KR102386991B1 - Radiation shieiding apparatus to enable normal detector operation in highradiation field - Google Patents

Abstract

The present invention relates to a radiation shielding device, which forms a surface body with the structure of the empty inside, comprising: a body containing a radiation detector; holes formed on each surface of the body and introducing radiation into the body; and shielding blades installed on each of the hole to rotate and adjusting a radiation dose coming into each of the holes. According to the present invention, an environment in which a general radiation detector can operate normally for measurement in a high-radiation area is formed inside the body by adjusting the rotating speed of the shielding blades, thereby measuring and monitoring radiation and analyzing the nuclide thereof to be able to predict the irradiation dose of a worker accurately in advance.

Description

RADIATION SHIEIDING APPARATUS TO ENABLE NORMAL DETECTOR OPERATION IN HIGHRADIATION FIELD

The present invention relates to a radiation shielding device, and more particularly, in a high-radiation zone where radioactivity measurement, monitoring, and nuclide analysis are performed by creating an environment in which a general radiation detector can normally operate and measure in an environment in a high-radiation zone. It relates to a radiation shielding device that implements the normal operation of a general radiation detector.

In general, as known in the prior art such as Korean Utility Model Publication No. 20-0457203, it is a general radiation detector such as a Nal (TI) radiation detector that has been commercialized in an environment in a high radiation area such as a high-energy decommissioning waste target facility. When the radiation dose is measured, the dead time occurs and the radiation dose cannot be measured.

That is, in a high-radiation zone environment, a typical radiation detector for nuclide analysis and nuclide inventory evaluation has a dead time due to its physical characteristics, and it takes time to recover the potential difference to a sufficiently high value.

A high radiation area refers to an area within the radiation control area where the external radiation dose rate at a distance of 30 cm from the surface of the radiation source or shielding body exceeds or is likely to exceed 1 mSv/hr. The amount of time the detection system that records the event is unable to record an event after another initial event has been recorded.

Due to this dead time, a typical radiation detector in a high-radiation zone environment cannot distinguish between a preceding event and a successive event of a subsequent event, resulting in a pile-up event in which event loss or partial fit is recorded instead.

Therefore, it is necessary to implement an environment in which a general radiation detector can analyze decommissioned waste or measure in a high-radiation area.

Korean Utility Model Publication No. 20-0457203

SUMMARY OF THE INVENTION An object of the present invention is to provide a radiation shielding device capable of creating an environment in which a general radiation detector can normally operate and measure in an environment in a high radiation area.

The technical problems to be solved by the present invention are not limited to the technical problems mentioned above, and other technical problems not mentioned will be clearly understood by those of ordinary skill in the art to which the present invention belongs from the description below. will be able

The present invention for achieving the above object forms a tetrahedron of a hollow structure, a body having a built-in radiation detector; holes formed on each side of the body for introducing radiation into the inside of the body; And it is installed in each hole and rotates, it includes a shielding blade for controlling the amount of radiation flowing into each hole.

More specifically, the radiation detector may be installed at a position shielded from radiation when the shielding wings are placed in a diagonal direction on each side of the body.

The shielding wing may have a lead plate material embedded at both ends, respectively.

According to the present invention, by adjusting the rotational speed of the shielding wing, an environment is created inside the body in which a general radiation detector can operate normally in an environment in a high-radiation area to measure, thereby measuring, monitoring, and analyzing radioactivity, so that the exposure dose of the operator is achieved. can be accurately predicted in advance.

1 is a view showing a radiation shielding device of the present invention.
2 and 3 are views each showing an internal appearance after separating the upper surface in the present invention.
Figure 4 is an exploded view showing the shielding wing in the present invention.
5 is a view showing a state in which the shielding blade rotates and shields the radiation detector in the present invention.
6 is a view showing a state in which the shielding wing rotates and exposes the radiation detector in the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Identical elements in the drawings are denoted by the same reference numerals wherever possible. In addition, detailed descriptions of well-known functions and configurations that may unnecessarily obscure the gist of the present invention will be omitted.

1 to 3 , the radiation shielding device of the present invention includes a body 10 and a shielding wing 20 . The body 10 forms a tetrahedron of a hollow structure, and the shielding wings 20 are rotatably installed on each side of the body 10 . The radiation detector 30 for measuring and monitoring radioactivity and analyzing nuclides is installed inside the body 10 .

The body 10 and the shielding wing 20 are made of a material having excellent radiation shielding ability, and preferably made of an aluminum material. The radiation detector 30 may be a Nal (TI) radiation detector, which is a general radiation detector that measures and monitors radioactivity and analyzes nuclides.

As illustrated in the figure, the body 10 may be a hexahedron, and is designed to have a thickness sufficient to sufficiently shield radiation, and a hole 40 is formed on each side thereof. At this time, the hole 40 is not formed on the lower surface because the body 10 faces the floor when installed in a high-radiation zone environment, but the hole 40 is formed when the body 10 is placed in the air through the support angle. can be

As described above, the holes 40 formed on each side of the body 10 introduce radiation into the interior of the body 10 from the front, rear, left, right, and top of the body 10 so that the radiation detector 30 can measure the radiation. .

The shield wing 20 is installed in each hole 40 and rotates in place. In each hole 40, a support 11 is formed from each side of the body 10 across each hole 40, and a shielding wing 20 is installed on the support 11 to rotate in place.

A driving motor 50 is installed on the support 11 and connected to the shielding wing 20 , and the shielding wing 20 is rotated by the driving of the driving motor 50 . The driving motor 50 may be a servomotor with precise and easy control of the position and rotational speed (RPM) of the shielding wing 20 .

The shielding wing 20 rotating by the driving of the driving motor 50 adjusts the amount of radiation flowing into each hole 40 so that the radiation detector 30 can measure radiation in the high-radiation area environment.

That is, the shielding wing 20 adjusts the opening/closing rate of each hole 40 according to the rotation speed so that the radiation detector 30 can measure radiation in an environment in the high-radiation area. As the rotation speed of the shielding wing 20 increases, the opening rate of each hole 40 decreases and the shielding rate increases. Accordingly, as the rotational speed of the shielding wing 20 increases, the amount of radiation introduced into each hole 40 is reduced.

In this case, the radiation detector 30 is preferably installed at a position shielded from radiation when the shielding wings 20 are placed in a diagonal direction on each side of the body 10 . That is, as illustrated in FIG. 2 , the radiation detector 30 is located on the diagonal of the lower surface between the front and right sides of the body 10 so that the shielding wings 20 are diagonally from each side of the body 10 . It is preferably shielded from radiation when placed.

In this way, the radiation detector 30 is installed in a position to be shielded when the shielding wing 20 is placed in a 45 degree diagonal direction on each side of the body 10, so that the shielding rate for the radiation detector 30 is each hole 40 It can be done in the same way, so that the radiation detector 30 can perform accurate radioactivity measurement and nuclide analysis in the direction of each side of the body 10 .

On the other hand, the shielding wing 20 can increase the radiation shielding rate by embedding the plate material 21 made of lead material at both ends, respectively. The shielding wing 20 forms an accommodating groove 23 for accommodating the lead plate material 21 at both ends, and covers and closes the accommodating groove 23 with a cover, so that the lead plate material 21 at both ends, respectively. can be embedded. The shielding wing 20 expands the area of both ends to sufficiently cover the radiation detector 30 to increase the shielding rate, and the extended both ends form a circle, thereby reducing rotational resistance.

As illustrated in FIG. 4 , the shielding wing 20 has a circular shape having a receiving groove 23 for accommodating the lead plate material 21 , and the shielding portions 25a forming both ends of the shielding wing 20 . ) and the wing body 25 consisting of a connection part 25b connecting the shielding parts 25a, and the wing body 25 having the same shape as the wing body 25 and being coupled to the wing body 25 to cover the receiving groove 23 (26) can be made. The shielding wing 20 can adjust the number of plates 21 accommodated in the receiving groove 23 according to the environment in the high radiation area.

The radiation detector 30 is located at a height that the shielding wing 20 can sufficiently shield, and as illustrated in the figure, the radiation detector 30 is located at the tip of the support rod 35 erected from the lower surface of the body 10 . It is installed and the shielding wing 20 may be located at a height that can be sufficiently shielded.

As shown in Figures 5 and 6, the radiation shielding device of the present invention as such enters the environment in the high-radiation zone in a state in which the shielding wing 20 covers the radiation detector 30. Under the control of the driving motor 50, the shielding wing 20 in each hole 40 is stopped while covering the radiation detector 30, and thus the radiation detector 30 from each hole 40 through the shielding wing 20 ) is not exposed, and the shielding device of the present invention enters the decommissioning waste target facility, which is, for example, a high-radiation area.

The shielding device of the present invention that has entered the high-radiation zone environment is driven by the driving motor 50 to rotate the shielding wing 20 to shield and expose the radiation detector 30 from each hole 40. do.

The radiation detector 30 measures the radiation flowing in from each hole 40 formed on the 5 sides of the body 10 while the shielding wing 20 rotates, and the radiation detector 30 determines the dead time and the direction of the radiation. When measured, the driving motor 50 is driven so that the radiation detector 30 reaches the dead time or less, so that the shielding wing 20 rotates at a higher speed. As the rotation speed of the shielding wing 20 increases, the shielding rate of the radiation detector 30 increases and the amount of radiation introduced into the body 10 through each hole 40 decreases.

As such, when the radiation detector 30 reaches less than the dead time due to the increase in rotation of the shielding wing 20 , the radiation detector 30 measures the radiation and analyzes the nuclide.

As described above, according to the present invention, by adjusting the rotational speed of the shielding wing, an environment is created inside the body in which a general radiation detector operates normally in an environment in a high-radiation area and can be measured, thereby measuring, monitoring, and analyzing radioactivity. It is possible to accurately predict the exposure dose of workers in advance.

The present invention has been looked at with a focus on preferred embodiments, and those of ordinary skill in the art to which the present invention pertains can implement embodiments other than the detailed description of the present invention within the essential technical scope of the present invention. will be able Here, the essential technical scope of the present invention is indicated in the claims, and all differences within the scope equivalent thereto should be construed as being included in the present invention.

10: body 11: support
20: shield wing 21: lead material plate
23: receiving groove 25: wing body
25a: shielding part 25b: connecting part
26: cover 30: radiation detector
35: support rod 40: hole
50: drive motor

Claims (3)

a body with a built-in radiation detector;
a hole formed in the body and through which radiation is introduced into the body; and
It is installed in the hole and includes a rotating shielding wing,
The body constitutes a tetrahedron of a hollow structure, and the radiation detector is installed inside the tetrahedron,
The hole is formed on each side of the body, and the radiation passes through each side of the body through each hole and flows into the inside,
The shielding wing is installed in each hole and is located on each side of the body,
As each of the shielding wings rotates, a lead plate is embedded in both ends of each shielding wing that shields the radiation detector, and receiving grooves for accommodating the plate are formed at both ends, and the receiving groove is covered with a cover to cover the plate. built in,
Each of the shielding blades is stopped so that one of the two ends enters the radiation zone while shielding the radiation detector, and with rotation of each shielding blade, the two ends repeatedly shield and expose the radiation detector The radiation shielding device, characterized in that the radiation detector measures the radiation without a dead time by increasing the rotation speed of each shielding blade to increase the shielding rate of the radiation detector.
According to claim 1,
The radiation detector is a radiation shielding device, characterized in that installed at a position shielded from radiation when the shielding wings are placed in a diagonal direction on each side of the body.
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