JP2002022885A - Reflector element filled with small balls - Google Patents

Abstract

PROBLEM TO BE SOLVED: To drastically enlarge flattened area of neutron flux in a neutron irradiation test and finely control neutron spectrum as an irradiation field condition. SOLUTION: In a reflector element 1 for material testing reactor structured with a box 6, small balls of a reflector material are filled in the gap between the outer wall of the box and a pipe 5 for loading a capsule by controlling filling density.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a reflector element filled with small spheres, and more particularly to a neutron irradiation test using a material test furnace, which enables fine adjustment of a neutron spectrum as an irradiation field condition. It is to try.

[0002]

2. Description of the Related Art Around the core of a nuclear reactor is covered with a structure made of a material that repels neutrons, called a reflector, in order to reduce the amount of neutrons leaking from the core. In light water reactors, water as a coolant also plays a role.
In the material test furnace, beryllium having a large neutron scattering cross section is used as a reflector, and aluminum having a small neutron scattering cross section is used to adjust the amount of neutrons leaking from the core.

[0003] In such a material test furnace, the reflector is a member for testing the material properties for neutrons (in this case, by charging various materials into the reflector in addition to its original function). (Referred to as irradiation holes). In recent years, the demand for the above-described material property test has been increasing more and more in order to develop new materials that can withstand neutron irradiation.

FIG. 1 shows an example of a core arrangement of a material testing furnace (JMTR) in a case where 11 reflector elements of I are used as irradiation holes.

[0005] In the case of such a material property test, it is important that the density of the neutron flux irradiated on the material is uniform. However, as shown in FIG. Since the neutron flux tends to be large at the center and small at both the upper and lower ends, the neutron flux density is uniform (generally, the neutron flux peaks within -15% of the neutron flux peak and is defined as the flattened area). That is, there is a problem that a region suitable for a material test is small. Here, the cost of such a material property test is extremely high. Therefore, if a large number of materials can be tested at once, it is very useful in terms of cost, and a solution has been desired.

[0006]

SUMMARY OF THE INVENTION The present invention satisfies the above-described needs and provides a reflector element which achieves a significant reduction in test costs by effectively expanding the flattened area of the neutron flux. The purpose is to propose. The present invention also seeks to achieve a fine adjustment of the neutron spectrum as irradiation field conditions by allowing an optional change of the neutron flux over the longitudinal direction of the reflector element.

[0007]

Means for Solving the Problems The inventors of the present invention have made intensive studies to achieve the above object, and as a result, conventionally, a solid material such as beryllium or aluminum has been used as a reflector element. However, it has been found that the use of small spheres of a reflector material such as beryllium or aluminum instead of the solid material is extremely effective in achieving the intended purpose. The present invention is based on the above findings.

That is, the gist of the present invention is as follows. 1. A reflector element for a material test furnace having a casing structure, wherein a gap between an outer wall of the casing and a pipe for loading a capsule is filled with small spheres of a reflector material. Body element.

[0009] 2. The globule-filled reflector element of claim 1, wherein the reflector material is beryllium or aluminum.

[0010] 3. 3. The small sphere-filled reflector element according to the above 1 or 2, wherein the packing density of the small spheres is changed in the axial direction of the reflector element.

4. 4. The method according to the above 1, 2, or 3, wherein the packing density of the small spheres is changed in accordance with the ratio of the helium generation amount (He) to the ejection number (DPA) per target atom (He / DPA). Small sphere-filled reflector element.

[0012]

BEST MODE FOR CARRYING OUT THE INVENTION The present invention will be specifically described below based on the research results on which the present invention is based. Now,
The inventors obtained the axial distributions of the fast neutron flux, the thermal neutron flux, and the ratio of the fast neutron flux to the thermal neutron flux passing through the reflector element under the conditions described below.

Here, the reflector element having the dimensions and shape shown in FIG. 3 was used. FIG. 3A is a perspective view of the reflector element, and FIG. 3B is a cross-sectional view of the main body of the reflector element. In the figure, reference numeral 1 denotes a main body of the reflector element, 2 denotes a lower adapter, 3 denotes a handle, and 4 denotes an irradiation hole. The irradiation hole 4 is loaded with a capsule (a material to be used for an irradiation test) (not shown). Reference numeral 5 denotes a pipe for loading the capsule, and reference numeral 6 denotes a housing. Small spheres of a reflector material such as beryllium and aluminum are filled in the gap between the pipe 5 for loading the capsule and the housing 6.

Calculation conditions Core configuration: Assuming a core with no capsules loaded. Irradiation hole: I-11 irradiation hole (Be reflector region one layer) (see FIG. 1). Capsule: Aluminum cylinder (φ40mm). The calculations are based on the Be and Al spheres being filled into the reflector element, as well as the solid Be and
The test was performed for a case where an Al reflector element (hereinafter, simply referred to as a Be reflector element and an Al reflector element) was loaded into the I-11 irradiation hole of the reactor core. The calculation case is as follows. (a) When the Be spheres are filled up to 80% filling ratio (hereinafter, referred to as 80% PF) (filling atmosphere is helium). (b) When the Be spheres are filled with 60% PF (the atmosphere in the filling section is helium). (c) When the Al spheres are 60% PF-filled (filling atmosphere is helium). (d) Be reflector element. (e) Al reflector element. The packing density of the small spheres was adjusted by using various small spheres having different diameters.

Calculation Results The axial distributions of the fast neutron flux, the thermal neutron flux and the ratio of the fast neutron flux to the thermal neutron flux passing through the capsule (aluminum cylinder) (the center of the core is 0, the upper and lower ± 30
cm plotted). The obtained results are shown in FIGS.
6 and FIG.

Fast neutron flux As shown in FIG. 4, compared with the case of the Be reflector element,
When the packing density of the Be spherules is 80% PF, the fast neutron flux increases by about 5%. Similarly, the packing density of Be spheres is 60%
Approximately 13% in the case of PF.
% PF) increases by about 18%. In the case of the Al reflector element, the increase is about 16%.

Thermal neutron flux As shown in FIG. 5, compared with the case of the Be reflector element,
When the packing density of Be spherules is 80% PF, the thermal neutron flux is reduced by about 12%. Similarly, the packing density of Be spheres is 60% P.
Approximately 14% in the case of F. In addition, when Al spheres are used (60%
PF) is reduced by about 22%. In the case of the Al reflector element, the reduction is about 26%.

The ratio of the fast neutron flux to the thermal neutron flux (φf /
φth) As shown in FIG. 6, the values in each case are as follows. Be reflector element: 0.18 Be small sphere (80% PF): 0.22 Be small sphere (60% PF): 0.23 Al small sphere (60% PF): 0.28 Al reflector element: 0.29

As described above, the packing density of the reflector material,
Furthermore, by changing the material, the fast neutron flux, the thermal neutron flux, and the ratio of the fast neutron flux to the thermal neutron flux that pass through the reflector element can be appropriately adjusted. Therefore, the neutron spectrum as the irradiation field condition can be adjusted by changing the material of the reflector material and the packing density as necessary.

As described above, if the material and the packing density of the reflector material are changed, the neutron spectrum as the irradiation field condition can be adjusted, but the fluctuation of the neutron flux in the axial direction of the reflector element is large. Here, when the fluctuation of the neutron flux in the axial direction is large, there is a problem that the flattened area of the neutron flux, that is, the area suitable for the material test is small, and in that case, the test cost is increased. It is as follows.

However, as is clear from FIGS. 4 and 5, if the packing density of the reflector material is changed, the value of the neutron flux changes accordingly. Therefore, the inventors tried to expand the flattened region of the neutron flux in the axial direction of the reflector element by changing the packing density of the reflector material across the axial direction of the reflector element.

As described above, as for the fast neutron flux, the smaller the packing density of the Be sphere, the larger the size of the neutron flux. Therefore, in the region where the fast neutron flux density is originally large in the axial direction of the reflector element (the central region in the axial direction), the neutron density is reduced by increasing the packing density of the Be spheres, while the density of the fast neutron flux is originally increased. If the neutron density is increased by lowering the packing density of the Be spheres in the region where is small (upper and lower end regions), the neutron flux density difference between the two regions should decrease.

FIG. 7 shows an axial center area of the reflector element (+5.
0 to -20.0 cm), the packing density of Be spheres is 80%
The flattened area of the neutron flux when the packing density of the Be spherules was reduced to 60% PF at both ends (+30.0 to +5.0 cm and −20.0 to −30.0 cm) Of the conventional Be as a reflector element
This is shown in comparison with the case where a reflector element is used. As shown in the figure, when the conventional Be solid material was used, the flattened area, which was only 28 cm, changed the packing density of the Be spheres in the axial direction of the reflector element according to the present invention. Is 35cm and 25
% Also increased.

In FIG. 7, the packing density of the Be spheres is
Although mainly described in the case of changing in two stages of the axial direction center part and both ends of the reflector element, the area where the packing density of the Be microsphere is changed is further subdivided in the axial direction of the reflector element, and each Needless to say, if the packing density of the Be spheres in the region is more finely controlled, the flattened region of the neutron flux can be further expanded.

As described above, by changing the packing density of the reflector material in the axial direction of the reflector element, and further, the material itself of the reflector material, the flattened region of the neutron flux can be effectively expanded. . Also, if this technique is used, not only can the flattened region of the neutron flux be enlarged, but also the neutron density in the axial direction of the reflector element can be changed at will. Fine tuning of the neutron spectrum becomes a reality.

He / DPA is often used as an index for neutron irradiation conditions when irradiating in a nuclear fusion reactor or a nuclear reactor. In the above index, He (atomic ppm) is the amount of helium generated by neutron irradiation, which is generated by a nuclear reaction between neutrons and atoms in a material. DPA (Displacement Per Atom) is the target atom 1
This is called the number of protrusions per unit, and is one of the indexes indicating the degree of deterioration of a material due to neutron irradiation.

Particularly, in a neutron irradiation test of a steel material such as stainless steel, this He / DPA is often used as an index. Therefore, when testing the steel materials as described above, if the He / DPA can be appropriately controlled to a desired value, it can be said that the merit in the irradiation test is extremely large, but according to the present invention, this He / DPA Can be easily controlled.

That is, FIG. 8 shows a comparison of DPA per operation cycle of a material test reactor (JMTR) when various reflector elements are used.
Changing the packing density of the reflector material or changing the material itself does not change much. On the other hand, as shown in FIG. 9, the amount of He generated per operation cycle of the material test furnace (JMTR) greatly changes according to a change in the packing density of the reflector material or a change in the material. Therefore, the value of He / DPA can be appropriately changed by changing the packing density of the reflector material or by changing the material itself. That is, the control width of He / DPA can be significantly improved.

In the present invention, the atmosphere in the space between the outer wall of the housing and the pipe for loading the capsule, in which the small spheres of the reflector material are filled, is not particularly limited. Among them, the use of a helium gas atmosphere is particularly advantageous in terms of thermal conductivity.

[0030]

Thus, according to the present invention, the flattened region of the neutron flux can be greatly expanded by appropriately adjusting the packing density in the reflector axial direction by using the reflector material as small spheres. Further, in the present invention, the range of spectrum control in the neutron spectrum adjustment irradiation can be effectively expanded, so that the neutron spectrum can be finely adjusted.

[Brief description of the drawings]

FIG. 1 is a diagram showing an example of a core arrangement of a material test reactor (JMTR).

FIG. 2 is a diagram showing a change in density of a neutron flux irradiated from a reactor core in an axial direction.

3A is a perspective view of a reflector element, and FIG. 3B is a sectional view of a reflector element body.

FIG. 4 is a graph showing the axial distribution of a fast neutron flux passing through a capsule when the material of the reflector material and the packing density are different.

FIG. 5 is a graph showing the axial distribution of a thermal neutron flux passing through a capsule when the material of the reflector material and the packing density are different.

FIG. 6 is a graph showing the axial distribution of the ratio between the fast neutron flux and the thermal neutron flux passing through the capsule when the material of the reflector material and the packing density are different.

FIG. 7 shows a conventional Be reflector element using a flattened area of a neutron flux when the packing density of Be spheres is changed in a central area in the axial direction of the reflector element and both end areas thereof as a reflector element. 7 is a graph shown in comparison with the case where.

FIG. 8 is a graph showing a comparison of DPA per four operation cycles with a material test reactor (JMTR) using various reflector elements.

FIG. 9 is a graph showing a comparison of the amount of He generated per four operation cycles in a material test furnace (JMTR) when various reflector elements are used.

 ────────────────────────────────────────────────── ─── Continued on the front page (72) Inventor Miharu Nagao 3607 Niibori, Narita-cho, Oarai-machi, Higashiibaraki-gun, Ibaraki Pref. Japan Atomic Energy Research Institute Oarai Research Institute No.2 56 Inside Nihon Insulator Co., Ltd.

Claims (4)

[Claims] 1. A reflector element for a material test furnace having a housing structure, wherein a gap between an outer wall of the housing and a pipe for loading a capsule is filled with small spheres of the reflector material. Small sphere-filled reflector element. 2. The reflector element as claimed in claim 1, wherein the reflector material is beryllium or aluminum. 3. The reflector element filled with small spheres according to claim 1, wherein the packing density of the small spheres is changed in the axial direction of the reflector element. 4. The method according to claim 1, wherein the packing density of the small spheres is changed in accordance with a ratio He / DPA of a helium generation amount (He) to a pop-out number (DPA) per target atom. , 2 or 3, the sphere-filled reflector element.