KR20020074743A - Oxidization-Deoxidization Apparutus using Plasma for a used Nuclear Fuel and Mehtod thereof - Google Patents

Abstract

PURPOSE: An apparatus and method is provided to easily obtain powder suitable for manufacturing a sintered body, while improving process efficiency by shortening reaction time for oxidation reduction. CONSTITUTION: An apparatus for oxidation reduction of spent nuclear fuel, comprises a plasma generating unit(1); a glass reactor(3) for performing oxidation reduction process by using the plasma gas which is ionized by the plasma gas generating power being supplied from the plasma generating unit; a rotating unit for rotating the glass reactor; and a gas injection unit(4) and a gas discharge unit(5) for injecting and discharging gas into and from the glass reactor. The glass reactor includes plasma feeding terminals(2,12,13) for feeding the ionized plasma gas to the glass reactor. A method for oxidation reduction of spent nuclear fuel, comprises a first step of injecting a reaction gas to the glass reactor through the gas injection unit; a second step of supplying an ionized plasma gas to the gas reactor by the current applied from the plasma generating unit; and a third step of permitting reaction between the reaction gas and the ionized plasma gas by rotating the glass reactor.

Description

Oxidation-reoxidization Apparatus using Plasma for a used Nuclear Fuel and Mehtod

The present invention relates to a redox apparatus and a method which is one of the processes of developing a light and heavy reactor linked fuel cycle technology. In particular, the present invention relates to an apparatus and a method for more smoothly performing a redox reaction than using a conventional technique by applying a plasma gas reaction to a redox process to redox spent fuel.

The development of the nuclear cycle technology following the nuclear reactor is actively being promoted in Korea in accordance with the advancement of nuclear technology.

Currently, there is a great need to develop a dry process technology that can replace the conventional fuel material wet handling process among the following nuclear cycle related technologies.

In particular, all the processes of developing light and heavy water reactor fuel cycle technology that process spent fuel from light water reactor nuclear power plant promoted by Korea Atomic Energy Research Institute and reuse it as nuclear fuel of heavy water reactor nuclear power plant are under research and development as dry process. .

Our country has the world's only light and heavy water reactors. The spent nuclear fuel that is being accumulated and discharged from the currently operating light water reactor has fissile material (~ 1.5 w / o) higher than that of natural uranium (~ 0.7 w / o). Along with achieving two goals for the disposal of high-level radioactive waste, groundbreaking electricity will be available to lay the foundation for nuclear fuel cycle technology independence.

To this end, in recent years, the technology for the dry processing of spent nuclear fuel from light water reactor type nuclear power plant and reusing it as fuel of heavy water reactor type nuclear power plant using natural uranium as fuel is nearing completion.

This technique uses the light water reactor type spent fuel as a heavy water reactor type spent fuel for heavy water reactor type nuclear power plants without separating the U-235, Pu-239, 241, etc. contained in the spent fuel by dry method. With the international community's confidence in handling sensitive nuclear materials, it can reduce the consumption of natural uranium used as heavy water reactor fuel, and reduce the disposal of light water reactor spent fuel.

The dry method used here consists of a series of processes as follows. That is, spent fuel cutting process, stripping process, redox process, grinding process, granulation process, mixing process, compacting process, sintering process, polishing process, fuel rod manufacturing process, fuel bundle manufacturing process and the like.

Since the process after the mixing process is the same as the existing heavy water reactor fuel manufacturing process except that the work is performed in a shielding facility, the characteristics of this method are the spent fuel cutting process, the stripping process, It can be found in the redox process, grinding process, granulation process, etc. Among these, the redox process can be seen as the most representative feature.

The redox process is a process of oxidizing and reducing the stripped spent fuel into fine powder. The principle is as follows.

The main component of spent fuel is U-238, and as already mentioned, it contains about 1.5% of fissile materials such as U-235, Pu-239, and 241, and about 3% of fission products. Is UO ₂ , and compounds of other elements also exist in most oxide states.

Therefore, the chemical main components of spent fuel can be seen in UO ₂ form like the nuclear fuel before use. To make it into heavy water fuel, it must be powdered and reprocessed to the size of heavy water fuel sintered body. However, when UO ₂ is oxidized, it becomes U ₃ O ₈ and changes to a fine powder due to internal stress due to the density difference according to the phase change. When the U ₃ O ₈ powder is reduced again, it becomes a UO ₂ powder.

The redox process is a very important process because the physical properties of the nuclear fuel sintered body obtained through the sintering process depend on the state of the powder obtained here.

To date, redox processes have generally been prepared using general electric furnaces that can control the atmosphere.

Put the stripped spent fuel into the electric furnace, close the door, heat it to 400 ℃ for 3-4 hours under air atmosphere to oxidize to make U ₃ O ₈ powder, and then raise the temperature to 700 ℃ under hydrogen atmosphere to reduce it for 3-4 hours. To make UO ₂ powder.

In addition, the method for producing a sintered body for producing the UO ₂ powder has been disclosed in the "Method of manufacturing a fuel sintered body" in Patent Publication No. 2000-19009.

According to the disclosed invention, the UO ₂ sintered body after use is oxidized by heating to a temperature of 300 to 800 ° C. while maintaining the oxidizing gas atmosphere. Here, as the oxidizing gas, one of air, oxygen, a mixture of air and an inert gas, and a mixed gas of oxygen and an inert gas is used.

In the conventional redox method, the reduction degree is often not constant depending on the powder layer during reduction.

That is, the reduction of the outer powder layer directly in contact with hydrogen occurs easily, but the reduction of the inner powder layer is insufficient due to insufficient contact with hydrogen compared to the outer powder layer and the free oxygen being difficult to be removed quickly.

Therefore, in order to obtain a sufficiently reduced powder, there is a problem in that the reduction for a relatively long time, or the oxidation, reduction process should be repeated several times.

In addition, according to the method of Patent Publication No. 2000-19009, since the unreacted sintered flakes and powder aggregates are mixed in the oxidation process, there is a problem in that the process has to be filtered using a separate sieve.

The present invention is to solve the problems of the prior art, an object of the present invention is to facilitate the long-range control of the oxidation and reduction process, excellent reaction control, and also used fuel oxidation using a plasma gas having excellent reactivity It is to provide a reducing apparatus and a method thereof.

As a technical idea for achieving the object of the present invention, the apparatus and method of the present invention proposes a device consisting of a plasma generating unit, a plasma supply terminal, a glass reactor, a gas injection and discharge unit, a drive motor and a reducer,

The reactor gas entering the glass reactor through the gas injection and discharge part is ionized through the plasma supply terminal by the current applied from the plasma generator, and the ionized plasma gas is introduced into the glass reactor rotating by the drive reducer and the motor. A method of reacting with post-fuel fuel to redox is presented.

1 is a schematic configuration diagram of a spent fuel redox device using plasma according to an embodiment of the present invention.

FIG. 2 is a detailed configuration diagram illustrating a tube inlet which is a main part of FIG. 1.

FIG. 3 is a detailed configuration diagram of a rotating unit which is a main part of FIG. 1.

4 is a detailed configuration diagram of a glass reactor, which is an essential part of FIG. 1.

5 is a configuration diagram for explaining the operation of the embodiment of the present invention.

<Description of Major Symbols in Drawing>

1: Plasma generator 2, 12, 13: plasma supply terminal

3: glass reactor 4: gas injection part

5: gas discharge part 6: driving motor and reducer

7: rotating part 8: support stand

9: expected 10: junction

11: glass reactor support 20: tube inlet body

21: through hole 22: disc-shaped joint

23: O-ring part 24, 25: bearing part

30: cylindrical fastener 31: opening

32: screw connection part 33: the rotating body

34: fixed cap 40: reactor body

41: projection 42: junction

Hereinafter, with reference to the accompanying drawings will be described in detail the configuration and operation of the invention for the embodiment of the present invention.

1 is a schematic configuration diagram of a spent fuel redox device using a plasma according to the present invention.

As shown in FIG. 1, the present invention provides a glass reactor 3 formed with a glass and a hole into which a gas injection tube can be inserted at one side thereof, and a glass;

A gas injection unit 4 including a rotary unit 7 joined to the hole side of the glass reactor, a driving motor and a reducer 6 for transmitting power to the rotary unit, and a gas tube introduced into the rotary unit 7; A gas discharge section 5,

A support 8 for fixedly holding the motor and the reducer 6 and the rotating part 7, a base 9 joined to the support 8 to support the entire apparatus, and a plasma in the glass reactor 3. It is composed of a plasma generator (1) for supplying the.

The configuration of the present invention will be described in more detail.

The base 8 having the predetermined area and placed on the ground, and the drive motor and the reducer 6 fixed to the upper surface of the base and having a deceleration function at an upper predetermined position can be fixedly supported, and the rotary part 7 and And a power transmission means such as a chain for transmitting power from the motor 6 to the rotary unit 7 for fixing the member supporting the glass reactor 3 rotatably,

A gas injection unit 4 including a gas injection tube inserted into one end of the rotary unit 7, a gas discharge unit 5 connected to a predetermined position of the gas injection unit 4 to discharge gas; A large beaker-shaped glass reactor 3 of glass material bonded to the other end of the rotating part 7 and a plurality of copper plates 12 and 13 for applying plasma gas generating power to the glass reactor 3. And a plasma supply terminal (2) made of the like and a plasma generator (1) for supplying plasma gas generating power to the plasma supply terminal (2).

In the configuration presented in the embodiment of the present invention further comprises a support for fixing the support (8) and the rotating part (7), bonded to one side of the support to support the gas discharge part (5) It further comprises a fixing for.

In addition, it further comprises a glass reactor (3) fixing portion for supporting the glass reactor (3) rotatably coupled to the upper side of the support (8).

Figure 2 is inserted into the rotary part 7 of the embodiment of the present invention and the gas injection tube through the tube to be inserted into the glass reactor 3, while the tube inlet for fixing the glass reactor 3 in close contact It is a detail view of a part and junction part.

As shown in FIG. 2, FIG. 2A is a front sectional view and FIG. 2B is a side view.

Referring to FIG. 2 (A), in this configuration, the junction between the gas injection tube inlet and the glass reactor 3 is integrally formed.

Predetermined length formed with a through hole 21 in the longitudinal direction through which the tube can be inserted, and bearing parts 24 and 25 contacting the tube at both ends of the through hole 21 to enable sealing and rotation. The tube inlet body 20 of the, and is coupled to one end of the tube inlet body 20 and has a protrusion protruding in the direction opposite to the tube inlet body 20 at the periphery, the inside of the protrusion O-ring-shaped sealing portion 23 formed along the circumference is formed, and is composed of a disk-shaped joint portion 22 in which a hole corresponding to the through-hole 21 of the tube inlet body 20 is formed. .

Protrusions formed on the periphery of the disc-shaped joint 22 and the O-ring-shaped sealing 23 formed therein are constitutions for enhancing the sealing property when bonded to the glass reactor 3.

3 is a detailed configuration diagram of the rotating unit for transmitting the rotational force to the glass reactor 3 while receiving the tube inlet body 20.

As shown in FIG. 3, the elements constituting the rotating part are cylindrical fasteners 30 fixedly coupled to the support of the present invention, and are accommodated in the cylindrical fasteners 30 and rotated by the driving motor and the reducer 6. Rotor 33 for receiving a rotational force to the glass reactor (3) by receiving a power transmission means such as a chain,

It is fastened to the support and consists of a fixed cap 34 for guiding the gas injection tube to the tube inlet body 20.

Reference numeral 31, which is not described in FIG. 3, is an opening formed to allow the cylindrical fastener 30 and the tube inlet body 20 to be inserted, and the support part 32 is connected to the support of the motor unit. Screw fastening portion for fixing the cylindrical fastener 30.

4 is a schematic cross-sectional view of the glass reactor 3 of the embodiment of the present invention. Large beaker-shaped reactor body 40 formed of a glass material, a predetermined number of protrusions 41 protruding to the inner side closed portion of the reactor body 40, and the opening side of the reactor body 40 The contact portion 42 is formed in contact with the disk-shaped junction portion 22 formed in the hermetic seal, and the plasma supply terminals 12 and 13 are provided along the outer circumferential surface of the reactor body 40.

Hereinafter will be described the operation of the embodiment of the present invention described above. First, the operation of each component will be described.

① Plasma Generator

The plasma generator unit 1 may use a plasma generator such as direct current (AC), alternating current (AC), electron cyclotron resonance (ECR), or the like depending on the purpose and condition of redox reaction of spent fuel.

② Plasma Supply Terminal

Since the plasma supply terminal 2 generates plasma by various plasma generators supplied by the plasma generator unit 1, the portion to which the plasma supply terminal is connected generates a large amount of heat and induction current. It is preferable to use heat-resistant plastics and to use materials having good electrical conductivity so that resistance of current or induction current do not occur.

③ glass reactor

The glass reactor 3 to contain the spent fuel is made of pyrex glass to withstand various reaction pressures. In addition, the glass reactor (3) joint is equipped with an O-ring, etc. in a flange form to maintain the airtightness while the glass reactor is rotating, and the inner surface of the glass reactor is provided with four projections or grooves in the longitudinal direction so that the powder inside the glass reactor can be Allow to mix well during rotation.

④ Gas injection discharge part

The gas injection unit 4 and the gas discharge unit 5 are connected to the glass reactor so that the gas discharge tube rotates together with the redox tank, but other parts of the gas injection discharge unit do not rotate. The discharge pipe, the gas injection part and the discharge part use a Teflon seal or a mechanical seal to prevent the gas from leaking, and the discharge pipe rotates.

⑤ Drive reducer and motor

The drive reducer and the motor 6 are devices for rotating the glass reactor using a drive transmission device such as a chain. Using a chain or the like to accurately transmit power from the motor to the glass reactor via the rotating unit 7, and the angle can be adjusted in various ranges in the horizontal direction with the glass reactor.

FIG. 5 illustrates an example in which the redox apparatus, which is an embodiment of the present invention, may rotate up and down by a predetermined angle with respect to a central axis of the gas injection unit, the rotating unit, and the glass reactor in which the motor support unit and the glass reactor support unit are combined. It is to.

The apparatus according to the present invention can be oxidized and reduced while controlling the atmosphere of the plasma gas which is ionized by the current applied from the plasma generator unit 1. Therefore, it is excellent in reaction controllability, and it is easy to manufacture the powder suitable for a subsequent process, and also the redox time can be shortened by the outstanding reactivity of plasma gas, and the efficiency of a process can be improved.

In addition, the apparatus according to the present invention can be oxidized, reduced by putting the spent fuel in the glass reactor (3), and rotates, and the projections in the longitudinal direction of about four places installed on the inner surface of the glass reactor with the rotation of the glass reactor (3) (41) or evenly mixed by the grooves. Therefore, during the oxidation and reduction process, the powder is evenly reacted with the plasma gas to obtain a very uniform powder, the oxidation and reduction time can be shortened.

It is well-known that the technical idea of this invention is not limited to the Example demonstrated above. The protection scope of the present invention may include various embodiments that can be predicted by those skilled in the art from the technical spirit of the present invention.

For example, various embodiments of the plasma generating apparatus, various embodiments of the plasma supply means, embodiments by various materials and shapes of the glass reactor, and other embodiments of the driving apparatus.

One of the most important processes in the development of light and heavy reactor-linked fuel cycle technology development, which processes spent fuel from light-water reactor nuclear power plant and reuses it as a nuclear fuel of heavy-water reactor nuclear power plant in developing the nuclear cycle technology of the reactor. May be referred to as a redox process.

Therefore, the quality of the final fuel sintered body depends on the state of the powder obtained by the redox process.

When the spent fuel is redoxed by the apparatus according to the present invention, it is easy to obtain a powder suitable for the subsequent fuel fuel sintering manufacturing process because it has excellent redox control property and can easily control the state of the powder.

In addition, it is possible to increase the efficiency of the process by shortening the redox reaction time due to the excellent reactivity of the plasma gas.

In addition, the redox can be reduced by rotating the glass reactor, and the powder produced through the redox can be reacted with uniform mixing by the longitudinal grooves provided on the inner surface of the glass reactor, thereby maintaining the state of the final powder very uniformly. Can be.

Therefore, with this powder, a superior fuel sintered body can be produced when the subsequent fuel sintering process is performed.

Claims (9)

In the device for redox of spent fuel, A plasma generator for generating plasma, A glass reactor for performing a redox process by using the ionized plasma gas by the plasma gas generating power supplied from the plasma generator; Rotation drive means for rotating the glass reactor, A spent fuel redox device using plasma, comprising gas injection and discharge means for injecting and discharging gas into the glass reactor. The method according to claim 1, And the plasma reactor is provided with a plasma supply terminal for supplying the ionizing plasma gas to the glass reactor by applying the plasma gas generating power from the plasma generator. The method according to claim 2, And the plasma supply terminal is a copper plate having a predetermined width, and at least one of the plasma supply terminals is installed along the outer circumferential surface of the glass reactor. The method according to claim 1, The glass reactor is composed of a large beaker shape made of Pyrex Glass (Pyrex Glass) material, it is characterized in that the powder inside the glass reactor is well mixed during rotation by installing a plurality of longitudinal projections or grooves in a predetermined portion of the inner portion A spent fuel redox device using plasma. The method according to claim 1, And the glass reactor is hermetically bonded to the rotating unit. The method according to claim 5, The portion where the rotary part and the glass reactor are joined is a disc-shaped flange-shaped structure in which a hole into which the gas injection tube is inserted at the center of the rotary part is formed, and a sealing ring is installed inside the circumferential surface at a predetermined part. A spent fuel redox device using plasma, wherein the junction of the glass reactor has a structure corresponding to the disk-shaped flange. The method according to claim 1, The drive motor unit is a spent fuel redox device using a plasma, characterized in that the motor is equipped with a deceleration function is installed on the support fixedly mounted on the base supporting the device. 8. The glass reactor of claim 7, wherein one end is rotatably installed with a support on which the motor is fixed, and the other end further comprises a glass reactor support fixed to the glass reactor. And the gas injection unit, the rotating unit, and the glass reactor can rotate up and down by a predetermined angle around a portion where the motor support unit and the glass reactor support unit are coupled to each other. In a method of treating spent fuel comprising a redox process, The redox process, Injecting the reactant into the glass reactor through the gas injection unit; Supplying an ionized plasma gas to the glass reactor by a current applied from the plasma generator; And a process comprising the step of rotating the glass reactor to react the reactant with the ionized plasma gas.