KR102260311B1 - Heat treatment system for contaminated soil using heating rod - Google Patents

Abstract

The present invention relates to a heat treatment device for contaminated soil using a heating rod which comprises: a housing in which contaminated soil is stored; and a plurality of heating rods which are detachably formed at the housing and selectively apply heat to the contaminated soil. According to the present invention, purification efficiency of the contaminated soil can be possible.

Description

Heat treatment system for contaminated soil using heating rod

The present invention relates to a device for purifying contaminated soil by thermal desorption by insertion of a heating rod.

Recently, the seriousness of soil and groundwater contamination due to wastes and hazardous chemicals generated by population growth and industrial development around the world has increased, and the importance of the soil environment affected by development projects is emerging.

In particular, with the continuous economic development and the improvement of the income level, the consumption of oil has greatly increased due to the supply of automobiles along with industrial activities. Accordingly, the problem of soil and groundwater contamination due to the leakage of oil and hazardous chemicals classified as non-aqueous phase liquids (NAPLs) from oil storage tanks at gas stations and underground storage tanks for industrial facilities storing chemical substances has been highlighted.

Accordingly, techniques for purifying contaminated soil using various heat treatment systems (thermal desorption systems) have been proposed. Here, the heat treatment system is a system that separates and removes contaminants contained in the contaminated soil through a thermal desorption reaction, and burns the contaminants by directly heating the contaminated soil to a high temperature. As a prior document, Korean Patent Registration No. 10-847058, etc. also relates to a heat treatment system for such contaminated soil.

The technology includes a dryer for drying the contaminated soil and separating and discharging waste gas generated during drying from the contaminated soil; a pyrolysis device for separating the contaminated soil into purified soil and pyrolysis gas by indirectly heating the dried contaminated soil in a closed state, and then separately discharging the purified soil and pyrolysis gas; a conveying fan for forcibly conveying the discharged pyrolysis gas; a burner for heating the pyrolysis device by oxidizing the waste gas discharged from the dryer and the pyrolysis gas forcibly transported from the transfer fan; It consists of a cooling facility that cools the discharged purified soil by spraying cooling water directly.

However, in the case of the above technology, there is a problem in that it is not easy to move to an area where the purification of contaminated soil is to be performed due to its own weight, etc., and there is a problem in that selective treatment according to the capacity of the contaminated soil to be treated is not easy.

Korean Patent Registration No. 10-847058

The present invention has been devised to solve the above problems, and by making it a unit so that it can be applied directly on the ground in the field, the mobility to the purification zone is improved, and the efficient and stable thermal desorption according to the capacity of the contaminated soil to be treated. It is intended to provide a heat treatment device for contaminated soil that can be treated.

Contaminated soil heat treatment apparatus (hereinafter referred to as "apparatus of the present invention") using a heating rod of the present invention as a means for solving the above-mentioned problems, a housing in which the contaminated soil is stored; A plurality of heating rods configured to be detachably attached to the housing and capable of selectively applying heat to the contaminated soil; characterized in that it comprises a.

As an example, the housing is partitioned by a partition wall, and a storage part for storing contaminated soil is configured on the lower part, a collecting part for collecting gas generated through heat treatment is configured on the upper part, and a fastening hole for fastening the heating rod is formed on the upper surface. do.

As an example, the heating rod is fastened to the fastening hole and is characterized in that it includes a head having a terminal exposed to enable electrical connection with an external power source, and a body having a heating wire embedded in the lower part of the head to generate heat.

As an example, the body is characterized in that it is composed of a heating part having a heating wire embedded therein and inserted into the storage part and a non-heating part embedded in the collecting part on the upper part of the heating part.

As an example, the heating part and the non-heating part are made of a heat-insulating material, a space is formed therein, and a connection body having a connection hole for electrical connection with a heating wire and a heating part and a non-heating part are respectively fastened at both ends of the connection body It is characterized in that it is connected by a heat-blocking connector including a fastening rim.

As an example, the barrier rib is formed of a mesh network through which gas passes, and a through hole opposite the fastening hole is formed in the barrier rib to allow the body to pass through, and the through hole is formed in the central portion to face the through hole. A condensed water storage device comprising a second through hole through which the non-heating unit passes in the body, and a condensed water storage device that is connected to the second through hole so that the cross section is formed in a concave shape to induce and store water droplets condensed in the non-heating unit characterized by being

As described above, the device of the present invention is unitized and easily moved to a contaminated soil treatment site, and the heat treatment capacity can be easily selected, thereby increasing the purification efficiency of the contaminated soil.

In addition, the apparatus of the present invention has an advantage in that it is possible to control the pollution and load of the rear end by reducing and discharging heat and absolute humidity from the gas generated during the heat treatment process.

1 is a side cross-sectional view showing the device of the present invention,
2 is a schematic diagram showing an embodiment of the present invention,
3 is a schematic diagram showing a heating rod as one configuration of the present invention,
Figure 4 is a side cross-sectional view showing an example of the heating rod shown in Figure 3,
5 is a partial view showing another embodiment of the present invention.

Hereinafter, the configuration and operation of the present invention will be described in more detail based on the accompanying drawings. In describing the present invention, the terms or words used in the present specification and claims are based on the principle that the inventor can appropriately define the concept of the term in order to best describe his or her invention. It must be interpreted as a meaning and concept consistent with the technical idea of

The apparatus 1 of the present invention includes a housing 2 in which contaminated soil is stored, as shown in FIG. 1 ; A plurality of heating rods (3) configured to be detachably attached to the housing (2) and selectively apply heat to the contaminated soil; characterized in that it includes.

That is, the device 1 of the present invention relates to a technology for thermal desorption of the contaminated soil of the housing 2 by heating the heating rod 3 in a state where the contaminated soil is embedded in the housing 2 . Since the housing 2 and the heating rod 3 are unitized and can be used by assembly in the field, they have excellent mobility and can control the heat applied to the heating rod 3, thereby enabling efficient operation.

As shown in FIG. 1, the housing 2 is partitioned by a partition wall 23, and a storage unit 21 for storing contaminated soil (S) is configured at the lower portion, and gas generated through heat treatment is collected at the upper portion. The part 22 is configured and a fastening hole 23 to which the heating rod 3 is fastened is formed on the upper surface.

Although not shown in the drawings, the storage unit 21 is configured to form a door that can be opened and closed so that the contaminated soil is accommodated in the storage unit 21 through the door.

The collecting unit 22 is a space in which gas generated during the thermal desorption process is collected. Although not shown in the drawings, a gas discharge line is formed in the collecting unit 22 so that the gas is discharged to the outside.

In addition, although the housing 2 is not shown in the drawings, it is appropriate that the outer surface is formed of a heat insulating material or a heat insulating structure to control the outflow of heat by the heating rod 3 to the outside.

Here, since various known materials or known structures exist for the insulating material or the insulating structure, a detailed description thereof will be omitted.

The heating rod 3 is fastened to the fastening hole 23 as shown in FIGS. 1 to 3 and the terminal 311 for electrical connection with the external power source 5 is exposed with the head 31 and , It characterized in that it includes a body 32 in which the heating wire 321-1 is embedded in the lower part of the head 31 to generate heat.

The head 31 is fastened to the fastening hole 23 so that the terminals 311 are exposed to the outside so that each terminal 311 is electrically connected to the power source 5 so that electricity is applied as shown in FIG. 2 . will do As shown in FIG. 2 , the application of electricity is such that the application is made under the control of the control unit 4 , and the heating rod 3 to which electricity is applied by the control of the control unit 4 can be selected.

Since the structure in which the head 31 is fastened so that the upper end is exposed in the fastening hole 23 may be implemented by various known structures, a detailed description thereof will be omitted. However, in this structure, a watertight structure is placed between the exposed head 31 and the fastening hole 23 to prevent the gas from being exposed.

In the heating rod 3, the body 32 has a heating wire 321-1 embedded therein, and the heating part 321 embedded in the storage part 21 and the heating part 321 are collected from the upper part. It is characterized in that it is composed of a non-heating part 322 that is embedded in the part 22 .

That is, the heating wire 321-1 is embedded only in the heating part 321, and the heating wire 321-1 is only embedded in the non-heating part 321 so that only the wire 322-1 for electrical connection with an external power source is embedded. This is so that heat is generated only in the portion 321 .

The reason for this configuration is that the heating unit 321 generates heat in the storage unit 21 in which the contaminated soil S is embedded to induce thermal desorption of the contaminated soil S, and the gas generated in the thermal desorption process is collected It is collected by the part 22, and the gas collected in the collecting part 22 is a high-temperature gas. In particular, when the moisture content of the contaminated soil is high, it is a high-temperature and high-humidity gas. When this high-temperature and high-humidity gas is discharged to the outside, white smoke, etc. may be generated. The concern is high, and there is a high possibility that a load will be generated on the post-processing device when the post-processing device is passed. Accordingly, in the present invention, the non-heating unit 322 is embedded in the collecting unit 22 so that heat is radiated from the high-temperature and high-humidity gas in the non-heating unit 322 . The heat transferred to the non-heating unit 322 is discharged to the outside through the head 31 . For this purpose, it is reasonable that the heating unit 321, the non-heating unit 322, and the head 31 are made of an aluminum material having high thermal conductivity.

That is, the heating rod 3 functions as a heating means in the storage unit 21 and functions as a heat dissipation means in the collecting unit 22 .

Accordingly, an embodiment for further doubling the function of the non-heating unit 322 as a heat dissipation means is illustrated in FIG. 4 .

In this embodiment, the heating part 321 and the non-heating part 322 are made of a heat-insulating material, a space 711 is formed therein, and a connection hole 712 for electrical connection with the heating wire 321-1 is provided. Connected by a heat-blocking connector 7 including fastening rims 72 and 73 that are fastened to the heating part 321 and the non-heating part 322 on both sides of the configured connection body 71 and the connection body 71, respectively. is characterized by

That is, the heat transfer between the heating unit 321 and the non-heating unit 322 is controlled by the configuration of the heat blocking connector 7 .

To this end, first of all, the heat-blocking connector 7 is preferably made of a heat-blocking material as various known materials. Here, the heat-blocking material uses a material having a relatively low thermal conductivity, so that the heating part 321 and the non-heating part 322 are used as the material itself. To each other, heat transfer is controlled.

In addition, structurally, the space 711 is formed inside the connection body 71 where the heating part 321 and the non-heating part 322 are in contact with each other to form a mutual heat shielding structure.

As shown in the drawing, the fastening rims 72 and 73 protruding from both sides of the connection body 71 are inserted into the heating part 321 and the non-heating part 322, respectively, so that they are heated by the heat-blocking connector 7 The part 321 and the non-heating part 322 are interconnected.

The barrier rib 23 is configured such that the gas (g) generated in the thermal desorption process in the storage unit 21 flows upward and is collected by the collecting unit 22 through the barrier rib 23. For this purpose, the barrier rib ( 23) is appropriate to be composed of a mesh network in which a plurality of gaps are formed.

In this way, the barrier rib 23 is configured as a mesh network in which a plurality of gaps are formed to allow the gas g to penetrate the barrier rib 23 through the gap as well as foreign substances mixed in the gas g during the penetration process. This is to ensure that filtration is performed by That is, the contaminants contained in the gas g are primarily filtered out from the partition wall 23 .

Although not shown in the drawings, it is preferable that the partition wall 23 is configured to be detachable from the housing 2 to facilitate cleaning or replacement when the partition wall 23 is blocked.

As shown in FIG. 5 , a through hole 231 opposite to the fastening hole 23 is formed in the partition 23 to allow the body 32 to pass therethrough.

However, as mentioned above, although the heating part 321 and the non-heating part 322 are configured to be thermally blocked, the moisture mixed in the gas (g) during the heat dissipation process of the non-heating part 322 is not heated by the non-heating part 322 . It is condensed and condensed into condensed water (w), and the generation of such condensed water (w) lowers the absolute humidity from the gas (g) so that problems such as white smoke generation are controlled. 322 ) and is transmitted to the heating unit 321 through the gap between the through hole 231 or the partition wall 23 , there is a problem in that the heating efficiency of the heating unit 321 is reduced.

Accordingly, in this embodiment, at the position where the through hole 231 is formed, the second through hole 61 through which the non-heating part 322 passes in the body 32 opposite to the through hole 231 in the central part; The condensed water storage device 62 is included in the rim recess 62 so that the condensed water droplets are induced and stored in the non-heating part 322 so that the cross section is formed in a concave shape in connection with the second through hole 61. to solve the above problems.

As shown in the drawing, the condensed water storage port 62 is configured on the upper part of the partition wall 23, and the condensed water formed on the outer periphery of the non-heating part 322 falls and is guided to the edge recess 62 and stored. By blocking the transfer of water to the heating unit 321 located at the bottom, the thermal efficiency is prevented from being lowered, and the condensed water, which may contain a large amount of contaminants, is re-introduced into the polluted soil below, thereby reducing the thermal desorption efficiency. to prevent it from happening.

The condensed water stored in the edge recess 62 by the operation mechanism as described above is to be treated by opening the housing 2 after thermal desorption is completed.

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 content described in the detailed description of the specification, but should be defined by the claims.

1: device of the present invention 2: housing
3: heating rod

Claims (6)

a housing in which contaminated soil is stored;
a plurality of heating rods configured to be detachably attached to the housing and selectively applying heat to the contaminated soil;
including,
The housing is partitioned by a partition wall, the lower part is configured to store contaminated soil, the upper part is configured to collect gas generated through heat treatment, and the upper surface is formed with a fastening hole to which the heating rod is fastened,
The heating rod includes a head that is fastened to the fastening hole and has a terminal exposed to enable electrical connection with an external power source, and a body in which a heating wire is embedded under the head to generate heat,
The body consists of a heating part having a heating wire embedded therein and inserted into the storage part, and a non-heating part embedded in the collecting part on the upper part of the heating part,
The partition wall is composed of a mesh network through which gas passes, and a through hole opposite the fastening hole is formed in the partition wall so that the body passes through,
At the position where the through-hole is formed, a second through-hole through which the non-heating part in the body passes opposite the through-hole in the central part is formed in a concave shape in connection with the second through-hole, so that the water droplets condensed on the non-heated part Contaminated soil heat treatment apparatus using a heating rod, characterized in that it includes a condensed water storage device consisting of a rim groove to be stored.
delete delete delete The method of claim 1,
The heating part and the non-heating part are made of a heat-blocking material, a space is formed therein, a connection body having a connection hole for electrical connection with a heating wire, and a fastening border fastened to the heating part and the non-heating part at both ends of the connection body, respectively Contaminated soil heat treatment apparatus using a heating rod, characterized in that it is connected by a heat-blocking connector comprising.

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