KR20140075383A - Californium neutron source container with optimum lead shielding - Google Patents

Abstract

The present invention is to provide a californium neutron source container using an optimum lead shielding method capable of reducing the weight of a lead shielding material to preferentially block gamma rays generated by the reaction between a neutron and a polyethylene shielding material by placing the lead shielding material inside the source container before energy is attenuated.

Description

The present invention relates to a calibrated neutron source container with optimal lead shielding,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a caliperron neutron source employing an optimal lead shielding method. More particularly, the present invention relates to a method of shielding the lead shield by reducing the weight of the lead shield by placing the lead shield inside the source and shielding the generated gamma rays by reacting the neutron and the polyethylene shield before the energy is attenuated The present invention relates to a caliperron neutron source source.

The Nuclear Safety Regulations require the radiation level to be regularly measured as a radiation management zone for areas that are likely to be exposed to unintended radiation. In particular, for nuclear power plants, exposure of workers by neutrons As shown in FIG.

In order to calibrate neutron dosimeter and neutron dosimeter used for this purpose, a caliper neutron source is used to calibrate the neutron dosimeter, and it is housed in a crew box except when working to minimize the radiation exposure of the calibrator.

In order to shield the neutrons emitted from the source of the car- riphonium source, a material containing a large amount of hydrogen atoms, such as paraffin and polyethylene, is used to utilize the energy attenuation caused by the elastic scattering of neutrons and hydrogen atoms. . At this time, lead is used as a typical shield to attenuate gamma rays generated when polyethylene reacts with neutrons.

However, in order to effectively shield the gamma rays generated by the reaction between the neutron and polyethylene, it is best to place the lead shield outside the polyethylene shield. In this case, since the lead shield increases in size, the weight of the shield increases, There is a disadvantage that it increases.

SUMMARY OF THE INVENTION Accordingly, the present invention has been made keeping in mind the above problems occurring in the prior art, and it is an object of the present invention to reduce the weight of the lead shield by arranging the lead shield in the source, thereby shielding the gamma rays generated by the reaction between the neutron and the polyethylene shield, The purpose of the present invention is to provide a neutron beam source capable of generating a neutron beam.

According to a first aspect of the present invention, a caliperron neutron source source to which an optimal lead shielding method is applied comprises a caliper source, A source guide tube capable of transferring the caliper source to a position required for calibration by air pressure or a cable; A shield made of lead containing the caliper source, and a shield made of polyethylene wrapping the shield made of lead.

According to a second aspect of the present invention, the shield made of lead is characterized in that the shield is made to be located at a point where the energy of the neutron, which is the portion where the intensity of the gamma ray generated by the reaction between the neutron and polyethylene reacts, .

The caliper neutron source source employing the optimal lead shielding method of the present invention

First, since the shield made of lead for attenuating the gamma ray generated by the reaction of the neutron and polyethylene is located in the middle of the polyethylene shield, unnecessary lead shielding can be reduced, and weight reduction and cost reduction can be expected.

That is, in the basic structure of the neutron source source, the weight is greatly increased because of the lead for shielding the gamma ray rather than the polyethylene for neutron shielding. When neutrons lose their energy due to collision with hydrogen atoms contained in polyethylene and are trapped in polyethylene, a high energy gamma ray of 2.2 Mev is generated. Usually, the outer part of polyethylene is shielded by lead to attenuate the gamma rays. This method is a structure that can use a lot of lead, and inevitably leads to an increase in weight and an increase in cost.

Second, since the lead material is of a poor quality, sufficient strength can not be ensured when it is placed on the outside, and it is difficult to manufacture a separate casing. Accordingly, in the present invention, it is possible to improve the durability by improving the mechanical strength of the source of the ship by minimizing the shielding material of a lead material having poor workability.

FIG. 1 is a side cross-sectional view of a caliperron neutron source employing an optimal lead shielding method according to an embodiment of the present invention.

Hereinafter, the present invention will be described in more detail with reference to the accompanying drawings. The accompanying drawings, which are merely illustrative of the present invention, are for the purpose of illustrating embodiments only and are not intended to limit the generality of the present invention. The following detailed description applies to all subjects of the invention on the same basis.

FIG. 1 is a cross-sectional side view of a capillary neutron source employing an optimal lead shielding method according to an embodiment of the present invention, wherein reference numeral 1 is a caliperron neutron source, reference numeral 2 is a caliper source, reference numeral 3 is a polyethylene shield, And 5 is a lead shield.

According to a first aspect of the present invention, as shown in Fig. 1, a caliperron neutron source housing 1 is equipped with a caliper source 2 at its center.

A neutron source is a source (americium + beryllium) that emits neutrons by reacting with neutrons (such as caliphonium) and particles or radiation that spontaneously emit neutrons. The caliphonium source has a half-life of 2.64 years and the average energy of neutrons emitted is 2.3 MeV. The energy distribution is similar to the energy distribution of neutrons generated by nuclear power plants, and is therefore widely used for calibration of neutron dose rate meters and for reference of personal dosimeters.

According to the present invention, a carousel type storage box is adopted for loading and selecting a plurality of sources, and the storage box can be rotated to select a hole equipped with a desired source.

According to one embodiment of the present invention, the source of the caliper source 4 mounted at the center is provided with a source guide tube 4 which can be transported to a position required for calibration by air pressure or a cable. Usually, the crew is mounted on the crew holder, and finally the crew holder is transported using air pressure or cable.

According to the present invention, in order to minimize the dose of worker exposure due to neutrons and gamma rays when the calibration operation is not carried out, a shielding body made of lead is used around the caliper source 1, which is located at the center of the caliper source 1 5 and a shield 3 made of polyethylene are double-wrapped.

Here, the principle that polyethylene shields neutrons is that energy is attenuated and finally absorbed by elastic collision of hydrogen and neutrons constituting polyethylene. When density is higher than 0.95 g / ㎤, it is classified as high density polyethylene. The higher the density, the higher the number of hydrogen atoms per unit volume, and the probability of collision of neutrons can be increased. As a result, the use of high density polyethylene can reduce the volume of seam welding.

In the present invention, the amount of polyethylene filled in the source varies with the intensity of the neutron source and is calculated using a simulation program such as MCNP. The polyethylene is filled with a cylinder, and the neutron source is located in the center of the cylinder.

In the present invention, it is preferable that the polyethylene is processed into a disk having a predetermined thickness and laminated from the bottom, and a lead shield formed by pouring molten lead into a cylindrical steel frame is placed in the middle portion of the polyethylene.

According to the second aspect of the present invention, it is preferable that the shield made of lead is positioned in the portion where the intensity of the gamma ray generated by the reaction of the neutron and the polyethylene is largest.

That is, in the basic structure of the neutron source source, the weight is greatly increased because of the lead for shielding the gamma ray rather than the polyethylene for neutron shielding. The 2.2 MeV high energy gamma ray is decayed and converted into thermal neutron, which is generated by capturing in neutrons. This structure shields the outside of polyethylene from lead and lowers the gamma ray dose. The role of lead primarily shields the 2.2 MeV gamma ray. The minimum thickness of polyethylene, which is converted to thermal neutrons from polyethylene, is determined by the neutron energy, so lead is inserted outside the minimum thickness and the outside is again covered with polyethylene It will be done.

This minimum thickness, that is, the intensity of the gamma ray, is the point at which the neutron energy is attenuated and transformed into thermal neutron, which can be calculated using a simulation program such as MCNP. Based on the results of several studies, it may be desirable to shield the gamma rays with 5 cm thickness of lead.

A characteristic feature of the present invention is the order of using polyethylene and lead to shield neutrons and gamma. That is, when a shield is formed in the order of "polyethylene + lead + polyethylene ", as in the present invention, the amount of lead can be minimized by placing the lead shield at a minimum distance where gamma rays are generated, And also has the advantage of increasing the mechanical strength incidentally.

1: Caliphonium neutron source source
2: The source of the caliphonium
3: Polyethylene shield
4: Sailor's Guide
5: Lead Shield

Claims (2)

A caliper source seated in the center; A source guide tube capable of transferring the caliper source to a position required for calibration by air pressure or a cable; A shield made of lead containing the caliper source, and a shield made of polyethylene wrapping the shield made of lead. The present invention relates to a caliper neutron source having an optimal lead shielding method. The shield according to claim 1, characterized in that the shield made of lead is located at a point where the energy of the neutrons, which is the strongest part of the gamma rays generated by the reaction between neutrons and polyethylene, is attenuated and converted into thermal neutrons. A method of applying a calibrated neutron source.

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