KR102136362B1 - System of real time detecting uranium from hydrofluoric acid - Google Patents

Abstract

The present invention particularly relates to a uranium detection system having a detection chamber capable of detecting whether or not uranium is contained in the total amount of hydrofluoric acid solution generated in a reconversion converter for nuclear fuel enrichment, a reconversion converter and discharged from the reactor An HF condenser receiving gas and condensing it into a liquid hydrofluoric acid solution, a uranium detector receiving a hydrofluoric acid solution condensed from the HF condenser to detect whether uranium is detected in the hydrofluoric acid solution, a detection chamber in which a uranium detector is installed, and a uranium detector Real-time uranium detection system in the hydrofluoric acid solution, which consists of a storage tank that stores the hydrofluoric acid solution that has passed through, so that the uranium detection process of the hydrofluoric acid solution is more accurate and safe, but the efficiency of the process is even higher. Want to provide

Description

System of real time detecting uranium from hydrofluoric acid}

The present invention relates to a uranium detection system, and more particularly, to a uranium detection system having a detection chamber capable of detecting whether or not uranium is contained in the total amount of the hydrofluoric acid solution generated in a reconversion conversion process for nuclear fuel concentration.

The production of nuclear fuel includes uranium ore (U ₃ O ₈ ) mining and screening process, reduction process (UO ₂ ), fluorination process (UF ₄ ), fluorination process (UF ₆ ), reconversion process (UO ₂ ), and concentration process (U ₂₃₅ ).

Here, the re-conversion process is performed in the re-conversion converter shown in FIG. 1, and UF ₆ and nitrogen (N ₂ ) and water vapor (H ₂ O) are injected together to produce a powder in the form of UO ₂ F ₂ , and then centrifuged. After the separation process, U ₂₃₅ is converted into UO ₂ powder, which is the main axis, and then extracted and transferred to a concentration process.

In this case, the hydrofluoric acid gas (6HF) generated in the process of producing UO ₂ F ₂ powder and the off-gas composed of water vapor, nitrogen gas, and hydrogen gas (off-gas) is a toxic gas harmful to the human body, hydrofluoric acid gas (6HF). Since it contains, it needs to be collected and reprocessed.

Therefore, when the generated exhaust gas is condensed, the hydrofluoric acid gas (6HF) is dissolved in water to form a hydrofluoric acid solution, and the hydrofluoric acid solution is collected separately. At this time, the flow rate is about 0.5Kg HF/min and unreacted nitrogen and residual hydrogen are discharged through the vent pipe.

However, in the hydrofluoric acid solution, uranium that cannot be separated may be mixed when the preceding process is operated abnormally. In this case, since the hydrofluoric acid solution is still flowing, it is necessary to check whether uranium is detected in real time, and if uranium is detected, it must be stored and reprocessed immediately.

However, at present, there is a problem in that technology for a system having a structure in which such real-time detection is made of high accuracy is insufficient, and a hydrofluoric acid solution having a risk of exposure may be discharged or detection accuracy may be low, resulting in unnecessary process interruption.

Patent Publication No. 1994-7001955 (published date: June 28, 1994)

Accordingly, the present invention is to improve the problems of the prior art, it is possible to detect in real time whether or not uranium is detected for the total amount of hydrofluoric acid solution generated in the reconversion process, and the accuracy of uranium detection while using conventional uranium detection equipment Provides a real-time uranium detection system in a hydrofluoric acid solution, which has a structure that can improve the fluorine solution by detecting the uranium solution immediately, when the uranium is detected in the hydrofluoric acid solution. I want to.

A real-time uranium detection system in a hydrofluoric acid solution according to the present invention for achieving this purpose is a UF ₆ gas and nitrogen gas (N ₂ ) and water vapor (H ₂ O) modified from U ₃ O ₈ type uranium powder for uranium concentration. A reactor that receives and converts UO ₂ F ₂ and discharges exhaust gas composed of hydrogen fluoride (6HF), water vapor (H ₂ O), nitrogen (N ₂ ), and hydrogen (H ₂ ) generated in the conversion process, Re-conversion converter consisting of a rotator that extracts UO ₂ powder by centrifugal force while receiving UO ₂ F ₂ from a reactor and rotates itself, and a hopper that collects UO ₂ powder from the rotator and delivers it to a concentration process, and exhaust gas from the reactor A HF condenser receiving condensation into a liquid hydrofluoric acid solution, a uranium detector receiving a hydrofluoric acid solution condensed from the HF condenser to detect whether uranium is detected in the hydrofluoric acid solution, a detection chamber in which a uranium detector is installed, and a uranium detector. Consisting of a storage tank for storing the passed hydrofluoric acid solution, the condensed liquid is temporarily retained inside the detection chamber, and a uranium detector is installed inside the detection chamber to detect in real time whether uranium is detected for the total amount of the hydrofluoric acid solution. It is characterized by detecting.

Here, the detection chamber is preferably cylindrical, and the uranium detector is disposed at the center of the detection chamber.

In this case, the detection chamber is preferably formed in the shape of a hollow in the center of the cylinder, the outer wall of the detection chamber is sealed with a radiation shield, and the inner wall forming the hollow can pass radiation, and an entrance through which hydrofluoric acid solution flows into the chamber. The tube and the outlet tube from which the hydrofluoric acid solution is discharged are installed to be spaced apart from each other, and a uranium detector is installed inside the hollow.

In addition, the inlet pipe and the outlet pipe are preferably installed in opposite directions, the inlet pipe is connected to the lower portion of the detection chamber, and the outlet pipe is connected to the upper portion of the detection chamber, so that the hydrofluoric acid solution introduced into the detection chamber is connected to the outer wall. By filling all the space inside the detection chamber surrounded by the inner wall and then discharged to the outlet tube, the uranium detector can detect uranium across the entire inner wall of the detection chamber forming a hollow.

In addition, the storage tank is preferably composed of a normal solution tank and a uranium detection tank, and when uranium is not detected in the hydrofluoric acid solution, the hydrofluoric acid solution that has passed through the detection chamber enters the normal solution tank, and uranium in the hydrofluoric acid solution. When detected, the hydrofluoric acid solution that has passed through the detection chamber enters the uranium detection tank.

In addition, the uranium detector is preferably connected to the control unit, the control unit is connected to the operation unit, the uranium detector sends uranium detection and uranium detection values to the control unit, the control unit by sending the measurement value to the operation unit, the control unit By checking the uranium detection signal sent and received by the operator to be controlled, the pipe connecting the normal solution tank and the detection chamber is blocked, and the pipe connecting the uranium detection tank and the detection chamber is opened.

At this time, the inside of the detection chamber is preferably provided with an inner partition wall surrounding the hollow, separating the detection chamber inner space into an inner chamber and an outer wall chamber, the inner chamber is formed in a form surrounding the hollow, and the outer chamber is an inner partition wall It becomes a space between the outer wall and the inlet pipe and the outlet pipe are directly connected to the inside of the inner chamber, so that the flow of the hydrofluoric acid solution is formed close to the uranium detector.

Particularly preferably, an opening/closing door communicating the inner chamber and the outer chamber is installed on the inner partition wall, and when uranium is detected in the hydrofluoric acid solution, the opening/closing door is immediately opened, and as the hydrofluoric acid solution flows into the outer chamber, hydrofluoric acid enters the outer chamber By stopping the outflow of the hydrofluoric acid solution into the outlet tube while the solution is being filled, it is prevented that the hydrofluoric acid solution in which uranium is detected is introduced into the normal solution tank.

The real-time uranium detection system in the hydrofluoric acid solution according to the present invention can detect in real time whether uranium is detected with respect to the total amount of the hydrofluoric acid solution generated in the reconversion process, while using the conventional uranium detection equipment, the accuracy of uranium detection is conventional. Even more improved, it does not cause unnecessary interruption of the process, and when uranium is detected in the hydrofluoric acid solution, it has the effect of immediately collecting the detected hydrofluoric acid solution.

1 is a block diagram of a re-conversion converter,
2 is a block diagram of a uranium detection system according to an embodiment of the present invention,
Figure 3a is a conceptual diagram showing the structure of the detection chamber in Figure 2,
Figure 3b is a perspective view of Figure 3a,
FIG. 4 is a configuration diagram that embodies and expands FIG. 2,
5 is a perspective view showing a modified embodiment of the detection chamber,
Figure 6 is a plan view of Figure 5,
7 is a partially enlarged view of FIG. 5,

The specific structure or functional descriptions presented in the embodiments of the present invention are exemplified for the purpose of explaining the embodiments according to the concept of the present invention, and the embodiments according to the concept of the present invention may be implemented in various forms. In addition, it should not be construed as being limited to the embodiments described herein, and should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the present invention.

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

Uranium detection system according to an embodiment of the present invention, as shown in Figures 1 and 2 reconversion converter 10, HF condenser 20, uranium detector 40, and detection chamber 30 ) And storage tanks 51 and 52.

Referring to Figure 1, the reconversion converter 10, UF ₆ gas and nitrogen gas (N ₂ ) and water vapor (H ₂ O) modified from U ₃ O ₈ type uranium powder for uranium concentration as described above ) To convert to UO ₂ F ₂ and a reactor that discharges exhaust gas composed of hydrogen hexafluoride (6HF), water vapor (H ₂ O), nitrogen (N ₂ ), and hydrogen (H ₂ ) generated during the conversion process ( 11), a rotator 12 that receives UO ₂ F ₂ from the reactor 11 and extracts UO ₂ powder by centrifugal force while being rotated by itself, and a hopper that collects UO ₂ powder from the rotator 12 and delivers it to a concentration process (13).

Here, hydrofluoric acid gas (6HF) generated in the process of producing UO ₂ F ₂ type powder and exhaust gas (off-gas) composed of water vapor, nitrogen gas, and hydrogen gas is used to produce fluorine gas (6HF), a poisonous gas harmful to the human body. Since it contains, it needs to be collected and reprocessed.

The HF condenser 20 condenses the exhaust gas with cooling water to transform the exhaust gas into a hydrofluoric acid solution. At this time, the flow rate of the condensed hydrofluoric acid solution is 0.5 kg HF/min in one embodiment, and nitrogen and residual hydrogen may be discharged through a vent pipe (not shown).

The uranium detector 40 is installed inside the detection chamber 30 in which the hydrofluoric acid solution is filled, as shown in FIGS. 3A and 4. Here, the capacity of the detection chamber can be adjusted as much as necessary, and when the flow rate of the hydrofluoric acid solution is 0.5 Kg HF/min, it is approximately 4 kg HF. In this case, the time for the hydrofluoric acid solution to remain in the detection chamber 30 is not particularly limited, but when the flow rate of the hydrofluoric acid solution is 0.5 Kg HF/min, it is approximately 4 minutes.

For reference, the uranium detector 40 can be generally adopted as long as it can detect uranium. However, the uranium detector is preferably selected as a non-contact type because durability of the detection chamber 30 and corrosion resistance of hydrofluoric acid should be considered. As an example, a scintillation analyzer LaBr3 may be employed as the uranium detector 40 in the present invention.

The hydrofluoric acid solution that has passed through the detection chamber 30 in which the uranium detector 40 is installed is sent to the storage tanks 51 and 52 as shown in FIG. 2.

At this time, while the condensed hydrofluoric acid solution temporarily stays inside the detection chamber 30, whether or not uranium is contained in real time is detected by the uranium detector 40.

Hereinafter, the organic coupling relationship between each component and components will be described in more detail.

The present invention is characterized in that it simultaneously achieves the goal of achieving the best safety by thoroughly separating the uranium-containing hydrofluoric acid solution and the goal of being difficult to harmonize with each other, that the treatment process of the hydrofluoric acid solution must proceed as efficiently as possible.

Achieving these two goals is possible by first maximizing the uranium detection performance, and immediately identifying the exact time when the hydrofluoric acid solution should be separated and discharged. By maximizing the resolution of the uranium detection performance as described above, unnecessary process interruptions are minimized, and the hydrofluoric acid solution containing uranium can be thoroughly separated.

In order to maximize the uranium detection performance, the detection chamber 30 is manufactured in a cylindrical shape as illustrated in FIG. 3A, and the detection chamber 30 is formed with a hollow 33 having a cylindrical shape at the center. 40) is disposed inside the hollow (30).

Therefore, in real time, the hydrofluoric acid solution passing through the detection chamber 30 flows in an enclosed form around the uranium detector 40, so that the entire hydrofluoric acid solution can be inspected as well as inside the detection chamber 30. Since the entire hydrofluoric acid solution is located at the same distance radially around the uranium detector 40, the detection capability of the uranium detector 40 can be maximized.

In addition, the outer wall 31 of the detection chamber 30 is sealed with a radiation shield, the inner wall forming the hollow 33 can pass radiation, and the detection chamber 30 has an inlet tube 311 through which a hydrofluoric acid solution flows. The outlet pipes 312 through which the hydrofluoric acid solution is discharged are installed to be spaced apart from each other.

In particular, the inlet pipe 311 and the outlet pipe 312 are installed opposite to each other as shown in FIG. 3A, and the inlet pipe 311 is connected to the lower portion of the detection chamber 30 and the outlet pipe 312 is detected. It is connected to the top of the chamber 30. Therefore, the hydrofluoric acid solution introduced into the detection chamber 30 through the inlet pipe 311 fills all the inside of the detection chamber 30 without leaving an empty space inside the detection chamber 30 and is then discharged to the outlet pipe 312. . Due to this configuration, the uranium detector 40 can inspect a large amount of hydrofluoric acid solution in a short time by using the entire space inside the detection chamber 30. That is, since the hydrofluoric acid solution inside the detection chamber 30 is exposed at a time toward the uranium detector 40 disposed in the hollow 33 inside the detection chamber 30, real-time detection is performed even if it passes through the detection chamber 30 at a predetermined flow rate or more. This is possible. In addition, a drain pipe 313 may be installed under the outlet pipe 312 as illustrated in FIG. 3A.

On the other hand, the storage tank is composed of a normal solution tank 51 and a uranium detection tank 52, and when uranium is not detected in the hydrofluoric acid solution, the hydrofluoric acid solution passing through the detection chamber 30 is a normal solution tank 51 When uranium is detected in the hydrofluoric acid solution, the hydrofluoric acid solution that has passed through the detection chamber 30 flows into the uranium detection tank 52. Therefore, the fluorine solution in which uranium is detected can be separately collected.

And the uranium detection tank 52 is made of radiation shielding material to prevent exposure.

In addition, the uranium detector 40 is connected to the control unit 60 provided for remote control of the uranium detector to be capable of transmitting and receiving signals to each other, and the control unit 60 is an operation unit 70 provided for an operator to operate the control unit 60 In connection with (Operation CRT), the uranium detector 40 transmits a measurement value to the control unit 60 whether or not uranium is detected and when uranium is detected.

Here, the uranium detector 40 may transmit the measurement results to the control unit 60 in real time or the measurement results at regular time intervals, such as once every 10 minutes.

At this time, the control unit 60 checks the uranium detection signal received and received from the control unit 60 by the operator managing the operation unit 70 by sending the measurement value to the operation unit 70, and then the normal solution tank 51 and the detection chamber (30) The tube connecting between is blocked, and the tube connecting between the uranium detection tank 52 and the detection chamber 30 is opened.

In addition, even if the operator 70 does not operate the operator to transfer the hydrofluoric acid solution transferred to the normal solution tank 51 to the uranium detection tank 52 depending on whether or not uranium is detected, hydrofluoric acid is automatically detected. The solution may be configured to transmit an operation signal to the control unit 60 to be transferred to the uranium detection tank 52.

In the present invention, the detection chamber 30 is shown in FIG. 5 so that more accurate detection is achieved by increasing the uranium detection resolution, and when uranium is detected, movement of the hydrofluoric acid solution to the normal solution tank 51 can be stopped as soon as possible. As can be seen, the interior space can be divided.

More specifically, as illustrated in FIG. 5, an inner partition wall 34 surrounding the hollow is installed inside the detection chamber 30, and the inner space of the detection chamber 30 is divided into an inner chamber 341 and an outer wall chamber 342. To separate. At this time, the inner chamber 341 is formed in a shape surrounding the hollow, the outer chamber 342 becomes a space between the inner partition wall 34 and the outer wall 31, and the inlet pipe 311 and the outlet pipe 312 are internal. By being directly connected to the interior of the chamber 341, the flow of the hydrofluoric acid solution is formed to be more limited to an area close to the uranium detector 40.

In this case, an opening/closing door 36 communicating the inner chamber 341 and the outer chamber 342 is installed on the inner partition wall 34, and when uranium is detected in the hydrofluoric acid solution, the opening/closing door 36 is immediately opened, and hydrofluoric acid As the solution flows into the outer chamber 342, while the hydrofluoric acid solution is filled in the outer chamber 342 space, the flow of the hydrofluoric acid solution into the outlet tube 312 is temporarily stopped for a certain period of time. As a result, it is possible to prevent the fluoride solution in which uranium is detected from flowing into the normal solution tank 51.

When the detection chamber 34 is manufactured with the configuration as shown in FIG. 5, two special effects may be generated. The first is that the detection accuracy is further improved by making the thickness of the space surrounding the uranium detector 40 in the hydrofluoric acid solution thinner. This effect can be said to be more significant because the entire amount of the hydrofluoric acid solution passes through the uranium detector 40.

Second, the outer chamber 342 and the inner chamber 341 communicate with each other when the opening/closing door 36 shown in FIG. 7 is opened, and the opening/closing door 36 is immediately opened when uranium is detected in the hydrofluoric acid solution. Since the flow of the hydrofluoric acid solution is stopped while the outer chamber 342 is filled, the tube connected to the normal solution tank 51 is sealed during that time, and the tube connecting the uranium detection tank 52 and the detection chamber 30 is opened. , It is that the amount of uranium mixed with the hydrofluoric acid solution into the normal solution tank 51 can be minimized.

For reference, the opening/closing module 35 for opening the opening/closing door 36 reveals that any known configuration of the module can be adopted as long as it is a mechanism capable of opening and closing the opening/closing door 36 remotely.

As a result, in the present invention, the uranium detection process of the hydrofluoric acid solution is more accurate and safe, but the efficiency of the process can be further increased, thereby achieving all of the dual goals.

The present invention described above is not limited by the above-described embodiments and accompanying drawings, and various substitutions, modifications, and changes are possible within the scope of the present invention without departing from the technical spirit of the present invention. It will be apparent to those who have the knowledge of.

10: Reconversion Conversion furnace 11: Reactor
12: rotator 13: hopper
20: HF condenser 30: detection chamber
31: outer wall 32: chamber interior space
33: hollow 34: inner partition wall
35: opening and closing module 36: opening and closing door
40: uranium detector 51: normal solution tank
52: uranium detection tank 60: control unit
70: control unit 311: entrance tube
312: outlet pipe 313: drain pipe
341: inner chamber 342: outer chamber

Claims (8)

UF ₆ gas transformed from U ₃ O ₈ type uranium powder and nitrogen gas (N ₂ ) and water vapor (H ₂ O) are converted to UO ₂ F ₂ for uranium enrichment, and hydrogen hexafluoride generated in the conversion process (6HF), a reactor that discharges exhaust gas composed of water vapor (H ₂ O), nitrogen (N ₂ ), and hydrogen (H ₂ ), and receives UO ₂ F ₂ from the reactor, rotates itself, and generates UO ₂ powder by centrifugal force. A re-conversion converter consisting of a rotator for extraction and a hopper for collecting UO ₂ powder from the rotator and transferring it to a concentration process;
An HF condenser that receives exhaust gas from the reactor and condenses it into a liquid hydrofluoric acid solution;
A uranium detector that receives the hydrofluoric acid solution condensed from the HF condenser and detects whether uranium is detected in the hydrofluoric acid solution;
A detection chamber in which a uranium detector is installed; And,
It consists of a storage tank that stores the hydrofluoric acid solution that has passed through the uranium detector,
The condensed liquid temporarily stays inside the detection chamber, and a uranium detector is installed inside the detection chamber to detect in real time whether uranium is detected for the total amount of the hydrofluoric acid solution,
The detection chamber is a cylindrical shape, the uranium detector is disposed in the center of the detection chamber,
The detection chamber is formed in the center of the cylinder-shaped hollow, the outer wall of the detection chamber is sealed with a radiation shielding material, the inner wall forming the hollow can pass radiation, the chamber has an inlet tube and a hydrofluoric acid solution into which a hydrofluoric acid solution is introduced. The outlet pipes to be discharged are installed spaced apart from each other, and the uranium detector is installed inside the hollow,
The inlet pipe and the outlet pipe are installed in opposite directions, the inlet pipe is connected to the lower portion of the detection chamber, and the outlet pipe is connected to the upper portion of the detection chamber, so that the hydrofluoric acid solution flowing into the detection chamber is surrounded by outer and inner walls. By filling all the space inside the detection chamber and then discharged to the outlet tube, the uranium detector can detect uranium across the entire inner wall of the detection chamber forming a hollow,
The storage tank is composed of a normal solution tank and a uranium detection tank, and when uranium is not detected in the hydrofluoric acid solution, the hydrofluoric acid solution passing through the detection chamber enters the normal solution tank, and when uranium is detected in the hydrofluoric acid solution The hydrofluoric acid solution passing through the detection chamber enters the uranium detection tank,
The uranium detector is connected to a control unit provided for remote control of the uranium detector to enable signal transmission and reception, and the control unit is connected to an operation unit provided to allow an operator to operate the control unit, and the uranium detector detects uranium and detects uranium. In this case, the measurement value is sent to the control unit, and the control unit sends the measurement value to the operation unit, so that the operator managing the operation unit checks the uranium detection signal sent and received from the control unit, and the pipe connecting the normal solution tank and the detection chamber is blocked. The tube connecting the uranium detection tank and the detection chamber,
An inner partition wall surrounding the hollow is installed in the detection chamber to separate the interior space of the detection chamber into an inner chamber and an outer wall chamber,
The inner chamber is formed in a shape surrounding the hollow, and the outer chamber becomes a space between the inner and outer walls,
The inlet tube and outlet tube are directly connected to the inside of the inner chamber, so that the flow of the hydrofluoric acid solution is formed in close proximity to the uranium detector Real-time uranium detection system in a hydrofluoric acid solution. delete delete delete delete delete delete According to claim 1,
An opening/closing door communicating the inner chamber and the outer chamber is installed on the inner partition wall, and when uranium is detected in the hydrofluoric acid solution, the opening/closing door is immediately opened, and as the hydrofluoric acid solution enters the outer chamber, the hydrofluoric acid solution is filled in the outer chamber space. Real-time uranium detection system in a hydrofluoric acid solution, characterized in that the hydrofluoric acid solution is prevented from flowing into the outlet tube while the hydrofluoric acid solution in which uranium is detected is prevented from entering the normal solution tank.

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