JPH01280299A - Neutron shield concrete material - Google Patents

Abstract

PURPOSE:To accurately set such thickness that prescribed neutron shield effect is obtained by adding a prescribed-amount of hydrogen-containing material as a neutron shield concrete material which cuts off neutrons generated by a neutron generation source. CONSTITUTION:This concrete material cuts off the neutrons generated by the neutron generation source in radiation-relative facilities. Then part of thin aggregate 2 in concrete 1 is replaced with a prescribed amount of added hydrogen-containing material 3. Consequently, the contents of hydrogen which prevent neutrons from being transmitted increases in the concrete 1 to increase neutron shield effect per unit and also accurately grasp the minimum value of the hydrogen content rate. The thickness with which the prescribed neutron shield effect is obtained is therefore accurately set according to the relation between the hydrogen content rate and neutron shield effect. Consequently, the thin concrete material which is clear in shield effect and thin is obtained and its use range is widened.

Description

[Detailed Description of the Invention] "Industrial Application Field" This invention is used to shield neutrons generated in radiation-related facilities equipped with neutron sources such as fusion reactors, nuclear reactors, medical accelerators, and high-energy accelerators. This relates to neutron shielding concrete materials.

"Conventional technology" Conventionally, when concrete is used as a neutron shielding material, the hydrogen content in concrete that exhibits an effective neutron shielding effect is unclear, so the amount of hydrogen is underestimated. I needed to set it thicker on the safe side.

In other words, most of the hydrogen in concrete exists as moisture such as free water, so even if the mixing ratio of concrete is determined appropriately when designing the shielding,
Water evaporates from the concrete surface for an extremely long period before and after the concrete hardens.
This results in a decrease in hydrogen content.

For this reason, the hydrogen content after concrete hardens becomes unclear, and it is extremely difficult to accurately determine the hydrogen content.

Furthermore, over a long period of time, the moisture content of concrete decreases,
The shielding ability may be reduced, which is currently a problem, especially in terms of extending the life of nuclear reactors.

``Problem to be solved by the invention'' For this reason, conventionally, when using concrete as described above as a neutron shielding material, the thickness required for the shielding material was not known, so when designing the shielding, The neutron shielding effect of concrete was underestimated and its thickness was set thicker than originally necessary, which resulted in the use of an excessive amount of concrete and increased costs.

In addition, we believe that it would be difficult to use materials such as concrete, whose neutron shielding effect is unclear, as a shielding material, especially in facilities that generate large amounts of neutrons, such as nuclear fusion reactors that will be put into practical use in the future. Currently, there are plans to use steel as a shielding material for areas other than the high-temperature parts of fusion reactors. However, since steel is more expensive than concrete, it has been desired to reduce costs by using as many concrete shielding materials as possible.

"Means for Solving the Problem" The neutron shielding concrete of the present invention is a neutron shielding concrete material that shields neutrons generated from a neutron source, and is a neutron shielding concrete material in which a predetermined amount of fine aggregate is replaced with a part of fine aggregate in concrete. Hydrogen-containing substances are added.

Another neutron-shielding concrete of the present invention is a neutron-shielding concrete material that shields neutrons generated from a neutron source, and the surface of the concrete is coated with a watertight material.

"Function" In the neutron-shielding concrete material of this invention, by adding a predetermined amount of hydrogen-containing material to replace a part of the fine aggregate in the concrete, the content of hydrogen that prevents neutron transmission increases in the concrete. As a result, the neutron shielding effect of concrete increases per unit thickness, and
Since the minimum value of hydrogen content in concrete can be accurately determined, it is possible to accurately set the thickness that will provide the desired neutron shielding effect by investigating the relationship between hydrogen content and neutron shielding effect. can. Therefore, it is possible to produce a concrete shielding material with a clear neutron shielding effect and a relatively thin thickness, thereby expanding the scope of use of concrete as a neutron shielding material.

In addition, in other neutron-shielding concrete materials of the present invention, the surface of the concrete is coated with a watertight material to prevent moisture loss due to water vapor evaporation from the surface of the concrete, thereby reducing the hydrogen content in the concrete. is kept constant. This eliminates the need to set the concrete thickness on the safe side and allows the thickness required to be accurately set to obtain the desired neutron shielding effect, thereby preventing excessive use of concrete. In addition to eliminating neutron shielding, the range of use of concrete as a neutron shielding material can be expanded.

"Example" A first embodiment of this invention will be described below.

The neutron-shielding concrete of this example is a neutron-shielding concrete material that shields neutrons generated from a neutron source, and as shown in FIG. A hydrogen-containing material 3 of the form is added.

Examples of the hydrogen-containing material 3 include compounds or mixtures with high hydrogen content such as paraffin wax, polyethylene, methacrylic acid resin, ethyl cellulose, polystyrene, lithium hydride, lithium boron hydride, and microcapsules filled with water. These hydrogen-containing substances 3 are formed into particles with a diameter of several square meters and are dispersed in the concrete l.

Such neutron-shielding concrete materials can be obtained at low cost and in large quantities, and are easy to form, making it easy to manufacture large shields such as nuclear reactor containment vessels or walls of radiation-related equipment on-site. Moreover, the constructed shielding body can exhibit a reliable neutron shielding effect.

Next, a second embodiment of the invention will be described.

In the neutron shielding concrete of this embodiment, as shown in FIG.
The inside of the casing 4 is filled with concrete 1, and then, as shown in FIG. 3, the casing 4 is covered with a stainless steel lid 5 to seal the inside of the casing 4.

According to this neutron shielding concrete material, the casing 4
It can be formed into various complicated shapes depending on the shape of the casing 4, and even more complicated shapes can be formed by combining multiple casings 4. Moreover, it is easy to attach to equipment, so it can be easily moved in nuclear fusion reactors etc. shield, partial shield,
It can also be used as a shielding block.

Next, a third embodiment of the invention will be described.

The neutron shielding concrete of this example has a watertight paint applied to the concrete surface.

Any paint can be used as the above paint as long as it is highly watertight such as epoxy paint or urethane paint, but it is preferable to use paint for tritium facilities as a coating material for concrete in tritium facilities. It is better to use the one developed in

According to this neutron-shielding concrete material, most of it is made up of concrete that can be obtained cheaply and in large quantities and is easy to construct on-site. It is possible to produce a shield of

Next, an example in which the neutron shielding concrete materials of these examples are used as a shielding material for a nuclear fusion device will be described with reference to FIGS. 4 and 5.

In this fusion device, a ring-shaped fusion reactor 6 is covered with a dome-shaped shielding body 7, and the fusion reactor 6 is surrounded by a plurality of movable shielding blocks made of the neutron-shielding concrete material of the second embodiment. 8, and the neutron shielding concrete material of the first embodiment is used as the material of the shielding body 7.

"Experimental example" In order to investigate the hydrogen content required when using concrete as a neutron shielding material, neutrons were irradiated to concrete with a hydrogen content of 10.0% and concrete with a hydrogen content of 6.3%. The neutron flux inside each concrete was analyzed using a computer.

Prior to this computer analysis, we actually irradiated the end face of a sample made of cylindrical mortar with neutron flux, measured the neutron flux at each depth of this sample, and compared the results with the computer analysis results. . However, the above-mentioned mortar is made of mortar with a hydrogen content of 6.3%, which is the same as the mortar in ordinary concrete, and has a diameter of 600z* and a length of 60Oxxl.

In this experiment, first, the sample was set at a position 20 cx away from the target in the beer line direction of the fusion neutron source (accelerator), and the sample was irradiated with neutrons for a maximum of 10 hours. After doing this, the reaction rates of the seven types of activation foils that had been set inside the sample in advance were calculated based on measurements using a Ge detector, and the results were further analyzed using a computer. A spectrum of neutron flux was created.

On the other hand, the accelerator was operated with a weak current to irradiate the sample with neutrons, and at the same time, the neutron flux inside the sample was detected using a small NE213 detector to obtain a spectrum.

As a result of these two experiments, the computer analysis results are as follows.
It was found that the results agreed with the actual measurement results within an error range of ±15%.

Next, a concrete structural material with a hydrogen content of 6.3% similar to the above sample and a similar shape with a hydrogen content of io.

% concrete structural material, and when the end face of each concrete structural material is irradiated with fusion neutrons, the depth of the end face of each concrete structural material is Oxx, 25x
x, 50xx1100xm, 200iu+, 400
JII, the neutron flux at each position of 550Xm was analyzed, and the ratio of the neutron flux at each position in each structure was determined.

The relationship between the neutron flux ratio and neutron energy is graphed and shown in FIGS. 6 and 7.

As a result, the hydrogen content is 6.3% and the hydrogen content is 10%.
．． The neutron flux ratio in the case of 0% is when the depth from the end face is 55
In the deep part of 0xg, it is 0.6 in the low energy part and 0.7 to 0.8 in the high energy part, and the hydrogen content is 10.0% (1.5 x 10- in terms of hydrogen atomic number density). ”)
It was found that the above concrete has sufficient shielding ability as a neutron shielding material.

"Effects of the Invention" According to the neutron shielding concrete material of the present invention, a predetermined amount of hydrogen-containing substance is added in place of a part of the fine aggregate in the concrete, so the hydrogen content in the concrete prevents neutron transmission. This makes it possible to increase the neutron shielding effect of concrete per unit thickness, as well as accurately grasp the minimum value of the hydrogen content in concrete. By examining the relationship with the shielding effect, it is possible to accurately set the thickness that provides a predetermined neutron shielding effect. Therefore, it is possible to produce a concrete shielding material with a clear neutron shielding effect and a relatively thin thickness, thereby expanding the scope of use of concrete as a neutron shielding material. In addition, this neutron shielding concrete material can be obtained inexpensively and in large quantities;
Moreover, because it is easy to mold, large shields such as nuclear reactor containment vessels or walls of radiation-related equipment can be easily manufactured on site, and the constructed shield has a reliable neutron shielding effect. can be demonstrated.

Further, according to another neutron shielding concrete material of the present invention, since the surface of the concrete is coated with a watertight material, it is possible to prevent moisture loss due to water vapor evaporation from the surface of the concrete. The content can be kept constant. This eliminates the need to set the concrete thickness on the safe side and allows the thickness required to be accurately set to obtain the desired neutron shielding effect, thereby preventing excessive use of concrete. In addition to this, the scope of use of concrete as a neutron shielding material can be expanded.

In addition, in this neutron-shielding concrete material, if the watertight material is made of a metal casing such as stainless steel, it can be formed into various complicated shapes depending on the shape of the casing, and multiple casings can be formed. It is also possible to form a more complex structure by combining them, and since it is easy to attach to equipment, it can be used as a movable shield, a partial shield, a shield block, etc. in a nuclear fusion reactor, etc.

In addition, when the above-mentioned watertight material is made of highly watertight paint, most of it is made of concrete, which can be obtained cheaply and in large quantities and is easy to construct on-site, making it difficult to manufacture large-sized shielding bodies. be able to.

Furthermore, it is possible to suppress the decline in the shielding ability of concrete due to aging, and it is possible to maintain high shielding ability over a long period of time.

[Brief explanation of the drawing]

FIG. 1 is a sectional view of a neutron shielding concrete material according to a first embodiment of the present invention. FIGS. 2 and 3 are explanatory diagrams illustrating a method for manufacturing a neutron-shielding concrete material according to a second embodiment of the present invention. 4 and 5 are diagrams showing a nuclear fusion reactor to which the neutron shielding concrete material of the present invention is applied, with FIG. 4 being a longitudinal sectional view and FIG. 5 being a plan view. FIGS. 6 and 7 are graphs showing the relationship between the neutron flux ratio and neutron energy of concrete of each moisture content at each depth position. l...Concrete, 2...Fine aggregate, 3...Hydrogen-containing material, 4...Watertight material (casing).

Claims (2)

[Claims] (1) A neutron-shielding concrete material that shields neutrons generated from a neutron source, characterized in that a predetermined amount of hydrogen-containing material is added to replace a part of fine aggregate in the concrete. Shielding concrete material. (2) A neutron-shielding concrete material that shields neutrons generated from a neutron source, characterized in that the surface of the concrete is covered with a watertight material.