KR102492880B1 - Activated carbon extraction and injection device of Tritium Removal Facility helium refrigeration system - Google Patents

Abstract

Provided is an activated carbon extraction and injection device used to extract or inject activated carbon in a tritium removal facility (TRF) helium refrigeration system. An activated carbon extraction and injection device according to an embodiment of the present invention comprises: an extraction unit which is formed on one side of an activated carbon storage tank to be inserted therein and, when inserted into one side of the activated carbon storage tank, uses a driving force to extract activated carbon in the activated carbon storage tank; and an injection unit including an inject port for injecting the activated carbon into the activated carbon storage tank and an inject pipe connected to the injection port and formed to be inserted into the upper side of the activated carbon storage tank, wherein when the injection pipe is inserted into the upper part of the activated carbon storage tank, the activated carbon supplied through the injection port is injected into the activated carbon storage tank. As a result, the activated carbon is extracted using the driving force during the operation of extracting the activated carbon, such that work efficiency can be improved. In addition, when injecting the activated carbon, an activated carbon injection time can be shortened and the activated carbon can be prevented from leaking out during the injection process.

Description

Activated carbon extraction and injection device of Tritium Removal Facility helium refrigeration system}

The present invention relates to an activated carbon extraction and injection device, and more particularly, to a TRF (Tritium Removal Facility) helium refrigeration system used to extract or inject activated carbon.

The function of activated carbon in the TRF helium refrigeration system is to increase helium purity (dew point) through an activated carbon tank for the purpose of removing helium internal impurities and oil. Periodic replacement is required due to deterioration in performance due to contamination during long-term operation.

Such activated carbon withdrawal work has used a method in which the worker directly scrapes and removes the activated carbon using a stick having a certain length after disassembling the lower flange of the activated carbon storage tank, and the injection work is a temporary gourd or made of thin steel plate. A method of injecting activated carbon into an upper part of an activated carbon storage tank using a funnel has been used.

Such a withdrawal operation and injection operation have a problem in that work efficiency is reduced, and an improvement plan for this problem is required.

The present invention has been made to solve the above problems, and an object of the present invention is to improve work efficiency by withdrawing activated carbon using a driving force during the operation of withdrawing activated carbon from a TRF helium refrigeration system, and activated carbon It is to provide an activated carbon withdrawal and injection device capable of reducing the activated carbon injection time during the injection operation and preventing the leakage of activated carbon to the outside during the injection process.

According to an embodiment of the present invention for achieving the above object, an activated carbon withdrawal and injection device is formed to be drawn into one side of an activated carbon storage tank, and stores activated carbon using a driving force when drawn into one side of the activated carbon storage tank. a withdrawing unit allowing the activated carbon in the tank to be withdrawn; and an inlet for injecting activated carbon into the activated carbon storage tank and an injection pipe connected to the inlet and formed to be drawn into the upper side of the activated carbon storage tank, so that when the injection pipe is drawn into the upper side of the activated carbon storage tank, through the inlet It includes; an injection unit for injecting the supplied activated carbon into the activated carbon storage tank.

And the withdrawing part is formed extending along the length direction, when the wing is rotated in a state drawn into one side of the activated carbon storage tank, the activated carbon mounted on the wing is transported along the rotating wing screw; a motor that transmits a driving force to the screw so that the screw rotates; and a discharge port that is connected to the screw and allows the activated carbon transported along the rotating blade to be discharged to the outside when the wing of the screw rotates while being drawn into one side of the activated carbon storage tank.

In addition, the drawing unit may further include a control device for controlling whether or not the motor rotates, a rotation direction, and a speed.

And the injection unit may further include a fixed flange connecting the injection port and the injection tube.

In addition, the inlet may be formed in a funnel shape in which the size of the diameter increases from the lower side to the upper side.

The injection unit may further include a fixing pin coupled to the fixing flange so that the inclination of the injection pipe is adjusted when the injection pipe is introduced into the upper side of the activated carbon storage tank.

On the other hand, according to another embodiment of the present invention, the activated carbon withdrawal device is formed extending along the longitudinal direction so as to be drawn into one side of the activated carbon storage tank, and when the blade rotates while being drawn into one side of the activated carbon storage tank, A screw that allows the activated carbon mounted on the wing to be transported along the rotating wing; a motor that transmits a driving force to the screw so that the screw rotates; and a discharge port that is connected to the screw and allows the activated carbon transported along the rotating blade to be discharged to the outside when the wing of the screw rotates while being drawn into one side of the activated carbon storage tank.

And according to another embodiment of the present invention, the activated carbon injection device, the inlet for injecting the activated carbon into the activated carbon storage tank; and an injection pipe that is connected to the inlet, is formed to be able to be drawn into the upper side of the activated carbon storage tank, and allows the activated carbon supplied through the inlet to be injected into the activated carbon storage tank when the activated carbon is drawn into the upper side of the activated carbon storage tank. there is.

As described above, according to the embodiments of the present invention, it is possible to improve work efficiency by taking out the activated carbon using a driving force during the work of taking out the activated carbon.

In addition, when the activated carbon is injected, the activated carbon injection time can be shortened, and the leakage of the activated carbon to the outside during the injection process can be prevented.

1 is a view provided for explanation of an activated carbon withdrawal and injection device according to an embodiment of the present invention;
2 is a perspective view provided for explaining the configuration of a lead-out unit according to an embodiment of the present invention;
Figure 3 is a cross-sectional view showing the inside of the draw-out according to an embodiment of the present invention, and
4 is a perspective view provided for explaining the configuration of an injection unit according to an embodiment of the present invention.

Hereinafter, the present invention will be described in more detail with reference to the drawings.

1 is a diagram provided for explanation of an activated carbon withdrawing and injecting device according to an embodiment of the present invention.

Activated carbon withdrawing and injecting device according to the present embodiment improves work efficiency by withdrawing activated carbon using a driving force during an operation of withdrawing activated carbon, shortens the activated carbon injection time during an operation of injecting activated carbon, and reduces the amount of activated carbon in the injection process. leakage to the outside can be prevented.

To this end, the activated carbon withdrawal and injection device reduces the active carbon injection time during the operation of withdrawing activated carbon from the TRF helium refrigeration system, the withdrawal unit 100 capable of withdrawing activated carbon using a driving force, and the operation of injecting activated carbon, It may include an injection unit 200 capable of preventing the outflow of activated carbon during the injection process.

Specifically, the withdrawing unit 100 is formed to be able to be drawn into one side of the activated carbon storage tank, so that activated carbon in the activated carbon storage tank can be drawn out using a driving force when drawn into one side of the activated carbon storage tank. A more detailed description of the drawing unit 100 will be described later with reference to FIG. 2 .

The injection unit 200 is provided with an injection port 210 for injecting activated carbon into the activated carbon storage tank and an injection pipe 220 connected to the injection port 210 and formed to be drawn into the upper side of the activated carbon storage tank. When the tube 220 is introduced into the upper side of the activated carbon storage tank, activated carbon supplied through the inlet 210 may be injected into the activated carbon storage tank. A more detailed description of the injection unit 200 will be described later with reference to FIG. 3 .

FIG. 2 is a view provided for explaining the configuration of the lead-out unit 100 according to an embodiment of the present invention, and FIG. 3 is a cross-sectional view showing the inside of the lead-out unit according to an embodiment of the present invention.

Referring to FIGS. 2 and 3 , when the withdrawing unit 100 according to the present embodiment is pulled into one side of the activated carbon storage tank, the screw 110 is used to pull out the activated carbon in the activated carbon storage tank using a driving force. , a motor 120, an outlet 130, a control device 140, and a first fixed flange 150 and an internal transfer path 160.

The screw 110 extends in the longitudinal direction, and when the blade rotates while being inserted into one side of the activated carbon storage tank, the activated carbon mounted on the blade can be transported along the rotating blade.

The motor 120 may transmit a driving force to the screw 110 so that the screw 110 rotates.

The discharge port 130 is connected to the screw 110, and when the wing of the screw 110 rotates while being drawn into one side of the activated carbon storage tank, the activated carbon transported along the rotating wing can be discharged to the outside. there is.

Specifically, when the screw 110 rotates, the lead-out unit 100 is provided with an internal transport path 160 that allows the activated carbon to be transported (inflowed) into the take-out unit 100 along the wings of the screw 110. And, the outlet 130 extends downward from the internal transport path, so that the activated carbon transported along the internal transport path can be transported downward and discharged to the outside.

Here, the inner conveyance path 160 extends along the longitudinal direction where the motor 120 is provided in the first fixed flange 150, and a part of the screw 110 is drawn in and connected to the motor. , A discharge port 130 may be provided below a part of the screw and the part where the motor is connected.

The control device 140 is connected to the motor 120 and can control whether the motor 120 rotates, the direction and speed of the motor 120 .

Specifically, the control device 140 may perform a power supply of the motor 120, determine whether to supply power, control whether or not to rotate the motor 120, and control the rotation direction in a forward or reverse direction.

In addition, the controller 140 may control the rotational speed of the motor 120 to rotate at a rotational speed corresponding to a specific stage among a plurality of stages (eg, strong, medium, weak, etc.) determined at the time of manufacturing the motor 120. there is.

Here, the motor 120 and the control device 140 are manufactured as one module together with the other components of the draw-out unit 100, and are portable, and through this, the operator who needs to move the equipment for work convenience can be provided.

The first fixing flange 150 is provided at the rear end of the screw 110 and can be coupled to one side of the activated carbon storage tank. At this time, the screw 110 positioned at the front end of the first fixing flange 150 is the activated carbon It can be drawn into one side of the storage tank.

To this end, an outlet capable of engaging with the first fixing flange 150 may be provided in the activated carbon storage tank.

4 is a perspective view provided for explaining the configuration of the injection unit 200 according to an embodiment of the present invention.

Referring to FIG. 4 , the injection unit 200 may further include a second fixing flange 230 and a fixing pin 240 in addition to the injection port 210 and the injection pipe 220 described above.

The inlet 210 is formed in a funnel shape, the diameter of which increases from the bottom to the top, shortens the activated carbon injection time during the injection of activated carbon, and prevents the activated carbon from leaking out during the injection process. .

The second fixing flange 230 may connect the injection hole 210 and the injection pipe 220 . That is, the injection port 210 and the injection pipe 220 are connected by flange coupling.

The fixing pin 240 is coupled to the fixing flange so that the inclination can be adjusted when the injection pipe 220 is introduced into the upper side of the activated carbon storage tank.

That is, the fixing pin 240 is formed so that one side is coupled to the fixed flange and the other side is in contact with the upper side of the activated carbon storage tank, so that the inclination of the injection pipe 220 is can be adjusted.

Here, the operator may apply an external force to adjust the inclination of the portion in contact with the upper side of the activated carbon storage tank, and then fix it using a wire or the like.

Although the preferred embodiments of the present invention have been shown and described above, the present invention is not limited to the specific embodiments described above, and is common in the art to which the present invention pertains without departing from the gist of the present invention claimed in the claims. Of course, various modifications are possible by those who have knowledge of, and these modifications should not be individually understood from the technical spirit or prospect of the present invention.

100: withdrawal unit
110: screw
120: motor
130: outlet
140: control device
150: first fixed flange
160: internal transfer path
200: injection unit
210: inlet
220: injection pipe
230: second fixed flange
240: fixing pin

Claims (8)

a withdrawing unit that is formed to be drawn into one side of the activated carbon storage tank and allows the activated carbon in the activated carbon storage tank to be drawn out using a driving force when the activated carbon is drawn into one side of the activated carbon storage tank; and
An inlet for injecting activated carbon into the activated carbon storage tank and an injection pipe connected to the inlet and formed to be drawn into the upper side of the activated carbon storage tank are provided, and when the injection pipe is drawn into the upper side of the activated carbon storage tank, supply through the inlet is provided. An injection unit for injecting the activated carbon into the activated carbon storage tank; includes,
the inlet,
It is formed in a funnel shape in which the size of the diameter increases from the bottom to the top,
the injection part,
Activated carbon withdrawal and injection device, characterized in that it further comprises; fixed pin coupled to the fixed flange, so that the inclination is adjusted when the injection pipe is drawn into the upper side of the activated carbon storage tank.
The method of claim 1,
withdrawal part,
a screw that extends along the longitudinal direction and allows the activated carbon mounted on the wing to be transported along the rotating wing when the wing rotates while being drawn into one side of the activated carbon storage tank;
a motor that transmits a driving force to the screw so that the screw rotates; and
Activated carbon withdrawal and injection device comprising: a discharge port connected to the screw and allowing the activated carbon transported along the rotating blade to be discharged to the outside when the blade of the screw rotates in a state drawn into one side of the activated carbon storage tank.
The method of claim 2,
withdrawal part,
Activated carbon withdrawal and injection device characterized in that it further comprises; a control device for controlling whether or not the motor rotates, the rotation direction and speed.
The method of claim 1,
the injection part,
Activated carbon withdrawal and injection device, characterized in that it further comprises; a fixed flange connecting the injection port and the injection pipe.
delete delete delete An inlet for injecting activated carbon into an activated carbon storage tank; and
An injection pipe connected to the inlet and formed to be able to be drawn into the upper side of the activated carbon storage tank, so that when the activated carbon is drawn into the upper side of the activated carbon storage tank, the activated carbon supplied through the inlet is injected into the activated carbon storage tank,
the inlet,
It is formed in a funnel shape in which the size of the diameter increases from the bottom to the top,
Activated carbon injection device,
The activated carbon injection device further comprising a fixing pin coupled to the fixing flange to adjust the inclination of the injection pipe when the injection pipe is introduced into the upper side of the activated carbon storage tank.

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