JPS63118683A - Liquid scintillation counter - Google Patents

Abstract

PURPOSE:To prevent the influence of background such as radioactive substances existing in the outside air by covering a vial with a vial cap. CONSTITUTION:A vial 10 is covered with a vial cap 40 on a turntable 22 and is moved to a carrying-in hole 22a. Simultaneously, a lower turntable 28 is half rotated to move a vial holding pocket 21 to a position under the carrying-in hole 22a. Then, the table 28 is operated, and a pinion 38 raises a moving rod 36 and lowers the rod 36 with the vial 10 on its front end. Thus, the vial covered with the cap 40 is stored in the pocket 32. Next, the table 28 is moved by half rotation furthermore, and an elevator part 26 is operated to supply the vial 10 to a measuring part 34. This measuring part 34 is provided with photomultipliers 12-1 and 12-2 to detect the quantity of emitted light. Thus, the influence of background is prevented.

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Application Field] The present invention relates to a liquid scintillation counter, and particularly to a liquid scintillation counter that measures the radiation dose of a low-energy β-ray emitting nuclide using a liquid scintillator.

[Prior Art] A liquid scintillation counter is well known, which measures radiation by mixing a radioactive substance into a liquid scintillator as a phosphor and detecting the amount of fluorescence emitted. energy β
Good measurements of lines, etc. have been made.

As shown in FIG. 2, this liquid scintillation counter performs two-stage excitation using a liquid scintillator containing primary and secondary phosphors in a vial 10, and the light emitted by this excitation is emitted from a photomultiplier tube 12. supplied to Generally, two photomultiplier tubes 12 are provided, and the fluorescent pulses manually applied to these two photomultiplier tubes 12-1, 12-2 are passed through an amplifier 14-1, 14-2 via a The signal is supplied to the coincidence counting circuit 16. Therefore, photomultiplier tube 1
Fluorescence pulses are input at the same time at 2 and counted as radiation pulses at 6 o'clock, and the radiation dose is measured by the pulse analysis circuit 18. By counting the input pulses simultaneously in this way, it is possible to satisfactorily remove electrical noise generated by photomultiplier tubes and the like, and to accurately measure radioactivity.

[Problems to be solved by the invention] However, since such scintillation counters measure extremely low-level radiation doses, the background has a large effect on the measured values, making it difficult to perform accurate measurements. be.

In recent years, new construction materials such as gypsum board and rock wool have been used, and the large amount of radium contained in these materials produces 222Rn and its daughter nuclides, and when these radionuclides are mixed into the air, the measured values become background. It has become a problem as a new background.

Furthermore, there is a problem in that static electricity is generated on the surface of the vial due to air convection when the vial is fed to the measuring section, and this static electricity affects the background value.

Purpose of the Invention The present invention has been made in view of the above-mentioned conventional problems.
The objective is to provide a liquid scintillation counter that can accurately measure low-energy radiation while reducing background effects caused by the vial being placed in air.

[Means for Solving the Problems] In order to achieve the above object, the present invention mixes a radioactive substance and a liquid scintillator in a vial, and detects the amount of luminescence generated at this time with a photomultiplier tube. , a liquid scintillation counter for measuring radiation, comprising a vial cap that covers the vial so as to shield it from external air, and detecting the amount of light emitted in the vial while covered with the vial cap.

[Function] According to the above configuration, the vial containing the measurement sample is covered with a vial cap before being sent to the measurement section, or the vial cap is placed and fixed in the measurement section in advance. The vial is supplied to a measuring section, and the amount of light emitted within the vial is detected in this measuring section.

Therefore, the vial cap significantly reduces the background influence of radioactive substances such as radon present in the air and static electricity adhering to the vial surface on the measured values, making it possible to accurately measure radiation of low-energy β-ray emitting nuclides. be exposed.

[Embodiments] Hereinafter, preferred embodiments of the present invention will be described based on the drawings.

FIG. 1 shows a cross-sectional view and a top view of the liquid scintillation counter, in which a vial 1O containing a measurement sample is placed on the right side of the counter body 20, and a vial 1O containing a sample to be measured is placed on the right side of the counter body 20.
A turntable 22 is provided for feeding up to 2a. Then, this turntable 22 is connected to a motor 24.
The measuring vial 10 is fed to the measuring section from the loading port 22a by sequentially rotating the measuring vial 10 at the lower turntable 28 which serves as the elevator section 26.

That is, the lower turntable 28 is rotationally driven by the driving section 30, so that the elevator section 26 and the vial holding pocket 32 reciprocate below both the turntable 22 and the measuring section 34.

The elevator section 26 has a rack and pinion configuration, and a pinion 38 is attached to the lower side of the vial holding pocket 32 with respect to a movable rod 36 provided as a rack. Therefore, by rotating the pinion 38 via a motor (not shown), the moving rod 36 moves up and down, and the vial 10 can be taken down from the turntable 22 and fed to the measuring section 34 by the moving rod 36. Become.

A characteristic feature of the present invention is that the background factor caused by placing the vial 10 in the air is eliminated, and the vial 10 is provided with a vial cap 40.

This vial cap 40 is tilted to cover the entire vial 10 placed on the turntable 22, and is configured to be fed to the measuring section 34 on the lower turntable 28 with the vial cap 4o still on. ing.

The present embodiment has the above configuration, and its operation will be explained below.

First, as mentioned above, vial 1o is turntable 2.
2 is covered with a vial cap 4o, and the entrance 22a is opened.
Move up to. At the same time, the lower turntable 28 rotates approximately half a turn to move the vial holding pocket 32 to below the loading port 22a. Then, the elevator section 26 is activated, and the binion 38 raises the moving rod 36, places the vial 10 on the tip thereof, and lowers it. In this manner, the vial 10 covered with the vial cap 40 is accommodated in the vial holding pocket 32.

Next, the lower turntable 28 is further moved approximately half a turn, and the elevator section 26 is again operated here to feed the vial 10 to the measuring section 34.

A photomultiplier tube 12-1, 12-2 is disposed in the measuring section 34, and the amount of light emitted is detected by this.

In this way, the background was measured with the vial cap 40 covered, and the results were as follows.

That is, the average of 10 background measurements performed on three channels A, B, and C was as shown in the following table.

As is clear from this table, it is better to measure with the vial cap 40 set aside than to measure as it is.
It can be seen that the amount of background is significantly reduced. This is because the vial cap 40 prevents radioactive substances such as radon present in the air from being adsorbed to the vial surface, and also prevents the generation of static electricity on the vial surface without causing air convection near the vial. It is.

The vial cap 40 is arranged to cover the vial on the turntable 22, but in the present invention, the vial cap 40 may be attached to the measuring section 34, thereby avoiding air contact with the vial 10 from the outside. By doing so, the effects of radon etc. can be eliminated.

[Effects of the Invention] As explained above, according to the present invention, since the vial is covered with a vial cap, background effects caused by radioactive substances and static electricity present in the outside air can be prevented. The key is to accurately measure radiation at low energy levels.

[Brief explanation of the drawing]

FIG. 1 shows a liquid scintillation counter according to the present invention, (a) is a longitudinal sectional view thereof, (b) is a top view thereof, and FIG. 2 is a block diagram showing a schematic configuration of a conventional device. 10... Vial 12... Photomultiplier tube 22... Turntable 26... Elevator part 28... Lower turntable 34... 7ilIj fixed part 36... Moving rod 38... Pinion 40... Vial cap.

Claims (3)

[Claims] (1) In a liquid scintillation counter that measures radiation by mixing a radioactive substance and a liquid scintillator in a vial and detecting the amount of light emitted at this time with a photomultiplier tube, the A liquid scintillation counter comprising a vial cap that covers a vial, and detecting the amount of luminescence inside the vial while the vial is covered with the vial cap. (2) In the counter described in claim (1),
A liquid scintillation counter characterized in that a vial placed on a turntable for temporary placement is covered with a vial cap, and the vial is supplied as is to a radiation-shielded measuring section on a lower turntable having an elevator. (3) In the counter described in claim (1),
A liquid scintillation counter characterized in that the vial cap is disposed in a vial feeding section of a measuring section.