KR101801083B1 - Apparatus for separating resin in spent resin mixture produced from nuclear power plants - Google Patents

Abstract

The present invention relates to a device for separating waste resin from a waste resin mixture produced in a nuclear power plant. According to an embodiment of the present invention, the device for separating waste resin from a waste resin mixture produced in a nuclear power plant comprises a selecting tank, a buffer tank, a circulating tank, a 1-1 pipe, a 1-2 pipe, a 2-1 pipe, and a 2-2 pipe. The device for separating waste resin from a waste resin mixture produced in a nuclear power plant according to the present invention can separate the waste resin mixture depending on a particle size.

Description

TECHNICAL FIELD The present invention relates to an apparatus for separating a waste resin from a waste-

The present invention relates to an apparatus for separating effluent from a waste water mixture generated in a nuclear power plant.

The waste water generated from the operation of a nuclear power plant (nuclear power plant) is classified as middle-level wastes because the concentration of C-14 in the wastewater is high, and it is difficult to treat because it is higher than the total amount standard of the Korea Nuclear Environment Authority. Also, in order to dismantle nuclear power plants in the future, it is necessary to deal with nuclear power plants. Therefore, countermeasures are urgently needed.

When the contaminated water is continuously circulated in the nuclear power plant, ions are generated and adversely affect the operation. The porous resin is used to collect anions. Activated carbon and zeolite are also used for ion capture.

Since waste water, activated carbon, and zeolite generated from nuclear power plants are mixed and stored in large-scale storage tanks, it is necessary to first separate activated carbon and zeolite from such waste water mixture, and to treat the separated waste water by removing C-14 .

Korean Patent No. 10-1102438

SUMMARY OF THE INVENTION Accordingly, the present invention has been made in view of the above circumstances, and an object of the present invention is to provide a method for separating waste water from a waste water mixture generated in a nuclear power plant for treating a radioactive material C-14 in a mixture of waste water, activated carbon and zeolite generated from the nuclear power plant And to provide a device.

In order to achieve the above object, the apparatus for separating waste water from a waste water mixture mixed with waste water, activated carbon and zeolite generated from a nuclear power plant according to the present invention is a cylindrical container, A first mesh screen disposed at a lower portion of the inlet and having a first mesh screen, a second mesh screen spaced apart from a lower portion of the first mesh screen and having a second mesh network of a smaller size than the first mesh screen, A screening tank having two screens; 1. A cylindrical container comprising: a buffer tank having a third screen having a third mesh net; 1. A cylindrical container comprising: a circulation tank having a fourth screen having a fourth mesh net; A 1-1 pipeline extending from the screening tank to an upper portion of the buffer tank; A 1-2 pipe leading from the bottom of the buffer tank to the selection tank; A second-1 pipe leading from the selection tank to an upper portion of the circulation tank; A second -2 pipe leading from the lower portion of the circulation tank to the selection tank; Wherein the waste water mixture injected through the inlet is separated from the first screen and the second screen according to the particle size, and the separated waste water is circulated through the first 1-1 pipe and the 1-2 pipe, And the separated activated carbon and zeolite are collected in the fourth screen of the circulation tank while being circulated through the second-1 piping and the second-2 piping, while being collected in the third screen of the buffer tank have.

A vertical rod extending vertically in the sorting tank; A plurality of agitating blades spaced apart from the vertical bar; And the inside of the selection tank may be stirred by the stirring vane while the vertical bar is rotating.

The suction pipe further includes a suction pipe connected to a bottom of the selection tank, and the suction pipe is connected to the 2-1 pipe by a three-way valve.

Further, the 1-1 piping is connected to the screening tank adjacent to the upper portion of the second screen.

Further, the 2-1 pipe is connected to the screening tank adjacent to the upper portion of the first screen.

According to the present invention, a waste water mixture generated in a nuclear power plant is passed through a first screen and a second screen, separated according to a particle size, and each separated component is circulated through a pipe, An apparatus for separating waste resin can be provided.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view showing a configuration of an apparatus for separating waste resin from a waste water mixture according to an embodiment of the present invention; FIG.
FIG. 2 is a view showing a state in which the waste water mixture is classified into sizes by the first screen and the second screen in the apparatus of FIG. 1; FIG.
FIG. 3 is a view showing a state in which waste water is collected in a buffer tank while circulating water between a selective tank and a buffer tank in the apparatus of FIG. 1; FIG.
FIG. 4 is a view showing a state in which the activated carbon, the zeolite and the fine powder are collected in the circulation tank while circulating water between the selection tank and the circulation tank in the apparatus of FIG. 1;
FIG. 5 is a view showing a state in which the contents of the selection tank are completely filled in the circulation tank and the selection tank is empty in FIG. 4;

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the drawings, like reference numerals refer to like elements throughout. The same reference numerals in the drawings denote like elements throughout the drawings.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view showing a configuration of an apparatus for separating waste resin from a waste water mixture according to an embodiment of the present invention; FIG. FIG. 2 is a view showing a state in which the waste water mixture is classified into sizes by the first screen and the second screen in the apparatus of FIG. 1; FIG. FIG. 3 is a view showing a state in which waste water is collected in a buffer tank while circulating water between a selective tank and a buffer tank in the apparatus of FIG. 1; FIG. FIG. 4 is a view showing a state in which the activated carbon, the zeolite and the fine powder are collected in the circulation tank while circulating water between the selection tank and the circulation tank in the apparatus of FIG. 1; FIG. 5 is a view showing a state in which the contents of the selection tank are completely filled in the circulation tank and the selection tank is empty in FIG. 4;

In nuclear power plants, activated carbon, zeolite and waste water are used for ion treatment of water. Currently, these waste water mixtures are stored in a large storage tank without being treated separately. The present invention relates to an apparatus for separating waste resin from a waste water mixture to remove and treat C-14, a radioactive material contained in waste water.

(Hereinafter referred to as a separation apparatus) 100 for separating waste resin from a waste water mixture of the present invention comprises a sorting tank 110, a buffer tank 120, a circulation tank 130, a first- The second piping 160, the second piping 170, the suction piping 180, and the like. The first piping 140, the second piping 150, the second piping 160, the second piping 170,

The sorting tank 110 is a cylindrical container having an inlet 111, a first screen 112, and a second screen 113. The inlet port 111 is for introducing the waste water mixture, and is formed on the upper portion of the sorting tank 110.

The first screen 112 is located at a lower portion of the inlet 111 and has a first mesh network. The first screen 112 is formed to have a size capable of colliding the activated carbon and the zeolite.

The second screen 113 is spaced apart from the lower portion of the first screen 112 and has a second mesh network of a smaller size than the first mesh network. The second screen 113 is formed to have a size capable of collapsing the waste water.

The sorting tank 110 also includes a vertical bar 114 extending vertically and a plurality of stirring vanes 115 spaced apart from and attached to the vertical bar 114. While the vertical bar 114 is rotating, the inside of the selection tank 110 can be agitated by the stirring vane 115.

The buffer tank 120 is a cylindrical container and has a third screen 121 having a third mesh network. The third screen 121 is formed to have a size capable of collapsing the waste water.

The buffer tank 120 also includes a vertical bar 122 extending vertically and a plurality of stirring vanes 123 spaced apart and attached to the vertical bar 122. While the vertical bar 122 is rotating, the inside of the buffer tank 120 can be stirred by the stirring vane 123. [ The buffer tank 120 may be located above the sorting tank 110.

The circulation tank 130 is a cylindrical container and has a fourth screen 131 having a fourth mesh net. The fourth screen 131 is formed to have a size capable of holding fine particles (activated carbon fine powder, zeolite fine powder) and smaller than the first to third screens 112, 113 and 121.

The circulation tank 130 also includes a vertical bar 132 extending vertically and a plurality of stirring blades 133 spaced apart from and attached to the vertical bar 132. The inside of the circulation tank 130 can be stirred by the stirring vane 133 while the vertical bar 132 rotates. The stirring wing 115 prevents the first screen 112 and the second screen 112 from being clogged by activated carbon, zeolite, waste water, etc., so that the mixture can be separated by particle size.

The 1-1 pipeline 140 leads from the screening tank 110 to the top of the buffer tank 120. The 1-1 pipe 140 is connected to the selection tank 110 at a position adjacent to the upper portion of the second screen 113. The 1-1 piping 140 is used to transfer the waste paper in the sorting tank 110 to the buffer tank 120. The 1-1 piping 140 is provided with a valve 141 and a pump 142 adjacent to the selection tank 110.

The 1-2 pipe 150 leads from the bottom of the buffer tank 120 to the selection tank 110. The 1-2 pipe 150 is used to transfer the water that has passed through the buffer tank 120 to the sorting tank 110. A valve 151 is provided adjacent to the selection tank 110 in the 1-2 pipe 150 and an end of the 1-2 pipe 150 is connected to the first screen 112 of the screening tank 110, 2 screen 113. In this way,

The second-1 piping 160 extends from the selection tank 110 to the upper portion of the circulation tank 130. The second-1 pipe 160 is connected to the selection tank 110 at a position adjacent to the upper portion of the first screen 112. The 2-1 pipe 160 is used to transfer the activated carbon, zeolite, active carbon powder, and zeolite powder in the selection tank 110 to the circulation tank 130. The second-1 pipe 160 is provided with a valve 161 adjacent to the selection tank 110 and a valve 164 adjacent to the pump 163 and the circulation tank 130.

The second-2 pipe 170 leads from the bottom of the circulation tank 130 to the selection tank 110. The second-2 pipe 170 is used to transfer the water that has passed through the circulation tank 130 to the selection tank 110. A valve 172 adjacent to the circulation tank 130, a pump 172 and a valve 171 adjacent to the selection tank 110 are installed in the second -2 pipe 170. The end of the second-2 pipe 170 may be positioned between the first screen 112 and the second screen 113 of the sorting tank 110.

The suction pipe 180 is connected to the bottom of the selection tank 110. The suction piping 180 may be connected to the upper portion of the circulation tank 130 through the second-1 piping 160 and the three-way valve 162. The suction pipe 180 is used to send the water in the selection tank 110 to the circulation tank 130.

Hereinafter, with reference to FIGS. 2 to 5, a method of separating waste resin from a waste water mixture using the separation apparatus of the present invention will be described.

Referring to FIG. 2, first, the circulation tank 130 is filled with water, and then the water is fed to the screening tank 110 through the second-2 pipe 170 to fill the first screen 112. Next, the waste water mixture is introduced into the sorting tank 110 through the inlet port 111.

Next, the water in the selection tank 110 is discharged to the lower portion of the first screen 112 while rotating the stirring vane 115. When the water is discharged from the selection tank 110, the suction pipe 180 is used and the discharged water is transferred to the circulation tank 130 through the second-1 pipe 160.

Accordingly, the relatively large activated carbon and zeolite are filtered on the first screen 112, the waste water is disposed on the second screen 113, and the fine particles are mainly located in the lower portion of the second screen 113.

3, the water in the selection tank 110 is circulated through the 1-1 piping 140 and the 1-2 piping 150, and at this time, the stirring vanes 115 can be rotated have. Accordingly, the waste water located on the second screen 113 can be transferred to the buffer tank 120 and collected on the third screen 121. The size of the mesh network of the third screen 121 is similar to that of the second screen 113. The end of the 1-1 pipeline 140 is positioned adjacent to the second screen 113 where the waste water is mainly concentrated. Although the water of the selection tank 110 includes the water, these differentiations are not filtered by the third screen 121, but continue to circulate and enter the selection tank 110.

The buffer tank 120 is positioned higher than the selection tank 110 so that the water entering the buffer tank 120 is automatically discharged to the selection tank 110. [ .

By this process, the waste water is collected on the third screen 121 of the buffer tank 120 and the separated waste water falls downward by the opening of the valve 124 and is conveyed by the screw 125 to the reactor 10 ). ≪ / RTI > Water separated from the waste water by the circulation process enters the selection tank 110.

Next, referring to FIGS. 4 and 5, the water in the circulation tank 130 is sent to the screening tank 110 through the second -2 pipe 170 to fill the water on the first screen 112. The water in the selection tank 110 is circulated through the second-1 pipe 160 and the second-second pipe 170, at which time the stirring vane 115 can be rotated. Accordingly, the activated carbon, zeolite, and fine particles located on the first screen 112 can be transferred to the circulation tank 130 and collected on the fourth screen 131. The mesh screen size of the fourth screen 131 is smaller than that of the second screen 113. The end of the second-1 pipe 160 is positioned adjacent to the first screen 112 in which activated carbon and zeolite are filtered.

The activated carbon, zeolite, and fine particles are collected on the fourth screen 131 of the circulation tank 130 by this process, and the selection tank 110 can be mostly emptied.

The process described with reference to FIG. 2 to FIG. 5 may be repeated according to the separation state of the waste water mixture.

According to the separation apparatus of the present invention, the separation tank 110, the buffer tank 120, the circulation tank 130, the 1-1 piping 140, the 1-2 piping 150, Activated carbon and zeolite are mixed with activated carbon, zeolite, and other mixture of fine powders and wastewater generated from the nuclear power plant by the piping 160, the second -2 pipe 170, the suction pipe 180, . The separated waste water in the buffer tank 120 can be suitably treated in the reactor 10.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention will be.

10: Reactor
100: waste water separator
110: Selection tank
111:
112: first screen
113: Second screen
114: vertical bar
115: stirring wing
120: Buffer tank
121: Third screen
122: vertical bar
123: stirring wing
130: circulation tank
131: fourth screen
132: vertical bar
133: stirring wing
140: 1-1 pipe
150: 1-1 pipe
160: 2-1 pipe
170: 2-1 piping
180: Suction piping

Claims (5)

An apparatus for separating effluent from a waste water mixture mixed with waste water generated from a nuclear power plant, activated carbon and zeolite,
A cylindrical container comprising: an inlet for introducing a waste solution mixture into an upper portion; a first screen spaced apart from the bottom of the inlet and having a first mesh network; a first screen positioned apart from a lower portion of the first screen, A screen having a second screen having a second mesh net smaller than the mesh;
1. A cylindrical container comprising: a buffer tank having a third screen having a third mesh net;
1. A cylindrical container comprising: a circulation tank having a fourth screen having a fourth mesh net;
A 1-1 pipeline extending from the screening tank to an upper portion of the buffer tank;
A 1-2 pipe leading from the bottom of the buffer tank to the selection tank;
A second-1 pipe leading from the selection tank to an upper portion of the circulation tank;
A second -2 pipe leading from the lower portion of the circulation tank to the selection tank;
/ RTI >
The waste water mixture injected through the inlet port is separated from the first screen and the second screen depending on the size,
The separated waste water is collected on the third screen of the buffer tank while being circulated through the 1-1 pipe and the 1-2 pipe,
The separated activated carbon and zeolite are circulated through the second-1 piping and the second-second piping, and the waste water, activated carbon, and zeolite generated in the nuclear power plant that can be collected on the fourth screen of the circulation tank are mixed Apparatus for separating effluent from a waste water mixture. The method according to claim 1,
A vertical bar extending vertically in the selection tank;
A plurality of agitating blades spaced apart from the vertical bar;
Lt; / RTI >
An apparatus for separating waste water from a waste water mixture in which waste water, activated carbon, and zeolite are mixed, generated in a nuclear power plant, which can be stirred by the stirring wing, while the vertical bar is rotated. The method according to claim 1,
Further comprising a suction pipe connected to the bottom of the screening tank,
Wherein the suction pipe is connected to the second-1 pipe through a three-way valve, and the waste water is separated from the waste water mixture in which the waste water, activated carbon and zeolite are mixed. 3. The method of claim 2,
The apparatus for separating waste water from a waste water mixture comprising waste water, activated carbon and zeolite generated in a nuclear power plant connected to the screening tank adjacent to an upper portion of the second screen. 3. The method of claim 2,
And the second-1 pipe is a waste water mixture containing waste water, activated carbon, and zeolite mixed in a nuclear power plant connected to the screening tank adjacent to an upper portion of the first screen.

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