JPS62282287A - Method and apparatus for measuring radioactivity level under high background - Google Patents

Abstract

PURPOSE:To perform the measurement of a radioactivity level with high accuracy and high efficiency and to minimize the quantity of waste contaminated with radioactivity, by detecting radioactive rays at two or more positions and calculating the difference between the detection valves at said positions. CONSTITUTION:A radiation detector 1 and a radiation detector 2 are respectively arranged at positions separated by distances l1, l2 from the concrete disassembling waste at disassembling work site of a nuclear facility such as an atomic reactor successively carried by a belt conveyor 4. The count values of the detectors 1, 2 respectively consist of the contribution part due to the concrete disassembling waste 3 and that due to a background but, by calculating the difference between the count values of the detectors 1, 2, the contribution part from the concrete disassembling waste 3, that is, a radioactivity level can be known regardless of the contribution parts due to the background.

Description

[Detailed Description of the Invention] 3. Detailed Description of the Invention [Field of Industrial Application] The present invention relates to the measurement of radioactivity levels in radioactive waste, etc., and is particularly applicable to demolition work sites of nuclear facilities such as nuclear reactors. The present invention relates to a method and apparatus for measuring radioactivity levels under high background conditions, which are ideal for measuring radioactivity levels in concrete demolished debris, etc.

(Prior Art) A huge amount of concrete demolition debris is generated during the demolition work of nuclear facilities such as nuclear power plants, and there is a strong possibility that this concrete demolition debris is contaminated with radioactivity.

The source of contamination of concrete in nuclear power plants is mainly induced radioactivity produced by nuclear reactions between neutrons, especially thermal neutrons, that have passed through the reactor pressure vessel and the atomic nuclei of the materials that make up the concrete. Therefore, the level of induced radioactivity in the concrete is high near the reactor because the neutron flux is high, but the neutron flux is attenuated in the concrete, so the concentration of induced radioactivity decreases rapidly as you move away from the reactor.

This means that the concrete with a high level of contamination is limited to some concrete around the reactor; most of the concrete outside the secondary shield or bioshield has very low levels of contamination or no contamination at all. It shows what can be said.

If we can measure the contamination level of this huge amount of concrete demolition debris, rationally categorize it according to its contamination level, and manage, store, and dispose of it according to each contamination level, it will reduce the cost of waste management. In turn, this can lead to cost reductions for nuclear power generation itself.

By the way, the radioactivity level of the generated concrete demolition waste is measured on the spot, and depending on the level, it is classified as -FQ waste, scraped bell waste, low level waste, medium level waste, etc. It would be more rational to separate them. This is because if a certain amount of concrete demolition debris is pooled and then divided into sections, the amount of work will be extremely large.

Places where such concrete demolition debris occurs are often places with a high radiation density, that is, under high background. Therefore, the measurement of radioactivity levels in concrete demolition debris is hidden by high background counts, making it difficult to evaluate only the contribution from the target concrete demolition debris, and the measurement accuracy is extremely poor. As a result, when classifying contamination levels, we are forced to make decisions on the safe side, and end up classifying them into higher levels.

Conventionally, radiation measurement under background
For example, when using a 1it unregistered device, these values are checked during actual measurements to eliminate the effects of cosmic rays or weak radioactivity contained in the device itself. , proportional counters, 0M counters, etc., even if the radiation source is removed, a small amount of background is counted, and this background changes from day to day, so this value should be measured before and after the main measurement. Or, if the background is extremely high, the area around the counter tube is covered with an iron plate or lead block to prevent the background from being counted. In addition, when measuring the radioactivity level of concrete demolition debris generated during the demolition work of nuclear facilities, the radioactive contamination level is estimated by manually measuring the gamma ray dose using a 0M counter for 1 batch of concrete demolition debris. Is going.

[Problem that the invention seeks to solve]

However, when measuring radioactivity levels using an ionization chamber, proportional counter, GM counter, etc., background values are measured before or after the actual measurement in order to eliminate the influence of background. With conventional methods of measurement, background values are measured as the work progresses at work sites such as nuclear facility demolition sites where a huge amount of concrete demolition debris of various sizes is contaminated with various levels of radioactivity. fluctuates, and it would take a long time to measure it sequentially.

In addition, even if the counter tube is covered with a shielding material such as lead, it is not possible to completely remove the background.Furthermore, the dose of gamma rays is measured manually using a 0M counter tube for each corbel of concrete demolition. In the conventional method of estimating the contamination level, since the amount of concrete demolished waste is enormous, the batch size itself has to be increased to some extent in order to streamline the sorting by contamination level, which requires detailed sorting. I won't be able to do it. Therefore, for example, if part of a batch of concrete demolished waste is contaminated, the entire batch will be treated as contaminated concrete, resulting in an increase in the amount of radioactively contaminated waste.

The present invention is intended to solve the above problems, and it is possible to measure radioactivity levels with high precision and efficiency even under a high background, and it is possible to measure radioactivity levels according to the radioactive contamination level of the target object. It is an object of the present invention to provide a method and apparatus for measuring radioactivity levels under high background conditions, which enable fine classification and minimize the amount of radioactively contaminated waste.

〔Example〕

Examples will be described below with reference to the drawings.

FIG. 1 is a diagram showing an embodiment of the radioactivity level measuring method of the present invention, where 1 and 2 are radiation detectors, 3 is a concrete demolition bin, and 4 is a belt conveyor.

In the figure, the detector 1 is located at a distance β1 from the concrete demolishing bin 3, and the detector 2 is located at a distance β1 from the concrete demolishing bin 3.
Place it at a distance of 12 from.

It is assumed that the concrete demolished debris 3 is sequentially transported by, for example, a belt conveyor 4.

Next, to explain the measurement principle, of the count CI of detector l, the contribution from concrete demolition debris is a5. Letting b be the contribution due to the background, c,=a,+b. Similarly, the count c2 of detector 2 is Ct=+3, where a2 is the contribution from concrete demolition debris. +
l) Here, from the positional relationship of each detector, C, -c! = ii, -at (12+ 1 +) (1K-11) (1-t+1+) C1t-1+), and from the count values CI and C2 of each detector 1.2, the contribution from concrete demolition debris a, , a2 can be determined, and the radioactivity level of concrete can be determined regardless of the contribution from the background.

In the above embodiment, two detectors were used to measure the radioactivity level at different distances from the concrete demolition bin 3, but it goes without saying that one detector may be used at different times.

As described above, background effects can be removed by measuring radioactivity levels at different distances from the concrete demolition bin, but in reality, the count values in each measurement are subject to errors such as chance errors. Therefore, if the background b is very thick compared to the contribution a from concrete demolition debris (a < l), the error in each measurement will be approximately 5, and according to the law, the error propagation is twice. The error in the measurement of is a stone. Therefore, for example, if the final error of a is about 10%, then f'maku - Therefore, a2 b< -.For example, if the count number of a is about 1000, the background counting will be reduced. We have to keep it below about 5,000.

FIG. 2 shows an embodiment in which the accuracy is improved by suppressing the contribution caused by the background in this manner.

Figure 2 shows an example in which the detector is covered with a lead shield in order to improve measurement accuracy by suppressing background contributions, and the same reference numbers as in Figure 1 indicate the same contents. In Figure 6, 5.6 is a lead shield.

In the figure, the shielding body 5.6 is not intended to completely shield the detector, but can be used in conjunction with the method of measuring the radioactivity level by varying the distance from the demolition bin 3, and by shielding the detector. This makes it possible to suppress the value of b below a predetermined value and keep the error of a within a predetermined range, and the measurement method is the same as in the case of FIG.

FIG. 3 shows the overall configuration of the radioactivity level measuring device according to the present invention, and the same reference numbers as in FIG. 2 indicate the same contents, 7 is a detector control device, 8 is a calculator, 9 is a sorter, 1
0 is medium level waste conveyor, 11 is low level waste conveyor, 12 is very low level waste conveyor, 13 bar-s
It is a waste conveyor.

In the figure, a detector control bag W7 controls the position of the detector, moves it, and sets it at a predetermined position.

The data obtained from the detector is input manually to the calculator 8, where calculations as described above are performed, background contributions are removed, and the radioactivity level of the concrete demolished debris 3 is measured. Based on the radioactivity level measured in this way, the sorter 9 separates the waste into medium-level waste, low-level waste, extremely low-level waste, general waste, etc., according to the radioactivity level, and the waste is sorted by the respective belt conveyors. Sort it out. In this way, by combining a calculator as an information processing device and a classification device for each radioactivity level,
Wasteful (concrete demolition debris) can be sorted quickly and automatically.

〔Effect of the invention〕

As described above, according to the present invention, it is possible to remove background contributions and measure radioactivity levels with high accuracy. This can prevent them from being separated into different categories.

In addition, by classifying the measurement object in real time according to the measured radioactivity level, for example, a huge amount of concrete demolition debris that occurs at the demolition site of a nuclear facility, it is possible to distinguish high-level contaminated areas, low-level contaminated areas, It becomes easy to separate areas that are not contaminated, and it is possible to appropriately manage, store, and dispose of waste according to the level of contamination.

Q! Since it can be mechanically sorted at high speed, it is possible to measure waste in small chunks.In order to streamline sorting according to the contamination level of vast amounts of concrete demolition debris, unlike conventional methods, the size of the batch itself can be reduced. By increasing the amount of radioactive waste, it is no longer necessary to treat the entire concrete demolished bunch as contaminated concrete, even if a part of it is contaminated, and as a result, the amount of radioactively contaminated waste can be minimized.

[Brief explanation of the drawing]

FIG. 1 is a diagram showing an embodiment of the radioactivity level measuring method of the present invention, FIG. 2 is a diagram showing another embodiment of the present invention in which the detector of FIG. 1 is shielded with a shielding body, and FIG. FIG. 1 is a diagram showing an embodiment of the radioactivity level measuring device of the present invention.

Claims (9)

[Claims] (1) Changed the distance from the radiation source to the radiation detector 2
Radioactivity under high background, which is characterized by detecting radiation at more than one location and determining the difference between the detected values at each location to remove the influence of the background and measure the radioactivity level of the radiation source. Level measurement method. (2) The radioactivity level measuring method under high background according to claim 1, wherein the radiation detection at the two or more positions is performed using a plurality of detectors. (3) The radioactivity level under high background according to claim 1, wherein the radiation detection at the two or more positions is performed using one detector at different times. Measuring method. (4) The radioactivity level measuring method under high background according to any one of claims 1 to 3, wherein the radiation detector is shielded with a shielding body. (5) A radiation detector, a detector position control device that controls the position of the radiation detector, and each radiation detected at two or more positions with different distances from the radiation source set by the detector position control device. A radioactivity level measuring device under high background, comprising an information processing means that calculates the radioactivity level of a radiation source from the difference in detected values and performs classification according to the calculated radioactivity level. (6) A high backrest according to claim 5, characterized in that a plurality of the radiation detectors are provided and are arranged at different positions from each other at different distances from the radiation source by the detector position control device. Radioactivity level measuring device below the ground. (7) The radiation detector is provided in one piece, and the detector position control device detects radiation at two or more positions at different distances from the radiation source at different times. A radioactivity level measuring device under high background according to item 5. (8) The radioactivity level measuring device under high background according to any one of claims 5 to 7, wherein the radiation detector is shielded by a shielding body. (9) The radioactivity level measuring device under high background according to claim 5, wherein the information processing means drives and controls a distributing device that distributes the radiation sources for each calculated radioactivity level. .