KR102390455B1 - Sludge recovery apparatus - Google Patents

Abstract

The present invention relates to a sludge recovery device. The sludge recovery apparatus according to an embodiment of the present invention includes an outer hydrocyclone unit forming a space of a set volume therein; an inner hydro cyclone unit located in the inner space of the outer hydro cyclone unit, the upper end being fixed to the upper wall of the outer hydro cyclone unit, and the lower end being provided to be open; and a main discharge member provided in a pipe structure having a set length and inserted into an upper wall of the outer hydro cyclone unit to be connected to the inner space of the inner hydro cyclone unit.

Description

Sludge recovery apparatus

The present invention relates to a sludge recovery device, and more particularly, to a sludge recovery device capable of effectively separating and recovering sludge mixed with water from a radioactive waste treatment system of a nuclear power plant.

In general, sludge composed of various organic and inorganic oxidizing substances is accumulated on the bottom of the tank for the radioactive waste treatment system of a nuclear power plant, and the inner wall of the tank has a layer of free and adherent oxide contamination depending on the material, use and degree of oxidation inside the tank. is accumulated. In order to safely dismantle a radioactively contaminated tank, it is necessary to recover and treat the radioactive sludge in advance because of the presence of sludge inside the tank and the contamination characteristics on the inner wall.

In general, there are centrifuges, which have been found to be effective in concentrating and dewatering sludge, and hydrocyclones specially invented for liquid treatment.

First, a centrifuge is a mechanical device used to separate, purify, and concentrate substances with different components or specific gravity using centrifugal force. The centrifuge can continuously repeat the process, process a large amount in a short time, and it is easy to operate in a sterile state. However, since a large amount of material is required for the test, the equipment becomes larger, the installation capital and maintenance cost are high, and there are problems in that there is a lot of energy consumption.

On the other hand, a hydrocyclone is a water treatment device that separates particles from a suspension using sedimentation by centrifugal force and the resistance of the fluid. This device is capable of continuous operation even in internal friction or extreme cold conditions, and is very versatile, such as being used not only for solid-liquid separation at low cost, but also for high-high, air-go and oil-water separation. there is

An object of the present invention is to provide a sludge recovery device capable of effectively separating and recovering sludge discharged in a mixed state with water from a radioactive waste treatment system of a nuclear power plant.

Another object of the present invention is to provide a sludge recovery device capable of effectively separating sludge by using a large centrifugal force generated through rotation.

According to an aspect of the present invention, an outer hydro cyclone unit forming a space of a set volume therein; an inner hydro cyclone unit located in the inner space of the outer hydro cyclone unit, the upper end being fixed to the upper wall of the outer hydro cyclone unit, and the lower end being provided to be open; and a main discharge member provided in a pipe structure having a set length and inserted into an upper wall of the outer hydro cyclone unit to be connected to the inner space of the inner hydro cyclone unit.

In addition, the outer hydro cyclone portion, located on the upper portion of the outer hydro cyclone portion, in the shape of a pipe having a set length in the vertical direction, the upper end is blocked by the upper wall and the lower end is a partition flow portion provided in an open state; and a confluence part connected to the lower end of the divided flow part and formed to have a smaller cross-sectional area of the inner space toward the bottom.

In addition, the inner hydro cyclone unit, the outer surface may be positioned to be spaced apart from the inner surface of the outer hydro cyclone unit by a set distance, and the vertical length may be provided to correspond to the vertical length of the divided flow part.

In addition, it may further include a collection chamber having a space of a set volume therein and connected to the lower end of the outer hydrocyclone part.

In addition, in the inner space of the inner hydrocyclone part, spaced a set distance downward from the lower end of the main discharge member, may further include a rotation member provided rotatably.

According to an embodiment of the present invention, there can be provided a sludge recovery device capable of effectively separating and recovering sludge that is discharged in a mixed state with water from a radioactive waste treatment system of a nuclear power plant.

In addition, according to an embodiment of the present invention, after generating a large centrifugal force through rotation, there may be provided a sludge recovery device capable of effectively separating sludge using this.

1 is a view showing a sludge recovery apparatus according to an embodiment of the present invention.
FIG. 2 is a longitudinal cross-sectional view of the sludge recovery device of FIG. 1 .
3 is a cross-sectional view of the upper end of the sludge recovery device of FIG.
FIG. 4 is a view showing a state in which a first supply pipe and a second supply pipe are connected to the sludge recovery device of FIG. 1 .
FIG. 5 is a view showing the rotation member of FIG. 1 .
6 is a view showing an operating state of the sludge recovery device of FIG.

Hereinafter, an embodiment of the present invention will be described in more detail with reference to the accompanying drawings. Embodiments of the present invention may be modified in various forms, and the scope of the present invention should not be construed as being limited to the following embodiments. This embodiment is provided to more completely explain the present invention to those of ordinary skill in the art. Accordingly, the shapes of elements in the drawings are exaggerated to emphasize a clearer description.

1 is a view showing a sludge recovery device according to an embodiment of the present invention, FIG. 2 is a longitudinal cross-sectional view of the sludge recovery device of FIG. 1, FIG. 3 is a cross-sectional view of the upper end of the sludge recovery device of FIG. 1, and FIG. 4 1 is a view showing a state in which the first supply pipe and the second supply pipe are connected to the sludge recovery device of FIG. 1 , and FIG. 5 is a view showing the rotating member of FIG. 1 .

1 to 5 , the sludge recovery device 1 includes an outer hydrocyclone unit 10 , an inner hydrocyclone unit 20 , a collection chamber 30 , and a main discharge member 40 .

The outer hydrocyclone part 10 is provided to form a space with a set volume therein. The outer hydrocyclone part 10 includes a partitioned flow part 110 and a merging part 120 .

The partition flow part 110 is located on the outer side of the hydrocyclone part 10 . The partition flow unit 110 is provided in the shape of a pipe having a set length in the vertical direction, the upper end is blocked by the upper wall 130 and the lower end is provided in an open state. The cross-sectional shape of the inner space of the partitioned flow unit 110 may be constantly provided along the vertical direction. The inner space of the partition flow unit 110 may be provided in a cylindrical shape.

The merging part 120 is positioned to be connected to the lower end of the partition flow part 110 . The merging part 120 is formed so that the cross-sectional area of the inner space becomes smaller as it goes downward. For example, the inner surface of the confluence part 120 may be provided to be inclined toward the inner center as it goes downward. The lower end of the confluence part 120 is provided to be open. The vertical length of the merging part 120 may be provided to be shorter than the vertical length of the divided flow part 110 .

The inner hydro cyclone unit 20 is located in the inner space of the outer hydro cyclone unit 10 . The upper end of the inner hydro cyclone unit 20 is fixed to the upper wall 130 of the outer hydro cyclone unit 10, and the lower end is provided to be open. The outer surface of the inner hydro cyclone unit 20 is positioned to be spaced apart from the inner surface of the outer hydro cyclone unit 10 by a set distance. The inner space of the inner hydrocyclone unit 20 may be provided in a cylindrical shape or a polygonal column shape. The vertical length of the inner hydrocyclone unit 20 may be provided to correspond to the vertical length of the partition flow unit 110 . On a horizontal plane, the center of the inner hydro cyclone unit 20 may be positioned to correspond to the center of the outer hydro cyclone unit 10 . As an example, the inner hydrocyclone unit 20 and the divided flow unit 110 may be provided in the form of concentric circles. The cross-sectional area of the inner space of the inner hydrocyclone unit 20 is greater than the cross-sectional area of the lower end of the confluence part 120 .

The collection chamber 30 has a space of a set volume therein, and is connected to the lower end of the outer hydrocyclone unit 10 . For example, an underflow nozzle 125 having a set length may be connected to the lower end of the merging part 120 , and the collection chamber 30 may be connected to the underflow nozzle 125 . A sludge valve 126 may be provided at one point in the longitudinal direction of the underflow nozzle 125 .

The main discharge member 40 discharges the water from which the sludge is separated. The main discharge member 40 is provided in a pipe structure having a set length, and is inserted into the upper wall 130 of the outer hydro cyclone unit 10 so as to be connected to the inner space of the inner hydro cyclone unit 20 . For example, the main discharge member 40 may be positioned to be vertically aligned with the central region of the inner hydrocyclone unit 20 .

A discharge pipe 41 is connected to the upper portion of the main discharge member 40 . A discharge valve 42 may be located at one point in the longitudinal direction of the discharge pipe 41 . The discharge valve 42 opens and closes the discharge pipe 41 . In addition, the discharge valve 42 may control the degree of opening of the discharge pipe 41 . A recovery pipe 45 is branched at one point in the longitudinal direction of the discharge pipe 41 . The return pipe 45 may branch at a point upstream of the discharge valve 42 . The recovery pipe 45 passes through the outer hydro cyclone unit 10 and is connected to the inner space of the inner hydro cyclone unit 20 . Water discharged through the main discharge member 40 may be supplied to the inner space of the inner hydrocyclone unit 20 through the recovery pipe 45 . The longitudinal direction of the recovery pipe 45 connected to the inner hydro cyclone unit 20 may be formed to face a tangential direction of a point spaced a set distance from the center of the inner hydro cyclone unit 20 on a horizontal plane. A recovery valve 46 may be positioned at one point in the longitudinal direction of the recovery pipe 45 . The recovery valve 46 opens and closes the recovery pipe 45 . In addition, the recovery valve 46 may control the degree of opening of the recovery pipe 45 .

A first insertion hole 111 and a second insertion hole 112 are formed on a side surface of the upper end of the partition flow unit 110 . An inner insertion hole 210 is formed at the upper end of the inner hydrocyclone unit 20 . A first supply pipe 151 may be inserted into the first insertion hole 111 . The first supply pipe 151 is connected to the space formed between the outer hydrocyclone unit 10 and the inner hydrocyclone unit 20 to supply a suspension including sludge. The first insertion hole 111 may be formed so that the inserted first supply pipe 151 faces a tangential direction of a point spaced a set distance from the center of the outer hydrocyclone part 10 on a horizontal plane.

The inner insertion hole 210 may be formed to face the second insertion hole 112 on a horizontal plane. A second supply pipe 152 may be inserted into the second insertion hole 112 and the inner insertion hole 210 . The second supply pipe 152 supplies water to the inner space of the inner hydrocyclone unit 20 . For example, the second supply pipe 152 may supply pure water. The first insertion hole 111 , the second insertion hole 112 , and the inner insertion hole 210 have the same direction as the suspension discharged from the first supply pipe 151 and the water discharged from the second supply pipe 152 . can be positioned to rotate. In addition, the position where the second insertion hole 112, the inner insertion hole 210, and the recovery pipe 45 are connected to the inner hydrocyclone unit 20, the water introduced through the second supply pipe 152 and, The water introduced into the recovery pipe 45 may be positioned to rotate in the same direction.

A rotation member 50 may be provided in the inner space of the inner hydrocyclone unit 20 by a set distance downward from the lower end of the main discharge member 40 . A rotation shaft 51 is connected to the upper portion of the central region of the rotation member 50 , and an upper end of the rotation shaft 51 is connected to the driving member 52 . The rotating member 50 may be located in the central region of the inner hydrocyclone unit 20 in the longitudinal direction. Accordingly, the rotating member 50 and the rotating shaft 51 are rotatably provided by the power provided by the driving member 52 . For example, the rotating shaft 51 extends upward and is provided to pass through the upper portion of the main discharging member 40 , and the driving member 52 may be connected to the upper end of the rotating shaft 51 above the main discharging member 40 . there is. The driving member 52 may be provided with a variable rotation speed. The driving member 52 may be a motor. In addition, a bearing 53 may be provided in a region where the rotation shaft 51 and the main discharge member 40 contact each other.

The rotating member 50 includes a connecting portion 500 and an intersecting portion 501 .

The connecting portion 500 has a set length and is provided so that the longitudinal direction crosses the vertical direction. For example, the longitudinal direction of the connection part 500 is provided to be positioned on a horizontal plane. The length of the connection part 500 may be greater than the diameter of the opening at the bottom of the main discharge member 40 . The connection part 500 may have a length symmetrical in both directions about the rotation axis 51 .

The crossing parts 501 are respectively located at both ends of the connection part 500 . The crossing portion 501 has a set length and is provided so that the longitudinal direction is directed upwards and downwards. The upper end of the cross section 501 is provided to extend a predetermined length above the connecting section 500 . In addition, the lower end of the cross section 501 may be provided to extend a set length downward of the connection part 500 , or may be provided to be connected to both ends of the connection part 500 . The upper end of the cross section 501 may be provided to be positioned below the lower end of the main discharge member 40 .

6 is a view showing an operating state of the sludge recovery device of FIG.

Hereinafter, with reference to FIG. 6, the operation|movement of the sludge recovery apparatus 1 is demonstrated.

In order to operate the sludge recovery device 1 , the first supply pipe 151 is inserted into the first insertion hole 111 and connected to the space between the outer hydrocyclone unit 10 and the inner hydrocyclone unit 20 . and the second supply pipe 152 is inserted into the inner insertion hole 210 after being inserted into the second insertion hole 112 , and is connected to the inner space of the inner hydrocyclone unit 20 . Further, the driving member 52 is operated to rotate the rotating member 50 . The rotation speed of the rotating member 50 may be variably adjusted according to the supplied suspension, the supplied water, the amount of water discharged through the main discharging member 40 , and the like.

이 작용하며, 이에 따라 현탁액에 포함된 슬러지 입자는 외측 방향으로 보다 큰 힘을 받는다.The suspension supplied through the first supply pipe 151 is moved downward while rotating in a spiral form in the space between the outer hydrocyclone part 10 and the inner hydrocyclone part 20 . Upon rotation, the suspension exerts a centrifugal force (

, and thus the sludge particles contained in the suspension are subjected to a greater force in the outward direction.

The water supplied through the second supply pipe 152 rotates in a spiral shape along the inner wall of the inner hydrocyclone unit 20 and moves downward while forming a cocurrent with the suspension. At this time, the flow of water to the main discharge member 40 is blocked by the rotating member 50 . In particular, in the course of rotating the rotating member 50 , the rotating member 50 forms a cylindrical partition to effectively block the flow of water to the main discharge member 40 .

Suspension and water meet each other at the lower end of the partition flow unit 110 and the inner hydrocyclone unit 20 . Thus, the suspension and water meet after momentum is formed through the two paths, and have a greater momentum than if they flowed through a single path. In addition, the water flowing through the inner hydrocyclone unit 20 is located inside the suspension. Accordingly, the sludge contained in the suspension is blocked from flowing in the inward direction by the water flowing through the inner hydrocyclone unit 20 . As a result, the sludge is moved downward while receiving centrifugal force in the outward direction, and then is discharged to the collection chamber 30 through the nozzle 125 . And, according to the rotation of the rotating member 50 and the rotating shaft 51 , the water moving to the lower end of the merging part 120 is guided to move upward, and then discharged through the main discharging member 40 after rising.

In addition, whether or not water is supplied to the inner hydrocyclone unit 20 through the recovery pipe 45 and the amount of supplied water may be controlled through the discharge valve 42 and the recovery valve 46 . Accordingly, the water discharged through the main discharge member 40 is introduced back into the inner space of the inner hydrocyclone unit 20 through the recovery pipe 45, and can be used for filtration of the suspension. Water flows more effectively in a spiral shape inside the inner hydrocyclone unit 20 , and the amount of water supplied through the second supply pipe 152 can be reduced.

The above detailed description is illustrative of the present invention. In addition, the above description shows and describes preferred embodiments of the present invention, and the present invention can be used in various other combinations, modifications, and environments. That is, changes or modifications are possible within the scope of the concept of the invention disclosed herein, the scope equivalent to the written disclosure, and/or within the scope of skill or knowledge in the art. The written embodiment describes the best state for implementing the technical idea of the present invention, and various changes required in specific application fields and uses of the present invention are possible. Accordingly, the detailed description of the present invention is not intended to limit the present invention to the disclosed embodiments. Also, the appended claims should be construed to include other embodiments.

10: outer hydro cyclone portion 20: inner hydro cyclone portion
30: collection chamber 40: main exhaust member
50: rotation member 110: partition flow part
120: junction 130: upper wall
500: connection 501: intersection

Claims (5)

an outer hydrocyclone unit forming a space of a set volume therein;
an inner hydro cyclone unit located in the inner space of the outer hydro cyclone unit, the upper end being fixed to the upper wall of the outer hydro cyclone unit, and the lower end being provided to be open; and
It is provided in a piping structure having a set length, and includes a main discharge member inserted into the upper wall of the outer hydro cyclone unit so as to be connected to the inner space of the inner hydro cyclone unit,
In the inner space of the inner hydro cyclone part, spaced a set distance downward from the lower end of the main discharge member, further comprising a rotating member provided rotatably,
The rotating member includes a rotating shaft connected to the driving member to provide power, a connecting portion having a length symmetrical in both directions about the rotating shaft at an end of the rotating shaft and larger than a diameter of an opening at the bottom of the main discharge member; The sludge recovery apparatus, characterized in that it is formed to have a predetermined length along the vertical direction at both ends and includes an intersection portion positioned so that the upper end is disposed below the lower end of the main discharge member. According to claim 1,
The outer hydrocyclone unit,
It is located on the upper portion of the outer hydro cyclone, and has a pipe shape having a set length in the vertical direction, the upper end is blocked by the upper wall and the lower end is provided in an open state flow section; and
The sludge recovery device including a merging part connected to the lower end of the divided flow part and formed to have a smaller cross-sectional area of the inner space toward the bottom. 3. The method of claim 2,
The inner hydro cyclone unit, the outer surface is positioned to be spaced apart from the inner surface of the outer hydro cyclone unit by a set distance, the vertical length of the sludge recovery device provided to correspond to the vertical length of the flow section. According to claim 1,
The sludge recovery device further comprising a collection chamber having a space of a set volume therein and connected to the lower end of the outer hydrocyclone part. delete

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