of the rainwater storage and IoT fusion non-point pollution removal type water supply system for tree growth of the present invention is the construction method of the rainwater storage and water supply system for tree growth according to claim 1, and the periphery of the tree A first step of forming a space in the ground by excavating; The first wick is inserted into the first through-hole of the water collecting part, the second wick is inserted into the second through-hole of the three-way elbow storage, the third wick is inserted into the third through-hole of the corrugated pipe, and the three-way elbow storage and A second step of connecting the corrugated pipes, connecting the water collecting part to the upper part of the three-way elbow pipe, and then arranging the water collecting part, the three-way elbow pipe, and the corrugated pipes in the underground space; and a third step of filling the underground space with soil.

According to the present invention, there are the following effects.

First, rainwater can be collected through the catchment part, and rainwater can be stored in the three-way elbow storage and corrugated pipes, so that damage caused by heavy rain and localized heavy rain can be prevented, and the three-way elbow storage and rainwater inside the corrugated pipes or the water collector during dry season can be prevented. By sucking in rainwater inside the wick and slowly supplying it to the soil on the tree side, there is an effect of preventing the tree from dying.

In addition, the water collector, the three-way elbow tube, and the corrugated pipe are arranged in a form surrounding the tree, and the rainwater is transferred to the soil on the tree side through the first through hole, the second through hole, and the third through hole, so that the entire surrounding area of the tree is watered. can be transmitted, and there is an effect of supplying enough water to the tree to grow the tree.

In addition, by expanding and contracting the corrugated pipe and changing the shape corresponding to the underground environment of the tree periphery, there is an effect that the installation can be easily performed in the tree periphery.

1 shows a rainwater storage and IoT fusion non-point pollution removal type water supply system for tree growth according to the present invention.
Figure 2 shows a non-point pollution removal type water supply system converged with rainwater storage and IoT for tree growth according to the present invention.
Figure 3 shows a rainwater storage and IoT fusion non-point pollution removal type water supply system for tree growth according to the present invention.
4 shows a water collection unit of a non-point pollution removal type water supply system converged with rainwater storage and IoT for tree growth according to the present invention.
5 shows a water collection unit of a rainwater storage and IoT fusion non-point pollution removal type water supply system for tree growth according to the present invention.
6 shows a water collection unit of a rainwater storage and IoT fusion non-point pollution removal type water supply system for tree growth according to the present invention.
7 shows a water collection unit of a rainwater storage and IoT fusion non-point pollution removal type water supply system for tree growth according to the present invention.
8 shows a water collection unit of a rainwater storage and IoT fusion non-point pollution removal type water supply system for tree growth according to the present invention.

A preferred embodiment of the present invention will be described in more detail with reference to the accompanying drawings, but already well-known technical parts will be omitted or compressed for conciseness of description.

FIG. 3 shows a first embodiment of the water collection unit 100 of the non-point pollution removal type water supply system 10 that converges rainwater storage and IoT for tree growth according to the present invention, and FIGS. 4 to 6 are related to the present invention. 7 and 8 show a rainwater storage and water supply system 10 for tree growth according to the present invention. It is shown for the third embodiment of the water collector 100.

The rainwater storage and water supply system 10 for tree growth according to the present invention includes a water collector 100, a three-way elbow storage pipe 200, a corrugated pipe 300, and a wick (S).

Referring to FIG. 1, the water collecting unit 100 is spaced apart from the tree T at a predetermined interval and buried in all directions of the tree T to collect rainwater W, and has a plurality of first through holes on the outer surface. (100h) is formed.

The water collecting unit 100 of the rainwater storage and water supply system 10 for tree growth according to the present invention may be implemented through the first embodiment, the second embodiment, or the third embodiment.

Referring to FIG. 3, the water collecting part 100 according to the first embodiment is described. The water collecting part 100 is fixed to the upper part of the three-way elbow storage tube 200 and has a plurality of first through holes 100h on the outer surface. The formed water collecting pipe 110, the filter 120 inserted into the water collecting pipe 110, and the lower part inserted into the upper part of the filter 120, the upper and lower parts are open, and rainwater (W) flows into the upper part A grating (G) is provided and includes a water collecting cover 130 gradually narrowing toward the bottom in a tapered shape.

In addition, the filter 120 is fixed to the inside of the collecting pipe 110 by hooking the top of the collecting pipe 110 with a ring provided at the top, and foreign matter included in the rainwater W flowing through the collecting cover 130 ( not shown).

In addition, by removing the water collecting cover 130 and taking out the filter container 120 from the water collecting pipe 110 and emptying it, the inside of the water collecting part 100 can be easily cleaned.

Referring to FIGS. 4 to 6, the water collector 100 according to the second embodiment is described. The water collector 100 is buried in the ground, the upper end is exposed to the ground, and a plurality of first through holes ( 100h') is formed, and the upper and lower surfaces are opened and inserted into the hollow first penetration tube 110' and the inner hollow of the first penetration tube 110', and the upper end is compared to the upper end of the first penetration tube 110'. It is formed to be relatively high and includes a hollow first collecting pipe 120 'with upper and lower surfaces opened, and the lower end of the first infiltration pipe 110' is connected to the upper part of the three-way elbow storage pipe 200, and the first The collection pipe 120' communicates with the three-way elbow storage pipe 200, and the inner wall of the first infiltration pipe 110' and the outer wall of the first collection pipe 120' are spaced apart by a predetermined interval, and the first infiltration pipe 110 The rainwater (W) introduced between the inner wall of ') and the outer wall of the first collecting pipe (120') penetrates into the surrounding soil (E) through the first through hole (100h'), and the inside of the first collecting pipe (120'). The rainwater (W) flowing into is discharged to the three-way elbow storage pipe 200, and the lower end of the first infiltration pipe 110' is formed to correspond to the cross section of the first collecting pipe 120'. is formed, and the lower end of the first collecting pipe 120' is seated on the hanging end 113', so that rainwater flowing between the inner wall of the first infiltration pipe 110' and the outer wall of the first collecting pipe 120' ( W) and the rainwater (W) flowing into the first collection pipe 120' are configured not to mix with each other, and the first penetration pipe 110' is formed to become narrower toward the bottom, and the water stop material ( 114') is installed, the first inlet end 111' is formed at the top of the first infiltration pipe 110', and the second inlet end 121' is formed at the top of the first collection pipe 120'. formed, and the first collection pipe 120' is connected to the upper end of the first infiltration pipe 110' so that the rainwater W overflowing from the upper surface of the first infiltration pipe 110' has a water quality higher than a certain standard. have a height difference.

The water collecting part 100 according to the second embodiment includes a first penetration tube 110' formed in a substantially hollow cylindrical shape, and a first penetration tube 110' formed in a substantially hollow cylindrical shape inserted into the first penetration tube 110'. It includes a water collection pipe 120'.

The first infiltration pipe (110') collects the initial rainfall and infiltrates it into the surrounding soil (E), and the first collection pipe (120') collects the secondary rainfall that overflows due to the increase in rainfall time and amount. and serves to capture it.

The first permeation tube 110' is formed in a hollow cylindrical shape with open upper and lower surfaces, and the lower end is formed to become narrower toward the end.

A dish-shaped primary inlet end 111' is formed at the upper end of the first infiltration tube 110'.

The primary inflow end 111' is installed so that its upper end coincides with the ground surface, so that it collects rainwater (W) collected from the surroundings and introduces it into the first infiltration pipe 110'. The upper surface of the primary inlet end 111' may be formed to be open, or a separate perforated cover may be provided.

A plurality of first through holes 100h' are formed on the side surface of the first penetration tube 110'. The first through hole 100h' is for permeating rainwater W introduced through the primary inflow end 111' into the surrounding soil E.

At the lower end of the first infiltration pipe 110', a hooking end 113' is formed to correspond to the cross section of the first collecting pipe 120' to be described below. The lower end of the first collecting pipe 120' is seated on the hanging end 113'.

A waterstop material 114' may be provided at the lower end of the first permeation tube 110'. The water stop material 114' prevents rainwater (W) discharged through the lower end of the first permeation tube 110' from flowing out and does not flow in from the surrounding soil E through the lower end of the first permeation tube 110'. serves to prevent

It is preferable that the first collecting pipe 120' is connected by being inserted into the first infiltration pipe 110', and the upper end is formed relatively higher than the upper end of the first infiltration pipe 110'.

The height difference between the top of the first collection pipe 120' and the top of the first infiltration pipe 110' may be determined based on the good quality of rainwater W flowing to the top of the first collection pipe 120'. there is. That is, when the water quality of the rainwater W overflowing the first collection pipe 120' becomes suitable for reuse due to an increase in the rainfall time and amount, the first collection pipe 120' is the first infiltration pipe. The height difference of (110') can be determined as an appropriate height difference.

A secondary inlet end 121' may also be formed at an upper end of the first collection pipe 120'. The secondary inflow end 121' is also formed in a dish shape to collect rainwater W flowing from the first infiltration pipe 110'.

The upper surface of the secondary inflow end 121' may also be opened or a separate cover 122' may be provided. A plurality of through-holes are also formed in the cover 122', so that rainwater W can flow into the first collection pipe 120'.

The lower surface of the first water collection pipe 120' configured as described above is opened, and the rainwater (W) flowing into the first water collection pipe 120' is discharged to the lower surface of the first infiltration pipe 110' through the lower surface. can

Referring to FIGS. 7 and 8 , the water collecting part 100 according to the second embodiment is described. The water collecting part 100 is opened vertically, has an internal space, and has a plurality of first through holes on the outer surface. (100h") is formed, and the hollow penetration pipe 110" is buried in the ground and penetrates rainwater W into the ground through the first through hole 100h", and the upper side of the penetration pipe 110" It is coupled to the opening, the lower part is open and communicates with the inner space of the infiltration tube 110 ", the upper end is exposed to the ground, and a plurality of inlet holes 121" are formed on the upper surface through the inlet hole 121 ". It is inserted into the inlet cap 120" through which rainwater (W) flows and the infiltration pipe 110" is coupled to the lower opening of the infiltration pipe 110", and the lower part is connected to the upper part of the three-way elbow storage pipe 200. And, it includes a filtering unit 130 "where the rainwater (W) introduced through the inlet hole 121" is filtered, and the rainwater filtered by the filtering unit 130" and drained to the three-way elbow storage 200 ( When the water level of W) rises beyond the top of the three-way elbow storage pipe 200, the rainwater W introduced through the inlet hole 121 "is penetrated into the ground through the first through hole 100h".

The water collecting unit 100 according to the second embodiment is composed of components including an infiltration tube 110", an inlet cap 120" and a filtering unit 130", which will be described in detail as follows.

The permeation pipe 110 "is open vertically and has a hollow shape in which an internal space is provided, and a plurality of first through holes 100h" are formed in a protruding shape on an outer surface thereof.

The infiltration pipe 110" is vertically buried in the ground and allows rainwater W introduced through an inlet cap 120" to be described below to penetrate into the ground through the first through hole 100h".

At this time, the infiltration tube 110 "is in the shape of a board made of soft synthetic resin, and has a clip member 111 integrally provided with a fitting hole 111a formed at one end, and a fitting protrusion 112 on the other side. ) is provided.

That is, the plate-shaped infiltration tube 110" made of soft synthetic resin is rolled into a round shape, and the fitting hole 111a of the clip member 111 is fitted into the fitting protrusion 112 so that the penetration tube 110" is cylindrical. will be assembled with

In this way, since the plate-shaped infiltration tube 110 "made of soft synthetic resin can be assembled into a cylindrical shape by rolling it round, there is an advantage of easy storage and handling.

The inlet cap 120" is coupled to the upper opening of the infiltration tube 110". Preferably, the upper end of the infiltration tube 110" is fitted into the lower end of the inlet cap 120".

Here, the lower portion of the inlet cap 120" is open to communicate with the inner space of the infiltration pipe 110".

In addition, a plurality of inlet holes 121" are formed on the upper surface, and since the upper end is installed in a state where it is exposed to the ground, rainwater W flows into the inside through the inlet hole 121" formed on the upper surface.

The filtering unit 130 "is inserted into the infiltration pipe 110" and coupled to the lower opening of the infiltration pipe 110 ", the lower part is connected to the upper part of the three-way elbow storage pipe 200, and the inlet hole 121" ) Rainwater (W) introduced through is filtered.

In other words, the filtering unit 130" includes a main body 131", a nonwoven fabric 132" and a lid 133".

The main body 131" has a conical shape that is opened up and down and has an internal space. Here, the opened lower side is referred to as a first opening 131a" and has a smaller diameter than the first opening 131a". The open upper side is referred to as a second opening 131c".

In addition, along the outer surface of the main body 131 ", a concave hole 131b" having a long hole through which rainwater W is passed is formed long in the longitudinal direction of the main body 131 ".

The nonwoven fabric 132" is attached to the outer surface of the main body 131" in a form surrounding the main body 131". That is, the rainwater (W) flowing into the main body 131" of the filtering unit 130" While passing through the concave hole 131b" formed in the main body 131", it is filtered in the nonwoven fabric 132" and then drained into the three-way elbow storage 200.

The lid 133" is mounted inside the first opening 131a" having a larger diameter than the second opening 131c" formed in the main body 131" to seal the first opening 131a". do.

At this time, a plurality of through holes 133a" through which rainwater W is passed are formed in the lid 133".

That is, rainwater W introduced through the inlet cap 120" passes through the through hole 133a" formed in the cover 133", flows into the main body 131", and then is filtered through the nonwoven fabric 132". After that, it is drained into the three-way elbow storage pipe (200).

On the other hand, the filtering part 130" is formed by spaced apart protrusions protruding convexly toward the inside of the first opening 131a" of the main body 131" along the inside of the first opening 131a".

In addition, concave locking grooves 133b" corresponding to the locking protrusions formed in the first opening 131a" are spaced apart from each other along the outer side of the lid 133".

At this time, when the locking groove 133b" coincides with the locking projection, the cover 133" does not interfere with the locking projection and can be inserted into the first opening 131a" or detached from the first opening 131a". Conversely, when the lid 133" is rotated in a state where the lid 133" is inserted into the first opening 131a" so that the locking protrusion and the locking groove 133b" do not coincide with each other, the lid 133" ) interferes with the locking protrusion to prevent separation from the first opening 131a", so that the lid 133" is fixed to the first opening 131a".

Here, a handle (not shown) may be further formed on the upper surface of the lid 133″, so that the user can hold the lid 133″ or easily rotate the lid 133″ after gripping.

This filtering part 130" is in the form of upper and lower light, that is, the position of the first opening 131a" of the main body 131" is disposed on the lower side and the position of the second opening 131c" is disposed on the upper side. It is mounted inside the infiltration tube 110 ".

In this way, when the water level of the rainwater (W) filtered by the filtering unit 130 "and drained into the three-way elbow pipe 200 rises beyond the top of the three-way elbow pipe 200, the inlet cap 120" The middle and late rainwater (W) containing relatively few pollutants introduced through the formed inlet hole (121") does not drain into the three-way elbow storage pipe (200), but directly penetrates into the ground through the first through hole (100h"). It will be.

Due to the arrangement of the filtering unit 130", the rainwater W introduced through the inlet cap 120" is filtered by the non-woven fabric 132" and then introduced into the main body 131" and then the lid 133" It passes through the through hole (133a") formed in the ) and is drained into the three-way elbow storage tube (200).

Referring to FIG. 1, the three-way elbow storage 200 is connected to the lower part of the water collecting part 100, receives the rainwater W collected in the water collecting part 100, and has a plurality of second through holes on the outer surface. (200h) is formed and has three openings communicating with each other and orthogonal to each other.

Additionally, a collecting portion 210 may be formed at the bottom of the three-way elbow storage pipe 200 to collect foreign substances (not shown) contained in the rainwater W by being formed in an upwardly concave shape, and the collecting portion 210 ) By treating foreign substances (not shown) collected in the three-way El storage 200 can be easily cleaned inside.

The collecting portion 210 also stores rainwater and preferably has a concave shape protruding greatly toward the bottom in order to increase the storage amount of rainwater.

1 to 3, the corrugated pipe 300 has both ends connected to three-way elbow tubes 200 spaced apart from each other to connect the three-way elbow tubes 200, and the rainwater from the three-way elbow tube 200 (W) is supplied, a plurality of third through holes 300h are formed at the upper end, and are provided to be flexible.

Referring to FIG. 3 , the corrugated pipe 300 includes an extension portion 310 provided to be flexible and a fixing portion 320 having a third through hole 300h formed therein.

In addition, a wick (S) is inserted into the third through hole (300h) of the fixing portion, so that rainwater (W) inside the corrugated pipe (300) can be transferred to soil (E) on the side of the tree (T).

Figure 2 shows a state in which the shape is changed so that the corrugated tube 300 is stretched and bent toward the center in order to install the corrugated tube 300 so as not to overlap with the stone R shown in Figure 1.

Therefore, since the corrugated pipe 300 can be installed by being stretched and installed in a shape corresponding to the underground environment around the tree T, the installation of the corrugated pipe 300 around the tree T can be made easy.

In addition, the three-way elbow storage pipe 200 and the corrugated pipe 300 store rainwater W introduced through the water collector 100.

Referring to FIG. 1, the wick S is inserted into the first through hole 100h, the second through hole 200h, and the third through hole 300h, respectively, one side protrudes outward, and the other side portion is placed inside

And, the wick (S) may be provided by twisting a thread or cloth.

Additionally, a plurality of wicks S inserted into the first through-holes 100h are inserted into the first through-holes 100h, respectively, or wicks S formed integrally are inserted into the first through-holes 100h. can be inserted.

Referring to Figure 3, rainwater (W) absorbed from the other side of one wick (S) disposed inside the three-way elbow storage tube (200) protrudes from the first through holes (100h) (S) It can be delivered to one side of.

In addition, the wick (S) is the soil of the tree (T) side of the rainwater (W) inside the three-way elbow storage 200 or the rainwater (W) inside the corrugated pipe 300 or the rainwater (W) inside the water collector 100 By transferring water to (E), sufficient water is supplied to the tree T in the entire periphery of the tree T so that the tree T can grow.

Additionally, the wick S is not inserted into the first through-holes 100h located on the opposite side of the tree T among the first through-holes 100h formed in the water collector 100, and heavy rain or concentrated rain When a large amount of rainwater (W) flows into the water collector 100 due to heavy rain, the rainwater (W) is discharged into the ground through the first through-holes (100h) located on the opposite side of the tree (T), thereby Rainwater (W) flowing into the 100 can be prevented from flowing backward.

In summary, since the rainwater (W) can be collected through the water collector 100 and the rainwater (W) can be stored in the three-way elbow storage 200 and the corrugated pipe 300, damage caused by heavy rain and torrential rain can be prevented. In the dry season, the wick (S) absorbs the rainwater (W) inside the three-way elbow storage pipe (200) and the corrugated pipe (300) or the rainwater (W) inside the water collector to return it to the soil (E) on the tree (T) side. By slowly supplying, it is possible to prevent the tree T from dying.

In addition, the corrugated pipe 300 can be stretched and changed into a shape corresponding to the underground environment around the tree T, so that the installation can be easily performed around the tree T.

Additionally, a wet cloth (not shown) may be further included that surrounds the outer circumferential surface of the corrugated pipe 300 and disperses water delivered from the wick S inserted into the third through hole 300h.

A construction method of the rainwater storage and water supply system 10 for tree growth will be described.

First, the first step (S100) of forming a space in the ground by excavating the periphery of the tree (T) is performed.

Additionally, when the tree T is not planted, the location where the tree T is to be planted and the area around the location where the tree T is to be planted are excavated, and the rainwater retention water supply system 10 for tree growth After the installation of the tree (T) can be planted.

Then, the wick (S) is inserted into the first through hole (100h), the second through hole (200h) and the third through hole (300h), respectively, and connects the three-way elbow tube (200) and the corrugated tube (300), After connecting the water collecting part 100 to the upper part of the three-way elbow pipe 200, the second step (S200) of arranging the water collecting part 100, the three-way elbow pipe 200, and the corrugated pipe 300 in the underground space Conduct.

Here, the corrugated pipes 300 may be changed into a shape corresponding to the underground environment by being stretched and arranged in an underground space.

Then, by performing the third step (S300) of filling the underground space with soil E, the construction of the rainwater storage and water supply system 10 for tree growth is completed.

As a result, the rainwater storage and water supply system 10 for tree growth according to the present invention collects rainwater (W) through the water collector 100, and collects rainwater (W) in the three-way elbow storage 200 and the corrugated pipe 300 Since it can retain, it is possible to prevent damage caused by heavy rain and torrential rain, and the wick (S) sucks the rainwater (W) inside the three-way elbow storage (200) and the corrugated pipe (300) during the dry season, causing the tree (T) By supplying the soil E on the side slowly, it is possible to prevent the tree T from dying.

In addition, the water collecting part 100, the three-way elbow pipe 200, and the corrugated pipe 300 are arranged in a form surrounding the tree T, and the first through hole 100h, the second through hole 200h, and the third through hole By transferring rainwater W to the soil E on the side of the tree T through the hole 300h, water can be delivered to the entire surrounding area of the tree T, and sufficient water is supplied to the tree T so that the tree ( T) can be grown.

In addition, by expanding and contracting the corrugated pipe 300 and changing the shape corresponding to the underground environment around the tree T, the installation can be easily performed on the periphery of the tree T.

On the other hand, the present invention is configured to enable efficient management of the filter 120 by detecting the accumulated amount of non-point pollution collected in the filter 120, and the non-point pollution accumulated amount detection sensor 400 is the filter 120 (see FIG. 3) and/or installed on the water collecting cover 130 (see FIG. 7) to detect the accumulated amount of non-point pollution. The installation location of the non-point pollution accumulation amount detection sensor 400 is not limited to the filter 120 and the catchment cover 130, and can be installed anywhere non-point pollution accumulates.

The non-point pollution accumulation amount detection sensor 400 detects the amount of non-point pollution accumulated in the strainer 120 or the catchment cover 130 or detects the maximum amount, and transmits the detected value to a remote control room server or a manager's portable terminal (smart phone app). ), and the manager quickly cleans or replaces the filter 120 and the water collecting cover 130 based on this information.

As described above, the detailed description of the present invention has been made by way of examples, but since the above-described embodiments have only been described with a preferred example of the present invention, it is understood that the present invention is limited only to the above embodiments. It should not be, and the scope of the present invention should be understood as the following claims and their equivalents.

10: Rainwater retention water supply system for tree growth
100: collection part 110: collection pipe 1000h: first through hole
120: strainer 130: catchment cover 110': first infiltration pipe 120': first collection pipe
110": infiltration pipe 120": inflow cap 130": filtering unit 200: three-way elbow storage
200h: second through hole 210: collecting part 300: corrugated pipe
300h: 3rd through hole S: wick T: tree W: rainwater E: soil R: stone
400: non-point contamination accumulation sensor,

Claims (7)

a water collecting unit spaced apart from the tree by a predetermined interval and buried in all directions of the tree to collect rainwater and having a plurality of first through-holes formed on an outer surface thereof;
A three-way elbow storage connected to the lower part of the water collecting part, receiving rainwater collected in the water collecting part, having a plurality of second through holes formed on the outer surface, communicating with each other and having three openings orthogonal to each other;
Both ends are connected to the three-way elbow tubes spaced apart from each other to connect the three-way elbow tubes, receive the rainwater from the three-way elbow tubes, and have a plurality of third through-holes formed at the top, provided to be flexible corrugated tube;
A wick inserted into the first through hole, the second through hole, and the third through hole, respectively;
The three-way elbow pipe and the corrugated pipe retain the rainwater,
The wick transfers rainwater inside the water collector, rainwater inside the three-way elbow storage tube, or rainwater inside the corrugated pipe to the soil on the tree side,
The collector,
A collection pipe fixed to the upper part of the three-way elbow storage pipe and having a plurality of first through-holes formed on the outer surface;
A filter passage inserted into the water collection pipe;
The lower part is fitted to the upper part of the gutter, the upper part and the lower part are opened, and a grating through which rainwater flows into the upper part is provided, and a water catchment cover gradually narrowing toward the lower part in a tapered shape, and
A non-point pollution accumulation amount detection sensor installed on at least one side of the filter container and the catchment cover and detecting the accumulation amount of non-point pollution and transmitting it to a manager,
The filter is characterized in that for filtering foreign substances contained in the rainwater flowing through the water collecting cover
Rainwater retention and IoT fusion non-point pollution removal water supply system for tree growth.
delete According to claim 1,
The collector,
A hollow first penetration tube buried in the ground and having an upper end exposed to the ground, a plurality of first through holes formed on the outer surface, and an upper and lower surface being opened; and
A hollow first collection pipe inserted into the hollow inside the first infiltration pipe, formed to have an upper end relatively higher than the upper end of the first infiltration pipe, and having upper and lower surfaces opened,
The lower end of the first infiltration tube is connected to the upper part of the three-way elbow tube,
The first collection pipe communicates with the three-way elbow storage,
The inner wall of the first infiltration pipe and the outer wall of the first collecting pipe are spaced apart by a predetermined interval,
Rainwater introduced between the inner wall of the first infiltration pipe and the outer wall of the first collection pipe penetrates into the surrounding soil through the first through hole,
Rainwater flowing into the first collection pipe is discharged into the three-way elbow storage pipe,
A hooking end corresponding to the cross section of the first collecting pipe is formed at the lower end of the first infiltration pipe, and the lower end of the first collecting pipe is seated on the hanging end, so that the inner wall of the first infiltration pipe and the The rainwater flowing between the outer walls of the first collecting pipe and the rainwater flowing into the first collecting pipe are configured not to mix with each other,
The first penetration pipe is formed to become narrower toward the lower end, and a stopper is installed at the lower end,
A first inlet end is formed at the upper end of the first infiltration tube,
A secondary inlet is formed at the upper end of the first collection pipe,
Characterized in that the first collection pipe has a height difference from the upper end of the first infiltration pipe so that rainwater overflowing from the upper surface of the first infiltration pipe has a water quality of a certain standard or higher
Rainwater retention and IoT fusion non-point pollution removal water supply system for tree growth.
According to claim 1,
The collector,
A hollow penetration pipe that is open vertically, has an internal space, has a plurality of first through holes formed on the outer surface, and is buried in the ground to allow rainwater to penetrate into the ground through the first through hole;
It is coupled to the upper opening of the infiltration pipe, the lower part is open and communicates with the inner space of the infiltration pipe, the upper end is exposed to the ground, and a plurality of inlet holes are formed on the upper surface so that rainwater flows through the inlet hole. cap and
It is inserted into the infiltration pipe and coupled to the lower opening of the infiltration pipe, the lower part is connected to the upper part of the three-way elbow storage, and a filtering part through which rainwater flowing through the inlet hole is filtered,
When the level of rainwater filtered by the filtering unit and drained into the three-way elbow pipe rises beyond the upper end of the three-way elbow pipe, the rainwater introduced through the inlet hole penetrates into the ground through the first through hole. characterized by
Rainwater retention and IoT fusion non-point pollution removal water supply system for tree growth.
According to claim 1,
Characterized in that it further comprises a wet cloth wrapping the outer circumferential surface of the corrugated pipe and dispersing water delivered from the wick inserted into the third through hole.
Rainwater retention and IoT fusion non-point pollution removal water supply system for tree growth.
According to claim 1,
Characterized in that the lower part of the three-way elbow storage is formed in a concave shape upward to form a collecting part for collecting foreign substances contained in the rainwater
Rainwater retention and IoT fusion non-point pollution removal water supply system for tree growth.
As a construction method of rainwater storage and IoT fusion non-point pollution removal type water supply system for tree growth according to claim 1,
A first step of excavating the periphery of the tree to form a space in the ground;
The first wick is inserted into the first through-hole of the water collecting part, the second wick is inserted into the second through-hole of the three-way elbow storage, the third wick is inserted into the third through-hole of the corrugated pipe, and the three-way elbow storage and A second step of connecting the corrugated pipes, connecting the water collecting part to the upper part of the three-way elbow pipe, and then arranging the water collecting part, the three-way elbow pipe, and the corrugated pipes in the underground space; and
Characterized in that it comprises a; third step of filling the underground space with soil
Construction method of rainwater retention and IoT fusion non-point pollution removal water supply system for tree growth.

Images