KR20170032103A - Hybrid nuclear reactor with separable core - Google Patents

Abstract

According to the present invention, disclosed is a separable core type hybrid nuclear reactor using a single nuclear reactor, capable of a power generation operation as a normal research nuclear reactor, and also facilitating the use as critical facilities. When the nuclear reactor is used as the critical facilities, a portion of core is separated and moved in a lateral direction to secure a space, and a lattice of nuclear reactor component materials is charged in the secured space for a critical experiment, and thus a lattice characteristic experiment can be performed. According to the present invention, the nuclear reactor described above comprises: a separable core type hybrid nuclear reactor (100) installed inside a concrete water tank (10); and a mode switching drive unit (20) controlling an operation mode of the hybrid nuclear reactor (100), wherein the separable core type hybrid nuclear reactor (100) comprises: a lattice structure (130) having a separable structure and installed on the bottom part of the concrete water tank (10); a reflector structure (150) having a separable structure and installed in an edge part of the lattice structure (130); and a partition structure (170) having a separable structure and installed to surround the reflector structure (150) on the lattice structure (130).

Description

{HYBRID NUCLEAR REACTOR WITH SEPARABLE CORE}

The present invention relates to a nuclear separation type hybrid reactor capable of operating a single reactor in an output operation mode or a critical experiment mode. More particularly, the present invention relates to a nuclear separation type hybrid reactor which can operate without separating the core in the output operation mode but can separate a part of the core during operation in the critical experiment mode, thereby securing a space for a critical experiment.

Critical facilities in the nuclear power field generally consist of repeatedly arranged unit lattices such as nuclear fuel, moderator, and coolant, which are the basic elements constituting the core of a nuclear reactor, repeatedly arranged in a critical state. It is used. For this purpose, the arrangement should be easily deformable if necessary and the heat output should be as low as possible. These critical facilities are widely used in related fields for designing and interpreting new reactors and nuclear fuel.

However, since Korea does not have such a critical facility, it is not possible to experimentally verify the nuclear characteristics of the reactor core when developing the reactor. As a result, if new concept nuclear fuel or nuclear reactors are developed, it will not be possible to obtain data on the characteristics of the northeasterns without resorting to foreign critical facilities.

Research Reactor, on the other hand, is a facility that uses neutrons from nuclear fission and its uses are very different from those of critical facilities.

Since most of the educational reactors in the world are installed in universities and most of them are low power reactors ranging from several hundreds of kW to several MWs, there are mainly NAA (Neutron Activation Analysis), RI (Radio-Isotope ; Radioisotope) production. In addition, the structure of the reactor is fixed so that it can not be studied or trained for nuclear reactors of different nuclear fuel structures or grid structures. On the other hand, high-power researches such as ATR and HANARO in the USA should be operated for a long time without stopping operation for nuclear fuel and materials research, cold neutron beam, etc., It is not appropriate to utilize it.

In the fuel assembly of the pressurized water reactor type nuclear fuel assembly having the fixed fuel pass through type fuel cylinder disclosed in the Japanese Patent Registration No. 10-1524798, only the nuclear fuel located in the upper region can be moved up and down, And does not disclose a technical structure capable of performing a lattice characteristic test by securing a space for a critical experiment using a reactor. Accordingly, there is a need for a new method of operating the reactor in a normal output operation mode or a critical experiment mode by using a single reactor.

A fuel assembly of a pressurized water reactor type nuclear fuel assembly having a fixed fuel passable fuel cylinder of Patent No. 10-1524798

SUMMARY OF THE INVENTION Accordingly, the present invention has been made keeping in mind the above problems occurring in the prior art, and an object of the present invention is to provide a nuclear reactor capable of operating in an output operation mode like a conventional research reactor using a single reactor, And to provide a hybrid reactor that can be used as a critical facility.

Another problem to be solved by the present invention is that when a reactor is to be used as a critical facility, a part of the core is separated and moved in the lateral direction to secure a critical experimental space, and a unit lattice of the reactor core material The present invention provides a hybrid reactor capable of performing core lattice characteristics experiments by repeatedly arranging the reactor.

In order to accomplish the above object, an embodiment of the present invention includes a concrete water tank, a core separated type hybrid reactor installed inside the concrete water tank, and a mode switching drive unit for controlling an operation mode of the hybrid reactor, The core separation type hybrid reactor includes a grid structure of a separable structure provided on a bottom portion of the concrete water tank, a reflector structure of a detachable structure installed at an edge portion of the grid structure, and a reflector structure installed on the edge of the grid structure to surround the reflector structure And a barrier structure having a separable structure.

In one embodiment of the present invention, the lattice structure includes a fixed lattice structure installed inside the concrete water tank and having a lattice-shaped receiving space, and a lattice-structure accommodating space And a movable grating structure having a movable grating structure.

According to an embodiment of the present invention, the reflector structure may include a fixed reflector provided at an edge portion of the fixed grating structure, and a reflector provided at one side edge of the movable grating structure, And a movable reflector disposed so as to surround the entire area.

In one embodiment of the present invention, the septum structure includes a fixed septum structure installed in the fixed grid structure and open at one side thereof, and a core-type nuclear reactor installed in the mobile grid structure and coupled with the fixed septum structure to form a core- And a movable partition wall structure for supporting the movable partition wall.

The nuclear separation type hybrid reactor according to one embodiment of the present invention can perform selective operation in an output operation mode or a critical experiment mode by using a single reactor, and when operating in a critical experiment mode, , And the core lattice characteristic experiment can be performed by repeatedly arranging the unit lattice of the reactor core material in the secured critical experiment space.

That is, the nuclear separation type hybrid reactor according to one embodiment of the present invention can be applied to various nuclear reactor lattice characteristic tests using hard water as a coolant using only one educational reactor, and to education and research using low power reactor Multi-purpose utilization in the field is possible.

In addition, the nuclear separation type hybrid reactor according to an embodiment of the present invention can reduce the unit lattice number to about 1/10 as compared with the critical value to be dried for the purpose of critical experiment.

In addition, the nuclear separation type hybrid reactor according to an embodiment of the present invention can empirically confirm the characteristics of the reactor core and can be used to acquire actual data on the characteristics of the new nuclear fuel.

In addition, the nuclear separation type hybrid reactor according to an embodiment of the present invention can be utilized for automatic shutdown of a reactor by applying a design that automatically moves part of the core using a control system during operation in an output mode.

FIG. 1 is a perspective view showing the overall structure of a nuclear separation type hybrid reactor according to an embodiment of the present invention. FIG. 1 is a perspective view of a nuclear separation type hybrid reactor separated from a concrete water tank to facilitate understanding of the structure.
FIG. 2 is a plan view showing an operation state of the core separated hybrid type reactor to the output operation mode according to an embodiment of the present invention. FIG.
FIG. 3 is an enlarged view for better understanding the overall configuration of a nuclear separation type hybrid reactor according to an embodiment of the present invention. FIG. 3 is a graph showing the configuration state of a hybrid reactor when operating in the output operation mode shown in FIG. FIG.
FIG. 4 is a perspective view of a nuclear separation type hybrid nuclear reactor according to an embodiment of the present invention. FIG.
5 is a partially exploded perspective view of a nuclear separation type hybrid reactor according to an embodiment of the present invention.
FIG. 6 is a plan view showing an operating state of a nuclear separation type hybrid reactor according to an embodiment of the present invention in a critical experiment mode. FIG.
FIG. 7 is a perspective view showing a configuration state of a hybrid reactor when operated in the critical experiment mode shown in FIG. 6. FIG.

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

FIG. 1 is a perspective view showing a whole structure of a nuclear separation type hybrid reactor according to an embodiment of the present invention, which separates a core separation type hybrid reactor from a concrete water tank. FIG. 2 is a plan view showing the operation state of the nuclear separation type hybrid reactor according to the present invention in an output operation mode. FIG. 3 is a perspective view showing a configuration of a hybrid reactor when the hybrid vehicle is operated in the output operation mode shown in FIG. 2. FIG. FIG. 4 is a perspective view of a nuclear separation type hybrid nuclear reactor according to the present invention, which is primarily partially decomposed.

Referring to FIG. 1, a nuclear separation type hybrid reactor 100 according to the present invention includes a concrete water tank 10 having an open top and storing a predetermined amount of water therein, And a mode switching driving unit 20 which is exposed to the outside of the water tank 10 and is disposed downward in a direction perpendicular to the inner wall of the water tank.

The core separable hybrid reactor 100 further comprises a supporting structure 110, a lattice structure 130, a reflector structure 150, and a barrier structure 170 as shown in FIGS.

The support structure 110 is fixed to the bottom of the concrete water tank 10 to support the grid structure 130 from the bottom. In order to allow water to flow in and out, Through holes are formed. The support structure 110 integrally includes a flange portion 112 protruding outwardly from the lower end of the side portion for coupling with the bottom portion of the concrete water tank 10.

The grid structure 130 is installed to be fixed to the upper portion of the support structure 110 and has a plurality of receiving spaces for mounting a plurality of nuclear fuel (NF) in a lattice structure. Particularly, the grid structure 130 is configured as a separable structure capable of separating from each other, and is coupled when the reactor is operated in the power operation mode. When the reactor is operated in the criticality operation mode, Thereby forming a space for a critical experiment inside.

The reflector structure 150 is installed in an upright position on an edge portion of the grating structure 130 and has a detachable structure that can be separated from each other like the grating structure 130. Even in this case, the reflector structure 150 maintains the mutually coupled state when the reactor is operated in the output operation mode, and separates when operating in the critical experiment mode to help form a space for the critical experiment inside .

The barrier rib structure 170 is installed to surround the reflector structure 150 from the upper part of the grid structure 130. The grid structure 130 and the reflector structure 150, And a separable structure. Also in this case, the barrier structure 170 is configured to be maintained in a mutually coupled state when operating in the output operation mode, and to be separated when operating in the critical experiment mode to help form a space for the threshold experiment inside .

5 is a partially exploded perspective view of a nuclear separation type hybrid reactor according to an embodiment of the present invention.

5, the lattice structure 130 is a mutually separable structure that is fixed to the upper portion of the support structure 110 inside the concrete water tank 10, and includes a plurality of receptacles for mounting the nuclear fuel (NF) A fixed grating structure 132 for forming a space in a grid structure and a plurality of accommodation spaces for mounting a nuclear fuel (NF) in a structure that can be laterally separated from the fixed grating structure 132, And a movable grid structure 140.

In an embodiment of the present invention, the fixed grating structure 132 is formed in a substantially diagonal shape in the form of a cross section. That is, the fixed grating structure 132 is formed so as to have an opening of one side opened to the outside so as to assemble the movable grating structure 140 in a manner to accommodate the movable grating structure 140 therein. It goes without saying that such an assembling method can be implemented as various modified embodiments.

The fixed grating structure 132 forms at least one pair of guide grooves 134 at an assembling site corresponding to the movable grating structure 140 and the movable grating structure 140 corresponds to the guide grooves 134 At least a pair of guide protrusions 144 for engaging with the assembling part are formed. In this case, the guide grooves 134 and the guide protrusions 144 may be disposed opposite to each other, and various modifications may be made to the guide grooves 134 in order to smoothly guide the guide grooves.

The fixed grid structure 132 integrally forms a flange portion 136 protruding outward from a bottom portion of the concrete water tank 10 on the lower end of the side portion for coupling with the support structure 110. The support structure 110 is integrally formed with a flange portion 114 protruding outward from the upper end portion of the side portion for coupling with the flange portion 136.

The movable lattice structure 140 is formed to protrude outward at one side for interlocking with the operation of the mode switching drive unit 20 and includes a tooth coupling unit 142 for screw connection.

The reflector structure 150 includes a fixed reflector 152 fixed to an edge portion of the fixed grid structure 132 in an upright state and a fixed reflector 152 fixed to an edge portion of the movable grid structure 140 in an upright state And a movable reflector 154 disposed to surround the entire area of the edge portion of the grid structure 130 together with the fixed reflector 152.

That is, the fixed reflector 152 is assembled in a state of being limited to the edge portion of the accommodating space of the remaining lattice structure excluding the assembling portion of the fixed grating structure 132 with respect to the movable grating structure 140, And the movable reflector 154 is assembled in a state where the movable reflector 154 is positioned at an edge portion of the accommodating space of the remaining lattice structure except the assembled portion of the movable grating structure 140 with respect to the fixed grating structure 132, do.

The barrier rib structure 170 includes a fixed barrier rib structure 172 formed at an upper portion of the fixed lattice structure 132 and having one side opened to cover the fixed reflector 152 from outside, And a movable partition wall structure 174 installed on the upper portion of the movable partition wall 140 to surround the movable reflector 154 and form a core separated type reactor through coupling with the fixed partition wall structure 172.

For this purpose, the fixed partition wall structure 172 integrally forms a flange portion 173 protruding outward at the lower end of the front edge portion of the edge for engagement with the fixed grid structure 132. The movable partition wall structure 174 integrally has a flange portion 175 protruding outward from the lower end of the edge portion for coupling with the movable grid structure 140. In this case, the movable lattice structure 140 integrally forms a flange 146 protruding from one side of the movable partition wall structure 174 for coupling with the flange portion 175.

The mode switching drive unit 20 includes a drive side rotary shaft 30 disposed downward in a direction perpendicular to the inner wall of the concrete water tank 10 and rotatably installed by a user, A driven side rotating shaft 50 which is screwed with the movable grid structure 140 and a driving side rotating shaft 50 provided between the driving side rotating shaft 30 and the driven side rotating shaft 50, And a gear box 40 for transmitting the rotation to the driven side rotary shaft 50.

In the embodiment of the present invention, the gear box 40 includes a worm gear 42 disposed at a lower free end portion of the driving-side rotary shaft 30, a tooth gear 42 coupled to the worm gear 42, A body 46 for rotatably mounting the worm gear 42 and the worm wheel 44 on the free end of the body 46; And a cover 48 which is made of a metal.

The driving-side rotary shaft 30 is rotatably supported by a plurality of mounting brackets 32 installed on the inner wall of the concrete water tank 10.

A lead screw 52 is coupled to the free end of the driven side rotary shaft 50 and the lead screw 52 is assembled to the tooth coupling part 142 of the movable type grid structure 140 in a screw- do. As a result, the rotation of the driving-side rotary shaft 30 is transmitted to the driven-side rotary shaft 50 via the gear box 40, and the rotation of the driven- Thereby moving the mobile grating structure 140 relative to the fixed grating structure 132 to a discrete position or vice versa.

Accordingly, the core separable hybrid reactor 100 according to the present invention configured as described above can operate a single reactor in either the output operation mode or the critical experiment mode.

This is because the lattice structure 130 is a separable structure composed of the fixed lattice structure 132 and the movable lattice structure 140 and the reflector structure 150 is composed of the fixed reflector 152 and the movable reflector 154 It is possible to separate the barrier structure 170 from the fixed barrier structure 172 and the movable barrier structure 174. Such a series of operation mode switching may be implemented using the driving unit 20 for switching the mode.

2 and 3, when the fixed lattice structure 132 and the movable lattice structure 140 constituting the lattice structure 130 are not separated from each other, The nuclear fuel (NF) installed in the receiving space of the grid structure formed in each of the plurality of nuclear reactors can be used to perform a role of a low-power research reactor. For example, the hybrid reactor 100 performs experiments and production activities that can be implemented with low power research such as NAA (Neutron Activation Analysis) and RI (Radioisotope) production using neutrons generated from the core. If the design that automatically moves the mode-switching type driving unit 20 using the control system during operation in the output mode is applied, it can be utilized for automatic stop of the reactor.

6 and 7, when the fixed lattice structure 132 constituting the lattice structure 130 is operated by the operation of the mode switching drive unit 20, And the movable grid structure 140 are shifted to a position spaced apart from each other so as to form a space X for a predetermined critical experiment between them, and the space (X) The results of this study are summarized as follows.

That is, in the mode-switching drive unit 20, the drive-side rotational shaft 30 is rotated by the worm gear 42 and the worm wheel 44 via the power transmission due to the interlocking action between the worm gear 42 and the worm wheel 44, The rotation of the rotary shaft 50 causes the rotation of the lead screw 52 to be a slave.

Since the rotation of the lead screw 52 moves the movable grating structure 140 from the fixed grating structure 132 in the transverse direction, the movable grating structure 140, the movable reflector 154, The movable partition wall structures 174 move in the lateral direction together. As a result, a space X for critical experiments can be provided between the fixed grid structure 132 and the movable grid structure 140 inside the core of the hybrid reactor 100.

In addition, when a grid composed of new reactor structural materials is loaded in the space X for the above critical experiment, the nuclear fuel NF mounted on the conventional fixed grid structure 132 and the movable grid structure 140 has a critical characteristic Since the neutrons serve as the source of the neutrons for the experiment, it is not necessary to construct a critical experiment device for performing the nodule grid experiment separately.

For example, as shown in FIG. 6, the hybrid reactor 100 according to the present invention has a fixed reflector 152, A And the movable reflector 154 and the movable reflector 154 are disposed so as to surround the entire circumference of the core with the reflector structure 150, When a nuclear fuel (denoted by a) is installed and a 3 * 6 array of nuclear fuel (denoted by b) is installed in the receiving space of the movable reflector 154, a 2 * 6 array of grid structures The space (X) is formed and the lattice characteristic test for the material is carried out when the lattice of the new reactor constituent materials is loaded in the formed space. And To determine the neutron flux distribution is very similar to the case performed in the state the core is configured so it is possible to obtain the economic benefits which can be operated to select a single reactor by any of the output operation mode or test mode threshold.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be construed as limited to the particular details of the embodiments set forth herein. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention as defined by the appended claims.

10-Concrete water tank 20-
30 - Drive side rotary shaft 40 - Gear box
42-Worm Gear 44-Worm Wheel
50- Dependent Side Rotary Shaft 52- Lead Screw
100-hybrid reactor 110-support structure
130-lattice structure 132-fixed lattice structure
140-Movable lattice structure 142-
150-reflector structure 152-fixed reflector
154-Movable reflector 170-Barrier structure
172-stationary bulkhead structure 174-mobile bulkhead structure

Claims (16)

A grating structure 130 of a detachable structure provided at a bottom portion of the concrete water tank 10;
A reflector structure 150 of a detachable structure installed at an edge portion of the lattice structure 130; And
And a barrier structure (170) of a separable structure installed to surround the reflector structure (150) at an upper portion of the grid structure (130). The method according to claim 1,
The lattice structure 130 includes a fixed lattice structure 132 installed inside the concrete water tank 10 and having a lattice-shaped receiving space,
Characterized in that it comprises a removable lattice structure (140) assembled in a removable structure with respect to the fixed lattice structure (132) and having a receiving space of a lattice structure. The method of claim 2,
Characterized in that the fixed grid structure (132) forms an opening with one side open to the outside for assembly with the movable grid structure (140). The method of claim 2,
The fixed grating structure 132 forms a guide groove 134 at a position where the fixed grating structure 132 is assembled with the movable grating structure 140. The movable grating structure 140 includes a guide projection 134 for coupling with the guide groove 134, (144). ≪ / RTI > The method of claim 2,
Wherein said fixed grid structure (132) forms a flange (136) for fixed support within said concrete water bath (10). The method of claim 2,
The reflector structure 150 includes a fixed reflector 152 provided at an edge portion of the fixed grating structure 132 and a fixed reflector 152 provided at one edge of the movable grating structure 140, And a movable reflector (154) arranged to surround the entire area of the edge portion of the lattice structure (130). The method of claim 2,
The barrier rib structure 170 includes a fixed barrier rib structure 172 installed on the fixed lattice structure 132 and having one side opened,
And a movable partition wall structure (174) installed in the movable grid structure (140) and forming a core separate type reactor through coupling with the fixed partition wall structure (172). The method of claim 7,
Wherein the fixed barrier structure (172) forms a flange (173) for engagement with the fixed grid structure (132). The method of claim 7,
Wherein the movable partition wall structure (174) forms a flange portion (175) for engagement with the movable grid structure (140). The method of claim 9,
Characterized in that the mobile grid structure (140) forms a flange portion (146) for engagement with the flange portion (175) of the mobile barrier structure (174). The method according to claim 1,
Further comprising a mode switching drive unit (20) for adjusting an operation mode,
The mode switching driver (20)
A driving side rotating shaft 30 vertically downwardly disposed along the inner wall of the concrete water tank 10,
A driven side rotary shaft 50 screwed with the movable lattice structure 140 of the grid structure 130,
And a gear box (40) for transmitting power between the drive side rotary shaft (30) and the driven side rotary shaft (50). The method of claim 11,
The gear box (40)
A worm gear 42 provided on the driving-side rotary shaft 30,
A worm wheel 44 coupled to the worm gear 42 and installed on the driven side rotary shaft 50,
A body 46 for rotatably mounting the worm gear 42 and the worm wheel 44,
And a cover (48) coupled to the body (46) so as to be openable and closable. The method of claim 11,
Wherein the driving-side rotary shaft (30) is rotatably supported by a mounting bracket (32) provided on an inner wall of the concrete water tank (10). The method of claim 11,
Further comprising a lead screw (52) coupled with the driven side rotary shaft (50)
Wherein the movable grid structure (140) defines a tooth coupling portion (142) for threaded engagement with the lead screw (52). The method according to claim 1,
Further comprising a support structure (110) installed at a bottom portion of the concrete water tank (10)
Wherein the grid structure (130) is secured to the top of the support structure (110). 16. The method of claim 15,
The support structure (110)
A flange portion 112 for engagement with the bottom portion of the concrete water tank 10, and
And a flange portion (114) for engagement with a bottom portion of the grid structure (130), respectively.

Images