KR20230096226A - Nuclear fuel rod structure and manufacturing method thereof - Google Patents

Abstract

Provided are a nuclear fuel rod assembly and a manufacturing method thereof. The nuclear fuel rod assembly comprises: an annular nuclear fuel sintering object; a combustible absorbent charged into a central portion of the nuclear fuel sintering object; a combustible absorbent cladding tube positioned between the nuclear fuel sintering object and the absorbent; and a filling gas layer filled between the nuclear fuel sintering object and the combustible absorbent cladding tube. The combustible absorbent comprises: a first combustible absorbent outer ring located in a central portion of the combustible absorbent cladding tube; and a first combustible absorbent inner core located in a central portion of the first combustible absorbent outer ring.

Description

Nuclear fuel rod assembly and manufacturing method thereof

The present invention relates to a nuclear fuel rod assembly and a manufacturing method thereof.

In the case of a pressurized water type nuclear power plant, boron, a water-soluble neutron absorbing material, is mixed with the reactor coolant to control excess reactivity. This method has the advantage of being able to control the reactivity of the nuclear reactor without generating non-uniform power distribution. However, the use of water-soluble boron has three main disadvantages. First, there is a problem in that the coolant becomes acidic and causes a corrosive environment inside the primary coolant system. In addition, a chemical and volume control system (CVCS) is required to control the boron concentration of the coolant. This becomes a factor that increases the construction cost and size of the nuclear power plant, and there is a problem in that cost is required for treating boron waste liquid generated when controlling the boron concentration of the coolant. In addition, the use of water-soluble boron increases the coolant temperature coefficient at the beginning of the cycle so that it approaches zero or becomes a small positive value. This has a problem of being an obstacle to controlling the reactor power using the coolant temperature.

As another method for controlling the reactivity of a nuclear reactor, there is a method using a control rod made of a solid neutron absorbing material and a control element drive mechanism (CEDM) for inserting or withdrawing the control rod from a fuel assembly guide tube. Here, since the control rods are locally inserted into the reactor core, non-uniform power distribution is generated. Therefore, it can be used as a means to maintain the core at a subcritical level when the reactor is stopped, but it is not a control method that can replace water-soluble boron.

In addition, as a combustible absorber-related technology, the separate type is a method in which the nuclear fuel rod and the combustible absorber are separately separated and loaded into the reactor. WABA (Wet Annular Burnable Absorber), which is made into an annular combustible absorber by mixing B4C, a combustible absorbent material, with Al2O3, and loaded into the control rod guide tube, and Pyrex, which loads a combustible absorber mixed with SiO2 and B2O3 into a general nuclear fuel rod. there is. This method has the advantage of effectively controlling the surplus reactivity during the operating cycle, but in the case of WABA, the number of control rods is limited, and in the case of Pyrex, the amount of nuclear fuel loaded is reduced. In addition, since the peak power factor is increased by generating a power balance inside the nuclear fuel assembly, the power density is limited.

On the other hand, the integrated type is a method in which a nuclear fuel material and a combustible absorbent material are charged together inside a nuclear fuel rod. IFBA (Integrated Fuel Burnable Absorber), which is used by coating the surface of a nuclear fuel pellet with ZrB2 and loading it into a fuel rod cladding, and IBA (Integral Burnable Absorber), which is manufactured into a nuclear fuel pellet by homogeneously mixing gadolinium oxide (Gd2O3) with UO2, a nuclear fuel material. ) is there. In the case of IFBA, there are disadvantages in that the pressure inside the rod increases due to the generation of helium by burning B-10, and the duration of excess reactivity control is short due to rapid combustion characteristics. In the case of IBA, there is a disadvantage in that the temperature of the nuclear fuel increases due to a decrease in the thermal conductivity of the nuclear fuel pellet, and although it burns relatively slowly than IFBA, gadolinium oxide is burned at around 15 GWD/MTU, and excess reactivity control is lost.

을 갖는 산화가돌리늄이 바람직하다. 한편, CSBA를 포함하는 핵연료 소결체의 제조시설을 갖추기 위해선 별도의 생산 시설을 구축해야 하며 이는 상당한 시간과 비용이 소요된다. There is a combustible absorber called CSBA (Centrally-Shielded Burnable Absorber) to overcome these disadvantages. This can effectively delay the burning rate of the combustible absorber by using the self-shielding effect of UO2 by locating the pure combustible absorber in the center of the nuclear fuel pellet. CSBA's combustible absorber material has a high neutron absorption cross section, oxidative stability, and a high melting point (2420

Gadolinium oxide having On the other hand, in order to have a manufacturing facility for a nuclear fuel pellet containing CSBA, a separate production facility must be built, which takes considerable time and money.

Due to the strong self-shielding effect of the concentrated Gd2O3, the neutron absorption reaction occurs only on the outer surface of CSBA, but as the self-shielding weakens as the concentrated gadolinium oxide on the surface burns, the inner concentrated Gd2O3 also starts to absorb neutrons. Therefore, as the combustion proceeds, the neutron absorption reaction by the concentrated Gd2O3 occurs in a spatially wider area, so the reactivity decreases, and the reactivity rises at the end of the combustion of the charged Gd2O3. Various combinations of concentrations of Gd-155 and Gd-157 are possible, but as the concentrations of Gd-155 and Gd-157 in Gd2O3 increase, there is only a difference in the timing of the reactivity rise, but the change in reactivity is still large. Therefore, there is a need for a combustible absorber capable of optimizing the excess reactivity of a nuclear reactor by providing other variables other than the insertion position, size, and shape of the combustible absorber (CSBA).

Korean Patent Publication No. 10-1990-0000927

The problem to be solved by the present invention is to control the excess reactivity and self-shielding degree according to combustion by differently adjusting the thickness of each layer and the material constituting the layer or its nuclide composition in a combustible absorber having a multi-layer structure. To provide a nuclear fuel rod assembly.

Another object of the present invention is to provide a nuclear fuel rod assembly capable of operating a boric acid-free core or a low-borate core by minimizing the range of change in excess reactivity according to combustion from the beginning of the cycle to the end of the cycle as a combustible absorber having a multi-layer structure.

Another object of the present invention is to provide a nuclear fuel rod assembly, which is a combustible absorber having a multi-layered structure and can be loaded into all nuclear fuel rods to reduce power imbalance inside the nuclear fuel assembly.

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

A nuclear fuel rod assembly according to an aspect of the present invention for achieving the above object is a nuclear fuel rod assembly, comprising: an annular nuclear fuel rod assembly; a combustible absorber loaded into the center of the nuclear fuel assembly; a combustible absorber cladding positioned between the nuclear fuel pellet and the combustible absorber; and a filling gas layer filled between the nuclear fuel pellet and the combustible absorber cladding, wherein the combustible absorber comprises: a first combustible absorber outer ring located at the center of the combustible absorber cladding and a first combustible absorber outer ring located at the center of the combustible absorber outer ring; 1Includes the combustible absorber inner core.

In addition, the combustible absorber may be fabricated based on a swaging method and then loaded onto the nuclear fuel pellet.

In addition, the nuclear fuel pellets have a multi-layered structure partitioned upward and downward, the combustible absorber cladding vertically penetrates the mutually partitioned nuclear fuel pellets, and the first combustible absorber outer ring vertically extends through the mutually partitioned nuclear fuel pellets. The first combustible absorber inner core vertically penetrates the mutually partitioned nuclear fuel pellets, and the filling gas layer is formed on the nuclear fuel pellets by the combustible absorber cladding, the first combustible absorber outer ring, and the first combustible absorber After the inner core is loaded, gas is formed above and below the mutually partitioned nuclear fuel pellets.

In addition, the combustible absorber further includes a second combustible absorber outer ring in which the first combustible absorber outer ring is located inside and a third combustible absorber outer ring in which the second combustible absorber outer ring is located inside, wherein the combustible absorber The cladding is positioned between the third combustible absorber outer ring and the nuclear fuel pellet.

In addition, the first combustible absorber inner core, the first combustible absorber outer ring, the second combustible absorber outer ring, and the third combustible absorber outer ring contain gadolinium oxide (Gd2O3).

In addition, the gadolinium oxide of the third outer ring of the combustible absorber contains an odd-numbered gadolinium isotope (Gd-155, Gd-157) having a first number density, and the gadolinium oxide of the outer ring of the second combustible absorber has a value greater than the first number density. Gadolinium oxide of the outer ring of the first combustible absorber includes odd-numbered gadolinium isotopes having a larger second number density value, and the gadolinium oxide of the outer ring of the first combustible absorber includes an odd-numbered gadolinium isotope having a third number density value greater than the second number density value, and inside the first combustible absorber The core gadolinium oxide includes an odd-numbered gadolinium isotope having a fourth number density greater than the third number density.

A method for manufacturing a nuclear fuel rod assembly according to another aspect of the present invention for achieving the above object, comprising: preparing an annular fuel rod assembly; charging a combustible absorber and a combustible absorber cladding into the nuclear fuel pellet; and filling a filling gas between the nuclear fuel pellet and the combustible absorber cladding, wherein the combustible absorber includes a first combustible absorber outer ring positioned at the center of the combustible absorber cladding and a central portion of the combustible absorber outer ring. It includes a first combustible absorber inner core.

In addition, the combustible absorber and the combustible absorber cladding are manufactured based on a swaging method.

According to the nuclear fuel rod assembly of the present invention as described above, one or more of the following effects are provided.

An object of the present invention is to provide a nuclear fuel rod assembly capable of controlling the degree of excess reactivity and self-shielding according to combustion by differently adjusting the thickness of each layer in a combustible absorber having a multi-layer structure and the material constituting the layer or the composition of the nuclide. can provide.

In addition, as a combustible absorber having a multi-layer structure, it is possible to provide a nuclear fuel rod assembly capable of operating a boric acid-free core or a low-borate core by minimizing a change in excess reactivity according to combustion from the beginning of the cycle to the end of the cycle.

In addition, as a combustible absorber having a multi-layer structure, it is possible to provide a nuclear fuel rod assembly capable of reducing power imbalance inside the nuclear fuel assembly by being loaded into all nuclear fuel rods.

1 is a plan view showing a state in which a nuclear fuel rod assembly according to an embodiment of the present invention is installed.
2 to 4 are diagrams schematically showing configurations of the nuclear fuel rod assembly according to FIG. 1 .
FIG. 5 is a view showing a modified example of configurations of the nuclear fuel rod assembly according to FIG. 1 .
6 is a graph showing evaluation results of infinite multiplication factors (reactivity) for nuclear fuel assemblies.
7 is a graph showing evaluation results of an infinite multiplication factor (reactivity) according to burnup of a nuclear fuel assembly loaded with a combustible absorber having a multilayer structure according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Advantages and features of the present invention, and methods for achieving them, will become clear with reference to the embodiments described below in detail in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below and may be implemented in various different forms, only the present embodiments make the disclosure of the present invention complete, and the common knowledge in the art to which the present invention belongs It is provided to fully inform the holder of the scope of the invention, and the present invention is only defined by the scope of the claims. Like reference numbers designate like elements throughout the specification.

1 to 4, a nuclear fuel rod assembly 100 according to an embodiment of the present invention includes a nuclear fuel pellet 110, a combustible absorber 120, a combustible absorber cladding 130, and a filling gas layer 140. .

Here, the combustible absorber 120 includes a first combustible absorber outer ring 121 and a first combustible absorber inner core 122. The nuclear fuel compact 110 has an annular structure. The nuclear fuel rod assembly 100 is installed in a nuclear reactor together with a guide tube in a state in which a combustible absorber is loaded.

Here, the combustible absorber 120 is loaded into the center of the nuclear fuel pellet 110. The combustible absorber cladding 130 is positioned between the nuclear fuel pellet 110 and the combustible absorber 120 .

In addition, the filling gas layer 140 is filled between the nuclear fuel pellet 110 and the combustible absorber cladding pipe 130 . The first combustible absorber outer ring 121 of the combustible absorber 120 is located at the center of the combustible absorber covering pipe 130.

The first combustible absorber inner core 122 of the combustible absorber 120 is located at the center of the combustible absorbent outer ring. After the combustible absorber 120 is manufactured based on the swaging method, it is loaded onto the nuclear fuel pellet 110.

Here, the nuclear fuel pellet 110 is made of a multi-layered structure mutually partitioned in upper and lower directions. The combustible absorber cladding 130 vertically penetrates the mutually partitioned nuclear fuel pellets 110 .

The first combustible absorber outer ring 121 vertically penetrates the mutually partitioned nuclear fuel pellets 110 . The first combustible absorber inner core 122 vertically penetrates the mutually partitioned nuclear fuel pellets 110 .

Meanwhile, the filling gas layer 140 is formed after the combustible absorber cladding 130, the first combustible absorber outer ring 121, and the first combustible absorber inner core 122 are loaded on the nuclear fuel pellets 110. In, the mutually partitioned nuclear fuel pellets 110 are formed vertically.

The number density of odd-numbered gadolinium isotopes (Gd-155, Gd-157) for each layer of gadolinium oxide and Gd2O3 of the combustible absorber 120 of the present invention is adjusted differently so that each self-shielding degree can be controlled there is.

Referring to FIG. 5, in the nuclear chain 100 according to the modified example of the present invention, the combustible absorber 120 further includes a second combustible absorber outer ring 123 and a third combustible absorber outer ring 124.

The second combustible absorber outer ring 123 of the combustible absorber 120 has the first combustible absorber outer ring 121 located inside. The third combustible absorber outer ring 124 of the combustible absorber 120 has the second combustible absorber outer ring 123 located inside.

Here, the combustible absorber cladding 130 is positioned between the third combustible absorber outer ring 124 and the nuclear fuel pellet 110 . The first combustible absorber inner core 122, the first combustible absorber outer ring 121, the second combustible absorber outer ring 123 and the third combustible absorber outer ring 124 contain gadolinium oxide (Gd2O3). include

Gadolinium oxide of the third combustible absorber outer ring contains odd-numbered gadolinium isotopes (Gd-155, Gd-157) having a first number density, and gadolinium oxide of the second combustible absorber outer ring has a first number density greater than the first number density It contains odd-numbered gadolinium isotopes of dichotomous values.

In addition, the gadolinium oxide of the outer ring of the first combustible absorber includes odd-numbered gadolinium isotopes having a third number density greater than the second number density, and the gadolinium oxide of the inner core of the first combustible absorber has a fourth number density greater than the third number density. It contains odd-numbered gadolinium isotopes of number density values.

The combustible absorber 120 has a multi-layered structure, each layer containing gadolinium oxide, but the number density of Gd-155 or Gd-157 having an odd mass number among Gd isotopes is adjusted differently for each layer, so that excess reactivity due to combustion and self-shielding degree to be controlled.

A flat excess reactivity can be obtained by adjusting the number density of odd-numbered gadolinium isotopes (Gd-155 or Gd-157) to decrease from the inner core to the outermost layer of the combustible absorber of multilayer structure.

In the method (S100) of manufacturing a nuclear fuel rod assembly according to an embodiment of the present invention based on the foregoing, the annular fuel rod assembly (S100) is prepared (S100), the combustible absorber (120) and the combustible absorber cladding (130). A step of charging the nuclear fuel pellets 110 (S120) and a filling gas between the nuclear fuel pellets 110 and the combustible absorber cladding 130 (S130).

The combustible absorber 120 includes a first combustible absorber outer ring 121 and a first combustible absorber inner core 122. The nuclear fuel compact 110 has an annular structure.

The combustible absorber 120 is loaded into the center of the nuclear fuel pellet 110 . The combustible absorber cladding 130 is positioned between the nuclear fuel pellet 110 and the combustible absorber.

The filling gas layer 140 is filled between the nuclear fuel pellet 110 and the combustible absorber cladding 130 . The first combustible absorber outer ring 121 of the combustible absorber 120 is located at the center of the combustible absorber covering pipe 130.

The first combustible absorber inner core 122 of the combustible absorber 120 is located at the center of the combustible absorbent outer ring. After the combustible absorber 120 is manufactured based on the swaging method, it is loaded onto the nuclear fuel pellet 110.

This is the evaluation result of the infinite multiplication factor (reactivity) according to the burnup of the nuclear fuel assembly loaded with the cylinder-shaped combustible absorber of FIG. 6 . 6 shows the resultant value when the combustible absorber 120 is made of a single layer rather than a multilayer from the inside to the outside. Here, the Y-axis represents the excess reactivity k-infinity, and the X-axis represents the burnup BU [GWD/MTU].

7 is an evaluation result of an infinite multiplication factor (reactivity) according to burnup of a nuclear fuel assembly loaded with a combustible absorber 120 having a multi-layer structure according to the present invention. As shown in FIG. 7, the evaluation result of the infinite multiplication factor (reactivity) according to the burnup of the nuclear fuel assembly loaded with the combustible absorber 120 of the multilayer structure according to the present invention is compared with the result of FIG. It can be seen that the value O is optimized to be more gentle. It can also be seen from FIG. 7 that the control value O is more optimized than values of other conditions.

Although the embodiments of the present invention have been described with reference to the above and accompanying drawings, those skilled in the art to which the present invention pertains can implement the present invention in other specific forms without changing the technical spirit or essential features. You will understand that there is Therefore, the embodiments described above should be understood as illustrative in all respects and not limiting.

110: nuclear fuel pellet
120: combustible absorber
121: first combustible absorber outer ring
122: first combustible absorber inner core
123: second combustible absorber outer ring
124: third combustible absorber outer ring
130: combustible absorber cladding
140: filling gas layer

Claims (9)

As a nuclear fuel rod assembly,
an annular nuclear fuel pellet;
a combustible absorber loaded into the center of the nuclear fuel pellet;
a combustible absorber cladding positioned between the nuclear fuel pellet and the absorber; and
A filling gas layer filled between the nuclear fuel pellet and the combustible absorber cladding;
The combustible absorber,
a first combustible absorber outer ring located at the center of the combustible absorber cladding;
A nuclear fuel rod assembly comprising a first combustible absorber inner core positioned at a center of the combustible absorber outer ring. According to claim 1,
The combustible absorber is manufactured based on a swaging method and then loaded onto the nuclear fuel assembly. According to claim 2,
The nuclear fuel assembly is made of a multi-layer structure mutually partitioned in upper and lower directions,
The combustible absorber cladding vertically penetrates the mutually partitioned nuclear fuel pellets,
The first combustible absorber outer ring vertically penetrates the mutually partitioned nuclear fuel pellets,
The first combustible absorber inner core vertically penetrates the mutually partitioned nuclear fuel pellets,
The filling gas layer,
After the combustible absorber cladding, the first combustible absorber outer ring, and the first combustible absorber inner core are loaded on the nuclear fuel pellets, the nuclear fuel rod assembly formed above and below the mutually partitioned nuclear fuel pellets. According to claim 1,
The combustible absorber,
a second combustible absorber outer ring in which the first combustible absorber outer ring is located;
Further comprising a third combustible absorber outer ring in which the second combustible absorber outer ring is located inside,
The combustible absorber cladding is positioned between the third combustible absorber outer ring and the nuclear fuel pellet assembly. According to claim 4,
wherein the first combustible absorber inner core, the first combustible absorber outer ring, the second combustible absorber outer ring, and the third combustible absorber outer ring contain gadolinium oxide (Gd2O3). According to claim 5,
The gadolinium oxide of the third combustible absorber outer ring includes an odd-numbered gadolinium isotope (Gd-155, Gd-157) having a first number density value,
The gadolinium oxide of the second combustible absorber outer ring includes odd-numbered gadolinium isotopes having a second number density greater than the first number density,
Gadolinium oxide in the outer ring of the first combustible absorber includes odd-numbered gadolinium isotopes having a third number density greater than the second number density,
Gadolinium oxide in the inner core of the first combustible absorber includes an odd-numbered gadolinium isotope having a fourth number density greater than the third number density, the nuclear fuel rod assembly As a method for manufacturing a nuclear fuel rod assembly,
Preparing an annular nuclear fuel pellet;
charging a combustible absorber and a combustible absorber cladding into the nuclear fuel pellet; and
Filling a filling gas between the nuclear fuel pellet and the combustible absorber cladding;
The combustible absorber,
a first combustible absorber outer ring located at the center of the combustible absorber cladding;
A method for manufacturing a nuclear fuel rod assembly comprising an inner core of a first combustible absorber positioned at a center of the outer ring of the combustible absorber. According to claim 7,
The method of manufacturing a nuclear fuel rod assembly, wherein the combustible absorber and the combustible absorber cladding are manufactured based on a swaging method. According to claim 1,
The combustible absorber cladding is made of a material containing at least one of niobium (Nb), molybdenum (Mo), tungsten (W), and tantalum (Ta).

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