KR102075649B1 - Uranium hexafluoride vaporization system - Google Patents

Abstract

Disclosed is a uranium hexafluoride vaporization system which prevents workers from being exposed to UF6 gas in advance. The uranium hexafluoride vaporization system comprises: a vaporizer having an internal space of a constant volume; a cylinder arranged inside the vaporizer and vaporizing solid UF6; a cylinder valve provided on one side of the cylinder to open and close the cylinder, and discharging gas UF6 to the outside of the cylinder; a discharge passage connected to the cylinder valve to guide the gas UF6 to a converter outside the vaporizer; a heater controlling a vaporization speed of the solid UF6 by supplying heat to the inside of the vaporizer; a fan promoting circulation of gas inside the vaporizer so that the heat supplied from the heater is uniformly transferred to the cylinder; and a leak detection device detecting whether the gas UF6 generated in the cylinder is leaked.

Description

Uranium hexafluoride vaporization system

The present invention relates to a uranium hexafluoride vaporization system, more specifically

The present invention relates to a vaporization system for safely vaporizing solid uranium hexafluoride to a conversion furnace.

In the gasification process of the nuclear fuel manufacturing reconversion process using UF6 cylinders, the UF6 cylinders are mounted outside an autoclave called a carburetor, and the special hose is used to connect the UF6 cylinders to the supply lines. Perform a leak test.

Therefore, various detection and blocking systems have been proposed for detecting leakage of various gases or gases.

For example, Korean Patent Publication No. 10-1385574 discloses a leak detection and blocking system of a liquefied heater.

Korean Unexamined Patent Publication No. 10-1385574

The present invention has been made to solve the above problems,

The present invention is to provide a uranium hexafluoride vaporization system that can monitor in advance the leakage of UF6 gas to the outside of the UF6 cylinder disposed in the vaporizer, to prevent the risk of workers exposed to UF6 gas in advance.

The present invention is to provide a uranium hexafluoride vaporization system including a safety device for safely opening and closing the UF6 cylinder valve outside the vaporizer.

The object of the present invention is not limited to the above-mentioned object, and other objects not mentioned will be clearly understood by those skilled in the art from the following description.

The characteristics of the present invention for achieving the object of the present invention as described above, and to perform the characteristic functions of the present invention described below are as follows.

A vaporizer formed with a constant volume of internal space; A cylinder disposed inside the vaporizer, in which vaporization of the solid UF6 takes place; A cylinder valve provided at one side of the cylinder to open and close the cylinder, and discharge the gas UF6 to the outside of the cylinder; A discharge passage connected to the cylinder valve to guide the gas UF6 to a conversion furnace outside the vaporizer; A heater which supplies heat to the inside of the vaporizer to control the vaporization rate of the solid UF6; A fan for promoting circulation of gas in the vaporizer so that heat supplied from the heater is uniformly transferred to the cylinder; It includes a leak detector for detecting whether the gas UF6 generated in the cylinder leaks.

Preferably, the cylinder valve, characterized in that the opening and closing by a safety device for preventing the leakage of the gas UF6, the safety device is rotated by the power supplied from the outside of the carburetor, and is intruding into the carburetor First arm;

A gear box connected to the first arm to transfer a rotational force of the first arm by changing an axis; And a second arm, one end of which is connected to the gearbox and the other end of which is connected to the cylinder valve, opening and closing the cylinder valve through a rotational movement.

In addition, the first arm is operated by a drive handle or a drive motor, the connection portion with the gear box is provided with a first universal joint, the second arm is characterized in that it comprises a second universal joint. It is done.

On the other hand, the leak detection device, the reaction chamber in which the gas inside the vaporizer is temporarily accommodated; A sensor unit provided inside the reaction chamber; And an external air supply line for supplying external air to the reaction chamber, wherein the sensor unit comprises: an HF sensor sensing HF gas; And a smoke detector for detecting smog.

Preferably, the reaction chamber includes a material that is visible on the front surface, and further includes a door that can be opened and closed on one side.

Preferably, the gas inside the vaporizer and the external air is introduced into the reaction chamber via a special nozzle.

Preferably, the external air supply line includes a vacuum pump and a filter.

On the other hand, the leak detection device, the reaction chamber in which the gas inside the vaporizer is temporarily accommodated; A sensor unit provided inside the reaction chamber; And an external air supply line for supplying external air to the reaction chamber, wherein the sensor unit comprises: an HF sensor sensing HF gas; Smoke detectors for detecting smog; And a signal generator for generating an alarm signal according to the detection of the HF gas or the smog, wherein the safety device further includes a control unit for opening and closing the cylinder valve according to the alarm signal generated from the signal generator.

Preferably, the gas in the vaporizer is introduced into the special nozzle through the nitrogen transfer line, the special nozzle is a tube formed of a constant diameter, so that the nitrogen transfer line is inserted therein A first region having an inner diameter larger than an outer diameter of the nitrogen transfer line, one end of which is inserted into the reaction chamber, wherein a space inside the special nozzle is formed only by the nitrogen transfer line, and the nitrogen transfer line; When dividing into a second region extending from the outer circumferential surface of the line, the external air supply line is in communication with the second region to supply the external air to the reaction chamber, and the external air and the gas inside the vaporizer are the special In order not to react inside the nozzle, the nitrogen transfer line protrudes from one end of the special nozzle to the inside of the reaction chamber. The special nozzle further comprises a plurality of pipe-shaped spacers arranged at regular intervals along the outer circumferential surface of the nitrogen transfer line in the second region, and the inner circumferential surface of the special nozzle and the outer circumferential surface of the nitrogen transfer line It is characterized by maintaining a constant interval.

As described above, according to the reaction chamber having a sensor unit for detecting the leakage through the reaction of nitrogen and the outside air in the vaporizer of the present invention provides an effect of easily detecting the presence or absence of UF6 leak from the outside.

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

1 is a process schematic diagram of a uranium hexafluoride vaporization system according to an embodiment of the present invention.
2 is a block diagram of a leak detection apparatus included in the uranium hexafluoride vaporization system according to an embodiment of the present invention.
3 is a perspective view of FIG. 2.
Figure 4 shows a special nozzle included in the uranium hexafluoride vaporization system according to an embodiment of the present invention.
5 is a block diagram of a safety device included in the uranium hexafluoride vaporization system according to an embodiment of the present invention.
6 is a plan view of a cylinder valve included in the uranium hexafluoride vaporization system according to an embodiment of the present invention.
7 is a side view of a cylinder valve included in the uranium hexafluoride vaporization system according to an embodiment of the present invention.
8 illustrates an operation state of a cylinder valve included in the uranium hexafluoride vaporization system according to an embodiment of the present invention.

Hereinafter, with reference to the drawings will be described the present invention in more detail. It should be noted that the same elements in the figures are represented by the same numerals wherever possible. In addition, descriptions of well-known functions and configurations that may unnecessarily obscure the subject matter of the present invention will be omitted.

In addition, various modifications may be made to the embodiments described below. The examples described below are not intended to be limiting of the embodiments, but should be understood to include all modifications, equivalents, and substitutes for them.

This will be described logically according to the drawings.

1 is a process schematic diagram of a uranium hexafluoride vaporization system according to an embodiment of the present invention.

1, the uranium hexafluoride vaporization system according to an embodiment of the present invention, the vaporizer 100, the cylinder 200, the cylinder valve 210, the discharge passage 230, the heater 300, And a fan 400 and a leak detection device 500.

The vaporizer 100 forms an internal space having a constant volume.

The cylinder 200 may be disposed in the inner space and may be swept using nitrogen gas. More specifically, the interior space of the vaporizer 100 may be formed of a substantially uniform material by using nitrogen gas N2 by flowing nitrogen gas N2 into the interior space of the vaporizer 100. In addition, the temperature of the space inside the vaporizer | carburetor 100 and 10 can be made substantially the same. The vaporizer 100 may be made of a tempered glass and the like surface is visible so that the cylinder 200, the inside of the inside can be observed from the outside.

The cylinder 200 is disposed inside the vaporizer 100, in which vaporization of the solid UF6 takes place. Since the vaporization rate of the solid UF6 depends on the temperature, the surface of the cylinder 200 may be formed of a material having high thermal conductivity such that sufficient heat exchange may occur with the vaporizer 100. In addition, the cylinder 200 does not need to be in direct contact with the inner surface of the vaporizer 100, and the gas such as nitrogen uniformly contained in the vaporizer 100 evenly contacts the outer peripheral surface of the cylinder 200 to enable uniform heat transfer. It may be fixed at a distance from the trap so as to be fixed. That is, by providing a support member or the like under the cylinder 200, the contact area with the gas inside the vaporizer 100 may be widened.

The solid UF6 is accommodated in the cylinder 200, and when the gas is vaporized into the gas UF6 by a rise in temperature, the cylinder 200 is configured to have a sufficient sealing performance so as not to leak into the vaporizer 100.

The cylinder valve 210 is provided at one side of the cylinder 200 to open and close the cylinder 200, and serves to discharge the gas UF6 generated inside the cylinder 200 to the outside. In consideration of the fact that the vaporized UF6 rises upward due to convection due to the increase in the internal temperature of the cylinder 200, the cylinder valve 210 may be more appropriately provided on the upper side of the cylinder 200. The cylinder valve 210 is generally opened and closed by rotation, and in addition to this, any means known in the art may be used to control the outflow rate of the gas and to allow sufficient discharge.

The discharge passage 230 has one end connected to the cylinder valve 210 to guide the gas UF6 flowing out to the outside by opening and closing the cylinder valve 210 to the outside. Therefore, it is bound to the opening and closing portion of the cylinder valve 210 without being spaced to complete the seal. Therefore, the gas UF6 discharged from the cylinder valve 210 is transferred to the outside of the vaporizer 100 through the discharge passage 230 without passing through the internal space of the vaporizer 100.

The other end of the discharge passage 230 is connected to the conversion passage located outside the vaporizer 100 to safely transport the gas UF6. The discharge flow path 230 is preferably made of a material having sufficient sealing performance, heat resistant and appropriate elasticity so that gas does not leak.

The heater 300 functions to heat the gas inside the vaporizer 100 to increase the internal temperature. It is also possible to arrange a heating source to the outside to heat through the surface of the vaporizer 100, but it is more preferable in terms of efficiency and uniformity of heat transfer to place the heating source inside to directly heat the internal gas. The heater 300 may be driven through electric energy, and in this case, the controller or the power supply unit may be located outside in consideration of the operator's convenience of operation.

The fan 400 facilitates movement of air through a rotational movement inside the vaporizer 100 so that the heat supplied by the heater 300 can be evenly spread throughout the vaporizer 100. Therefore, uniform heat may be transferred to the surface of the cylinder 200, which serves to control the flow rate of the gas UF6 discharged through the discharge passage 230 by keeping the evaporation rate of the UF6 constant. By controlling the rotational speed of the fan 400 can change the heat transfer efficiency into the cylinder 200.

The leak detection apparatus 500 is provided outside the vaporizer 100, and detects whether the gas UF6 generated from the cylinder 200 leaks into the space inside the vaporizer 100.

2 is a block diagram of a leak detection apparatus 500 included in the uranium hexafluoride vaporization system according to an embodiment of the present invention. 3 is a perspective view of FIG. 2.

2 and 3, the leak detection device 500 included in the uranium hexafluoride vaporization system according to an embodiment of the present invention, the reaction chamber 510, the sensor unit and the external air supply line 550 The sensor unit may include an HF sensor 531 and a mist detector 533.

The reaction chamber 510 forms a predetermined space to temporarily receive the gas transferred from the outside air and the vaporizer 100. It includes a sensor unit therein, the door 513 that can be opened and closed for maintenance of the sensor unit may be provided on one side. The front part of the reaction chamber 510 is made of a visible material so that the external sensor part can be visually identified from the outside. Materials such as acrylic will be appropriate.

Gas and external air inside the vaporizer 100 may be temporarily accommodated in the reaction chamber 510 to perform a chemical reaction. When UF6 gas is included in the gas transported from the vaporizer 100, UO2F2, HF gas and smog are generated by reacting with moisture contained in external air. The sensor unit may detect this and determine whether there is a leakage of UF6 in the vaporizer 100.

An exhaust port is formed in the upper portion of the reaction chamber 510, and the gases which have completed the reaction may be discharged to the outside.

The sensor unit is provided inside the reaction chamber 510.

The sensor unit may detect HF gas and smog generated by chemical reaction of external air and gas transferred from the inside of the vaporizer 100 in the reaction chamber 510. More specifically, the sensor unit may include an HF sensor 531 and a mist detector 533, and may further include a signal generator.

The HF sensor 531 may employ all known means for detecting HF gas, which is a toxic gas, and an electrochemical type sensor will be particularly suitable. The smoke detector 533 employs all known means for detecting smog, and a photoelectric type detector may be particularly suitable. The HF sensor 531 and the smoke detector 533 may transmit the information to the signal generator as each sensing object is detected, and the signal generator generates a notification signal according to the information. The notification signal may be output on an external speaker or display in the form of a leak alarm, or may be transmitted in the form of a message to the manager's mobile phone number.

The external air supply line 550 is connected to the outside and sucks air to supply to the reaction chamber 510. The external air supply line 550 may include a vacuum pump 551 and a filter 553.

The vacuum pump 551 provides power for intake of external air, and the filter 553 removes foreign matters floating on the external air, thereby preventing unnecessary chemical reactions from occurring in the reaction chamber 510.

The external air contains water vapor, and when HF gas leaks into the vaporizer 100 and is transferred to the reaction chamber 510, it serves to cause a chemical reaction. In order to maintain an appropriate chemical reaction ratio, the external air supply line 550 may further include a flow meter, and the vacuum pump 551 may be controlled according to the flow rate of the external air displayed on the flow meter. The external air supply line 550 may include one or more needle valves 210 to control the flow rate thereof properly.

The gas transferred from the vaporizer 100 to the reaction chamber 510 may be guided through the nitrogen transfer line 540. If there is no leakage of gas UF6 from the cylinder 200 into the vaporizer 100, the nitrogen transfer line 540 is transferred only nitrogen, but if there is a leak, the gas flowing through the nitrogen transfer line 540 includes UF6. do. The nitrogen transfer line 540 connects the reaction chamber 510 and the vaporizer 100, and the nitrogen transfer line 540 and the external air supply line 550 are connected to each other through the three-way valve 210 to one nozzle. It may be introduced into the reaction chamber 510 through.

At this time, the nozzle passing through the outside air and the gas inside the vaporizer 100 may be defined as a special nozzle (570).

Figure 4 shows a special nozzle 570 included in the uranium hexafluoride vaporization system according to an embodiment of the present invention.

Referring to Figure 4, the special nozzle 570 included in the uranium hexafluoride vaporization system according to an embodiment of the present invention, the carburetor to which the external air inlet and the vaporizer 100, the internal air flows into the external air flows (100) It is divided into the internal gas inlet.

The special nozzle 570 is a tubular shape having a constant diameter, one side of which is inserted into the reaction chamber 510 to constitute an outlet, and constitutes an inlet that is divided into the other external air inlet and the vaporizer 100 internal gas inlet. .

The special nozzle 570 has an inner diameter larger than the outer diameter of the nitrogen transfer line 540 so that the nitrogen transfer line 540 can be inserted therein. The nitrogen transfer line 540 is inserted into the reaction chamber 510 through the internal space of the special nozzle 570 along the longitudinal direction of the special nozzle 570.

Since the inner diameter of the special nozzle 570 is larger than the outer diameter of the nitrogen transfer line 540, a predetermined portion of the special nozzle 570 is separated from the nitrogen transfer line 540. In addition, the internal space of the special nozzle 570 may be divided into a first region 571 formed only by the nitrogen transfer line 540 and a second region 573 extending from the outer circumferential surface of the nitrogen transfer line. In this case, the above-described separation corresponds to the second area 573.

The special nozzle 570 is open at one side to communicate with the second region 573. At this time, the opening constitutes an external air inlet, and the external air supply line 550 is connected to this opening. Therefore, the external air transferred through the external air supply line 550 may flow into the reaction chamber 510 along the second region 573. That is, the external air inlet is formed by splitting from one side of the special nozzle 570, the external air flows into the external air inlet, and proceeds along the outer circumferential surface of the nitrogen transfer line 540 in the longitudinal direction of the special nozzle 570. It is introduced into the reaction chamber 510. The separation generated at the portion where the nitrogen transfer line 540 is inserted into the special nozzle 570 is completely sealed, and the second region 573 forms a completely closed space except for the outside air inlet and the outlet.

The second region 573 of the special nozzle 570 further includes a pipe-type spacer 545 disposed at regular intervals along the outer circumferential surface of the nitrogen transfer line 540.

The spacer 545 maintains the width of the second region 573 in the circumferential direction to induce a constant flow rate of the external air introduced into the reaction chamber 510 through the second region 573.

The spacer 545 is formed to have a predetermined length to correspond to the length of the special nozzle 570, and is disposed in the longitudinal direction of the special nozzle 570 between the outer circumferential surface of the nitrogen transfer line 540 and the inner circumferential surface of the special nozzle 570. . The pipe spacer 545 may be made of stainless steel or the like.

5 is a block diagram of a safety device 220 included in the uranium hexafluoride vaporization system according to an embodiment of the present invention.

Referring to FIG. 5, the safety device 220 included in the uranium hexafluoride vaporization system according to an embodiment of the present invention functions to open and close the cylinder valve 210 to prevent leakage of the gas UF6.

The safety device 220 includes a first arm, a gearbox 225 and a second arm 227.

The first arm is rotated by receiving power from the outside of the vaporizer 100, and is formed intruding into the vaporizer 100. It is also operated by the drive handle 240a or the drive motor 240b located outside. Therefore, the operator can safely perform the maintenance from the outside, and when the leak is detected it can be driven to close the cylinder valve 210.

One end of the first arm is exposed to the outside and is connected to the driving handle 240a or the driving motor 240b, and the other end is connected to the gearbox 225 inside the carburetor 100. The other end of the first arm connected to the gear box 225 may be provided with a universal joint 222.

The gear box 225 is connected to the first arm to transfer the rotational force of the first arm to the cylinder valve 210 by changing the axis. Therefore, the installation position of the drive handle 240a or the drive motor 240b is not greatly limited. As long as it is a known means for transmitting the rotational force by changing the axis, a person skilled in the art can be used as long as the change is applicable. For example, the bevel gears may be arranged at right angles to configure the gearbox 225.

One end of the second arm 227 is connected to the gear box 225 and the other end of the second arm 227 to open and close the cylinder valve 210 through a rotational movement. The second arm 227 also includes a universal joint 228, which can greatly alleviate structural limitations.

The safety device 220 may receive the notification signal by the signal generator included in the sensor unit, and open and close the cylinder valve 210. That is, when a leak is detected, the driving handle 240a or the driving motor 240b will close the cylinder valve 210.

The first arm 221 is introduced into the carburetor 100 and a through hole is formed. The first arm 221 is rotated by the driving handle 240a or the driving motor 240b to generate a space at a contact surface with the through hole. Thus, in consideration of the risk that the internal gas of the vaporizer 100 may leak, the contact surface of the through-hole and the first arm 221 may be sealed through a separate sealing device.

6 is a plan view of a cylinder valve included in the uranium hexafluoride vaporization system according to an embodiment of the present invention. 7 is a side view of a cylinder valve included in the uranium hexafluoride vaporization system according to an embodiment of the present invention. 8 illustrates an operation state of a cylinder valve included in the uranium hexafluoride vaporization system according to an embodiment of the present invention.

6 to 8, the cylinder valve included in the uranium hexafluoride according to an embodiment of the present invention may be operated by an external motor, and the user may operate the steering wheel directly. At this time, the connection portion between the shaft for transmitting the driving force of the motor and the shaft for transmitting the driving force of the handle may be specially designed so that the cylinder valve is not affected by the handle when the cylinder valve is operated by the motor. More specifically, when the motor is driven, the shaft for transmitting the driving force by the handle further includes a lock of the cylinder valve coaxially, it is possible to limit the movement of the shaft connected to the handle in accordance with the drive of the motor. The opposite is also true.

The following discloses configurations that include the technical features of the present invention.

A vaporizer formed with a constant volume of internal space; A cylinder disposed inside the vaporizer, in which vaporization of the solid UF6 takes place; A cylinder valve provided at one side of the cylinder to open and close the cylinder, and discharge the gas UF6 to the outside of the cylinder; A discharge passage connected to the cylinder valve to guide the gas UF6 to a conversion furnace outside the vaporizer; A heater which supplies heat to the inside of the vaporizer to control the vaporization rate of the solid UF6; A fan for promoting circulation of gas in the vaporizer so that heat supplied from the heater is uniformly transferred to the cylinder; It includes a leak detector for detecting whether the gas UF6 generated in the cylinder leaks.

Preferably, the cylinder valve, characterized in that the opening and closing by a safety device for preventing the leakage of the gas UF6, the safety device is rotated by the power supplied from the outside of the carburetor, and is intruding into the carburetor First arm;

A gear box connected to the first arm to transfer a rotational force of the first arm by changing an axis; And a second arm, one end of which is connected to the gearbox and the other end of which is connected to the cylinder valve, opening and closing the cylinder valve through a rotational movement.

In addition, the first arm is operated by a drive handle or a drive motor, the connection portion with the gear box is provided with a first universal joint, the second arm is characterized in that it comprises a second universal joint. It is done.

On the other hand, the leak detection device, the reaction chamber in which the gas inside the vaporizer is temporarily accommodated; A sensor unit provided inside the reaction chamber; And an external air supply line for supplying external air to the reaction chamber, wherein the sensor unit comprises: an HF sensor sensing HF gas; And a smoke detector for detecting smog.

Preferably, the reaction chamber includes a material that is visible on the front surface, and further includes a door that can be opened and closed on one side.

Preferably, the gas inside the vaporizer and the external air is introduced into the reaction chamber via a special nozzle.

Preferably, the external air supply line includes a vacuum pump and a filter.

On the other hand, the leak detection device, the reaction chamber in which the gas inside the vaporizer is temporarily accommodated; A sensor unit provided inside the reaction chamber; And an external air supply line for supplying external air to the reaction chamber, wherein the sensor unit comprises: an HF sensor sensing HF gas; Smoke detectors for detecting smog; And a signal generator for generating an alarm signal according to the detection of the HF gas or the smog, wherein the safety device further includes a control unit for opening and closing the cylinder valve according to the alarm signal generated from the signal generator.

Preferably, the gas in the vaporizer is introduced into the special nozzle through the nitrogen transfer line, the special nozzle is a tube formed of a constant diameter, so that the nitrogen transfer line is inserted therein A first region having an inner diameter larger than an outer diameter of the nitrogen transfer line, one end of which is inserted into the reaction chamber, wherein a space inside the special nozzle is formed only by the nitrogen transfer line, and the nitrogen transfer line; When dividing into a second region extending from the outer circumferential surface of the line, the external air supply line is in communication with the second region to supply the external air to the reaction chamber, and the external air and the gas inside the vaporizer are the special In order not to react inside the nozzle, the nitrogen transfer line protrudes from one end of the special nozzle to the inside of the reaction chamber. The special nozzle further comprises a plurality of pipe-shaped spacers arranged at regular intervals along the outer circumferential surface of the nitrogen transfer line in the second region, and the inner circumferential surface of the special nozzle and the outer circumferential surface of the nitrogen transfer line It is characterized by maintaining a constant interval.

On the other hand, the present invention is not limited to the embodiments of the present invention and the accompanying drawings in the above description, it is apparent to those skilled in the art that various substitutions, modifications and changes are possible without departing from the technical spirit of the present invention. something to do.

Carburetor 100
Cylinder 200
Cylinder Valve 210
Exhaust path 230
Safety device 220
First arm 221
Gearbox 225
2nd arm 227
Universal joint 222
Second Universal Joint 228
Drive handle 240a
Drive motor 240b
Heater 300
Fan 400
Leak Detector 500
Reaction chamber 510
Door 513
HF sensor 531
Smoke Detectors 533
External Air Supply Line 550
Vacuum Pump 551
Filter 553
Special Nozzles 570
First Zone 571
Second Zone 573
Nitrogen Transfer Line 540
Piped Spacers 545

Claims (9)

delete A vaporizer formed with a constant volume of internal space;
A cylinder disposed inside the vaporizer, in which vaporization of the solid UF6 takes place;
A cylinder valve provided at one side of the cylinder to open and close the cylinder, and discharge the gas UF6 to the outside of the cylinder;
A discharge passage connected to the cylinder valve to guide the gas UF6 to a conversion furnace outside the vaporizer;
A heater which supplies heat to the inside of the vaporizer to control the vaporization rate of the solid UF6;
A fan for promoting circulation of gas in the vaporizer so that heat supplied from the heater is uniformly transferred to the cylinder;
It includes a leak detection device for detecting whether the gas generated in the cylinder UF6 leak,
The cylinder valve,
It is characterized in that the opening and closing by a safety device for preventing the leakage of the gas UF6,
The safety device,
A first arm that rotates by receiving power from the outside of the carburetor and is intrusive into the carburetor;
A gear box connected to the first arm to transfer a rotational force of the first arm by changing an axis; and
One end is connected to the gear box and the other end is connected to the cylinder valve, the uranium hexafluoride vaporization system including a second arm for opening and closing the cylinder valve through a rotational movement.
The method of claim 2,
The first arm,
It is operated by a drive handle or a drive motor, the connection portion with the gear box is provided with a first universal joint,
The second arm,
A uranium hexafluoride vaporization system comprising a second universal joint.
A vaporizer formed with a constant volume of internal space;
A cylinder disposed inside the vaporizer, in which vaporization of the solid UF6 takes place;
A cylinder valve provided at one side of the cylinder to open and close the cylinder, and discharge the gas UF6 to the outside of the cylinder;
A discharge passage connected to the cylinder valve to guide the gas UF6 to a conversion furnace outside the vaporizer;
A heater which supplies heat to the inside of the vaporizer to control the vaporization rate of the solid UF6;
A fan for promoting circulation of gas in the vaporizer so that heat supplied from the heater is uniformly transferred to the cylinder;
It includes a leak detection device for detecting whether the gas generated in the cylinder UF6 leak,
The leak detection device,
A reaction chamber in which gas in the vaporizer is temporarily received;
A sensor unit provided inside the reaction chamber; And
An external air supply line for supplying external air to the reaction chamber,
The sensor unit,
HF sensor for detecting the HF gas; And
Uranium hexafluoride vaporization system including a smoke detector for detecting smog.
The method of claim 4, wherein
The reaction chamber,
A uranium hexafluoride vaporization system comprising a visible material on the front surface, and further comprising a door openable on one side.
The method of claim 4, wherein
The uranium hexafluoride vaporization system, characterized in that the gas inside the vaporizer and the external air is introduced into the reaction chamber via a special nozzle.
The method of claim 4, wherein
The external air supply line,
Uranium hexafluoride vaporization system comprising a vacuum pump and a filter.
The method of claim 2,
The leak detection device,
A reaction chamber in which gas in the vaporizer is temporarily received;
A sensor unit provided inside the reaction chamber; And
An external air supply line for supplying external air to the reaction chamber,
The sensor unit,
HF sensor for detecting the HF gas;
Smoke detectors for detecting smog; And
It includes a signal generator for generating an alarm signal in accordance with the detection of the HF gas or the smog,
The safety device,
The uranium hexafluoride vaporization system further comprising a control unit for opening and closing the cylinder valve in accordance with the alarm signal generated by the signal generator.
The method of claim 6,
The gas inside the vaporizer,
It is introduced into the special nozzle through the nitrogen transfer line,
The special nozzle,
A tube formed of a constant diameter, the inner diameter is larger than the outer diameter of the nitrogen transfer line so that the nitrogen transfer line is inserted therein, characterized in that one end is inserted into the reaction chamber,
When the space inside the special nozzle is divided into a first region formed only by the nitrogen transfer line and a second region extending from an outer circumferential surface of the nitrogen transfer line,
The external air supply line is in communication with the second area to supply the external air to the reaction chamber,
In order to prevent the external air and the gas inside the vaporizer from reacting in the special nozzle, the nitrogen transfer line is formed to protrude to the inside of the reaction chamber through one end of the special nozzle.
The special nozzle further includes a plurality of pipe-shaped spacers disposed at regular intervals along the outer circumferential surface of the nitrogen transfer line in the second region, so that the inner circumferential surface of the special nozzle and the outer circumferential surface of the nitrogen transfer line maintain a constant interval. Uranium hexafluoride vaporization system characterized in that.

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