KR102440347B1 - Polluted Soil Purification Apparatus - Google Patents

Abstract

Disclosed is a contaminated soil purification apparatus capable of increasing thermal desorption efficiency. According to one embodiment of the present invention, the contaminated soil purification apparatus comprises: a pre-processing unit processing contaminated soil to make fine particles; a heating chamber including a microwave oscillation unit generating microwaves and a plurality of dispersing members disposed on an inner wall to disperse the microwaves; a closed thermal desorption conveyor disposed inside the heating chamber, having the lower part of a frame with a half-pipe structure, having the upper part connected to a pipe for collecting vaporized contaminants, and having a conveyor screw disposed in the half-pipe structure to transfer the finely granulated contaminated soil in the pre-processing unit; and a purified soil reception unit receiving the purified soil which is heated in the heating chamber such that contaminants are removed from the purified soil, wherein a portion, in which the thermal desorption conveyor and the purified soil receiving unit are connected, has a closed structure in which air does not communicate with the outside.

Description

Polluted Soil Purification Apparatus

The present disclosure relates to an apparatus for purifying contaminated soil.

The content described in this section merely provides background information for the present disclosure and does not constitute the prior art.

As the severity of soil contamination due to oil rises, an apparatus for purifying contaminated soil is continuously being developed. The domestic market for soil remediation business is increasing by an average of 7% or more every year, and the market for soil remediation business is expanding worldwide.

Methods for purifying contaminated soil include land farming, soil washing, and thermal desorption.

The soil cultivation method is a method of biodegradation using aerobic organisms by laying contaminated soil on the surface, and has disadvantages in that it requires a large treatment space and takes a very long time to purify the contaminated soil.

The soil washing method is a method of decomposing high-temperature water or heavy metals into a liquid phase, which has a disadvantage in that the purification process of contaminated soil is complicated because it requires second and third contamination treatment.

The thermal desorption method has a shorter purification time and a relatively simplified purification process than the above-described method for remediing contaminated soil, and thus has good efficiency. When microwaves are applied to the thermal desorption method, there are advantages in that the purification apparatus can be simplified and the efficiency of heating the contaminated soil is high. However, when microwaves are used, especially when microwaves of a single frequency are used, a spark phenomenon due to local heating may occur due to the wave characteristics of microwaves. Due to such instability, it is impossible to commercialize a thermal desorption device using microwaves.

The apparatus for purifying contaminated soil according to an embodiment may stably heat the contaminated soil using microwaves.

Contaminated soil purification apparatus according to an embodiment can increase heating efficiency by configuring a closed structure.

The problems to be solved by the present invention are not limited to the problems mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the following description.

According to an embodiment of the present disclosure, a pre-processing unit for treating contaminated soil into fine particles; a heating chamber including a microwave oscillation unit generating microwaves and a plurality of dispersion members disposed on an inner wall to disperse microwaves; It is disposed inside the heating chamber, and the lower part of the frame has a half pipe structure, and a pipe for collecting vaporized contaminants is connected to the upper part, and a conveyor screw is disposed in the half pipe structure to obtain fine particles in the pretreatment unit. Closed-type thermal desorption conveyor for transporting contaminated soil; and a purified soil accommodating part for accommodating the purified soil heated in the heating chamber and treated with pollutants, wherein the part connected to the thermal desorption conveyor and the purified soil accommodating part has a closed structure in which air does not communicate with the outside. A purifier is provided.

According to an embodiment, the contaminated soil purifying apparatus has an effect of stably heating the contaminated soil by irradiating the contaminated soil with microwaves with a uniform intensity using a dispersing member.

According to one embodiment, there is an effect of increasing the thermal desorption efficiency by designing a closed structure in which air cannot be introduced from the outside while the contaminated soil is heated.

1 is a schematic diagram of an apparatus for purifying contaminated soil according to an embodiment of the present disclosure.
Figure 2 is a plan cross-sectional view of the contaminated soil purification apparatus according to an embodiment of the present disclosure.
3 is a cross-sectional view taken along line XX of FIG. 1 .
4 is a perspective view of a dispersing member according to an embodiment of the present disclosure.
5 is a view for explaining the microwave reflection characteristics of the dispersing member according to an embodiment of the present disclosure.
6 is an example for explaining the principle of the dispersing member of the present disclosure.

Hereinafter, some embodiments of the present disclosure will be described in detail with reference to exemplary drawings. In adding reference numerals to components in each drawing, it should be noted that the same components are given the same reference numerals as much as possible even though they are indicated in different drawings. In addition, in describing the present disclosure, if it is determined that a detailed description of a related known configuration or function may obscure the gist of the present disclosure, the detailed description thereof will be omitted.

In describing the components of the embodiment according to the present disclosure, reference numerals such as first, second, i), ii), a), b) may be used. These signs are only for distinguishing the elements from other elements, and the nature, order, or order of the elements are not limited by the signs. When a part in the specification 'includes' or 'includes' a certain component, it means that other components may be further included, rather than excluding other components unless explicitly stated otherwise. .

1 is a view of a contaminated soil purification apparatus according to an embodiment of the present disclosure. Figure 2 is a plan cross-sectional view of the contaminated soil purification apparatus according to an embodiment of the present disclosure. FIG. 3 is a cross-sectional view taken along line X-X of FIG. 1 . The drawing shown in FIG. 1 shows the internal structure of the heating chamber 200 for convenience of description. In FIGS. 1 to 3 , there may be differences in the arrangement positions of the microwave oscillation units 500 , but these are exemplary and a plurality of microwave oscillation units 500 may be arranged at appropriate positions according to circumstances. In addition, Figures 1 to 3 are also shown together with the internal structure for convenience in order to explain the contaminated soil purification apparatus (10).

1 to 3 , the contaminated soil purification apparatus 10 according to an embodiment of the present disclosure includes a pretreatment unit 100 , a heating chamber 200 , a thermal desorption conveyor 300 , a dispersing member 400 , a microwave It includes all or a part of the oscillation unit 500 , the purified soil receiving unit 600 , and the condenser 700 .

The pre-processing unit 100 pulverizes the contaminated soil introduced from the outside to an appropriate size. In the pre-processing unit 100, the contaminated soil is fine-grained. Contaminated soil requires a pretreatment process for pulverizing soil particles because the efficiency of combustion by heat generated in the thermal desorption conveyor 300 is low when the particle size is large, such as in a bulk state. In the present disclosure, the pre-processing unit 100 preferably includes at least one of a pulverizer for pulverizing the contaminated soil and a selector for sorting the contaminated soil by particle size. Contaminated soil may be transferred to the pre-processing unit 100 using a separate transfer facility. The polluted soil pulverized by the pretreatment unit 100 preferably has a particle size of 10 mm or less, but is not necessarily limited thereto. The contaminated soil finely granulated in the pre-processing unit 100 is transferred to the thermal desorption conveyor 300 .

The heating chamber 200 includes a microwave oscillation unit 500 and a plurality of dispersion members 400 . The microwave oscillator 500 generates microwaves, and the generated microwaves are irradiated into the heating chamber 200 . A plurality of microwave oscillation units 500 may be disposed in the frame of the heating chamber 200 . A plurality of dispersing members 400 are disposed on the inner wall of the heating chamber 200 , and serve to disperse microwaves into the heating chamber 200 .

The thermal desorption conveyor 300 is disposed inside the heating chamber 200 . The lower portion 330 of the thermal desorption conveyor 300 has a half pipe shape. A conveyor screw 310 is disposed in the lower portion 330 of the thermal desorption conveyor 300 . Since the lower portion 330 of the thermal desorption conveyor 300 has a half-pipe shape, it can be moved while evenly mixing the contaminated soil using the conveyor screw 310 corresponding to the half-pipe shape. The upper part 320 of the thermal desorption conveyor 300 may have a 'C' shape with an open bottom, but is not limited thereto. The conveyor screw 310 disposed in the half-pipe structure of the thermal desorption conveyor 300 serves to transfer the fine-grained contaminated soil in the pre-processing unit 100 . By using the conveyor screw 310 to transport the finely-granulated contaminated soil and mix the finely-granulated contaminated soil, so that it can be heated to a uniform temperature.

When the contaminated soil finely granulated by the conveyor screw 310 is transferred, the inner wall of the lower portion 330 of the thermal desorption conveyor 300 and the particles of the contaminated soil continuously rub. Therefore, it is preferable that the inner wall of the thermal desorption conveyor 300 lower part 330 is made of a material with little wear and tear even when the contaminated soil is continuously transported. For example, in order to prevent abrasion, the inner wall of the lower portion 330 of the thermal desorption conveyor 300 may be coated with an overlay or subjected to surface hardening heat treatment.

Referring to FIG. 3 , a microwave heating unit 340 is attached to the outer wall of the lower portion 330 of the thermal desorption conveyor 300 . The microwave heating unit 340 may be made of a material that is heated by microwaves. The microwave heating unit 340 is attached to the outer wall of the lower portion 330 of the thermal desorption conveyor 300 , so that it does not directly contact the fine-grained contaminated soil transported by the conveyor screw 310 . Therefore, this arrangement can prevent the microwave heating part 340 from being scratched and damaged by the finely-granulated contaminated soil.

The microwave heating unit 340 is heated by microwaves and serves to indirectly heat the fine-grained contaminated soil. Since it is difficult to generate heat to a desired temperature when the micro-particled contaminated soil is directly irradiated with microwaves, there is an effect that the contaminated soil can be heated to a high temperature by using the microwave heating unit 340 .

Unlike the microwave heating unit 340 shown in FIG. 3 , it is not necessary to be disposed only on the outer wall of the lower portion 330 of the thermal desorption conveyor 300 . For example, the lower portion 330 of the thermal desorption conveyor 300 has an empty structure inside and is made of a material that can transmit microwaves, and a microwave heating unit 340 is formed in the empty space of the lower portion 330 of the thermal desorption conveyor 300 . ) may be built-in and arranged.

The microwave heating unit 340 may be formed of a ferroelectric that partially transmits microwaves. Microwaves transmitted from the ferroelectric can be irradiated to fine-grained contaminated soil.

The upper portion 320 of the thermal desorption conveyor 300 and the lower portion 330 of the thermal desorption conveyor 300 may be made of different materials. For example, the upper portion 320 of the thermal desorption conveyor 300 may be made of a ceramic material through which microwaves are transmitted. Since the ceramic material has low thermal conductivity, the lower portion 330 of the thermal desorption conveyor 300 is not made of a ceramic material. The lower portion 330 of the thermal desorption conveyor 300 may be made of a metal material having high thermal conductivity. Since the lower portion 330 of the thermal desorption conveyor 300 is made of a metal material having high thermal conductivity, the heat generated by the microwave heating unit 340 can be transferred to the contaminated soil to heat the contaminated soil.

The upper 320 of the thermal desorption conveyor 300 and the lower 330 of the thermal desorption conveyor 300 may be formed integrally, but are not limited thereto, and may be combined after a separate manufacturing process.

The upper portion 320 of the thermal desorption conveyor 300 may be made of a ceramic material. Accordingly, the microwave generated by the microwave oscillation unit 500 or the microwave reflected by the dispersing member 400 passes through the upper part 320 of the thermal desorption conveyor 300 and is irradiated to the fine-grained contaminated soil. When only the microwave oscillation unit 500 is used, a spark phenomenon due to local heating may occur in the device, but the dispersing member 400 may be disposed to uniformly heat the fine-grained contaminated soil.

The upper portion 320 of the thermal desorption conveyor 300 may be made of a material having a very low relative permittivity. The upper portion 320 of the thermal desorption conveyor 300 is preferably made of a material having a relative permittivity of 0.01 or less.

The fine-grained contaminated soil is, for example, directly heated by a microwave passing through the upper part 320 of the thermal desorption conveyor 300, and a microwave heating unit 340 attached to the lower part 330 of the thermal desorption conveyor 300. indirectly heated.

When the contaminated soil in the thermal desorption conveyor 300 is heated, the contaminants are vaporized. The vaporized contaminants pass through the upper pipe 710 and are condensed in the condenser 700 . Although not shown in the drawings, a separate pipe and a receiving part for this may be additionally configured under the thermal desorption conveyor 300 in order to classify a material that is liquefied without being vaporized by heating.

The purified soil receiving unit 600 is heated in the heating chamber 200 to accommodate the purified soil treated with contaminants. Specifically, the purified soil receiving unit 600 is heated in the thermal desorption conveyor 300 to accommodate the purified soil treated with contaminants. An end portion of the thermal desorption conveyor 300 is configured with a closed portion 610 . When the thermal desorption conveyor 300 and the purified soil receiving part 600 are connected by the closing part 610, it is made of a closed structure that does not communicate with the outside air.

Although not shown in FIGS. 1 to 3 , the contaminated soil purification apparatus 10 according to an embodiment of the present disclosure may further include a nitrogen supply pipe (not shown). The nitrogen supply pipe is provided to supply nitrogen gas to the inside of the thermal desorption conveyor 300 . One end of the nitrogen supply pipe may be disposed in connection with a portion of the thermal desorption conveyor 300 .

In order to purify the contaminated soil, the inside of the thermal desorption conveyor 300 is heated. When a fire occurs inside the thermal desorption conveyor 300 during the heating process, nitrogen is supplied into the thermal desorption conveyor 300 using a nitrogen supply pipe. This can prevent fires or extinguish them early. For example, when the temperature inside the thermal desorption conveyor 300 is greater than or equal to the preset limit temperature, it is determined that a fire has occurred inside the thermal desorption conveyor 300, and nitrogen is supplied using a nitrogen supply pipe to extinguish the fire early. have. Specifically, the contaminated soil purification apparatus 10 according to an embodiment of the present disclosure may heat the contaminated soil to around 500 degrees Celsius to vaporize the pollutants. Therefore, when the temperature inside the thermal desorption conveyor 300 rises to more than 600 degrees Celsius, it can be estimated that the temperature rise is caused by an internal fire rather than a temperature rise using microwaves. In this case, the internal temperature can be lowered using nitrogen have. In this case, the preset limit temperature is 600 degrees Celsius.

The present disclosure is a closed structure that blocks air from the outside from the place where the contaminated soil is pulverized by the pre-processing unit 100 and transferred into the heating chamber 200 to the purified soil receiving unit 600 for accommodating the purified soil. can be made with Therefore, as the inside of the thermal desorption conveyor 300 is heated, the internal pressure increases than the external pressure, and as a result, there is a technical feature that the thermal desorption efficiency of the contaminated soil can be increased.

4 is a perspective view of a dispersing member according to an embodiment of the present disclosure. 5 is a view for explaining the microwave reflection characteristics of the dispersing member according to an embodiment of the present disclosure. 6 is an example for explaining the principle of the dispersing member of the present disclosure.

The dispersing member 400 is disposed on the inner wall of the heating chamber 200 , and is configured to disperse the incident microwave into the inside of the heating chamber 200 , in particular, the inside of the thermal desorption conveyor 300 . The dispersing member 400 is formed to reflect the irradiated microwaves in various directions so that the microwaves heat the entire interior of the heating chamber 200 uniformly. In particular, the dispersing member 400 disperses the microwaves so that the contaminated soil inside the thermal desorption conveyor 300 is uniformly heated.

The dispersing member 400 may be made of a material that reflects microwaves, such as aluminum.

One dispersion member 400 may include a plurality of reflection units 410 . Referring to FIG. 4 , the dispersing member 400 includes first to fifth reflecting units 410a to 410e. The first to fifth reflection parts 410a to 410e may be formed to extend in a direction perpendicular to the bottom surface of the dispersion member 400 .

At least two of the plurality of reflectors 410 may have different heights l. Preferably, as shown in FIG. 5 , the plurality of reflection units 410 may be formed with different heights l.

Each reflector 410 may include an upper surface formed at one end of the reflector 410 and a side surface extending vertically from the upper surface. The reflector 410 does not necessarily have to face only and may have a curved top or side surface.

A plurality of dispersing members 400 may be separately disposed on the inner wall of the heating chamber 200 , but may be integrally formed. That is, each shape and arrangement structure of the plurality of reflective units 410 may be determined as one reflective pattern, and the dispersion member 400 in which the reflective pattern is repeated may be formed. One such integrated dispersion member 400 may be disposed on each wall surface of the inner wall of the heating chamber 200 .

The shape of the dispersing member 400 is not limited to the above-described shape, and if it is a shape capable of reflecting different phases of microwaves by varying the height l, it corresponds to the dispersing member 400 according to the present disclosure. For example, the dispersion member 400 may include a reflective portion having a hemisphere shape.

In FIG. 4 , the third reflective part 410c is formed to have a wider width than the other reflective parts, but the present invention is not limited thereto, and the first to fifth reflective parts 410a to 410e may be formed to have the same width f. can In addition, although the dispersion member is formed symmetrically with respect to the center line (C) in FIG. 4, this is exemplary and may not necessarily be formed symmetrically.

Each reflector 410 may have an upper surface, which is a region where microwaves are mainly reflected, and a side surface perpendicular to the upper surface. Each surface is formed as a facing, but may also be formed as a curved surface.

The shape of the dispersing member 400 shown in FIG. 4 is exemplary, and at least two reflective units 410 having different heights l among the reflective units 410 included in the dispersing member 400 are formed. If yes, it falls under the present disclosure.

Since the dispersing member 400 is composed of a plurality of reflection units 410 having different heights l, the height of the reflection unit 410 when the microwave reflects each reflection unit 410 of the dispersing member 400 ( l) Microwaves with different phases are generated according to the difference. As the phases of the reflected microwaves are varied, there is a technical feature of irradiating the microwaves with a uniform intensity to the area of the heating chamber 200 .

That is, when the microwave is incident on the dispersing member 400 , it collides with the surface of each reflective unit 410 and is reflected, collides with each reflective unit 410 of the opposite dispersing member 400 , and is reflected back. Since it is repeated, the microwaves may be evenly distributed in the area of the heating chamber 200 . Microwaves having different phases are formed according to the difference in length of the reflectors 410 by being reflected by each reflector 410 .

For example, referring to FIG. 5 , when the first microwave m1 is reflected by one reflective part, the reflected second microwave m2 is reflected by the reflective part disposed on the opposite side, and the height of the opposite reflective part is Microwaves having different phases may be formed when different from each other and reflected by the third microwave m3.

FIG. 6A is a graph illustrating a case in which microwaves reflect a general reflective surface, and FIG. 6B is a graph illustrating a case in which microwaves reflect a dispersion member according to an embodiment of the present disclosure.

When a flat reflector, not the dispersion member 400 according to an embodiment of the present disclosure, is disposed inside the heating chamber 200, the phase does not vary even when irradiated with microwaves. Microwaves flow through it. In this case, the region (Y) having a weak microwave intensity will not be heated, and only a specific region (X) having a strong microwave intensity is locally heated. In order to solve this problem, it is necessary to oscillate with various microwaves having different frequencies, but under the current law, the frequencies of microwaves that can be used for commercial purposes are limited. That is, a single frequency must be used. If the contaminated soil contains components that ignite at high temperatures, there is a risk of fire such as sparks due to excessive heating of some areas due to local heating.

Referring to FIG. 6B , when the dispersion member 400 according to an embodiment of the present disclosure is used, the microwaves are reflected by the reflectors 410 having different heights, so that microwaves of various phases are heated. A region of the chamber 200 may be irradiated. In the case of the present disclosure, dangerous situations such as spark generation can be prevented by irradiating microwaves with uniform intensity to all regions as shown in FIG. 6(b), and excessive local heating does not occur in some regions.

The above description is merely illustrative of the technical idea of this embodiment, and various modifications and variations will be possible without departing from the essential characteristics of the present embodiment by those of ordinary skill in the art to which this embodiment belongs. Accordingly, the present embodiments are intended to explain rather than limit the technical spirit of the present embodiment, and the scope of the technical spirit of the present embodiment is not limited by these embodiments. The protection scope of this embodiment should be interpreted by the claims below, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present embodiment.

100: pre-processing unit 200: heating chamber
300: thermal desorption conveyor 400: dispersing member
500: microwave oscillation unit 600: purified soil receiving unit
700: capacitor

Claims (15)

A pre-processing unit for treating contaminated soil into fine particles;
a heating chamber including a microwave oscillation unit generating microwaves and a plurality of dispersion members disposed on an inner wall to disperse the microwaves;
It is disposed inside the heating chamber, the lower part has a half pipe structure, and a pipe for collecting vaporized contaminants is connected to the upper end, and the polluted soil finely grained by the pretreatment unit in the half pipe structure is removed. A closed-type thermal desorption conveyor on which the conveying conveyor screw is disposed; and
Comprising a purified soil accommodating part for accommodating the purified soil heated in the heating chamber and treated with contaminants,
A microwave heating part that is heated by the microwave is disposed at a lower portion of the thermal desorption conveyor,
Contaminated soil purification apparatus, characterized in that the upper portion of the thermal desorption conveyor is made of a material through which the microwave is transmitted. According to claim 1,
The microwave heating unit,
Contaminated soil purification device, characterized in that it is attached to the outer wall of the lower portion of the thermal desorption conveyor. According to claim 1,
The lower portion of the thermal desorption conveyor is formed in an empty structure,
Contaminated soil purification apparatus, characterized in that the microwave heating part is disposed inside the lower portion of the thermal desorption conveyor. According to claim 1,
Contaminated soil purification apparatus, characterized in that by hardening or overlay coating the surface of the inner wall of the lower portion of the thermal desorption conveyor in order to prevent abrasion caused by the contaminated soil. delete According to claim 1,
Contaminated soil purification device, characterized in that the upper portion of the thermal desorption conveyor is made of a ceramic material. According to claim 1,
Contaminated soil purification apparatus, characterized in that the upper portion of the thermal desorption conveyor is made of a material having a relative permittivity of 0.01 or less. According to claim 1,
Further comprising a condenser connected to the pipe at the top of the thermal desorption conveyor,
Contaminants vaporized in the thermal desorption conveyor pass through the pipe at the top of the thermal desorption conveyor to reach the condenser and condensed contaminated soil purification apparatus. delete According to claim 1,
Contaminated soil purification apparatus further comprising a nitrogen supply pipe provided to supply nitrogen gas to the inside of the thermal desorption conveyor. 11. The method of claim 10,
When the temperature inside the thermal desorption conveyor is greater than or equal to a preset limit temperature, the contaminated soil purification apparatus, characterized in that for supplying nitrogen to the inside of the thermal desorption conveyor using the nitrogen supply pipe. A pre-processing unit for treating contaminated soil into fine particles;
a heating chamber including a microwave oscillation unit generating microwaves and a plurality of dispersion members disposed on an inner wall to disperse the microwaves;
A conveyor screw disposed inside the heating chamber, having a half-pipe structure at a lower portion, a pipe for collecting vaporized contaminants connected to an upper end, and conveying fine-grained contaminated soil from the pretreatment unit within the half-pipe structure Closed thermal desorption conveyor is disposed; and
Comprising a purified soil accommodating part for accommodating the purified soil heated in the heating chamber and treated with contaminants,
The dispersion member includes a plurality of reflective parts,
Contaminated soil purification apparatus, characterized in that at least two of the plurality of reflection units have different heights so that a plurality of microwaves having different phases are formed as the microwaves are reflected by the plurality of reflection units. 13. The method of claim 12,
The plurality of reflectors,
an upper surface formed at one end; and
a side extending vertically from the upper surface
Contaminated soil purification apparatus comprising a. 14. The method of claim 13,
The upper surface and the side surfaces are contaminated soil purification apparatus, characterized in that formed in any one of a flat surface and a curved surface. 13. The method of claim 12,
Contaminated soil purification apparatus, characterized in that the plurality of reflection parts are integrally formed with each other.

Images