KR102277891B1 - Observation well arrangement structure for natural reduction monitoring - Google Patents

Abstract

The present invention is to measure the pollution cloud located in the pollution cloud; Shear pipe measurement at the front end of the pollution cloud measurement in the progress direction of groundwater; It relates to an observation well arrangement structure for natural reduction monitoring, characterized in that it comprises a; rear end pipe measurement at the rear end of the pollution cloud pipe measurement in the progress direction of the groundwater.

Description

Observation well arrangement structure for natural reduction monitoring

The present invention relates to an observation well arrangement structure for natural mitigation monitoring.

Natural reduction technology defines the natural purification of pollutants and methods of using movement delays, which is a different concept from neglect, and evaluates the possibility of reaching the target purification level within a reasonable time compared to other active purification methods and accelerated technology that can shorten the purification time can be added.

Such natural reduction includes major mechanisms of natural reduction: microbial decomposition, dispersion, dilution, adsorption, volatilization, radioactive decay, chemical/biological stabilization, transformation, and destruction.

As an example to which the promotion technology should be applied, BTEX, which is one of the main substances of soil pollution, is a toxic substance and needs to be urgently removed from the soil. When pollutants enter the rock crushing layer, the flow of polluted groundwater is not homogeneous, and in some areas, it has a faster movement speed than the speed of natural reduction, making it difficult to manage polluted groundwater. Therefore, in order to promote the natural reduction in the ground, it is necessary to control the pollutants first by using a mechanism such as adsorption. The primary control is to reduce the concentration of the pollutant effluent or reduce the effluent rate to facilitate subsequent biological decomposition.

On the other hand, it is necessary to understand the exact scope of pollution cloud in such natural reduction, and monitoring of the application of such promotion technology, such as whether or not the movement of pollutants is blocked, is necessary when applying the above-mentioned natural reduction promotion technology. It is necessary to study the arrangement structure of observation wells for monitoring.

Korean Patent Registration No. 10-1600548

Accordingly, the present invention is to solve the above-mentioned problems, and to provide an observation well arrangement structure that enables integrated monitoring of natural abatement.

The observation well arrangement structure for natural reduction monitoring of the present invention (hereinafter referred to as "structure of the present invention") includes: pollution cloud measurement located in a pollution cloud; Shear pipe measurement at the front end of the pollution cloud measurement in the progress direction of groundwater; It characterized in that it comprises a; downstream pipe measurement at the rear end of the measurement of the pollution cloud in the progress direction of the groundwater.

As an example, the contamination cloud measurement is arranged as a pair on a second imaginary line orthogonal to the first imaginary line connecting the front end pipe measurement and the rear end pipe measurement, and four observation wells form a quadrangular diamond structure. .

As an example, on the second virtual line, a plurality of diamond structures formed by front-end tube measurement, rear-end tube measurement, and a pair of pollution management measurement are formed so that one pollution management measurement is shared in both directions or one direction of the pollution management measurement. characterized.

As an example, each observation well includes a foundation formed by pouring concrete so that the upper end of the observation well is exposed, and a protective tube configured on the upper surface of the foundation so that the upper end of the observation well is embedded in a tubular shape. do.

As an example, a fastening pipe fastened to the upper end of the protection pipe, a control jaw that is bent outside the fastening pipe at the upper end of the fastening pipe, and forms an acute angle with the fastening pipe, and an antibacterial applied to the surface exposed to the outside from the control jaw It is characterized in that it further includes an inflow blocker comprising a coating layer.

As an example, a mounting port including one or more fixing bars having a fastening ring formed at the end is configured at the upper end of the protective tube, and one end is fixed so as to be detachably attached to a cable equipped with a sensor, and is fastened to the fastening ring on the outer periphery. It is characterized in that the length adjustment clamp comprising a body formed with a hook is further configured.

As an example, the fixing bar is characterized in that it is made of an elastic material.

As described above, the structure of the present invention has the advantage that the range of pollution clouds in the target site and the processing process of pollution clouds such as blocking the movement of pollutants by applying various natural reduction promotion technologies can be optimally monitored. .

1 is a schematic diagram showing the structure of the present invention;
2 is a schematic diagram showing an operating state of the structure of the present invention;
3 is a schematic diagram showing another operating state of the structure of the present invention;
4 is a side cross-sectional view showing an embodiment of each observation well of the present invention.
5 is a side cross-sectional view showing another embodiment of each observation well of the present invention.
6 is a side cross-sectional view showing another embodiment of each observation well of the present invention.

Hereinafter, embodiments of the present invention will be described in more detail with reference to the accompanying drawings.

The structure (1) of the present invention includes: a pollution cloud measurement (2) located in a pollution cloud as shown in FIG. 1; A shear pipe measurement (3) at the front end of the contamination pipe measurement (2) in the progressing direction of the groundwater; It is characterized in that it includes; a rear end pipe measurement (4) at the rear end of the contamination pipe measurement (2) in the progress direction of the groundwater.

As shown in FIG. 1, the contamination pipe measurement 2 is a pair on a second imaginary line 6 orthogonal to the first imaginary line 7 connecting the front end pipe measurement 3 and the rear end pipe measurement 4 It is characterized in that the four observation wells (2, 3, 4) form a quadrangular diamond structure (5).

In this way, a pair of pollution cloud measurement (2) is configured in the pollution cloud prediction area. As shown in the example shown in FIG. 1, if the pollution cloud is observed in only one pollution cloud measurement (2) as shown in FIG. 2, as shown in FIG. The position and extent of the pollution cloud can be monitored while extending the diamond structure 5 laterally so that the observed pollution cloud measurement 2 is shared.

Here, observations from all observation wells 2, 3, 4, such as pollution cloud measurement (2), are not shown in the drawings, but the cables inserted into each observation wells 2, 3 and 4, and one end of the cable, are a sensor cable including a sensor for deriving a sensing value from groundwater; a data logger connected at the other end of the cable to store a value sensed by the sensor; a central server receiving the sensed value from the data logger and analyzing the sensed value; It is reasonable that the analysis value derived from the central server is performed by a system including a monitor unit that is displayed.

The sensor cable is configured to include a cable inserted into the observation unit, and a sensor mounted on one end of the cable to derive a sensing value from groundwater. The value sensed in groundwater is characterized in that it is at least one of groundwater level, water temperature, electrical conductivity, and pH. For example, by measuring the electrical conductivity of groundwater, it is possible to derive a change in the degree of pollution for each location of the observation well.

The data logger is connected at the other end of the cable and corresponds to a configuration for storing values sensed by the sensor. In addition to the function of storing the value sensed by the sensor, the data logger also performs a communication function of transmitting the stored value to the central server to be described below. Since various known technologies exist for such a data logger, a detailed description thereof will be omitted.

The central server receives the sensed value from the data logger and performs a function of analyzing the sensed value. For example, as shown in Fig. 3, the natural reduction promotion technology such as injection of liquid activated carbon is applied to one shear pipe measurement (3-1), and the natural reduction promotion technique is not applied to the other shear pipe measurement (3-2). By comparing the sensing values sensed by the downstream pipe measurements (4-1, 4-2) that are opposite each other in the flow direction of the groundwater in the state, it is possible to derive data on whether the purification of pollutants by natural reduction is being performed, The speed at which the purification takes place can be derived, and a natural reduction model can be derived in the future based on such data.

Here, the mechanism for deriving a natural reduction model in the future may be configured in various ways, so a detailed description thereof will be omitted.

The shear pipe measurement (3) is configured at the front end of the contamination management pipe measurement (2) in the direction of groundwater flow, and as a point to apply the natural reduction promotion technology such as liquid activated carbon injection as well as observation by the above-mentioned groundwater sensing. function.

The rear end pipe measurement (4) is configured at the rear end of the contamination pipe measurement (2) in the progress direction of the groundwater, and corresponds to the configuration in which the above-mentioned observation by sensing of the groundwater is made.

That is, by comparing the sensing values made in the opposite front end pipe measurement (3) and the rear end pipe measurement (4), the speed of natural reduction when the acceleration technology is not applied, the speed of natural reduction when the acceleration technology is applied, and whether the movement of pollutants is blocked, etc. this can be done

In addition, the present invention provides an example of accurately monitoring the range and location of the pollution cloud by the enlargement of the observation wells 2, 3, and 4, that is, the enlarged structure of the diamond structure 5 in either direction or in one direction as shown in FIG. is showing

In this embodiment, as shown in FIG. 2 , on the second imaginary line 6, one contamination measurement 2 is shared in either direction or in one direction of the contamination measurement 2, respectively, so that one contamination measurement 2 is shared at the front end 3 and the rear end, respectively. It is characterized in that a plurality of diamond structures (5) formed by observation wells (4) and a pair of contamination observations (2) are formed.

With this structure, in each diamond structure 5, each front end tube measurement 3 is located on the third virtual line 8 at a position parallel to the second virtual line 6, and each rear end tube measurement 4 is located on the second It will be located on the fourth virtual line 9 at a position parallel to the virtual line 6 .

The expansion so that one pollution cloud measurement 2 is shared in both directions or one direction of the pollution cloud measurement 2 means that when the observation is started from the diamond structure 5 located on the outermost side of the drawing, the pollution cloud is spread in one direction. As the observed pollution cloud measurement (2) is shared, the diamond structure (5) is expanded, and if no pollution cloud is observed in the other non-shared pollution cloud measurement (2) among the expanded diamond structures (5), an enlarged structure is completed, and the extent and location of pollutants can be observed in this enlarged structure.

In addition, when the observation starts from the diamond structure 5 located in the center of the drawing, that is, when the pollution cloud is observed in both of a pair of pollution cloud measurement 2, the pollution cloud measurement 2 is shared in both directions and the diamond structure ( 5) is expanded and if no pollution cloud is observed in the measurement (2) of the other side of the pollution cloud that is not shared, the enlarged structure is completed, and the range and location of the pollution source are observed in this enlarged structure.

In addition, examples for each observation well (2, 3, 4) are shown in Figs. 4 to 6, which are shown based on the pollution cloud measurement (2), but other observation wells (3, 4) also It goes without saying that the same application is possible. Hereinafter, each embodiment will be described on the basis of the pollution cloud measurement (2).

First, in FIG. 4 , the foundation 22 is formed by pouring concrete so that the upper end of the pollution cloud measurement 2 is exposed, and the foundation 22 is built into the upper end of the pollution cloud measurement 2 in a tubular shape. ) presents an example in which the protective tube 23 configured on the upper surface is further configured.

The lower end of the pollution cloud measurement (2) is buried below the groundwater level so that the sensor derives various sensing values of the groundwater at the position of the pollution cloud measurement (2), and the upper part is buried so as to be exposed above the ground.

The base part 22 is formed by pouring concrete so that the upper end of the pollution control measurement 2 is exposed, and the reason for configuring the base part 22 is that the monitoring process of natural reduction is the progress process such as biological decomposition. As a long-term observation is required to be monitored, it is to ensure that the contamination measurement (2) and the protection tube (23) are firmly fixed, and organisms that flow on the ground are introduced into the contamination control measurement (2) and become contaminated, It is to allow the base unit 22 to primarily control problems such as sensing errors.

The protection tube 23 is configured in the upper surface of the base part 22 so that the upper end of the pollution control measurement 2 is embedded in a tubular shape so that the position of the pollution measurement 2 is easily recognized, as well as living organisms, etc. This is to control the inflow into the pollution control measurement 2 secondarily so that the above-mentioned problems such as pollution and sensing error are controlled.

In addition, in the present invention, as shown in FIG. 5 , the inflow blocking port 24 is configured to further increase the blocking efficiency of the inflow of living organisms into the pollution management measurement 2 to prevent contamination, sensing errors, and equipment failure. An example is given.

The inflow blocker 24 includes a fastening pipe 241 fastened to the upper end of the protective pipe 23 and a fastening pipe 241 bent outward from the fastening pipe 241 at the upper end of the fastening pipe 241, and the fastening pipe 241 and It characterized in that it comprises a control jaw 242 forming an acute angle and an antibacterial coating layer 243 applied to the surface exposed to the outside from the control jaw 242.

By the configuration bent at an acute angle in the fastening pipe 241 of the control jaw 242, the inflow of the living organism coming up from the ground is blocked to the measurement (2), and by the configuration of the antibacterial coating layer 243 This is to prevent insects, etc. from entering the inside of the pollution control measurement (2).

It is appropriate that the antibacterial coating layer 243 contains an antibacterial agent and an antifouling agent based on a resin.

By the addition of the antibacterial agent, the access of various insects and the like is controlled. Preferably, it is reasonable that the antimicrobial agent is an organic antibacterial agent. Cashew tree fruit extract may be used as an organic antibacterial agent. Cashew tree fruit extract contains cardanol and cardol as main ingredients and has an aromatic molecular structure, and strong natural organic antibacterial functions such as strong antibacterial, antifungal, antimicrobial, insect repellent, and antiseptic are expressed. It has high affinity with the skin, so it has strong adhesion and has excellent durability.

Chemically synthesized antibacterial agents are generally harmful to the human body and the environment, and although the antibacterial effect is strong, the durability of the antibacterial effect is short, so there is a problem in durability. It is harmless to the skin and has a long antibacterial effect. As such an extract of the cashew tree fruit can be obtained through the application of various known techniques, a detailed description thereof will be omitted.

The antifouling agent is not limited in its type, and for example, inorganic materials such as tungsten disulfide (WS2), molybdenum disulfide (MoS2), graphite, hexagonal boron nitride (h-BN), etc. It is reasonable to add it in the form of a high-grade unpowdered powder.

The antifouling agent is to lower the friction coefficient of the surface to prevent deposition of foreign substances such as plants, unlike organic antibacterial agents for preventing adhesion of insects, etc., so that foreign substances attached to the surface can be easily detached. This is to control the habitat of insects, etc. by preventing the deposition of foreign substances such as moss.

On the other hand, as mentioned above, as mentioned above, the measurement (2) requires long-term installation and monitoring, and continuous and stable monitoring is required at a certain depth of groundwater.

Accordingly, in the present invention, as shown in FIG. 6 , a mounting hole 25 including one or more fixing bars 252 having a fastening ring 253 formed at the end of the protective tube 23 is configured at the upper end of the protective tube 23 , and the cable (c) ) is fixed so as to be detachably attached to the outer periphery and provides an example in which a length adjustment clamp 26 including a body 261 having a locking hook 262 fastened to the fastening ring 253 is further configured.

As shown in FIG. 6 , the mounting hole 25 includes a mounting ring 251 attached to the inner periphery of the protective tube 23 and a plurality of fixing bars 252 protruding from the inner periphery of the mounting ring 251 and It is composed of a fastening ring 253 formed on the fixing bar (252). That is, by attaching the outer periphery of the mounting ring 251 to the inner periphery of the protective tube 23 , the mounting hole 25 is fixed to the protective tube 23 .

Preferably, it is appropriate that the fixing bar 252 is made of an elastic material. The reason that the fixing bar 252 is made of an elastic material as described above is that the fixing bar 252 buffers the force applied to the cable (c) by wind, the flow of groundwater, etc., so that the fixing bar 252 is caused by fatigue, etc. This is to prevent damage to the back.

As shown in the drawing, the length adjustment clamp 26 includes a body 261 having an open side and a hook 262 protruding from the outer periphery of the body 261 and fastened to the fastening ring 253 and the body ( 261) by placing the cable (c) inside the bolt coupling 263 to pressurize the opening.

After fixing the length adjustment clamp 26 through the bolt coupling 263 at a position corresponding to the length to be inserted into the observation part 2 of the cable c by this configuration, the length adjustment clamp 26 is By hooking the engaging hook 262 to the fastening ring 253 , the length adjustment clamp 26 is fixed in the protective tube 23 .

That is, the position of the sensor 32 at the end of the cable (c) is fixed so that the cable (c) is inserted to a desired depth by fixing the length adjustment clamp (26). In addition, as mentioned above, it is possible to improve the resistance to fatigue failure resulting from the action of continuous load by acting to mitigate the impact caused by wind or the like afterward based on the elasticity of the fixing bar 252 .

Those skilled in the art from the above description will be able to see that various changes and modifications are possible without departing from the technical spirit of the present invention. Accordingly, the technical scope of the present invention should not be limited to the contents described in the detailed description of the specification, but should be defined by the claims.

1: Structure of the present invention 2: Measurement of pollution management
3: Front end pipe measurement 4: Back end pipe measurement
5: Diamond structure

Claims (7)

measurement of pollution clouds located in pollution clouds;
Shear pipe measurement in front of the pollution cloud measurement in the progress direction of groundwater; and
Including, measuring the back-end pipe at the rear end of the measurement of the pollution cloud in the progressing direction of the groundwater;
Each observation well,
The lower part is buried below the groundwater level and the upper part is buried so that the upper part is exposed above the ground,
A foundation formed by pouring concrete from the ground so that the top of the observation well is exposed;
A protective tube configured on the upper surface of the base so that the upper end of the observation well is embedded in a tubular shape to recognize the position of the observation well and prevent contaminants from flowing into the tube;
A fastening pipe fastened to the upper end of the protection pipe, a control jaw that is bent to the outside of the fastening pipe at the upper end of the fastening pipe, and forms an acute angle with the fastening pipe to block an organism rising from the ground from flowing into the observation well; Observation well arrangement structure for natural reduction monitoring, characterized in that it includes an inflow barrier comprising an antibacterial coating layer applied to the surface exposed to the outside from and to which an antibacterial agent and an antifouling agent are added based on resin.
The method of claim 1,
The pollution monitoring is arranged as a pair on a second imaginary line orthogonal to the first imaginary line connecting the front-end pipe measurement and the rear-end pipe measurement, and four observation wells form a quadrangular diamond structure. observation well array structure for
3. The method of claim 2,
On the second virtual line, a plurality of diamond structures formed by front-end tube measurement, rear-end tube measurement, and a pair of pollution management measurement are formed so that one pollution management measurement is shared in either direction or in one direction of the pollution management measurement. Observation well arrangement structure for natural mitigation monitoring.
delete delete The method of claim 1,
At the upper end of the protective tube, a mounting hole including one or more fixing bars having a fastening ring formed at the end is configured, and one end is fixed to be detachably attached to a cable equipped with a sensor, and a hook hook fastened to the fastening ring is formed on the outer periphery. Observation well arrangement structure for natural reduction monitoring, characterized in that the length adjustment clamp comprising a body is further configured.
7. The method of claim 6,
The fixed bar is an observation well arrangement structure for natural reduction monitoring, characterized in that it is made of an elastic material.

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