KR102197709B1 - Impermeability barrier, Barrier module use impermeability barrier - Google Patents

Abstract

The present invention provides a barrier wall body that restricts the flow of fluid, a barrier wall fastening portion formed at one end of the barrier wall body in the width direction, and a shape corresponding to the barrier wall fastening portion formed at the other end of the barrier wall body in the width direction. A barrier wall composed of a barrier wall fitting portion having a barrier wall, an inlet through which fluid is introduced, an outlet through which the fluid introduced through the inlet is discharged, and a fluid that is located between the inlet and the outlet and moves from the inlet to the outlet. It relates to a wall coupling module comprising a water permeable wall composed of a foreign material removing unit for removing contaminants from the phase.

Description

Barrier wall, wall bonding module using barrier wall {Impermeability barrier, Barrier module use impermeability barrier}

The present invention relates to a barrier wall and a wall coupling module using the barrier wall, and more particularly, to limit the movement of contaminants appearing in response to the movement of groundwater, and a barrier wall that can be combined to form a module, using the same. It relates to a wall bonding module.

In general, the wall to prevent the diffusion of pollutants on the soil through the groundwater is a barrier wall that completely blocks the flow of groundwater, and the groundwater permeates and adsorbs and fixes the pollutants mixed with the groundwater to the filler provided inside. It is divided into a permeable wall that purifies.

In other words, if the purpose of removing pollutants from the ground is to permeate groundwater mixed with pollutants, use a permeable wall to remove pollutants mixed with groundwater, and to completely isolate pollutants from the ground from non-polluted areas. If it has, a barrier wall is used.

Among the walls that block or remove pollutants from the ground, the barrier wall is generally made through a method of excavating the ground to a certain depth and then inserting concrete into the excavated space.

However, the barrier wall made of concrete not only has the limitation that the concrete is corroded over time and the barrier wall can no longer block contaminants, and the concrete itself can act as a contaminant when the concrete is corroded. In order to have more than a certain strength, the concrete has to have a certain thickness or more, so there is also a problem that the excavation range is wider.

Accordingly, there is a need for a new barrier wall capable of solving the problems of the conventional barrier wall and a wall coupling module using the barrier wall.

Patent Document 1) Korean Patent Publication No. 10-0529301 (Name: Reactivity Recovery Method of Water-Permeable Reactive Wall for Purifying Contaminated Groundwater, Publication Date: 2005.03.21)

The present invention has been conceived to solve the above-described problems, and an object of the present invention is to solve the problem that the conventional barrier wall is made of concrete, corrosion occurs, environmental pollution, and construction is difficult. It is to provide a wall and a wall coupling module using the same.

In other words, it provides a barrier wall that can semi-permanently maintain its function as a wall with high corrosion resistance, minimize environmental pollution caused by the formation of the wall, and also minimize construction cost and construction period, and a wall-coupled module using the same.

A barrier wall body according to the present invention for achieving the above object includes: a barrier wall body 110 for limiting the flow of fluid; A blocking wall fastening part 120 formed at one end of the blocking wall body 110 in the width direction; And a blocking wall fitting part 130 formed at the other end of the blocking wall body 110 in the width direction and having a shape corresponding to the blocking wall fastening part 120.

In the barrier wall coupling module according to the present invention for achieving the above object, a plurality of barrier walls 100 are arranged in a width direction and adjacent to each other among a plurality of barrier walls 100 arranged in a width direction. The blocking wall fastening part 120 and the blocking wall fitting part 130 of the blocking wall 100 are coupled to each other.

The barrier wall coupling module according to the present invention for achieving the above object includes an inlet part 210 through which a fluid is introduced, an outlet part 220 through which the fluid introduced through the inlet part 210 is discharged, and the A permeable wall composed of a foreign substance removing part 230 located between the inlet part 210 and the outlet part 220 to remove contaminants in the fluid flowing from the inlet part 210 to the outlet part 220 It characterized in that it further comprises (200).

In addition, the water permeable wall 200 is coupled to the upper side of the barrier wall 100, has a shape having a length longer in the thickness direction than the barrier wall 100, the inlet portion 210 and the outlet portion 220 It characterized in that it is formed spaced apart from each other with the blocking wall 100 on the lower side.

In addition, the permeable wall 200 has a permeable wall fastening part 240 having a shape corresponding to the blocking wall fitting part 130 on one side in the width direction, and the blocking wall fastening part 120 on the other side in the width direction A permeable wall fitting portion 250 having a shape corresponding to is formed, and when the plurality of barrier walls 100 and the plurality of permeable walls 200 are arranged in the width direction according to a specified order, the fastening portions adjacent to each other and It characterized in that the fitting portion is coupled to each other.

In addition, the permeable wall 200 includes a columnar permeable wall body 200A in which the foreign material removing part 230 is formed in the center, and the inlet part 210 has a thickness of the permeable wall body 200A It is formed on one side in the direction and includes a first slit penetrating the permeable wall body 200A, and the outlet part 220 is formed on the other side of the permeable wall body 200A in the thickness direction, and the permeable wall body 200A It characterized in that it comprises a second slit passing through.

In addition, the foreign material removing unit 230 includes an adsorption space 230A formed in the vertical direction at the center of the permeable wall body 200A, and a nano adsorbent 230B provided on the adsorption space 230A. It features.

In addition, the adsorption space 230A is divided into two or more regions, and a separation plate 300 in which a perforation hole 310 is formed is further included.

In addition, the separating plate 300 is characterized in that it further includes an adsorbent fixing part 320 for positioning the nano adsorbent 230B to face the perforated hole 310.

In addition, the permeable wall body 200A includes an outer permeable wall body 200A-1 in which the permeable wall fastening part 240 and the permeable wall fitting part 250 are formed, and the outer permeable wall body 200A-1 ), and includes an inner permeable wall body 200A-2 on which the foreign matter removing part 230 is formed, and the inner permeable wall body 200A-2 is the outer permeable wall body 200A-1 It characterized in that it is rotatably coupled to.
In addition, the barrier body 110 for restricting the flow of fluid; A blocking wall fastening part 120 formed at one end of the blocking wall body 110 in the width direction; A barrier wall fitting portion 130 formed at the other end of the barrier body 110 in the width direction and having a shape corresponding to the barrier wall fastening portion 120; including, wall coupling using a barrier wall 100 In the module, coupled to the upper side of the barrier wall 100, the inlet portion 210 through which a fluid flows, an outlet portion 220 through which the fluid introduced through the inlet portion 210 is discharged, and the inlet Further comprising a permeable wall 200 consisting of a foreign material removing unit 230 for removing contaminants in a fluid moving from the part 210 to the outlet 220, the permeable wall 200 is the barrier wall The length in the thickness direction is longer than that of (100), so that one side and the other side in the thickness direction are formed to protrude from one side and the other side in the thickness direction of the barrier wall 100, and at one side and the other bottom side in the thickness direction of the protruding permeable wall 200 The inlet part 210 and the outlet part 220 are formed with the barrier wall 100 interposed therebetween, and an outlet through which gas is discharged is disposed under the inlet part 210 so that the discharged gas is floated. And an aeration unit 260 to direct the movement of the surrounding fluid to the inlet unit 210; It characterized in that it comprises a.

The barrier wall according to the present invention has the advantage of limiting the movement of pollutants to non-polluted areas even if the pollutants are distributed over a wide area because a plurality of barrier walls are connected to each other to form one wall coupling module.

In addition, the wall-coupled module of the present invention limits the movement of pollutants from the contaminated area to the non-polluted area, because the barrier wall and the permeable wall are combined to form a single module, but the contamination that is selectively mixed with groundwater in the designated area It has the advantage of being able to remove substances.

In addition, since the adsorption space on the water permeable wall can be separated by a separating plate, it is possible to minimize the consumption of the nano-adsorbent and improve the ability of the nano-adsorbent to remove contaminants.

1 is a perspective view showing a water permeable reaction wall according to a first embodiment of the present invention.
Figure 2 is a plan view and a partial enlarged view showing a wall coupling module consisting of a water-permeable reaction wall according to the first embodiment of the present invention.
3 is a perspective view showing a wall coupling module according to a second embodiment of the present invention.
Figure 4 is a plan view and a partial enlarged view showing a wall coupling module according to a second embodiment of the present invention.
5 is a plan view and a partial enlarged view showing a wall coupling module according to a third embodiment of the present invention.
6 is a front view showing a joining plate used in the third embodiment of the present invention.
7 is a plan view and a partial enlarged view showing a wall coupling module according to a fourth embodiment of the present invention.
8 is a perspective view showing a wall coupling module according to a fifth embodiment of the present invention.
9 is a cross-sectional view showing a wall coupling module according to a fifth embodiment of the present invention.
10 is a plan view showing a wall coupling module according to a sixth embodiment of the present invention.
11 is a cross-sectional view showing a wall coupling module according to a sixth embodiment of the present invention.

Advantages and features of the embodiments of the present invention, and a method of achieving them will become apparent with reference to the embodiments described later in detail together with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but may be implemented in a variety of different forms, and only these embodiments make the disclosure of the present invention complete, and common knowledge in the technical field to which the present invention pertains. It is provided to completely inform the scope of the invention to those who have, and the invention is only defined by the scope of the claims. The same reference numerals refer to the same elements throughout the specification.

In describing the embodiments of the present invention, if it is determined that a detailed description of a known function or configuration may unnecessarily obscure the subject matter of the present invention, a detailed description thereof will be omitted. In addition, terms to be described later are terms defined in consideration of functions in an embodiment of the present invention, which may vary according to the intention or custom of users or operators. Therefore, the definition should be made based on the contents throughout this specification.

Hereinafter, with reference to the accompanying drawings will be described with respect to the barrier wall 100 and the wall coupling module 1000 according to the present invention.

1 is a perspective view showing a barrier wall 100 according to the present invention, and FIG. 2 is a plan view and a partial enlarged view showing that the barrier walls 100 are gathered to form the wall coupling module 1000.

Referring to FIG. 1, the present inventors barrier wall 100 has a barrier wall body 110 that restricts the flow of fluid, and a barrier wall fastening part 120 formed at one end of the barrier wall body 110 in the width direction. And, a blocking wall fitting part 130 formed at the other end of the blocking wall body 110 in the width direction and having a shape corresponding to the blocking wall fastening part 120.

In detail, the barrier wall is inserted into the ground so that contaminants move in response to the flow of groundwater, limit contamination of non-polluted areas, and are made by adding an improving agent to a resin such as polyvinyl chloride (PVC) having high corrosion resistance. As a plastic sheet pile (PSP), it has the advantages of low manufacturing cost, excellent durability, and easy construction.

This barrier wall is a device for separating a contaminated area and a non-polluted area in which pollutants are located. Since a large area must be isolated from each other, in the present invention, the barrier wall body 110 of the plate shape corresponds to both sides in the width direction. By forming the blocking wall fastening part 120 and the blocking wall fitting part 130 to be formed, a plurality of blocking walls 100 are coupled to each other as shown in FIG. 2 to form one wall combining module 1000. It made it possible to form.

Referring again to FIG. 2, if the contaminated area DS is wide, the contaminated area DS and the non-contaminated area CP are separated from each other with a barrier wall 100, so that the pollutants in the contaminated area DS It should be prevented from polluting the non-polluted area (CP) by moving to the non-polluted area (CP) along the movement of the groundwater.

At this time, it is possible to limit the movement of groundwater from the contaminated area (DS) to the non-contaminated area (CP) through the connection portion between the blocking walls 100 only when the connection between the barrier walls 100 arranged in the width direction is made firmly, Since it is possible to prevent the barrier wall 100 from being separated from the designated position by an external force, in the present invention, a barrier wall fastening portion 120 and a barrier wall fitting portion 130 are formed on both sides of each barrier wall, so that the width When a plurality of blocking walls 100 are arranged in the direction, the blocking wall fitting part 130 is fitted to the blocking wall fastening part 120 of the blocking wall 100 adjacent to each other, so that the blocking walls 100 adjacent to each other can be combined with each other. I did it.

At this time, the blocking wall fitting portion 130 has a'T'-shaped cross section in which a protrusion is formed, and the blocking wall fastening portion 120 has a structure surrounding the protrusion 131, and the fitting portion 130 It goes without saying that it may be a structure that is slide-coupled to the fastening part 120.

In addition, referring to the perspective view of FIG. 3 and the plan view of FIG. 4, the wall coupling module 1000 according to the present invention may further include a permeable wall 200 for removing contaminants mixed with groundwater by passing groundwater, A permeable wall fastening part 240 having a shape corresponding to the blocking wall fitting part 130 is formed on one side of the permeable wall 200 in the width direction, and corresponding to the blocking wall fastening part 120 on the other side in the width direction A permeable wall fitting portion 250 having a shape that is formed, when the plurality of the barrier walls 100 and the plurality of the permeable walls 200 are arranged in the width direction in a specified order, the fastening portions and the fitting portions adjacent to each other They are combined with each other to form a wall coupling module 1000.

In detail, the permeable wall fastening part 240 has the same shape as the barrier wall fastening part 120, and the water permeable wall fitting part 250 has the same shape as the barrier wall fitting part 130, When the barrier wall 100 and the permeable wall 200 are arranged in the width direction, the barrier wall fastening part 120 and the barrier wall fitting part 130, the barrier wall fastening part 120, and the water permeable wall fitting part 250 are It was made possible to combine.

In addition, referring to FIG. 4, the water permeable wall 200 includes an inlet part 210 through which a fluid is introduced, an outlet part 220 through which the fluid introduced through the inlet part 210 is discharged, and the inlet part ( It may include a foreign material removing unit 230 positioned between the 210 and the outlet 220 to remove contaminants in a fluid flowing from the inlet 210 to the outlet 220.

In addition, the inlet part 210 may be a first slit 210A-1 formed on one side of the permeable wall body 200A in the thickness direction and passing through the permeable wall body 200A, and the outlet part 220 ) May be a second slit 210A-2 formed on the other side of the permeable wall body 200A in the thickness direction and passing through the permeable wall body 200A.

3 and 4, the permeable wall 200 includes a columnar permeable wall body 200A in which the foreign substance removing part 230 is formed in the center, and the permeable wall body 200A ), a plurality of slits 210A extending in the circumferential direction are arranged in a vertical direction, and the slits are located on one side of the permeable wall body 200A in the thickness direction, and a first slit into which fluid flows, and a permeable wall body ( 200A) is located on the other side in the thickness direction and includes a second slit through which the fluid is discharged.

That is, the first slits are gathered to form the inlet part 210 through which the fluid moves to the foreign material removing part 230, and the second slits are gathered to form the outlet part through which the fluid passing through the foreign material removing part 230 is discharged. It is to form 220.

In addition, the inlet portion 210 and the outlet portion 220 may have the same flow path cross-sectional area, but as shown in FIG. 4, the first region A in which the inlet portion 210 is formed is the outlet. It is formed to have a passage cross-sectional area wider than that of the second region B in which the portion 220 is formed, so that the flow of groundwater from the inlet portion 210 to the outlet portion 220 can be strengthened.

In detail, by making the flow path cross-sectional area of the first slit forming the inlet part 210 larger than the flow path cross-sectional area of the second slit forming the outlet part 220, the flow of the fluid is more I made it active.

In addition, the foreign material removing unit 230 includes an adsorption space 230A formed in the vertical direction at the center of the permeable wall body 200A, and a nano adsorbent 230B provided on the adsorption space 230A. I can.

At this time, the nano-adsorbent 230B positioned on the foreign material removing part 230 may be a porous material in which a plurality of nano- to micro-sized pores to which contaminants are adsorbed or adhered to may be formed, and the water permeable wall 200 ) May be a nanostructure formed by stacking nanotubes extending in the thickness direction of ), and in addition, it may be a variety of materials capable of removing contaminants from the groundwater passing through the groundwater.

Further, referring to FIG. 5, the wall coupling module 1000 according to the present invention may further include a separating plate 300 in which the adsorption space 230A is divided into two or more regions, and a perforated hole 310 is formed. .

In detail, in the permeable wall 200, the nano-adsorbent 230B is positioned on the adsorption space 230A to remove contaminants mixed in the groundwater passing through the adsorption space 230A.

At this time, if all of the nano-adsorbent 230B is filled in the adsorption space 230A, the amount of the nano-adsorbent 230B used in the wall bonding module is rapidly increased, so in the present invention, the separation plate 300 is used. The adsorption space 230A is located on one side in the thickness direction of the separating plate 300 in which the inlet part 210 is formed and the other side in the thickness direction in which the outlet part 220 is formed Separated into the second adsorption space 230A-2, and place the nano-adsorbent 230B only on the second adsorption space 230A-2, so that the amount of nano-adsorbent 230B required for the wall bonding module 1000 is reduced. Is minimized.

In addition, as shown in FIG. 6, the separation plate 300 has a plurality of perforation holes 310 communicating with the first adsorption space 230A-1 and the second adsorption space 230A-2 in the vertical direction. As a result, groundwater can be evenly introduced into the upper and lower sides of the nano-adsorbent 230B, and the nano-adsorbent 230B is provided on the other side in the thickness direction of the separation plate 300 as shown in FIG. The adsorbent fixing part 320 positioned to face each other may be formed.

In detail, when the nano-adsorbent 230B is placed in the adsorbent fixing part 320, it is introduced from the first adsorption space 230A-1 to the second adsorption space 230A-2 through the perforated hole 310. By allowing groundwater to pass through the nano-adsorbent 230B located on the adsorbent fixing part 320, the amount of the nano-adsorbent 230B can be further minimized.

At this time, the perforated hole 310 may have a slit-shaped flow path cross section extending in the vertical direction as shown in (a) of FIG. 6, and extend in the left and right direction as shown in (b) of FIG. 6 Since the formed slit-shaped flow path cross-section may be varied according to the intention of the designer, the adsorbent fixing part 320 may also have a variable shape corresponding to the shape of the perforated hole 310, The adsorbent 230B is placed in close contact with the perforated hole 310 so that the groundwater passing through the perforated hole 310 is sufficient to move to the outlet 220 through the nano-adsorbent 230B, so it is not limited thereto.

In addition, referring to the perspective view of FIG. 8 and the cross-sectional view AA of FIG. 9, in the present invention, in the wall coupling module 1000, the water permeable wall 200 is coupled to the upper side of the barrier wall 100, and the barrier wall 100 The thickness direction may have a long shape, and the inlet portion 210 and the outlet portion 220 may have a structure in which the inlet portion 210 and the outlet portion 220 are spaced apart from each other with the barrier wall 100 interposed therebetween.

When described in detail with reference to FIG. 9, when the inlet part 210 and the outlet part 220 are formed on one side and the other side in the thickness direction of the permeable wall 200, the inner flow path of the permeable wall 200 is Since it is formed in the thickness direction of 200), the movement path of the groundwater on the nano-adsorbent 230B through which the groundwater passes is shortened, so that the problem of lowering the adsorption efficiency of the nano-adsorbent 230B may occur. As shown in ), the inlet part 210 is formed at one lower end in the thickness direction of the permeable wall 200, and the outlet part 220 is formed at the other lower end in the thickness direction of the permeable wall 200, so that the groundwater is a nano-adsorbent. The moving path through 230B is to have a length sufficient for the nano-adsorbent 230B to remove contaminants mixed with groundwater.

In addition, the water permeable wall 200 is an aeration unit 260 that releases gas from the lower side of the inlet unit 210 so that the fluid moves toward the inlet unit 210 as shown in FIG. 9B. It may further include.

In detail, when the inlet part 210 and the outlet part 220 are formed under the permeable wall 200, the flow rate of groundwater flowing into the inlet part 210 decreases, so in the present invention, the aeration part 260 By discharging gas under the inlet part 210 by using, gas particles rise and push the groundwater to flow into the groundwater inlet part 110.

At this time, the aeration unit 260 may include a pump 261 that sucks gas and a pipe 262 that discharges the sucked gas to the lower side of the inlet part 210, and the pump 261 is It is formed to be able to adjust the amount of gas discharged to the pipe 262, the user can adjust the flow rate of the groundwater flowing into the inlet 210 by adjusting the control unit.

That is, by controlling the control unit, it is possible to control so that only the amount of groundwater from which the nano-adsorbent 230B can efficiently remove contaminants is introduced into the inlet part 210.

In addition, the gas supplied from the aeration unit 260 may be oxygen or oxygen-containing air capable of culturing aerobic microorganisms capable of decomposing contaminants attached to the nano-adsorbent 230B.

In detail, in the case of the nano-adsorbent 230B, contaminants mixed in the groundwater are removed through an adsorption and fixation method, and when a certain amount of contaminants adhere to the nano-adsorbent 230B, the purification ability decreases.

Therefore, in the present invention, oxygen or air is supplied to the nano-adsorbent 230B0 through the aeration unit 260 to propagate aerobic microorganisms capable of decomposing contaminants on the nano-adsorbent 230B. It made it possible to use it for a longer time.

In addition, the permeable wall 200 is located on one side in the thickness direction as shown in (c) of 9, and a guide part 270 for guiding the movement of the fluid moving from the aeration part 260 to the inlet part 210 It may further include.

In detail, as described above, the aeration unit 260 injects gas to introduce groundwater to the inlet unit 2100. At this time, the gas discharged from the aeration unit 260 does not flow into the inlet unit 210 and is In the present invention, the guide part 270 is formed on one side of the permeable wall 200 in the thickness direction, so that the gas discharged from the aeration part 260 and the groundwater moving by the gas are moved. It was directed toward the inlet part 210.

Further, referring to the plan view of FIG. 10 and the cross-sectional view BB of FIG. 11, the permeable wall body 200A includes an outer permeable wall body 200A- in which the permeable wall fastening part 240 and the permeable wall fitting part 250 are formed. 1), and an inner permeable wall body 200A-2 positioned inside the outer permeable wall body 200A-1 and on which the foreign matter removing part 230 is formed, and the inner permeable wall body 200A- 2) may be rotatably coupled to the outer permeable wall body (200A-1).

In detail, the inner permeable wall body 200A-2 has the nano-adsorbent 230B positioned at the center in the vertical direction. At this time, in the case of the nano-adsorbent (230B), since the purification ability decreases when more than a certain contaminant is attached, in the present invention, the inner water permeable wall body (200A-2) is rotatably formed, so that the inlet part 210 and the When a certain amount of contaminants is attached to a specific location of the nano-adsorbent 230B located on the groundwater movement path between the outlet 220 and the inlet 210 and the outlet 220, the inner permeable wall body 200A By rotating -2), a path through which the uncontaminated nano-adsorbent 230B moves to a specific area is formed.

At this time, the outer permeable wall body (200A-1) and the inner permeable wall body (200A-2) may be coupled to each other to have rotational displacement in various ways, as shown in FIG. Likewise, bent portions 200A-1A are formed at both ends in the longitudinal direction of the outer permeable wall body 200A-1, and the ends of the bent portions 200A-1A are formed on the inner permeable wall body 200A-2. It may have a structure in which groove portions 200A-2A to be fitted are formed.

The present invention is not limited to the above-described embodiments, and the scope of application thereof is diverse, as well as anyone with ordinary knowledge in the field to which the present invention belongs without departing from the gist of the present invention claimed in the claims. Of course, various modifications are possible.

100: barrier wall 110: barrier wall body
120: barrier wall fastening portion 130: barrier wall fitting portion
200: permeable wall 200A: permeable wall body
200A-1: outer permeable wall body 200A-2: inner permeable wall body
210: inlet 210A: slit
220: exit
230: foreign matter removal unit 230A: adsorption space
230B: nano-adsorbent
240: permeable wall coupling portion 250: permeable wall fitting portion
300: separator 310: perforated hole
320: adsorbent fixing part

Claims (10)

Blocking wall body 110 for restricting the flow of fluid; A blocking wall fastening part 120 formed at one end of the blocking wall body 110 in the width direction; A barrier wall fitting portion 130 formed at the other end of the barrier body 110 in the width direction and having a shape corresponding to the barrier wall fastening portion 120; including, wall coupling using a barrier wall 100 In the module,
An inlet part 210 that is coupled to an upper side of the barrier wall 100 and into which a fluid is introduced, an outlet part 220 through which the fluid introduced through the inlet part 210 is discharged, and the inlet part 210 Further comprising a water permeable wall 200 consisting of a foreign material removing unit 230 for removing contaminants in the fluid moving from the outlet 220,
The permeable wall 200 has a length longer in the thickness direction than the barrier wall 100, so that one side and the other side in the thickness direction protrude to one side and the other side in the thickness direction of the barrier wall 100,
The inlet part 210 and the outlet part 220 are formed at one side and the lower end of the other side in the thickness direction of the protruding permeable wall 200 with the blocking wall 100 interposed therebetween,
An aeration unit 260 in which an outlet through which gas is discharged is disposed below the inlet part 210 so that the discharged gas floats and a movement of the surrounding fluid is directed to the inlet part 210; Containing, wall coupling module.
The method of claim 1,
The plurality of blocking walls 100 are arranged in a width direction, and the blocking wall fastening part 120 of the blocking wall 100 adjacent to each other among the plurality of blocking walls 100 arranged in the width direction and the The wall coupling module, characterized in that the blocking wall fitting portion 130 is coupled to each other,
delete delete The method of claim 2,
The permeable wall 200 has a permeable wall fastening part 240 having a shape corresponding to the blocking wall fitting part 130 on one side in the width direction, and corresponding to the blocking wall fastening part 120 on the other side in the width direction A permeable wall fitting portion 250 having a shape that is formed is formed,
When arranging the plurality of blocking walls 100 and the plurality of permeable walls 200 in the width direction in a specified order, the fastening parts and the fitting parts adjacent to each other are coupled to each other.
The method of claim 5,
The permeable wall 200 includes a columnar permeable wall body 200A in which the foreign material removing part 230 is formed in the center, and the inlet part 210 is one side in the thickness direction of the permeable wall body 200A. It is formed in and includes a first slit penetrating the permeable wall body 200A, and the outlet 220 is formed on the other side of the permeable wall body 200A in the thickness direction and penetrates the permeable wall body 200A The wall coupling module, characterized in that it comprises a second slit.
The method of claim 6,
The foreign matter removing unit 230 includes an adsorption space 230A formed in the vertical direction at the center of the water permeable wall body 200A, and a nano adsorbent 230B provided on the adsorption space 230A. As a wall-mounted module.
The method of claim 7,
Separating the adsorption space (230A) into two or more regions, characterized in that it further comprises a separation plate (300) in which a perforated hole (310) is formed, the wall coupling module.
The method of claim 8,
The separating plate 300 further comprises an adsorbent fixing part 320 for positioning the nano adsorbent 230B to face the perforated hole 310.
The method of claim 9,
The permeable wall body 200A includes an outer permeable wall body 200A-1 in which the permeable wall fastening part 240 and the permeable wall fitting part 250 are formed, and the outer permeable wall body 200A-1. It is located inside and includes an inner permeable wall body 200A-2 on which the foreign matter removing part 230 is formed, and the inner permeable wall body 200A-2 rotates on the outer permeable wall body 200A-1 Wall coupling module, characterized in that the coupling possible.

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