KR20200069027A - Permeable reactive barrier, Barrier module use permeable reactive barrier - Google Patents

Abstract

The present invention relates to a permeable reactive wall and a wall coupling module using the same. The permeable reactive wall comprises: a permeable wall having an inlet part through which fluid is introduced, an outlet part through which the fluid introduced through the inlet part is discharged, and a foreign substance removing part positioned between the inlet part and the outlet part to remove contaminants on the fluid moved from the inlet part to the outlet part; and a blocking wall restricting flow of the fluid, thereby preventing the contaminants mixed in underground water from being introduced into non-contaminated regions.

Description

Permeable reactive barrier, Permeable reactive barrier, Barrier module use permeable reactive barrier}

The present invention relates to a water permeable reaction wall and a wall bonding module using a water permeable reaction wall, and more specifically, to limit the movement of contaminated water located in the formation, but to purify the contaminated water that overflows, thereby The present invention relates to a permeable reaction wall capable of preventing expansion of a contaminated zone and a wall coupling module using a permeable reaction wall.

In general, the permeable reaction wall is a device mainly for controlling the diffusion of contaminants on the soil through the groundwater, and permeates the groundwater and adsorbs, fixes, and purifies the pollutants contained in the groundwater, thereby contaminating it in response to the flow of groundwater Prevent the material from spreading.

However, in the case of the conventional permeable reaction wall, since the entire wall was structured to permeate groundwater, the flow rate of contaminated groundwater increases, and when the pollutant on the groundwater exceeds the limit for removing pollutants from the permeable reaction wall, the pollutant If it is not blocked by the permeable reaction wall and passes through the reaction wall, it enters a non-contaminated area, and if the pollutant is a pollutant that cannot be removed, the pollutants along with groundwater There was a problem that it penetrated into the non-contaminated area after passing through the permeable reaction wall.

That is, the conventional permeable reaction wall blocks both contaminated areas and non-contaminated areas, and simultaneously serves to remove contaminants contained in groundwater moving from non-contaminated areas to contaminated areas. When it exceeds a certain level, it not only loses the ability to remove pollutants, but also, if the pollutants are substances that are difficult to adsorb, fix, and purify, it can pass through the pollutants as it is to prevent contamination of non-polluted areas. It was not.

Accordingly, there is a need for a new water-permeable reaction wall that can solve the problems of the conventional water-permeable reaction wall and a reaction wall coupling module using the same.

Patent Literature 1) Korean Registered Patent Publication No. 10-0529301 (Name: Method for restoring reactivity of permeable reaction walls for purification of polluted groundwater, Publication date: March 21, 2005)

The present invention has been devised to solve the problems as described above, and the object of the present invention is a permeable reaction wall capable of restricting contaminants from moving to a non-contaminated area in the case of contaminants that are difficult to adsorb, fixate, and purify, It is to provide a wall coupling module using the same.

In addition, blocking the saturation zone to limit the transfer of contaminants to the non-contaminated zone, but by allowing only the contaminants that overflow the unsaturated zone to be removed by the permeable reaction wall, the ability to remove contaminants from the permeable reaction wall is exceeded. It is to provide a water permeable reaction wall that can be prevented and a wall bonding module using the same.

The permeable reaction wall according to the present invention for achieving the above object includes an inlet portion 110 through which fluid is introduced, an outlet portion 120 through which the fluid introduced through the inlet portion 110 is discharged, and A permeable wall that is located between the inlet part 110 and the outlet part 120 and is composed of a foreign material removing part 130 that removes contaminants from the fluid moving from the inlet part 110 to the outlet part 120. (100); characterized in that it comprises a.

In addition, the foreign matter removal unit 130 is an adsorption space 131 formed on the permeable wall 100, and a nano-adsorbent 132 that adsorbs contaminants on the fluid that is located on the adsorption space 131 and passes therethrough. It characterized in that it comprises a.

In addition, it further includes a blocking wall 200 that supports the lower side of the permeable wall 100 and restricts the flow of fluid, and the inlet part 110 and the outlet part 120 are of the permeable wall 100. It is characterized in that the blocking wall (200) on the lower side is spaced apart from each other on one side and the other side in the thickness direction.

In addition, it characterized in that it further comprises an aeration portion 300 to release the gas from the lower side of the inlet portion 110 to move the fluid to the inlet portion 110.

In addition, it is located on one side in the thickness direction of the permeable wall 100, further comprising a guide portion 400 for guiding the movement of the fluid moving from the aeration portion 300 to the inlet portion 110 do.

In addition, it is located on one side in the thickness direction of the permeable wall 100, further comprising a guide portion 400 for guiding the movement of the fluid moving from the aeration portion 300 to the inlet portion 110 do.

In addition, the blocking wall 200 protrudes to one side in the thickness direction in which the inlet portion 110 is located at both ends in the width direction of the central blocking wall 200A and the central blocking wall 200A extending in the width direction. It includes an edge blocking wall (200B) that is inclinedly coupled to the central blocking wall (200A), the permeable wall (100) width direction along the central blocking wall (200A) above the central blocking wall (200A) It characterized in that it comprises a central permeable wall (100A) that is formed to extend, and the edge permeable wall (100B) is formed to extend obliquely along the edge barrier wall (200B) on the upper side of the edge barrier wall (200B).

In addition, the blocking wall 200 is located on a saturated zone, and the permeable wall 100 is characterized in that it is located on an unsaturated zone.

In addition, a fastening portion is formed at one end in the width direction of the edge permeable wall 100B and the edge blocking wall 200B, and at the other end in the width direction of the edge permeable wall 100B and the edge blocking wall 200B. Characterized in that the fitting portion having a shape corresponding to the fastening portion is formed.

In addition, the inlet portion 110 and the outlet portion 120 are respectively formed on one side in the thickness direction and the other side in the thickness direction of the permeable wall 100, and the outlet portion 120 is the inlet portion 110 It is characterized in that it is located on the lower side.

The wall bonding module according to the present invention for achieving the above object, a plurality of the permeable reaction walls are arranged in the width direction, the permeability reaction adjacent to each other among the plurality of the permeable reaction walls arranged in the width direction Characterized in that the fastening portion and the fitting portion of the wall are coupled to each other.

In the water permeable reaction wall of the present invention, the blocking wall that blocks the movement of the fluid and the permeable wall that removes the contaminants in the fluid that is permeable and permeable are disposed vertically above each other, so that only contaminants flowing into the unsaturated zone can be selectively removed. There are advantages.

In addition, since the flow rate of the groundwater containing contaminants moving from the saturation zone to the unsaturation zone can be controlled using an aeration device, there is an advantage that the amount of contaminants flowing into the permeation wall can be adjusted to an amount that the permeation wall can remove.

In addition, there is an advantage in that aerobic microorganisms can be activated on the permeable wall by controlling a gas component used in the aeration device.

In addition, since a plurality of permeable reaction walls are connected to each other to form a single wall coupling module, even if the contaminated area is wide, there is an advantage that the contaminated area and the non-contaminated area can be separated by using the wall coupled module.

1 is a perspective view showing a permeable reaction wall according to the present invention.
2 is an AA cross-sectional view showing a water-permeable reaction wall according to a first embodiment of the present invention.
3 is an AA cross-sectional view showing a water permeable reaction wall according to a second embodiment of the present invention.
4 is an AA cross-sectional view showing a water-permeable reaction wall according to a third embodiment of the present invention.
5 is a perspective view showing a water permeable reaction wall according to a fourth embodiment.
6 is a perspective view showing a water-permeable reaction wall according to a fifth embodiment.
7 is a BB cross-sectional view of the permeable reaction wall according to the fifth embodiment.

Advantages and features of embodiments of the present invention, and methods of achieving them will be apparent with reference to embodiments described below in detail together with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but may be implemented in various different forms, and only the embodiments allow the disclosure of the present invention to be complete, and common knowledge in the technical field to which the present invention pertains. It is provided to completely inform the person having the scope of the invention, and the present invention is only defined by the scope of the claims. The same reference numerals refer to the same components throughout the specification.

In describing embodiments of the present invention, when it is determined that a detailed description of known functions or configurations may unnecessarily obscure the subject matter of the present invention, the detailed description 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 a user's or operator's intention or practice. 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 water permeable reaction wall 1000 and the wall coupling module.

1 is a perspective view showing a water permeable reaction wall 1000 according to the present invention.

Referring to Figure 1, the present invention permeable reaction wall 1000 is a permeable wall 100 for permeating a fluid and removing contaminants in the fluid by any one or more methods selected among adsorption, fixation, and purification, and the flow of fluid It comprises a blocking wall 200 to limit the.

In detail. In general, since contaminants spread by underground water in the ground and contaminate the surrounding area, the blocking wall 200 is placed on the saturated zone of the ground, and the permeable wall 100 is placed on the unsaturated zone of the ground, The blocking wall 200 blocks the flow of groundwater located in the saturation zone to prevent contaminants from spreading through the saturation zone to the non-contaminated area, and when the groundwater on the saturation zone overflows and moves to the unsaturated zone, the permeable wall It is to prevent pollutants from entering the non-polluting area by removing contaminants mixed with the groundwater at the same time as the (100) penetrates the contaminated groundwater.

At this time, it is an embodiment to place the permeable wall 100 and the blocking wall 200 in a saturated zone and an unsaturated zone, respectively, and each wall length and position corresponds to the installation environment and purpose of the permeable reaction wall. Of course, it can be changed.

2 is an A-A cross-sectional view showing a water permeable reaction wall 1000 according to the first embodiment.

Referring to FIG. 2, the permeable wall 100 includes an inlet portion 110 through which fluid is introduced, an outlet portion 120 through which the fluid introduced through the inlet portion 110 is discharged, and the inlet portion 110. ) Is located between the outlet portion 120 and includes a debris removing unit 130 for removing contaminants in the fluid moving from the inlet portion 110 to the outlet portion 120, and the debris removing portion ( 130 may include an adsorption space 131 formed on the permeable wall 100 and a nano-adsorbent 132 that is located on the adsorption space 131 and adsorbs contaminants on the fluid passing therethrough.

In detail, the permeable wall in which the inlet portion 110 is located on one side in the thickness direction of the permeable wall 100 in which contaminants are located and the non-contaminated area protecting the outlet portion 120 from contaminants ( 100) to the other side of the thickness direction, the contaminants mixed ground water is introduced into the inlet 110 and then discharged to the outlet 120, but between the inlet 110 and outlet 120 By positioning the debris removal unit 130, the groundwater flowing into the inlet 110 can be discharged to the non-polluted area through the outlet 120 after the contaminants are removed from the debris removal unit 130. .

At this time, the nano-adsorbent 132 located on the foreign matter removal unit 130 may be a porous material having a plurality of pores of nano-micro size to which contaminants are adsorbed or attached as a porous material, and the permeable wall 100 ) May be a nanostructure formed by stacking nanotubes extending in the thickness direction, and in addition, various materials capable of removing contaminants on the groundwater that can pass through the groundwater.

In addition, a plurality of the porous material and the nano-structure may be disposed in a cartridge form to form the nano-adsorbent 132.

In detail, in the case of the nano-adsorbent 132, if a certain amount of contaminants is attached, the purification ability to remove the contaminants mixed in the ground water is lost, and at this time, the nano-adsorbent 132 must be replaced. By forming a plurality of porous materials or nanostructures in the thickness direction of the permeable wall 100 to form a nano-adsorbent 132, any one of the plurality of porous materials or nanostructures loses its purification capacity when it loses its purification capacity Alternatively, the nanostructures can be replaced or removed.

In addition, it is recommended that the inlet portion 110 and the outlet portion 120 are formed to be spaced apart from each other with the blocking wall 200 disposed below the permeable wall 100.

In detail, when the inlet portion 110 and the outlet portion 120 are formed on one side and the other side in the thickness direction of the permeable wall 100, the internal flow path of the permeable wall 100 is the thickness of the permeable wall 100. It is formed in the direction, the ground water flow path on the nano-adsorbent 132 through which the ground water passes is shortened, the problem of the adsorption efficiency of the nano-adsorbent 132 may decrease, so in the present invention, the inlet portion 110 is passed through the permeable wall ( 100) is formed on the bottom of one side in the thickness direction, the outlet portion 120 is formed on the other side in the bottom of the thickness direction of the permeable wall 100, the path through which the ground water passes through the nano-adsorbent 132 is the nano-adsorbent 132 It was made to have a sufficient length to remove contaminants mixed with groundwater.

3 is an A-A cross-sectional view showing a water-permeable reaction wall 1000 according to a second embodiment.

Referring to FIG. 3, the permeable wall 100 may further include an aeration part 300 that discharges gas from the lower side of the inlet part 110 to direct the movement of the fluid to the inlet part 110. .

In detail, when the inlet portion 110 and the outlet portion 120 are formed below the permeable wall 100, the flow rate of the groundwater flowing into the inlet portion 110 is reduced. By discharging the gas under the inlet 110 using 300, the gas particles rise and push the groundwater so that the groundwater flows into the inlet 110.

At this time, the aeration part 300 may include a pump 310 for sucking gas, and a pipe 320 for discharging the sucked gas from under the inlet part 110, wherein the pump 310 is a control part By the amount of the gas discharged to the pipe 320 is formed to be adjustable, the user can control the flow rate of the groundwater flowing into the inlet 110 by adjusting the control unit.

That is, it is possible to control the control unit so that the nano-adsorbent 132 flows into the inlet 110 only in an amount of groundwater capable of removing pollutants more efficiently.

In addition, the gas supplied by the aeration unit 300 may be oxygen or air containing oxygen capable of culturing aerobic microorganisms capable of decomposing contaminants attached to the nanoadsorbent 132.

In detail, in the case of the nano-adsorbent 132, the contaminants mixed in the ground water are removed by adsorption and fixation, and when more than a certain amount of contaminants are attached to the nano-adsorbent 132, the purification ability is reduced.

Therefore, in the present invention, by supplying oxygen or air to the nano-adsorbent 132 through the aeration unit 300, by breeding aerobic microorganisms capable of decomposing contaminants on the nano-adsorbent 132, the nano-adsorbent 132 It made it possible to use for a longer period of time.

4 is an A-A cross-sectional view showing a water permeable reaction wall 1000 according to a third embodiment.

Referring to Figure 4, the permeable wall 100 is located on one side in the thickness direction of the permeable wall 100, a guide portion for guiding the movement of the fluid moving from the aeration portion 300 to the inlet portion 110 ( 400) may be further included.

In detail, as described above, the aeration part 300 injects gas to flow groundwater into the inlet part 110. At this time, since the gas discharged to the aeration part 300 does not flow into the inlet part 110 but may spread out to the outside, in the present invention, the guide part 400 on one side in the thickness direction of the permeable wall 100 To form the gas discharged from the aeration unit 300 and the movement of the ground water moving by the gas is directed toward the inlet unit 110.

5 is a perspective view showing the permeable reaction wall 1000 according to the fourth embodiment.

1 and 5, the blocking wall 200 includes a central blocking wall 200A extending in a width direction, and the inlet portions 110 at both ends in the width direction of the central blocking wall 200A. And an edge blocking wall 200B inclinedly coupled with the central blocking wall 200A so as to protrude toward one side in the thickness direction, and the permeable wall 100 is the central blocking wall above the central blocking wall 200A. It includes a central permeable wall (100A) formed to extend in the width direction along (200A), and an edge permeable wall (100B) is formed to extend obliquely along the edge blocking wall (200B) above the edge blocking wall (200B) can do.

Then, a fastening portion 20 is formed at one end in the width direction of the edge permeable wall 100B and the edge blocking wall 200B, and the width direction of the edge permeable wall 100B and the edge blocking wall 200B A fitting part 30 having a shape corresponding to the fastening part may be formed at the other end.

In detail, when the non-contaminated area for protecting from contaminants is widened, a plurality of the permeable reaction walls 1000 are connected to each other, so that the plurality of permeable reaction walls must separate the contaminated area and the non-contaminated area from each other. , In the present invention, the fastening portion 20 is formed on one side in the width direction of the permeable reaction wall 1000, and the fitting portion 30 is fitted on the fastening portion 20 on the other side in the width direction of the permeable reaction wall 1000. By forming, when the area for protecting from contaminants is wide, a plurality of permeable reaction walls are arranged in the width direction, and among the number of permeable reaction walls arranged in the width direction are adjacent to each other. The fastening part and the fitting part are combined with each other to form a wall coupling module.

6 is a perspective view showing a water-permeable reaction wall 1000 according to a fifth embodiment, and FIG. 7 is a B-B cross-sectional view of the water-permeable reaction wall 1000 according to a fifth embodiment.

6 and 7, in the permeable reaction wall 1000 according to the present invention, the inlet portion 110 and the outlet portion 120 are formed on one side in the thickness direction and the other side in the thickness direction of the permeable wall 100. It may be, the outlet 120 may be a structure that is located below the inlet 110.

In detail, in order to remove foreign substances mixed in the groundwater having a higher flow rate and send it to the non-polluted area, the entire permeable reaction wall 1000 is made of the permeable wall 100.

At this time, if the inlet portion 110 and the outlet portion 120 located on one side in the thickness direction of the permeable wall 100 are positioned facing each other on the same line, through the foreign material removing portion 130 in the inlet portion 110 Since the movement path of the groundwater moving to the outlet portion 120 is shortened, in the present invention, the inlet portion 110 and the outlet portion 120 are asymmetrically positioned above and below each other, so that the groundwater moves on the foreign matter removing portion 130 It is a long moving path.

In addition, in the present invention, a plurality of permeable reaction walls 1000 may be arranged in combination to form a single wall module, and a water collecting well for collecting or passing groundwater may be located between the permeable reaction walls.

In detail, a fitting part coupled to the fastening part of the water permeable reaction wall is formed on one side in the width direction of the water collecting well, and a fastening part is formed on the other side in the width direction of the water collecting well to form a fastening part to which the fitting part of the water permeable reaction wall is coupled. The sex reaction wall is coupled to each other through a fastening part and a fitting part to form a single wall module.

At this time, in the case of the central space where the slit through which the groundwater passes is formed on the surface of the collecting well and the nanoadsorbent that purifies the groundwater moving through the slit may be located in the center, and the nanoadsorbent is located to minimize the consumption of the nanoadsorbent. The nano-adsorbent may be located in only one of two spaces separated from each other by the slit-formed partition wall and separated by the partition wall.

In addition, as a method for reducing the consumption of the nano-adsorbent, the nano-adsorbent fixing portion for positioning the nano-adsorbent only at a position facing the slit may be formed on the partition wall.

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

100: permeable wall 100A: central permeable wall
100B: Edge permeable wall
110: inlet 120: outlet
130: foreign matter removal unit
131: adsorption space 132: nano adsorbent
200: barrier wall 200A: central barrier wall
200B: Edge blocking wall
300: aeration
400: guide unit

Claims (10)

According to claim 1,
It is located between the inlet part 110 through which the fluid is introduced, the outlet part 120 through which the fluid introduced through the inlet part 110 is discharged, and the inlet part 110 and the outlet part 120, It characterized in that it comprises a; permeable wall (100) comprising a foreign material removal unit 130 for removing contaminants from the fluid moving from the inlet 110 to the outlet 120.
According to claim 1,
The debris removal unit 130 comprises an adsorption space 131 formed on the permeable wall 100 and a nano-adsorbent 132 that is located on the adsorption space 131 and adsorbs contaminants on the fluid passing therethrough. It characterized in that it comprises, a permeable reaction wall.
According to claim 2,
Supporting the lower side of the permeable wall 100 further comprises a blocking wall 200 for limiting the flow of fluid,
The inlet portion 110 and the outlet portion 120 is characterized in that spaced apart from each other on one side and the other side in the thickness direction with the blocking wall 200 interposed therebetween under the permeable wall 100. Reaction wall.
According to claim 3,
It characterized in that it further comprises an aeration portion (300) to discharge the gas from the lower side of the inlet portion (110) to move the fluid to the inlet portion (110).
The method of claim 4,
Characterized in that it is located on one side in the thickness direction of the permeable wall 100, further comprising a guide portion 400 for guiding the movement of the fluid moving from the aeration portion 300 to the inlet portion 110, Permeable reaction wall.
The method according to any one of claims 3 to 5,
The blocking wall 200 is formed so as to protrude toward one side in the thickness direction in which the inlet portions 110 are located at both ends in the width direction of the central blocking wall 200A and the central blocking wall 200A extending in the width direction. Includes an edge blocking wall (200B) inclinedly coupled with the central blocking wall (200A),
The permeable wall 100 is a central permeable wall (100A) formed to extend in the width direction along the central barrier wall (200A) on the upper side of the central barrier wall (200A), and the upper edge of the barrier wall (200B) And an edge permeable wall (100B) formed to extend inclined along the edge blocking wall (200B).
The method of claim 6,
The barrier wall 200 is positioned on a saturated zone, and the permeable wall 100 is characterized in that positioned on an unsaturated zone, the permeable reaction wall.
The method of claim 6,
A fastening portion is formed at one end in the width direction of the edge permeable wall 100B and the edge blocking wall 200B, and the fastening portion is formed at the other end in the width direction of the edge permeable wall 100B and the edge blocking wall 200B. Characterized in that the fitting portion having a shape corresponding to, is formed, permeable reaction wall.
In the wall bonding module using the water permeable wall of claim 8,
A plurality of the water-permeable reaction walls are arranged in the width direction, characterized in that the fastening portion and the fitting portion of the water-permeable reaction walls adjacent to each other of the plurality of water-permeable reaction walls arranged in the width direction are coupled to each other, the wall Combined module.
According to claim 2,
The inlet part 110 and the outlet part 120 are respectively formed on one side in the thickness direction and the other side in the thickness direction of the permeable wall 100, and the outlet part 120 is lower than the inlet part 110. Characterized in that, it is permeable reaction wall.

Images