KR101286033B1 - Nuclear fuel assembly of research reactor - Google Patents

Abstract

PURPOSE: A nuclear fuel assembly unit of a research reactor is provided to increase the stability of the reactor by improving mechanical safety. CONSTITUTION: Side plates face each other at a certain interval. Multiple nuclear fuel plates (300) are vertically installed on the side plates. The nuclear fuel plate is made of a nuclear fuel area and a coating layer. Coated particle fuel (500) is dispersed to an aluminum matrix. A combustible absorber (600) is loaded inside the nuclear fuel plate.

Description

Nuclear fuel assembly of research reactors

The present invention relates to a nuclear fuel assembly for use in research reactors, and more particularly, to a nuclear fuel assembly for high performance research reactors with greatly enhanced safety.

Research reactors are reactors that provide the necessary neutrons for the study of the microstructure of materials and the various interactions between neutrons and various materials.

Most research reactors use plate fuel. For example, a reactor core is placed in a reactor pool, such as Japan's JRR-3M, surrounded by a heavy water tank that is a reflector, and is composed of a plurality of fuel assemblies. A control rod is connected inside the reactor and a control rod drive mechanism is connected to the lower part of the reactor to regulate the output of the reactor. The fuel assembly is composed of a plurality of fuel plates.

1 shows a nuclear fuel assembly 1 generally used in research reactors. Referring to the drawings, the nuclear fuel assembly 1 is made of aluminum and has two side plates 10 formed at both side portions thereof. ) And a plurality of nuclear fuel plates 20 installed at a predetermined distance vertically between the two side plates 10. The nuclear fuel plate 20 is generally composed of a plate-shaped aluminum matrix (Al matrix) in which the particulate fuel U ₃ Si ₂ is dispersed and a thin aluminum coating material surrounding it. The aluminum matrix containing the fuel is called fuel meat. On the other hand, the flammable absorber 30 is formed in a wire shape on the side plate 10 to which the plurality of nuclear fuel plates 20 are connected, respectively. The flammable absorber 30 is a material used to absorb neutrons for the purpose of controlling the reaction to research reactors, and cadmium (Cd) is generally used. On the other hand, the water used as the coolant between the plurality of nuclear fuel plate 20 is configured to flow at high speed for effective cooling.

Looking at the configuration of the nuclear fuel assembly (1) formed as described above in more detail, in general, the nuclear fuel assembly (1) used in the research reactor is about 7 to 10 cm in width, is formed in a size of 7 to 10 cm in length The plurality of nuclear fuel plates 20 installed therein have a thickness of about 0.5 to 1.0 mm of the aluminum matrix on which the particulate fuel is loaded, and a thickness of the aluminum coating layer coated thereon is about 0.4 mm, which is very thin. It can be seen that. Meanwhile, U ₃ Si ₂ , which is particle fuel loaded in the fuel plate 20, is designed to occupy about 42% of the volume of the fuel meat.

On the other hand, the material of the plurality of nuclear fuel plate 20 installed inside the nuclear fuel assembly (1) configured as described above has a problem that the strength is weak, the melting point is low 660 degrees, instead of good conductivity of aluminum. For example, the speed of the water 40, which is a coolant flowing between the plurality of nuclear fuel plates 20, may be very fast, about 15 m / sec, in the case of a high-performance research reactor. As a result, the nuclear fuel plate 20 is exposed to continuous vibration, and thus, the mechanical integrity is weakened, so that the nuclear fuel plate 20 may be damaged. In addition, since the melting point of the aluminum is low and the strength is weak, there is a problem that the nuclear fuel plate 20 expands and breaks even at a relatively low temperature as the burn-up of nuclear fuel increases.

Therefore, in the design of a high-performance research reactor that provides a high neutron flux to solve the problems described above, a very thin fuel plate 20 is used in a unique shape (eg, a curved shape) to improve mechanical safety. In some cases, but in this case, there is a disadvantage in that a large cost is required for the manufacture of the associated nuclear fuel plate 20. In addition, even when using such a very expensive unique nuclear fuel plate 20 it is necessary to maintain the temperature of the fuel relatively low in order to ensure the safety of the nuclear fuel, there is also a problem that the speed of the coolant must be very fast. In general, in the case of U ₃ Si ₂ particulate fuel used in research reactors, it is necessary to sufficiently maintain the temperature of the nuclear fuel to 150 ~ 200 ℃ or less to achieve a relatively high fuel combustion. On the other hand, in the case of maintaining the temperature of the nuclear fuel to the research reactor relatively low, as described above for the integrity of the nuclear fuel plate, the so-called Doppler effect caused by the nuclear fuel is weakened, which causes the inherent safety of the research reactor. Sometimes.

In addition, many research reactors use high enriched uranium, but most research reactors use low enriched uranium. In this case, simply replacing the highly enriched uranium fuel with the low enriched uranium fuel causes the U-235 loading of the reactor to be greatly reduced compared to the past, resulting in a problem of deterioration of the reactor performance. In order to alleviate this problem, there is a need for the development of a new nuclear fuel that can increase the U-235 loading compared to the widely used U ₃ Si ₂ particulate fuel.

Accordingly, the applicant of the present invention has invented a new nuclear fuel assembly for the research reactor that is formed more stably in order to solve the problems as described above.

Embodiments of the present invention, in order to solve the problems described above, to provide a nuclear fuel assembly to the research reactor that provides a high performance while significantly enhanced safety.

According to an aspect of the invention, the side plate disposed to face each other at a predetermined interval; A plurality of nuclear fuel plates disposed on the side plate at regular intervals in a vertical direction and comprising a nuclear fuel region composed of an aluminum matrix loaded with particle fuel and a coating layer covering the nuclear fuel region with an aluminum coating material; A coated particle fuel dispersed and loaded in an aluminum matrix of a nuclear fuel region of the nuclear fuel plate; And a flammable absorber loaded inside the nuclear fuel plate to provide a nuclear fuel assembly as a research reactor. Here, the coated particle fuel may use uranium dioxide (UO ₂ ) or uranium carbide (UC) as a fuel core.

Erbium (Er) may be used as the flammable absorber, and erbium (Er), which is the flammable absorber, may be mixed with the aluminum matrix of the nuclear fuel region. In addition, erbium, which is a flammable absorber, may be mixed with and loaded with a side plate made of aluminum.

In addition, gadolinium (Gd) may be used as the flammable absorber, and may be manufactured in a particle fuel form and dispersed and loaded in an aluminum matrix of a nuclear fuel region of the nuclear fuel plate.

In addition, it is possible to install a second combustible absorber in the form of a wire on the side plate, wherein the second combustible absorber can use gadolinium (Gd) or cadmium (Cd).

The nuclear fuel assembly for research according to the embodiments of the present invention has a much higher mechanical safety and a much higher nuclear fuel temperature than the conventional nuclear fuel assemblies, which greatly improves the stability of the nuclear reactor. Can be prevented from escaping to the outside. In addition, a much higher fuel temperature is allowed, which significantly improves the Doppler effect of the fuel, and consequently increases the intrinsic safety of the reactor, and can significantly increase the loading of the fuel compared to conventional U ₃ Si ₂ fuel.

1 shows a cross section of a nuclear fuel assembly into a research reactor according to the prior art.
2 shows a coated particle fuel according to an embodiment of the present invention.
Figure 3 shows a cross section of the nuclear fuel assembly to the research reactor according to an embodiment of the present invention.

Hereinafter, a nuclear fuel assembly as a research reactor according to an embodiment of the present invention will be described with reference to the drawings.

As described above, the nuclear fuel assembly for research reactor disperses and loads U ₃ Si ₂ with particulate fuel in an aluminum matrix forming the fuel meat of the fuel plate, and coats the coating layer with aluminum coating thereon. It is formed and manufactured. However, in the case of forming the nuclear fuel plate as described above, when the nuclear fuel plate is damaged, the nuclear fuel and fission products may come out of the nuclear fuel plate, which may threaten the stability of the research reactor. In addition, since the temperature of the fuel needs to be kept low, the coolant flow rate must be very fast, and the Doppler effect caused by the nuclear fuel becomes weak, which is undesirable from the viewpoint of intrinsic safety as a research reactor.

Therefore, the applicant of the present invention has been invented a method to ensure the safety of the nuclear fuel even in a temperature region much higher than the conventional fuel, more specifically, the coated particle fuel in the aluminum matrix forming the nuclear fuel region of the nuclear fuel plate It is to use a nuclear fuel plate that is distributed and loaded.

2 is a cross-sectional view of the coated particle fuel according to an embodiment of the present invention, referring to the drawing, the coated particle fuel 500 accommodates the expansion of the fuel core (510, kernel) due to combustion and nuclear fission In order to effectively trap the product, the fuel core 510, which is a fuel core, is formed by wrapping a double coating layer. As the fuel core 510, uranium dioxide (UO ₂ ) or uranium carbide (UC) may be used. The inner low density carbon buffer layer 520 of the coating layer is mainly formed to accommodate the expansion of the fuel core 510, and the zirconium (Zr) coating layer 530 of the metal formed on the outer side of the fission product is moved to the outside. It is formed to serve to prevent diffusion. The zirconium metal coating layer 530 may be replaced with a zirconium carbide (ZrC) coating layer. In the case of the fuel core 510 made of uranium dioxide or uranium carbide, when the temperature of the fuel core 510 is maintained at about 500 C or less, the external emission of the fission product is very limited, and the fuel core (510) Since the volume expansion of the 510 is small, it is possible to use the simple double coated particle fuel 500 as shown in FIG. On the other hand, in another embodiment of the present invention, the cover particle fuel 500 may be configured of only the low density carbon buffer layer 520 without using the zirconium metal coating layer 530, if necessary, 2 It is also possible to form a coating layer of more than heavy coating.

Therefore, the nuclear fuel assembly to the research reactor according to an embodiment of the present invention by using the coated particle fuel 500 as a nuclear fuel loaded on the nuclear fuel plate, it is possible to allow a much higher fuel temperature than before, thereby The safety can be greatly improved. In addition, as described above, even if there is a case in which a local damage or the like occurs in the nuclear fuel plate so that the coated particle fuel 500 escapes to the outside of the nuclear fuel plate, the actual fuel does not escape to the outside. There is an advantage to be strengthened. In addition, the relatively high fuel temperature, compared to the nuclear fuel of the existing research reactor, can improve the Doppler effect caused by the nuclear fuel, thereby enhancing the intrinsic safety of the reactor.

3 is a cross-sectional view of the nuclear fuel assembly 100 according to an embodiment of the present invention, the present invention will be described in more detail with reference to the drawings.

Nuclear fuel assembly 100 as a research reactor according to an embodiment of the present invention is a side plate 200 formed of aluminum disposed to face each other at a predetermined interval, the predetermined interval in the vertical direction on the side plate 200 It may include a plurality of nuclear fuel plate 300 is installed, and the coated particle fuel 500 and the flammable absorber 600 loaded in the nuclear fuel plate 300. Between the plurality of nuclear fuel plates 300, the water 400, which is a coolant, is configured to flow at a high speed.

The nuclear fuel plate 300 may include a nuclear fuel region 320 composed of an aluminum matrix in which particulate fuel is dispersed and loaded, and a coating layer 310 covering the nuclear fuel region 320 with an aluminum coating material. Here, as described above, the nuclear fuel plate 300 according to an embodiment of the present invention is characterized by a technique that uses the coated particle fuel 500 as a fuel. Meanwhile, although the diameter of the fuel core 510 of the coated particle fuel used in the present invention may be variously designed, the coated particle fuel 500 used in the nuclear fuel assembly 100 as a research reactor according to an embodiment of the present invention. It is preferable that the diameter of the fuel core 510 of () be as large as 500 μm or more.

On the other hand, the conventional nuclear fuel plate based on the U ₃ Si ₂ fuel is designed so that the particle fuel loaded therein occupies about 42% of the total volume of the nuclear fuel region, to ensure the mechanical integrity of the fuel plate. Therefore, in the nuclear fuel plate 300 of the nuclear fuel assembly 100 to the research reactor according to an embodiment of the present invention, by appropriately limiting the volume ratio of the coated particle fuel 500, the mechanical integrity of the nuclear fuel plate 300 It needs to be secured. Meanwhile, in the case of the coated particle fuel 500 used in the embodiment of the present invention, the volume of the coated particle fuel 500 is not affected by the fission gas even though the aluminum matrix in the nuclear fuel region is not affected by the fission gas. It is possible to maintain the integrity of the nuclear fuel plate 300 while maintaining the ratio higher than the conventional.

In the present invention, in order to maximize the fuel loading by increasing the volume fraction of the coated particle fuel 500 while maintaining the temperature of the nuclear fuel higher than before, as shown in FIG. 3, the thickness of the nuclear fuel plate 300 is increased. It has the feature of thickening than conventional. On the other hand, since the nuclear fuel plate 300 is much thicker than the conventional one, the mechanical integrity can be improved, and as a result, the nuclear fuel plate 300 can be designed to have a larger size.

In the case of the conventional fuel assembly 1, a combustible absorber 30 in the form of a wire is commonly used, as shown in FIG. As shown in FIG. 3, a flammable absorber 700 having the same concept as in the related art may also be used in the nuclear fuel assembly 100 according to an embodiment of the present invention, and in the present invention, a more efficient flammable absorber concept may be used. It is to be introduced, the following will be described in detail.

First, erbium (Er) is used as the flammable absorber 600, but the erbium (Er) is mixed with the aluminum matrix of the nuclear fuel region 320 of the nuclear fuel plate 300. In addition, it is also possible to mix and use to the aluminum coating layer 310 as needed. In this case, erbium (Er) effectively functions as a flammable absorber and at the same time improves the material properties of aluminum, thereby making it possible to further enhance the stability of the nuclear fuel plate 300. On the other hand, although erbium (Er) may be used in combination with the fuel core 510 of the coated particle fuel 500, the effect is not great, there is a problem that the manufacturing cost increases. In addition, it is also possible to use erbium mixed with the aluminum of the side plate 200.

Secondly, gadolinium (Gd) is used as the combustible absorber 600, and manufactured in the form of particulate fuel such as the coated particle fuel 500 to the aluminum matrix of the nuclear fuel region 320 of the nuclear fuel plate 300. There is a method of dispersing and loading together with the coated particle fuel (500). On the other hand, gadolinium (Gd) can also be used in combination with the fuel core 510 of the coated particle fuel 500, like erbium (Er), the effect is not great. In addition, in the case of gadolinium (Gd), it may be used in combination with the aluminum matrix of the nuclear fuel region 320 of the nuclear fuel plate 300, such as erbium (Er), in this case, gadolinium (Gd) is exhausted so quickly that the desired effect There is a problem that can not be achieved.

Third, it is also possible to use the erbium (Er) and gadolinium (Gd) at the same time. In this case, erbium (Er) is mixed with the aluminum matrix of the nuclear fuel region 320 of the nuclear fuel plate 300, and gadolinium (Gd) is produced in a separate particle fuel form and dispersed and loaded in the aluminum matrix. It is also possible to use them at the same time. In addition to the above-described method, the cadmium (Cd) or gadolinium (Gd) is loaded into the side plate 200 with the second combustible absorber 700 in a wire shape, similar to the method used in the conventional fuel assembly 1. It is also possible.

Therefore, the nuclear fuel assembly 100 as the research reactor according to the embodiment of the present invention, which is formed as described above, further enhances safety by using the coated particle fuel 500. In addition, in the fuel assembly 100 according to the present invention, the flammable absorber 600 is loaded in the nuclear fuel plate 300 in a manner different from that of the related art, and further improves the material characteristics of the nuclear fuel plate 300. There is a technical advantage that it can.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit of the invention as set forth in the appended claims. The present invention can be variously modified and changed by those skilled in the art, and it is also within the scope of the present invention.

100: fuel assembly 200: side plate
300: nuclear fuel plate 500: coated particle fuel
600: flammable absorber 700: second flammable absorber

Claims (9)

A side plate 200 disposed to face each other at a predetermined interval;
It is installed on the side plate 200 at regular intervals in a vertical direction, and includes a nuclear fuel region 320 composed of an aluminum matrix loaded with nuclear fuel and a coating layer 310 covering the nuclear fuel region 320 with an aluminum coating material. A plurality of nuclear fuel plates 300 configured;
A coated particle fuel 500 which is a nuclear fuel dispersed and loaded in an aluminum matrix of the nuclear fuel region 320 of the nuclear fuel plate 300; And
And a combustible absorber (600) loaded into the nuclear fuel plate (300).
The method of claim 1,
The coated particle fuel (500) is a fuel assembly (510, kernel) nuclear fuel assembly as a research reactor, characterized in that using uranium dioxide or uranium carbide.
The method of claim 2,
The coated particle fuel (500) is a coating layer is formed to accommodate the expansion of the fuel core (510, kernel), the coating layer is a nuclear fuel assembly for the research reactor, characterized in that formed of a carbon buffer layer (520).
The method of claim 3,
A nuclear fuel assembly of research data, characterized in that to form an additional zirconium coating layer (530) on the outside of the carbon buffer layer (520).
The method of claim 1,
The combustible absorber (600) is a nuclear fuel assembly for a research reactor, characterized in that the erbium (Er).
6. The method according to claim 1 or 5,
Erbium (Er), the combustible absorber (600), is a nuclear fuel assembly for research reactors, characterized in that used in the aluminum matrix of the nuclear fuel region (320).
The method of claim 1,
Gadolinium (Gd) is used as the flammable absorber 600, and manufactured in the form of particle fuel, which is dispersed in an aluminum matrix of the nuclear fuel region 320 of the nuclear fuel plate 300 and loaded with a nuclear fuel assembly for research reactors. .
The method of claim 1,
A nuclear fuel assembly for research reactors, characterized in that the second flammable absorber (700) in the form of a wire on the side plate (200).
9. The method of claim 8,
The second combustible absorber (700) is a nuclear fuel assembly for a research reactor, characterized in that cadmium (Cd) or gadolinium (Gd).

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