KR102315734B1 - Sludge treating apparatus for soil remediation with injection module and circylating module - Google Patents

Abstract

The present invention relates to a sedimentation tank device for circulating washing water and remediating contaminated soil, which can increase the use efficiency of resources by being provided with a circulation module that separates and reuses water after remediating the water and the contaminated soil put into a sedimentation tank, prevents floating substances or pollutants from being discharged together with remediated supernatant water by installing a diaphragm in front of a wear unit, and can increase the efficiency of discharge by collecting the pollutants floating on the upper part of the sedimentation tank into a guide module and a discharge module and providing the pollutants, thereby securing clean regeneration process water to maximize the remediation efficiency of the contaminated soil.

Description

Sedimentation tank device for purification of contaminated soil having a circulation module

The present invention relates to a settling tank device for efficiently purifying process wastewater by circulating the recycled water to be used for washing by returning the purified process wastewater to a soil washing system.

Contaminated soil can be generated from soil pollution such as oil storage, military bases, and coal mines around us, river sediments, lakes, and marine dredged soil.

Unlike water and air pollution, soil pollution is not easily revealed, and interest in its seriousness and treatment has only recently increased.

The concentration of heavy metals exceeding the standard is consistently detected in soil contamination surveys targeting industrial areas such as factories, waste landfills, waste metal mines, railway vehicle bases, and military bases.

In addition, dredging of sedimentary soil is continuously being planned and carried out according to various demands or for water quality protection in rivers, water sources, and the ocean.

Accordingly, the soil and soil containing a large amount of oil, heavy metals and various organic pollutants causes various environmental pollution problems in the ecosystem. A technology that has been studied a lot as an appropriate treatment method for these contaminated soil or sedimentary soil is the soil washing method, which is expressed as the soil washing method.

Methods for restoring contaminated soil include physical and chemical methods such as soil washing, incineration, solidification, stabilization and solvent extraction, and biological methods such as soil cultivation, composting, bioventing, and plant restoration. As can be distinguished, it is relatively easy among the various methods as described above, and since the treatment time is short, it is soil washing that can quickly restore the contaminated soil.

Soil washing is a technique that uses an appropriate cleaning agent to weaken the surface tension of harmful organic pollutants bound to soil particles or to separate heavy metals from soil particles by changing them into a liquid phase. It can remove a wide range of organic and inorganic pollutants. .

In general, the cleaning process of contaminated soil is a technology to purify contaminated soil by moving or dissolving the pollutants in the soil from the solid content of the soil into the cleaning solvent using a washing solvent and mechanical friction. After washing, the purified soil is separated from the solution Thus, it is reclaimed or taken out on site, and the solution remaining after separation is collected through wastewater treatment to recover contaminants and reused as a solvent. If the pollutant is an oil component, use an appropriate ionic or nonionic surfactant such as a cleaning agent to weaken the surface tension of harmful organic pollutants bound to the soil particles and move them to the washing water. An aqueous solution of strong acid, strong alkali, organic acid, EDTA, or oxalic acid is used as the washing solution.

A settling tank is used as a device that is basically used for cleaning these polluted soils. In the case of a sedimentation tank, it is a device that normally discharges the contaminated process wastewater through a coagulation reaction to discharge fine sludge, and sends the supernatant to the process water tank.

In the case of such a sedimentation tank, it is generally used to purify and recycle wastewater by precipitating the process wastewater, which is the last step, and discharging the sludge that is primarily precipitated, in a system implementing cleaning of contaminated soil, and washing oil contaminated soil In general, the system is not utilized as an active cleaning equipment.

In addition, after precipitation treatment is performed by mixing contaminated soil with water in a sedimentation tank, all used water is disposed of. The very low water resource utilization efficiency also causes a problem in terms of resource utilization.

Korean Patent No. 10-1406866 Korean Patent Registration No. 10-0526993

The present invention has been devised to solve the above-mentioned problem, and an object of the present invention is to return the purified process wastewater input to the sedimentation tank to the soil washing system, and the water separated from the pollutants for process wastewater purification An object of the present invention is to provide a sedimentation tank device structure capable of increasing resource use efficiency by having a circulation module that separates and reuses water after re-transfer to the sedimentation tank to purify contaminated soil.

As a means for solving the above-described problem, in the embodiment of the present invention, as shown in FIGS. 1 to 3 , a drive disposed in the center of the accommodation space F formed by the first partition wall 110 . a settling tank 100 connected to the rotating shaft 20 interlocking with the motor 10 and having a scrubber 30 for collecting and removing the sedimented sludge in the central part (P); a discharge module 200 disposed in an outward direction from the center of the settling tank 100, accommodating the floating pollutants floating in the upper part of the settling tank, and discharging to the outside of the settling tank 100 through rotation of the discharge screw member 230; a removal module 300 disposed on the floating material discharge module 200, collecting floating materials through rotation of a plurality of rotating blades 310 and guiding them to the inside of the discharge module 200; an external driving module 400 disposed outside the first bulkhead 110 of the settling tank 100 and simultaneously driving the discharge module 200 and the removal module 300 through a driving chain; It is disposed in the outward direction from the center of the settling tank 100, and through a plurality of injection nozzles 520, the fluid is sprayed obliquely to the highest water level surface (Y) of the settling tank 100 to remove the suspended matter in the direction of the removal module 300 The injection module 500 to lead to; And a circulation module for re-supplying the collected water to the process wastewater supply module (m) by dehydrating the suspended pollutants discharged from the discharge module (200), and circulating the recycled water purified in the settling tank to the soil washing process system (700) (600); including, to be able to provide a sedimentation tank device for cleaning contaminated soil having a circulation module.

According to an embodiment of the present invention, the water purified by the process wastewater input into the settling tank is returned to the soil washing system, and the water separated from the pollutants is returned to the sedimentation tank for process wastewater purification to purify the contaminated soil. By having a circulation module that separates and reuses water, the advantage of increasing resource use efficiency is realized.

In addition, the structure of the partition wall of the sedimentation tank in the present invention is implemented in a triple structure, and a diaphragm (third partition wall) is installed in front of the wear part implemented in the second partition wall part, so that the supernatant water from which suspended matter or contaminant oil is purified Prevents them from being discharged together, and increases the efficiency of discharge by collecting and providing the pollutants floating in the upper part of the settling tank with the guide module and the discharge module, thereby maximizing the efficiency of polluted soil purification by securing clean regeneration process water. It works.

In addition, a partition is installed to prevent floating substances or oil components floating above the upper water level in the settling tank from going out directly to the wear part, and a device using a rotating blade in a discharge module having a discharge screw member to remove floating substances or oil floating in the partition. A spray module is provided on the upper part of the settling tank device to actively collect and discharge floating pollutants using the system, and a removal module that collects floating pollutants through the spray module can be used to easily collect and discharge polluted soil. The advantage of maximizing efficiency is realized.

Furthermore, in the case of oil contamination or complex soil contamination, it effectively implements the removal of pollutants that are difficult to purify in operations such as water and agitation for purifying the input soil, while circulating the water used for purification. Since it can be used, the advantage of reducing the purification cost is also realized.

1 is a cross-sectional conceptual view of a sedimentation tank device for purifying contaminated soil having a circulation module according to an embodiment of the present invention.
FIG. 2 is a schematic top plan view of the sedimentation tank apparatus for purifying contaminated soil according to the embodiment of the present invention of FIG. 1 .
FIG. 3 is a schematic diagram showing the main part of the configuration of the injection module in FIG. 1 .
4 is a conceptual diagram illustrating the arrangement relationship of the settling tank, the removal module, and the discharge module in FIG. 1 .
5 to 11 are conceptual diagrams of main components for explaining the operation process of the embodiment of the present invention.

Advantages and features of the present invention, and methods for achieving them, will become apparent with reference to the embodiments described below in detail in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments described herein and may be embodied in other forms. Rather, the embodiments introduced herein are provided so that the disclosed subject matter may be thorough and complete, and that the spirit of the present invention may be sufficiently conveyed to those skilled in the art.

The terms used in the present application are only used to describe specific embodiments, and are not intended to limit the present invention. The singular expression includes the plural expression unless the context clearly dictates otherwise. In the present application, terms such as “comprise” or “have” are intended to designate that a feature, number, step, operation, component, part, or combination thereof described in the specification exists, but one or more other features It is to be understood that it does not preclude the possibility of the presence or addition of numbers, steps, operations, components, parts, or combinations thereof.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in a commonly used dictionary should be interpreted as having a meaning consistent with the meaning in the context of the related art, and should not be interpreted in an ideal or excessively formal meaning unless explicitly defined in the present application. does not

1 is a cross-sectional conceptual view of a sedimentation tank device for purifying contaminated soil (hereinafter, referred to as 'the present invention') having a circulation module according to an embodiment of the present invention. FIG. 2 is a conceptual top plan view of the sedimentation tank apparatus for purifying contaminated soil according to the embodiment of the present invention of FIG. 1 . 3 and 4 are schematic views of main parts in FIG. 1 .

1 to 4, the present invention is connected to the rotation shaft 20 interlocking with the drive motor 10 disposed in the center of the receiving space (F) formed by the first partition wall portion (110), A settling tank 100 having a scrubber 30 for collecting and removing the sludge to be formed in the central part P, is disposed in an outward direction from the center of the settling tank 100, and receives and discharges pollutant suspended matter floating in the upper part of the settling tank The discharge module 200 for discharging to the outside of the settling tank 100 through the rotation of the screw member 230, is disposed on the floating material discharge module 200, and collects the floating material through the rotation of a plurality of rotating blades 310 The removal module 300 for guiding into the interior of the discharge module 200 is disposed outside the first bulkhead 110 of the settling tank 100 , and drives the discharge module 200 and the removal module 300 . An external driving module 400 that simultaneously drives through a chain, is disposed in an outward direction from the center of the settling tank 100, and directs the fluid through a plurality of injection nozzles 520 to the highest water level surface (Y) of the settling tank 100 The water collected by dehydrating the polluted suspended matter discharged from the injection module 500 and the discharge module 200 for guiding the suspended matter in the direction of the removal module 300 by spraying it obliquely to the process wastewater supply module (m) is recycled. It supplies and is configured to include a circulation module 600 that circulates the regenerated water purified in the settling tank to the soil washing process system 700 .

In the present invention, the settling tank 100 includes a first partition wall portion 110 having an outer peripheral surface formed in a cylindrical shape, the upper surface of the first partition wall portion 110 has an open structure, and the lower portion is shown in FIG. 1 . It has a sloping bottom surface as described above, and is implemented in a structure in which the lower center is provided with an outlet (P) through which sludge is discharged according to the operation of the on-off valve.

An empty accommodating space F is provided inside the settling tank 100 , and the rotating shaft 20 rotated by the driving motor 10 is disposed at the center of the settling tank 100 .

A scrubber 30 having an inclined structure corresponding to the inclination of the lower surface of the settling tank 100 is disposed at the end of the rotation shaft 20 in association with the shaft rotation, and the scrubber 30 is the center of the receiving space (F). It is connected to the rotating shaft 20 interlocking with the driving motor 10 disposed on the , and collects the sedimented sludge to the central part P so that it can be removed.

That is, a scrubber 30 corresponding to the inclination of the lower surface of the settling tank 100 is disposed at the end of the rotary shaft 20 in conjunction with the shaft rotation, and the sludge deposited in the received process wastewater is scraped to the center and discharged. function will be performed.

The sludge in the process wastewater is precipitated by the operation of the scrubber 30, the sedimented sludge is discharged to the lower part of the settling tank, and the pollutants floating in the process wastewater are collected in the supernatant part of the settling tank. 300 ) and the discharge module 200 .

That is, when the pollutants mixed with the sludge are mixed with water in the process wastewater flowing into the settling tank of the present invention, floating matter or pollutant oil content among the pollutants is exposed. Such a suspended matter or pollutant oil is usually in the form of a suspended matter and has a light specific gravity. Considering the uppermost surface (X) of the settling tank 100, it floats on the highest water level surface (Y) in which water is accommodated.

The process wastewater is supplied to the inside of the settling tank 100 through a transfer pipe from the washing process wastewater supply module (m). In this case, the process wastewater normally introduced by having an inlet module (G) inside the settling tank of the present invention is first introduced through the inlet module (G), and then moves to the lower part of the settling tank. The inflow module (G) has a cylindrical structure with an empty interior (S1), and the inflowing process wastewater is stirred by the rotational operation of the scrubber, and the sludge contained in the process wastewater is precipitated and the scrubber rotates. is collected in the lower center of the sedimentation tank, and oil components or suspended matter inside the sedimentation tank float to the upper part of the settling tank.

In this case, these suspended substances float in the upper part of the settling tank and move randomly. Through the injection module 500, it is possible to artificially guide the suspended substances in a desired direction, and a removal module 300 and discharge to be described later. It is possible to efficiently discharge suspended matter by collecting it with the module 200 .

In particular, in the present invention, the water separated by dehydrating the suspended pollutants discharged through the sedimentation tank 100 is re-supplied to the process wastewater supply module (m) to undergo a purification process, and the regenerated water purified in the sedimentation tank is applied to the soil. It circulates to the washing process system 700 so that it can be provided with a purifying module 600 that can be used for soil washing.

Specifically, as shown in FIG. 1 , in the present invention, the circulation module 600 collects and dehydrates the suspended pollutants discharged through the discharge module 200, and discharges the solidified pollutants and dehydrates them. The dewatering module 610 for returning the wastewater to the process wastewater supply module m through the wastewater supply line 615, and collecting water passing through the wear part 124 of the settling tank 100, oil and moisture The oil-water separation module 620 for separating the sludge filter press module 630, which receives the sludge collected and discharged to the central part (P) of the settling tank 100, filters the sludge, and separates the compressed sludge with water 630, the oil-water The water separated by the separation module 620 and the water separated by the sludge filter press module 630 are supplied through the separated water supply lines 625 and 635 and stored in the regeneration water storage tank 640 and in the regeneration water storage tank 640. The stored water is configured to include a regeneration water supply line 645 for supplying the soil washing process system 700 for washing the contaminated soil.

The dewatering module 610 collects suspended contaminants discharged to the outside of the settling tank through the discharge module 200 to perform a dehydration process, and the water separated in the dewatering process is a wastewater supply line 615 . It is returned to the process wastewater supply module (m) that supplies process wastewater to the settling tank and undergoes purification again. In addition, the dehydrated floating pollutants are solidified and discharged as waste (T).

In addition, the oil-water separation module 620 is supplied with supernatant water via the wear part 124 in the triple structure partition structure provided in the settling tank to be described later, and performs a function of separating oil and moisture, The regenerated water from which the oil is separated can move to the regenerated water storage tank 640 through the first separated water supply line 625 . The regenerated water stored in the regenerated water storage tank 640 is then put into the process line of the soil washing process system 700, and can be recycled for the purpose of washing contaminated soil, thereby increasing the resource use efficiency.

In addition, the sludge filter press module 630 receives the sludge collected and discharged to the central part (P) of the settling tank 100, filters the sludge, and separates the compressed sludge and water. Thereafter, the separated water moves to the regeneration water storage tank 640 through the second separated water supply line 635 . The regenerated water stored in the regenerated water storage tank 640 is then put into the process line of the soil washing process system 700 through the regenerated water supply line 645, so that it can be recycled for the purpose of washing contaminated soil, thereby increasing the resource use efficiency. there will be At the same time, in the sludge filter press module 630, the sludge is separated from water and compressed, so that it can be discharged as a solid sludge in a block (cake) state.

In addition, in the present invention, as shown in FIG. 1 , the regeneration water supplied through the regeneration water supply line 645 is introduced into the process line of the soil washing process system 700 to wash the contaminated soil, and the process generated at this time The wastewater is provided to the process wastewater supply line 710 so that the sedimentation process and the purification process can be circulated in the sedimentation tank.

In the present invention, by providing a circulation module interlocking with the sedimentation tank, the separation wastewater generated as a result of the treatment of suspended pollutants and the process wastewater generated from the soil washing process system 700 are supplied to the sedimentation tank, so that the sedimentation and purification process can be repeated. By doing so, it is possible to build an efficient purification system by increasing the resource reuse efficiency.

That is, in the sedimentation tank apparatus of the present invention, when removing pollutants generated in the process of purifying process wastewater, the water discharged together with the sludge is filtered and supplied back to the sedimentation tank to perform the purification process, and at the same time, the wear part Recycled water passing through 124 is supplied to the soil washing system, and the process wastewater used for washing is supplied back to the settling tank to build a recirculation system to perform purification. In this way, the present invention can build an economical and eco-friendly system by increasing the water use efficiency through a circulation module that implements a process of recirculating water used in the settling tank.

Hereinafter, the operation process of the present invention will be described through another main configuration of the settling tank apparatus of the present invention to which the above-described circulation module is applied.

Referring to FIG. 3, FIG. 3 is a cross-sectional conceptual view showing the configuration of the injection module 500 as the main configuration of the present invention. The sludge deposited in the process wastewater received by the operation of the scrubber 20 disposed inside the settling tank 100 of the present invention as described above is scraped to the central portion and discharged.

In general, these pollutants are in the form of suspended matter and have a light specific gravity, and when the uppermost surface (X) of the settling tank 100 is considered, they are floated on the highest water level surface (Y) in which water is accommodated. In this case, these suspended substances float in the upper part of the settling tank and move randomly. Through the injection module 500, it is possible to artificially guide the suspended substances in a desired direction, and a removal module 300 and discharge to be described later. It is possible to efficiently discharge suspended matter by collecting it with the module 200 .

To this end, the injection module 500 has a tubular structure with an empty interior as shown in FIG. 3, and the fluid supplied from the external fluid supply unit (N) flows in and temporarily accommodates the injection housing 510 and, A plurality of injection nozzles 520 formed in the lower portion of the injection housing 510, formed at one end of the injection housing 510, and an angle adjusting unit 530 for rotating the injection housing 510 at a predetermined angle. can consist of

Specifically, the injection housing 510 of the injection module 500 may be made of a metal or synthetic resin material having a cylindrical structure, and has an empty structure. A fluid such as gas is supplied and temporarily accommodated. At the same time, a plurality of injection nozzles 520 capable of injecting a fluid are provided on the outer surface of the injection housing 510 .

The injection nozzle 520 may be formed so that the injection hole of the injection nozzle is generally incident on the upper plane of the settling tank at a predetermined inclination on the side surface of the division housing 510 . Preferably, in the embodiment of the present invention, the injection housing 510 in which the injection nozzle 520 is formed rotates at a predetermined angle, so that the injection port can adjust a predetermined injection angle on the upper plane of the settling tank. do.

That is, as shown in FIG. 3 , a rotating bearing member 535 is provided at a portion to which the outer circumferential surface of the injection housing 510 is fixed, so that the injection housing 510 is configured to rotate at a predetermined angle. . In order to adjust the angle, a rotation shaft 537 is provided to provide power for the injection housing 535 to rotate. The rotation of the rotating shaft 537 may be automated by a driving force generated by manual or motor driving.

In the case of the rotation angle, as shown in (a) of FIG. 3, when the injection nozzle 520 is disposed in the vertical lower direction of the injection housing 510, (b) rotates at a constant first angle θ1 In this case, the injection nozzle is inclined by y1-->y2, and (c) when it is rotated at a second angle (θ2) under rotation at a larger angle, the inclination angle is also increased by y1-->y2. . When the injection nozzle is inclined at the first angle (θ1) or the second angle (θ2) and the fluid is sprayed obliquely to the upper part of the settling tank, the greater the angle, the better the efficiency of pushing out suspended matter. Forming in the range of 60 degrees is advantageous in that it increases the transport efficiency of the suspended matter and prevents the suspended matter from flying out of the settling tank.

Hereinafter, the main configuration of the present invention in conjunction with the above-described injection module 500 will be described.

1, 4, and 9, the supply of process wastewater to the receiving space inside the settling tank of the present invention is supplied to the inside of the settling tank 100 through the transfer pipe from the washing process wastewater supply module (m). do.

In this case, the process wastewater normally introduced by having an inflow module (G) inside the settling tank of the present invention is stirred by the rotating operation of the scrubber, and moves to the lower part of the settling tank. The inflow module (G) is made of a cylindrical structure with an empty interior (S1), the inflowing process wastewater is stirred by the rotational operation of the scrubber, and the sludge contained in the process wastewater is precipitated to the lower part of the settling tank. They are collected, and oil components or suspended matter inside the settling tank float to the top.

The inflow module (G) is made of a cylindrical structure with an empty interior (S1), and performs a function of moving the inflowing process wastewater downward at a constant speed and pressure without scattering.

Specifically, in the case of a barrier rib structure through which suspended substances flow, in the present invention, as shown in FIGS. 1 and 5 , the third first barrier rib 110 as a whole implements the outer wall of the settling tank, in more detail is additionally provided with a second partition wall portion 120 and a third partition wall portion 130 to form a triple structure.

The first partition wall part 110 is formed along an inner upper portion of the first partition wall part 110 , and an upper concave-convex wear part 124 is implemented, and contaminants passing through the wear part 124 are removed. The second partition wall portion 120 and the second partition wall portion 120 are separated from each other to implement the receiving portion 122 for accommodating, and a space is formed to be higher than the height of the second partition wall portion 120, It may be configured to further include a third partition wall 130 that is implemented to prevent contaminants from entering the separation space.

The second partition wall part 120 has one end attached to the first height t1 inside the first partition wall part 110, and implements the receiving part 122 having a concave groove structure, and the end is bent. to implement a constant second height t2. As shown in FIG. 2 , the upper portion of the bent portion implementing the second height t2 may be implemented in a structure including the concave-convex wear portion 124 in which the concave-convex pattern is implemented.

As shown in FIG. 9 , in the wear part 124 , in the process wastewater inside the settling tank, sludge is precipitated and discharged to the outlet (P) of the center of the settling tank, and the suspended material floats on the upper part of the settling tank, so that the purified water The entry (w1-->w2) along the penetration hole 136 as shown in FIG. 9 formed on the binding site surface of the inner surface of the second region 132 of the third partition wall and the first partition wall 110 and enters the bending-type second bulkhead 120 that implements the receiving part 122 via the wear part 124 and allows the purified water to circulate again.

In addition, as in the structure shown in FIGS. 1 and 9 , the third partition wall 130 includes a first area 134 that is a surface area realizing a structure spaced apart from the bent area of the second partition wall 120 and The inclined structure may be implemented as a structure in which one end includes a second region 132 that is a surface region bound to the inner side of the first partition wall portion 110 .

In particular, the third height t3 of the distal end 135 of the first region 134 of the third partition wall 130 is preferably formed to be higher than the second height t2. This is because the distal end 135 of the first region 134 is formed to be higher than the height of the wear part 124 , so that the suspended material and supernatant water (water located in the upper part of the sedimentation tank) of the sedimentation tank enter the separation space 138 or the wear It allows to perform the function of a barrier to prevent it from passing to the part 124 .

When implemented with such a structure, the first height t1 to the upper end of the overall first bulkhead part 110 is formed to be the highest to form a settling tank as a whole, and the second height of the upper end of the second bulkhead part 120 is formed. By forming the third height t3 of the upper end of the third partition wall higher than (t2), the contaminants inside the settling tank are prevented from entering the separation space 138 or the wear part 124 . That is, the first height t1 > the second height t2 and the second height t2 < the third height t3 can be implemented.

When a step structure of such a height is implemented, as shown in FIGS. 1 and 4 , when a floating object floats on the highest water level surface (Y), it is primarily by the third partition wall part (t3). It is blocked, and it is possible to prevent a floating object or water from overflowing into the separation space 138 or the wear part 124 . That is, in the present invention, a diaphragm (third bulkhead) is installed in front of the wear part 124 to prevent suspended matter or pollutant oil from being discharged together with the purified supernatant water, thereby securing clean regeneration process water and maximizing the efficiency of polluted soil purification. be able to do However, in the case of water discharged through the wear part 124, it may contain a small amount of oil, which allows the separation process to be performed through an oil-water separation module to be described later.

In addition, the suspended material is made to be discharged through the discharge module 200 to be described later, and the purified supernatant water passes through the separation space 138 through the through hole 136 in the structure of FIG. 8 as described above, and , and moves through the wear part 124 . As described above, the water passing through the wear part 124 is supplied to the oil-water separation module 620 . The oil-water separation module 620 performs a function of separating oil and water, and the regenerated water from which oil is separated can move to the regenerated water storage tank 640 through the first separated water supply line 625 . Afterwards, the regenerated water stored in the regenerated water storage tank 640 is input to the process line of the soil washing process system 700 and can be recycled for the purpose of washing contaminated soil.

In addition, in the present invention, as shown in FIGS. 1 to 4 , the discharge module 200 and the removal module 300 are disposed in a direction crossing the area of the first partition wall part 110 in the center of the settling tank 100 . provide an extra day.

As shown in FIGS. 1 and 4 , the discharge module 200 collects and actively discharges suspended matter (contaminants) exposed to the highest water level surface (Y) of the upper part of the settling tank. In addition, a removal module 300 for guiding and injecting floating matter (contaminants) exposed to the highest water level surface (Y) of the upper part of the settling tank with the discharge module 200 is disposed adjacent to the upper part of the discharge module 200. make it possible

Specifically, the structure and operation of the discharge module 200 and the removal module 300 will be described with reference to FIGS. 4 to 9 .

4 and 5 , the discharge module 200 of the present invention has a cylindrical structure discharging housing ( 210) and an input groove 215 that is implemented in a structure that is opened along the longitudinal direction of the discharge housing 210 and receives pollutants, is disposed inside the discharge housing 210, and the first rotation shaft 232 of It may be configured to include a discharge screw member 230 for discharging the contaminants accommodated by the rotational operation to the outside.

As shown in FIGS. 4 and 5, the discharge housing 210 is implemented as a cylindrical tube structure having an empty inside, and the discharge screw member 230 in which a screw blade 235 is coupled to a rotating shaft is provided. are placed In addition, the upper surface of the Chinese cabbage housing 210 is provided with an input groove portion 215 opened with a predetermined width and length, and a portion of the discharge screw member 230 is exposed through the input groove portion 215 . do. As will be described later, at an upper position corresponding to the formation position of the input groove 215 , it is disposed in the transverse direction of the rotary blade 310 , and the rotary blade 310 rotates to collect floating matter and to the input groove 215 . Upon input, the discharging screw member 230 rotates and transports the injected floating material to be discharged to the outside of the settling tank.

The specific structure of the removal module 300 is, as shown in FIG. 4, a structure in which the rotation blade 310 of the wing structure is mounted on the second rotation shaft R, and in the structure of FIG. 4, the rotation blade 310 is A structure in which four are radially mounted at the same location (hereinafter, 'unit unit') is arranged side by side with a pair of spaced apart from each other. The unit unit rotates according to the rotation of the second rotating shaft (R) so that a part of the distal end of the rotating blade touches the highest water level in the upper part of the settling tank. In the present invention, a structure in which an elastic plate 315 having a plate structure is attached to the end of the rotating blade 310 may be a preferred example. The elastic plate 315 may be, for example, a plate structure made of a rubber material. The elastic plate 315 scrapes the floating substances (contaminants) floating on the water of the settling tank so that it can be put into the input groove 215 , and has elasticity with elasticity, and performs some friction with the input groove 215 . and scrape even the contaminants attached to the surface of the elastic plate 315 to provide the input groove.

In order to explain this structure, referring to FIG. 6 , FIG. 6 is a cross-sectional conceptual view illustrating an arrangement relationship between the removal module 300 and the discharge module 200 of FIG. 4 . ( FIGS. 7 and 8 are the An enlarged conceptual diagram and an overall front conceptual diagram are shown.)

As shown in FIG. 6 , the discharge module 200 is provided with a discharge screw member 230 inside the discharge housing 215 having a cylindrical structure, and an input groove 215 is disposed on the upper portion, and an input groove 215 is provided. ) on the left and right, the locking plate (I) protrudes to the outside.

The distal end of the elastic plate 315 attached to the distal end of the rotating blade 310 is configured to have a length capable of contacting the engaging plate I, and when rotating, the input groove 215 to a certain depth. By allowing the distal end of the elastic plate 315 to be introduced, the floating material can be accurately guided to the input groove 215 . Since the elastic plate 315 is made of a soft rubber material, it is possible to accurately scrape the floating material in contact with the locking plate I and put it into the input groove.

The rotating blade 310 of the present invention may be implemented with a rigid plastic or metal material, and the length (a) of the rotating blade 310 is longer than the length of the elastic plate (b), so that the rotation operation is performed. It is possible to solve the problem that the elastic plate is excessively bent and the operation of guiding the contaminants cannot be smoothly performed. For this purpose, it is preferable that the length (a) of the rotating blade 310 and the length of the elastic plate (b) be implemented in a ratio of 6-7:4-3.

9 is a state diagram illustrating the operation of the rotary blade 310 and the operation of the discharge module 200 .

9, the rotating blade 310 is disposed along the longitudinal direction of the discharge module 200, and the rotation of the rotating blade 310 is the elastic plate 315 to the lower part of the highest water level surface (Y). to come down, and the floating material is collected by rotating the elastic plate and put into the discharge module 200 through the input groove of the discharge module 20 .

The discharge screw member 230 in the discharge module 200 rotates and transports the input pollutants in the outward direction w3 and discharges them to the outside of the settling tank.

The suspended pollutants discharged in this way, as described above in the configuration of FIG. 1, collect the floating pollutants discharged to the outside of the settling tank through the discharge module 200, so that the dehydration process can be performed, and in the dehydration process The separated water is returned to the process wastewater supply module m that supplies process wastewater to the settling tank through the wastewater supply line 615 to undergo purification again. In addition, the dehydrated suspended contaminants are solidified and discharged as waste (T).

Overall, in the present invention, when the process wastewater flowing in from the washing process wastewater supply device m described above in FIG. 1 flows into the receiving space F, the operation of the structure shown in FIG. 9 is performed.

That is, as shown in FIGS. 1 and 9, the process wastewater is stirred according to the rotation of the scrubber 30, and the sludge contained in the process wastewater is precipitated into the center of the settling tank, It is collected in the center and discharged through the outlet (P). The sludge collected and discharged to the central part P of the settling tank 100 in this way is subjected to a filtering process and a separation process in the sludge filter press module 630 . That is, the sludge filter press module 630 filters the sludge supplied from the settling tank 100 and functions to separate the compressed sludge and water.

In this way, the separated water moves to the regeneration water storage tank 640 through the second separated water supply line 635 . The regenerated water stored in the regenerated water storage tank 640 is then put into the process line of the soil washing process system 700 through the regenerated water supply line 645, so that it can be recycled for the purpose of washing contaminated soil, thereby increasing the resource use efficiency. there will be At the same time, in the sludge filter press module 630, the sludge is separated from water and compressed, so that it can be discharged as a solid sludge in a block (cake) state.

In addition, in the present invention, contaminants (oil, fine suspended matter, etc.) contained in the process wastewater are suspended at the highest water level (Y) point of the settling tank 100 . Due to the presence of the third partition wall part 130 , the contaminants floating in this way are blocked without passing through the adjacent space 138 or the wear part 124 , and remain floating in the upper part of the settling tank.

In this case, the floating material on the highest water level (Y) surface is filtered through the rotation of the rotating blade 310 disposed on the upper part of the settling tank and guided to the input groove 215 of the discharge module 200, and the input groove 215. The contaminants introduced through the are driven to be discharged (w3) to the outside of the settling tank through the rotation of the discharge screw member (230). Thereafter, the contaminants solidified through the dehydration process in the dehydration module 610 are removed and discharged as described above.

At the same time, in the case of the purified water remaining after the sludge and suspended contaminants are discharged, as shown in FIG. 8 (see FIG. 1), it enters the separation space 135 through the through hole 136, and the wear part 124. Purified water is discharged through a path (w1-->w2) through Process wastewater is converted into process wastewater, and process wastewater can be used to be circulated back to the settling tank.

That is, in the present invention, active discharge of pollutants can be implemented through the operation of the removal module 300 and the discharge module 200, the sludge sediment is collected and discharged through the scrubber, and the purified water is It can be recycled and reused.

In addition, the operation of the removal module 300 and the discharge module 200 allows to increase the efficiency by applying a driving structure for simultaneously driving the first rotation shaft 232 and the second rotation shaft R.

Specifically, FIGS. 10 and 11 show a driving structure for simultaneously driving the respective rotation shafts R and 230 in the operation of the removal module 300 and the discharge module 200 .

The removal module 300 rotates the rotating blade 315 about the second rotating shaft R, and includes a gear g1 coupled to the rotating shaft. At the same time, the rotation of the rotation shaft 232 of the discharge module 200 is made according to the rotation operation of the motor M1, and the motor M1 and the first rotation shaft 232 are respectively gears g2 and g3. The rotational force is transmitted through the first chain c1 connecting the Through this, the first rotation shaft 232 and the rotation blade 310 of the removal module 300 are simultaneously rotated through the driving of one motor M1.

Such a power transmission structure implements the interlocking process of the removal module and the discharge module of the present invention more efficiently, and the advantage of enabling more efficient use of power is realized.

In the above, the present invention has been described based on a preferred embodiment, but the technical spirit of the present invention is not limited thereto, and it is possible for modifications or changes within the scope described in the claims to those of ordinary skill in the art to which the present invention pertains. Any such modifications or changes shall fall within the scope of the appended claims.

100: settling tank 110: first bulkhead part
120: second bulkhead 130: third bulkhead
200: discharge module 210: discharge housing
215: input groove 230: discharge screw member
300: removal module 310: rotating blade
315: elastic plate 400: drive module
500: injection module 510: injection housing
520: injection nozzle 530: angle adjustment unit
600: circulation module 610: dewatering module
620: oil-water separation module 630: sludge filter press module
640: recycled water storage tank 645: recycled water supply line
700: soil washing process system

Claims (6)

A scrubber that is connected to the rotation shaft 20 interlocking with the drive motor 10 disposed in the center of the accommodation space F formed by the first bulkhead 110 , and collects and removes the sludge deposited in the central portion P Settling tank 100 having (30); a discharge module 200 disposed in an outward direction from the center of the settling tank 100, accommodating the contaminant suspended matter floating in the upper part of the settling tank, and discharging to the outside of the settling tank 100 through the rotation of the discharge screw member 230; a removal module 300 disposed on the floating material discharge module 200, collecting floating materials through rotation of a plurality of rotating blades 310 and guiding them to the inside of the discharge module 200; an external driving module 400 disposed outside the first bulkhead 110 of the settling tank 100 and simultaneously driving the discharge module 200 and the removal module 300 through a driving chain; It is disposed in the outward direction from the center of the settling tank 100, and through a plurality of injection nozzles 520, the fluid is sprayed obliquely to the highest water level surface (Y) of the settling tank 100 to remove the suspended matter in the direction of the removal module 300 The injection module 500 to lead to; and a circulation module for re-supplying the collected water to the process wastewater supply module (m) by dehydrating the contaminant suspended matter discharged from the discharge module (200), and circulating the recycled water purified in the settling tank to the soil washing process system (700) (600);
The circulation module 600 collects and dehydrates the suspended pollutants discharged through the discharge module 200 , discharges the solidified pollutants, and discharges the dehydrated wastewater to the process wastewater through the wastewater supply line 615 . a dewatering module 610 for conveying to the supply module (m); an oil-water separation module 620 for collecting water passing through the wear part 124 of the settling tank 100 and separating oil and moisture; a sludge filter press module 630 that receives sludge collected and discharged to the central part (P) of the settling tank 100, filters the sludge, and separates the compressed sludge and water; a regeneration water storage tank 640 for receiving and storing the water separated by the oil-water separation module 620 and the water separated from the sludge filter press module 630 through separated water supply lines 625 and 635; The water stored in the regenerated water storage tank 640 is a regenerated water supply line 645 for supplying the soil washing process system 700 for washing the contaminated soil; including,
A sedimentation tank device for purifying contaminated soil having a circulation module.
delete The method according to claim 1,
Supplying the process wastewater generated after soil washing in the soil washing process system 700 to the process wastewater supply module (m) through the process wastewater supply line 710,
A sedimentation tank device for purifying contaminated soil having a circulation module.
4. The method according to claim 3,
The sedimentation tank device for purifying contaminated soil,
The first partition wall portion 110 is formed along the inner upper portion, the upper portion is bent to have an open structure, and the concave-convex wear portion 124 is implemented at one end of the upper portion, the second partition wall portion 120;
The second partition wall portion 120 and the separation space 138 are formed and formed to have an upper end 135 of a height formed higher than the height of the second partition wall portion 120, and A third partition wall portion 130 forming a path for allowing purified water entering through the lower permeation hole 136 to pass through the wear portion 124; further comprising,
A sedimentation tank device for purifying contaminated soil having a circulation module.
5. The method according to claim 4,
The discharge module 200 may include: a discharge housing 210 having a cylindrical structure disposed in a structure that crosses the outside of the first partition wall portion 110 in the center of the settling tank 100;
an input groove 215 configured to be opened along the longitudinal direction of the discharge housing 210 to receive contaminants;
It is disposed inside the discharge housing 210, the discharge screw member 230 for discharging the contaminants accommodated by the rotation operation of the first rotating shaft 232 to the outside; includes;
The removal module 300 is disposed adjacent to the upper portion of the discharge module 200, rotates according to the rotation of the second rotation shaft R, and a rotation blade 310 having an elastic plate 315 formed at the end thereof. A pair of unit units comprising
A sedimentation tank device for purifying contaminated soil having a circulation module.
6. The method of claim 5,
The injection module 500 has an empty tubular structure, and the fluid supplied from the external fluid supply unit (N) flows in and temporarily accommodates the injection housing 510; a plurality of injection nozzles 520 formed under the injection housing 510;
Contaminants guided by the fluid injected through the injection nozzle 520 of the injection module 500, and the contaminants through the rotation of the elastic plate 315, the input groove 215 of the upper portion of the discharge module 200 ) driven to be input,
A sedimentation tank device for purifying contaminated soil having a circulation module.

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