KR200242963Y1 - Restitutive system for polluted soil - Google Patents

Abstract

The present invention relates to a contaminated soil restoration system, and to form a predetermined pressure gradient in the soil to extract the gas-liquid contaminants present in the soil, or to inject air into the soil to the biodegradation of contaminants A plurality of well members installed; Adsorption means connected to the well member by a first flow path to suck contaminated vapor selectively among contaminants selectively extracted from each well member to remove organic substances present in the contaminated vapor; An air injection member connected to the well member by a second flow path to suck air in the air and selectively inject the air into the well member; And relay means for selectively opening and closing the first and second flow paths, and supplying contaminated vapor extracted from the well member to the adsorption means by a predetermined pumping force, or supplying air in the air to the air injection member. Extraction of material and injection of air can be carried out at the same time, and extraction or air injection can be carried out selectively if necessary, thereby providing a contaminated soil restoration system that improves workability and purification efficiency.

Description

Polluted soil recovery system {Restitutive system for polluted soil}

The present invention relates to a contaminated soil restoration system, and more particularly, to a contaminated soil restoration system having a structure integrating soil vapor extraction (SVE) and air injection (BV).

In recent years, as the industrialization accelerates, the consumption of oil increases rapidly, and the soil pollution caused by oil becomes a serious environmental problem in proportion to the increase of the oil storage facility and the traffic handling volume.

As such, the technology for restoring soil contaminated by oil is classified into physical, chemical, and biological technologies according to the restoration method, and in-situ and ex-situ technologies are used according to the location of restoration. Are classified. And, depending on the contaminated media (media) can be classified into soil and groundwater.

The underground treatment method forms the air between the soil with a pressure gradient lower than atmospheric pressure to make the soil in a vacuum state, and when the air is extracted to the outside, the volatile and semi-volatile pollutants existing between the pores of the soil are vaporized and Soil Vapor Extraction (SVE) using the principle that is discharged along with the air, and Bio Venting (BV) that increases the activity of microorganisms by forcibly injecting air into the soil to increase the oxygen concentration of the soil. .

However, the soil vapor extraction method (SVE) is relatively easy to install, inexpensive, suitable for the restoration of extensively contaminated soils, and effective for unsaturated aquifers, but is not able to purify saturated ground or groundwater contaminants. There is a disadvantage, the air injection method causes a change in the environment of the soil due to the increase in the concentration of oxygen in the soil, there is a disadvantage that requires a lot of purification time.

In order to overcome this, recently, there is a trend to research and develop a technique that combines the air injection method with the soil vapor extraction technique.

The present invention was created to improve the above problems, and it is possible to purify the unsaturated aquifer and the saturated soil pollutants by an automated device by unmanned operation, and in particular, the extraction of the pollutants and the air injection can be performed simultaneously. The aim is to provide a contaminated soil remediation system with a structure that can selectively perform any operation as needed.

1 is a schematic diagram of a device showing a contaminated soil restoration system according to a preferred embodiment of the present invention.

2 is a cross-sectional view showing the vacuum container shown in FIG.

3 is a cross-sectional view showing the adsorption means shown in FIG.

4 is a cross-sectional view showing the air injection member shown in FIG.

5 is a cross-sectional view showing the relay means shown in FIG.

FIG. 6 is a table for explaining an operating state of the valve body shown in FIG. 5 according to an embodiment. FIG.

7 to 9 is a device configuration for explaining the operation of the contaminated soil restoration system according to a preferred embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

10 ... well member 20 ... vacuum vessel

30 ... control unit 40 ... adsorption means

50 ... Air injection member 60 ... Relay means

The present invention for achieving the above object, to form a predetermined pressure gradient in the soil to extract the gas-liquid contaminants present in the soil, or to inject air into the soil to biodegrade the contaminants A plurality of well members installed in the ground; Adsorption means connected to the well member by a first flow path to suck contaminated vapor selectively among contaminants selectively extracted from each well member to remove organic substances present in the contaminated vapor; An air injection member connected to the well member by a second flow path to suck air in the air and selectively inject the air into the well member; And relay means for selectively opening and closing the first and second flow paths, and supplying contaminated vapor extracted from the well member to the adsorption means by a predetermined pumping force, or supplying atmospheric air to the air injection member. It is provided.

In addition, at least one vacuum container having a predetermined sealed space to accommodate the contaminant extracted from the well member is preferably further provided.

The vacuum container may include: an inlet hole communicating with each well member such that the gas-liquid contaminant extracted from the well member can be introduced into the closed space through a suction line; An outlet hole communicating with the first channel to supply the contaminated vapor of the contaminant to the adsorption means; A level sensor for detecting the level of contaminated water among the contaminants; A drain member that is turned on and off in accordance with the level of water sensed by the level sensor to selectively discharge the polluted water to maintain a constant level of the polluted water; A temperature sensor for sensing the temperature of the contaminated water; And a heating member on-off according to the temperature sensed by the temperature sensor to selectively heat the contaminated water to maintain a constant temperature of the contaminated water.

In addition, by detecting the detection signal of the water level sensor to selectively turn on or off the drain member according to the reference level of the contaminated water, or by detecting the detection signal of the temperature sensor to the heating according to the reference set temperature of the contaminated water It is preferable to further include a control unit for selectively turning on or off the operation of the member.

The suction means includes: at least one suction tank having a predetermined accommodation space, the suction port selectively communicating with the sealed space of the vacuum container, and the discharge port communicating with the outside; And activated carbon provided in the suction tank to adsorb organic substances of the contaminated vapor sucked into the suction tank.

The air injection member may include: an air tank connected to each well member and an injection line so as to suck air from the atmosphere and selectively inject the air into the well member.

The relay means includes: a plurality of valve bodies provided on the respective first and second flow paths to selectively communicate the first and second flow paths by a user's operation; A first vacuum pump installed on the first flow path to supply the contaminated vapor extracted from the well member to the adsorption means; A second vacuum pump installed on the second flow path to supply air in the atmosphere to the air injection member; And a flow meter installed at a point at which the first and second flow paths join so as to selectively measure the flow rates of the contaminated vapor and air supplied by the first and second vacuum pumps.

Therefore, the present invention can perform the extraction of contaminants and the injection of air at the same time, and the extraction operation or the air injection operation can be carried out exclusively if necessary, workability and purification efficiency is improved, unsaturated aquifer, as well as saturated It is not only able to purify the source of soil or groundwater, but also has the characteristics that it can reduce the human resources by unmanned work.

Hereinafter, a contaminated soil restoration system according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIG. 1, a contaminated soil restoration system according to a preferred embodiment of the present invention includes a plurality of well members 10 for extracting contaminants present in soil or injecting air into the soil to biodegrade contaminants. ), A vacuum container 20 having a predetermined sealed space to receive the contaminant selectively extracted from the well member 10, and the contaminant vapor contained in the contaminant contained in the vacuum container 20 to remove organic substances. Suction means 40 for sucking air, an air injection member 50 for sucking air in the air, and selectively injecting the air into the well member 10, and an inflow between the vacuum vessel 20 and the suction means 40 Selectively opening and closing the path and the inflow path between the air and the air injecting member 50 and supplying contaminated vapor in the vacuum vessel 20 to the adsorption means 40 by a predetermined pumping force or supplying air in the air to the air injecting member 50. By It comprises a relay means (60) for the class.

The well member 10 is inserted into the ground of the contaminated area contaminated with oil, and forms a predetermined pressure gradient in the soil to flow the air of the ground soil to extract soil vapors in the soil. It has a conventional well structure used to apply (SVE). In addition, the well member 10 has a structure for applying the air injection method (BV) for biodegrading contaminants contained in the soil by injecting air into the soil.

The well member 10 has a pipe shape having a predetermined length with the upper and lower ends closed, and has a porous screen for introducing contaminated vapor and contaminated water into the inner space or supplying air from the ground to the soil. A wealth (not shown) is provided. The well member 10 is divided into five of the first to fifth well members 11-15 according to the number shown in the drawing for convenience, and more than that may be installed depending on the oil distribution in the contaminated area.

1 and 2, the vacuum vessel 20 is a suction line 21 is connected to the well member 10, respectively, so as to suck the contaminated vapor and contaminated water extracted from the well member 10. And an inlet hole 22 selectively communicating with the internal space of the well member 10 to allow the contaminated vapor and the contaminated water to flow therethrough, and the adsorption means 40 to supply the volatile contaminated vapor on the gas among the contaminants to the adsorption means 40. An outlet hole 23 selectively communicating with the means 40, and a discharge hole 24 for discharging the contaminated water in the liquid phase to a predetermined outside.

The vacuum container 20 is selectively turned on and off in accordance with the water level sensor 25 for detecting the level of the contaminated water among the contaminants contained in the sealed space and the amount of water detected by the level sensor 25. Is provided with a drain member 26 for discharging the outside to a predetermined.

The drain member 26 is installed at the lower end of the vacuum vessel 20 to a contaminated water in the vacuum vessel 20 by a predetermined pumping force, for example, as an oil separator (not shown) that typically separates liquid oil and water. And a check valve 26b for selectively opening and closing the discharge hole 24 by the pumping force of the drain pump 26a.

The vacuum vessel 20 is selectively heated on and off in accordance with the temperature sensor 27 for sensing the temperature of the contaminated water, the temperature detected by the temperature sensor 27, the heating member having a heating wire or a heating lamp 28 is installed.

The restoration system of the present invention receives the detection signal of the water level sensor 25 and converts it into a predetermined control signal, and compares the control signal with the preset level of the contaminated water to determine the drain member 26 according to the preset level of the contaminated water. It is provided with a control unit 30 to selectively turn on-off. In addition, the control unit 30 receives the detection signal of the temperature sensor 27 and converts it into a predetermined control signal, and compares the control signal with the preset temperature of the contaminated water according to the preset temperature of the contaminated water. 28) selectively on-off.

As shown in FIGS. 1 and 3, the suction means 40 is sucked into the suction tank 42 and at least one suction tank 42 connected to the vacuum container 20 by a predetermined first flow path 41. Activated carbon 44 for adsorbing the organic matter of the contaminated vapor is provided.

The suction tank 42 has a suction port 43 to which the first flow passage 41 is connected, and a discharge port 45 for discharging pure steam from which organic substances have been removed through the activated carbon 44 to the outside.

As shown in FIGS. 1 and 4, the air injection member 50 selectively sucks air sucked from the air into the well member 10 by a predetermined pumping force of the second vacuum pump (84 of FIG. 5). It is provided with an air tank 51 connected to each well member 10 and the injection line 51 to inject.

The air tank 51 is connected to the inlet hole 52 selectively communicates with the atmosphere, the outlet hole 54 communicated with the injection line 51, the inlet hole 52 and the vacuum vessel 20 and suction It has a second flow path 55 which is in selective communication with the first flow path 41 between the tanks 42.

As shown in FIGS. 1 and 5, the relay means 60 has a first flow path 41 between the vacuum vessel 20 and the suction means 40 and a second flow path between the air and the air injection member 50 ( 55 and a plurality of valve bodies 70 which are opened and closed by manual operation of a user so as to selectively communicate the first and second flow passages 41 and 55, respectively.

The valve body 70 is divided into twelve of the first to twelfth valve bodies 71-82 as many as shown in the figure for convenience, and more than that may be installed. That is, the valve body 70 selectively opens and closes the first flow passage 41 through the vacuum vessel 20 to the adsorption means 40 and the second flow passage 55 through the air to the air injection member 50. Contaminants may be extracted from the well member 10 or air may be injected into the well member 10, and contaminant extraction and air injection may be simultaneously performed.

The relay means 60 is installed on the first passage 41 between the vacuum vessel 20 and the adsorption means 40 to supply a contaminated vapor in the vacuum vessel 20 to the adsorption means 40. (83) and a second vacuum pump (84) provided on the second flow passage (55) between the atmosphere and the air injection member (50) for supplying air in the atmosphere to the air injection member (50).

The relay means 60 is installed at the point where the first and second flow paths 41 and 55 join, respectively, by the pumping force of the first and second vacuum pumps 83 and 84 and the adsorption means 40. It further includes a flow meter (85) for measuring the flow rate of the contaminated vapor and air supplied to the air injection member (50), respectively.

The operation of the contaminated soil restoration system according to a preferred embodiment of the present invention having the configuration as described above will be described in detail with reference to the accompanying drawings.

First, as shown in FIG. 7, in the case of extracting a gas-liquid contaminant from contaminated soil in the ground by forming a pressure gradient throughout the well member 10, as shown in FIGS. And a valve body on the side of the first flow passage 41 that passes through the suction means 40 as in Embodiment 1 while the second vacuum pumps 83 and 84 are in operation, that is, the first valve bodies 71 and the third to third valves. The seventh valve body (73-77) is operated to open the first passage (41), and the valve body on the side of the second passage (55) that communicates with the air injection member (50), that is, the second valve body (72). The second flow passage 55 is closed by operating the eighth through twelfth valve bodies 78-82.

Subsequently, the internal space of the well member 10 is maintained in a vacuum state by the pumping force of the first vacuum pump 83, and a predetermined pressure gradient is formed, and the contaminated vapor and contaminated water remaining in the soil are stored in the well member ( 10) is sucked into the internal space. That is, when the air in the soil is sucked into the inner space of the well member 10, the pollutant is sucked into the inner space of the well member 10 together with the air sucked along the most breathable area.

Next, the contaminants introduced into the inner space of the well member 10 are sucked into the closed space of the vacuum container 20 through the suction line 21 by the pumping force of the first vacuum pump 83.

At this time, the water level sensor 25 detects the level of the contaminated water among the contaminants introduced into the closed space of the vacuum vessel 20. Subsequently, the controller 30 receives the detection signal sensed by the water level sensor 25, converts it into a predetermined control signal, and then compares the control signal with a predetermined water level to determine the on-off operation of the drain member 26. do. That is, when the level of the contaminated water reaches the point A of FIG. 2 of the vacuum container 20 which is the predetermined highest level, the controller 30 receives a detection signal corresponding to the point A from the water level sensor 25. The detection signal is converted into a control signal to determine the comparison with the preset water level, and then the discharge hole 24 is opened by providing an ON signal to the drain pump 26a. Therefore, the contaminated water contained in the vacuum vessel 20 is discharged to the outside through the discharge hole 24 of the vacuum vessel 20 by the pressure difference.

When the level of the contaminated water reaches the point B (see FIG. 2) of the vacuum container 20 which is the predetermined lowest level while the contaminated water continues to be discharged through the discharge hole 24 of the vacuum container 20, the controller 30 ) Receives a detection signal corresponding to the point B from the water level sensor 25, converts the detection signal into a control signal, compares it with a predetermined level, and provides an off signal to the drain pump 26a to discharge the discharge hole ( Close 24). Therefore, the contaminated water is not discharged to the outside until the water level reaches the point A of the vacuum vessel 20.

At the same time, the temperature sensor 27 detects the temperature of the contaminated water among the contaminants introduced into the closed space of the vacuum vessel 20. Subsequently, the controller 30 receives the detection signal sensed by the temperature sensor 27, converts the signal into a predetermined control signal, and then compares the control signal with a preset temperature to determine the on-off operation of the heating member 28. do. That is, when the water temperature of the contaminated water drops to the predetermined minimum temperature, the controller 30 receives a detection signal corresponding to the minimum temperature from the temperature sensor 27, converts the detection signal into a control signal, and compares it with the preset water temperature. After the determination, the heating member 28 is provided with an ON signal to heat the contaminated water. Therefore, the contaminated water contained in the vacuum vessel 20 is raised to a predetermined temperature by the exothermic action of the heating member 28.

When the temperature of the contaminated water reaches a preset maximum temperature while the temperature of the contaminated water continues to rise due to the exothermic action of the heating member 28, the control unit 30 detects a temperature corresponding to the maximum water temperature from the water level sensor 25. The signal is received, the detection signal is converted into a control signal to be compared with the predetermined water temperature, and then the heating signal is provided to the heating member 28 to stop the heating. Therefore, the contaminated water is not heated until the predetermined maximum water temperature is reached.

As such, the reason for keeping the temperature of the contaminated water contained in the vacuum container 20 constant is to prevent the vacuum container 20 from freezing in the winter and to increase the volatilization efficiency by heating the contaminated water containing volatile substances. To do so.

In addition, to measure the extraction amount of the contaminant sucked into the accommodation space of the suction tank 42, as shown in Figure 5 and 6, the first valve body 71, the third to sixth valve body ( 73-76), the eighth and ninth valve bodies 78 and 79, and the eleventh valve body 81 are opened, and the remaining valve bodies are closed. Then, the flow rate of the contaminant sucked from the vacuum vessel 20 into the suction tank 42 along the first flow passage 41 is measured by the flowmeter 85 and displayed to the outside.

On the other hand, since the first flow path 41 is opened with the operation of the first vacuum pump 83, the contaminant vapor among the contaminants contained in the vacuum vessel 20 is applied to the pumping force of the first vacuum pump 83. The suction is sucked into the accommodation space of the suction tank 42 along the first flow passage 41.

Subsequently, the contaminated vapor sucked into the suction tank 42 passes through the activated carbon 44, and the organic substance is adsorbed while passing through the activated carbon 44. The pure steam from which the organic material is removed is discharged to the outside through the outlet 45 of the suction tank 42.

As shown in FIG. 8, when air is injected into the entire well member 10 to biodegrade contaminants, as shown in FIGS. 5 and 6, the first and second vacuum pumps 83 are shown in FIG. And 84, the valve body of the second flow path 55 to the air tank 51, that is, the second to sixth valve body (72-76), the tenth valve body ( 80 to operate the second flow passage 55 to open the valve body of the first flow passage 41 that leads to the suction means 40, that is, the first valve body 71 and the seventh to ninth valve bodies 77-. 79), the eleventh and twelfth valve bodies 81 and 82 are operated to close the first flow passage 41; Then, the air in the atmosphere is sucked by the second vacuum pump 84 and supplied to the internal space of the air tank 51 through the second flow path 55.

Next, the air tank 51 supplies the compressed air at a predetermined pressure to each well member 10. At this time, when the injection amount of air injected into the well member 10 is to be measured, as shown in FIGS. 5 and 6, the second to sixth valve bodies 72-76, the eighth and ninth valves. The sieves 78 and 79 and the twelfth valve body 82 are opened, and the remaining valve bodies are closed. Then, the flow rate of the air supplied to the air tank 51 along the second flow path 55 is measured by the flow meter 85 and displayed to the outside.

As shown in FIG. 9, when contaminants are extracted from the second to fourth well members 12-14 and air is to be injected into the first and fifth well members 11 and 15, FIG. As shown in FIG. 5 and FIG. 6, the first and second valve bodies 71 and 72 and the fourth valve body as in Embodiment 3 with the first and second vacuum pumps 83 and 84 operating. The 74th, 6th and 7th valve bodies 76 and 77 and the 10th valve body 80 are operated to open, and the remaining valve bodies are closed. Then, the contaminants may be extracted from the second to fourth well members 12-14 by the above-described operation, and air may be injected into the first and fifth well members 11 and 15.

At this time, in order to measure the extraction amount of the contaminant extracted from the second to fourth well members 12-14, the first and second valve bodies 71 and 72, the fourth valve body 74, and the first The six valve body 76, the eighth valve body 78, the tenth and eleventh valve bodies 80.81 are operated to open, and the remaining valve bodies are closed. Then, the flow rate of the contaminants sucked into the suction tank 42 along the first flow passage 41 from the second to fourth well members 12-14 is measured by the flow meter 85 and displayed to the outside. In addition, when the amount of air injected into the first and fifth well members 11 and 15 is to be measured, the first and second valve bodies 71 and 72, the fourth valve body 74, and the sixth and The seventh valve body 76, 77, the ninth valve body 79, and the twelfth valve body 82 are opened, and the remaining valve bodies are closed. Then, the flow rate of the air supplied to the air tank 51 along the second flow path 55 is measured by the flow meter 85 and displayed to the outside.

Therefore, the contaminated soil restoration system according to the present invention physically extracts contaminants distributed in contaminated soil from the entire well member 10 or injects air into each of the well members 10 to biodegrade the contaminants biologically. In addition, the contaminant can be extracted from the well member 10 and air can be injected into the well member 10 at the same time.

As described above, the contaminated soil restoration system according to a preferred embodiment of the present invention has the following effects.

First, the extraction of contaminants and the injection of air can be carried out at the same time, and the extraction work or the air injection work can be carried out as needed. Therefore, the unsaturated aquifer and saturated soil contaminants can be transferred to the automated device by unmanned work. Purification is possible, and workability is improved.

Second, human resources can be reduced because unmanned work is possible.

Claims (7)

A plurality of well members installed in the ground to form a predetermined pressure gradient in the soil to extract the gas-liquid contaminants present in the soil or to inject air into the soil to biodegrade the contaminants; Adsorption means connected to the well member by a first flow path to suck contaminated vapor selectively among contaminants selectively extracted from each well member to remove organic substances present in the contaminated vapor; An air injection member connected to the well member by a second flow path to suck air in the air and selectively inject the air into the well member; And Relay means for selectively opening and closing the first and second flow paths, and supplying contaminated vapor extracted from the well member to the adsorption means by a predetermined pumping force, or supplying atmospheric air to the air injection member; Polluted soil restoration system characterized in that it comprises. The method of claim 1, And at least one vacuum container having a predetermined sealed space to receive the contaminant extracted from the well member. The method of claim 2, The vacuum vessel is: An inlet hole communicating with each well member such that the gas-liquid contaminant extracted from the well member can be introduced into the sealed space through a suction line; An outlet hole communicating with the first channel to supply the contaminated vapor of the contaminant to the adsorption means; A level sensor for detecting the level of contaminated water among the contaminants; A drain member that is turned on and off in accordance with the level of water sensed by the level sensor to selectively discharge the polluted water to maintain a constant level of the polluted water; A temperature sensor for sensing the temperature of the contaminated water; And And a heating member turned on and off in accordance with the temperature sensed by the temperature sensor to selectively heat the contaminated water to maintain a constant temperature of the contaminated water. The method of claim 3, Determine the detection signal of the water level sensor to selectively turn on or off the drain member according to the reference level of the contaminated water, or determine the detection signal of the temperature sensor to determine the heating member according to the reference set temperature of the contaminated water. And a control unit for selectively turning on or off the operation. The method according to any one of claims 1 to 4, The adsorption means is: At least one suction tank having a predetermined accommodation space, the suction port selectively communicating with the sealed space of the vacuum container, and the discharge port communicating with the outside; And And activated carbon provided in the suction tank to adsorb organic substances of the contaminated vapor sucked into the suction tank. The method according to any one of claims 1 to 4, The air injection member is: And an air tank connected to each well member and an injection line so as to suck air from the atmosphere and selectively inject the air into the well member. The method according to any one of claims 1 to 4, The relay means is: A plurality of valve bodies provided on each of said first and second flow paths to selectively communicate said first and second flow paths by a user's operation; A first vacuum pump installed on the first flow path to supply the contaminated vapor extracted from the well member to the adsorption means; A second vacuum pump installed on the second flow path to supply air in the atmosphere to the air injection member; And And a flow meter installed at a point at which the first and second flow paths join so as to selectively measure the flow rates of the contaminated vapor and air supplied by the first and second vacuum pumps. Restore system.