JP2003315461A - Radioactive dust monitor and device for judging recyclability of filter paper for radioactive dust monitor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a radioactive dust monitor capable of reducing use amount of long filter paper and a device for judging the recyclability of used filter papers. <P>SOLUTION: In the dust monitor, a rewinding motor 17 is coupled with a supply pulley 9 and a tension roller 11 is combined with a filter sending roller 2 as a filter carriage part. With the use of a flow rate value from a flow meter 4 and a negative suction pressure value from a pressure meter 5, a fluid resistance value is calculated, which is compared with a threshold value for recycling. The count value of a radiation detector 8 is also compared with a threshold for recycling. If both are below threshold values, pressurization by the tension roller 1 is stopped and the long filter paper 1 is rewound by the rewinding motor 17 for reusing. Recyclability judgment devices are categorized into one for judging by only the fluid resistance value and one judging by the fluid resistance value and the count value depending on the data of remaining filter paper. <P>COPYRIGHT: (C)2004,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a measuring technique for measuring the concentration of radioactivity existing in the air of a facility for handling radioactive substances.

[0002]

2. Description of the Related Art Radioactive dust monitors pass air at a monitoring point of a radioactive material handling facility through a filter paper,
The dust floating in the air is collected on the filter paper, the radiation from the collected dust is detected by the radiation detector, and the monitoring point is determined by the amount of air passing through the filter paper and the detection signal of the radiation detector. This is a device for measuring and monitoring the radioactivity concentration existing in the air of.

FIG. 7 is a perspective view showing the structure of an example of a dust collecting portion of a conventional radioactive dust monitor. In this example, as a filter paper for collecting dust, a long filter paper 1 supplied from a supply pulley 9 and wound around a winding pulley 10
Is used. This long filter paper 1 is a motor (M) 7
Is continuously and intermittently conveyed in the direction of the arrow by a pair of filter paper feed rollers 2 coupled to and driven by. The supply pulley 9 is constantly braked, and the take-up pulley 10 is connected to the motor (M) 7, so that the long filter paper 1 is conveyed at a predetermined speed without slack. An intake head 3 and a radiation detector 8 are arranged to face each other with the long filter paper 1 sandwiched therebetween at an intermediate position between the supply pulley 9 and the take-up pulley 10, and the intake head 3 comes into contact with the long filter paper 1 to prevent radiation. A space is provided between the detector 8 and the long filter paper 1 for supplying air to the dust collecting portion of the long filter paper 1. A suction pump 6 for sucking air is connected to the intake head 3 by piping, and a flow meter (FI) for measuring the flow rate of the air sucked by the intake head 3 is provided in the middle of the piping.
4 and a pressure gauge (PI) 5 for measuring the suction negative pressure on the intake side of the suction pump 6 are attached.

When the suction pump 6 is activated, the air in front of the suction head 3 is sucked through the long filter paper 1, and as a result, the dust in the air in front of the suction head 3 is applied to the surface of the long filter paper 1. Are captured. Since air at the monitoring point is introduced to the front surface of the intake head 3 by a pipe or the like (not shown), dust floating in the air at the monitoring point is collected on the surface of the long filter paper 1.

FIG. 8 is an explanatory view showing a dust collecting state of the long filter paper 1 which is most commonly used in the conventional radioactive dust monitor. Usually, a long filter paper 1 having a width of 75 mm is used, and the intake head 3 is manufactured so that a 50 mm width portion at the center thereof serves as the dust collecting area 101 (the shape of the intake port of the intake head 3 is 50 mm. × 50mm). Further, the conveying speed of the long filter paper 1 (in this section, "the conveying speed of the long filter paper 1" is simply referred to as "conveying speed" hereinafter) is set to a constant value, which is set to 25 mm / h. The most common. The dust collecting state on the long filter paper 1 is as shown in FIG.
The dust collection starts from the dust collection start position 102, and the dust is collected in a portion having a width of 50 mm on the right side thereof, that is, a hatched portion. In FIG. 8, this portion is shown as "a portion 103 for collecting dust". This portion extends to the right as the long filter paper 1 is conveyed, for example, at a speed of 25 mm / h.

The measurement target of the radioactive dust monitor is the radioactivity concentration existing in the air at the monitoring point,
The radioactivity concentration is indicated by the ratio of radioactivity contained in a fixed volume of aspirated air. Therefore, a flow meter 4 for measuring the flow rate of the sucked air is attached in the middle of the pipe, and the output condition of the suction pump 6 is controlled by the output signal so that the air flow rate is always maintained at a constant value. is doing.

As shown in FIG. 9, the suction pump 6 has a fixed suction negative pressure-air flow rate characteristic when the driving conditions are constant, and when the driving frequency is increased, the suction negative pressure value is the same. When the flow rate value increases and the drive frequency is lowered, the flow rate value for the same suction negative pressure value decreases. Therefore, in order to control the air flow rate to a constant value, it is necessary to control the drive frequency of the suction pump 6 by increasing or decreasing the concentration of dust existing in the air at the monitoring point. When the long filter paper 1 is conveyed at a constant speed, if the dust concentration increases, the amount of dust collected on the filter paper increases and the fluid resistance of that portion increases, so the drive frequency of the suction pump 6 is increased. Then, the suction negative pressure is increased to maintain the air flow rate at a constant value. When the dust concentration is low, the amount of collected dust is reduced and the fluid resistance is reduced. Therefore, the driving frequency is lowered, the suction negative pressure is reduced, and the air flow rate is maintained at a constant value.

Both the air flow rate and the conveying speed are set to constant values in order to keep the trapping condition of the trapped dust, which is the object of measurement by the radiation detector 8, constant. The fluctuation of the air flow rate and the fluctuation of the transport speed are both fluctuations in the collection condition of the collected dust, and are coefficients for calculating the radioactivity concentration from the radiation count rate value obtained from the output signal of the radiation detector 8. To decrease the measurement accuracy.

The set value of the air flow rate is determined from the condition for obtaining the radioactivity concentration with desired measurement accuracy. 25 mm /
The transport speed set to h is a transport speed that satisfies the condition that the dust trapping portion of the long filter paper 1 can secure a necessary air flow rate even if the air having the assumed highest dust concentration is sucked. . When collecting dust at this transportation speed, the maximum dose rate value of the radiation detected by the radiation detector is smaller than the upper limit dose rate value at which the radiation detector can detect the radiation with a predetermined detection accuracy. It is supposed.

Although a circular radiation detector 8 is shown in FIG. 7, the shape of the sensitive portion of the radiation detector 8 is the same as the shape of the suction port of the suction head 3, and the shape of the dust collecting portion. The shape does not need to be the same as that of the above, and may be any shape as long as accurate sensitivity calibration is possible. An example of the shape and dimensions shown in FIG. 7 is as follows:
The shape of the dust collecting portion is 50 mm × 50 mm, whereas the shape of the sensitive portion of the radiation detector 8 is φ50 mm.

In the above description, the case where the long filter paper 1 is continuously conveyed has been described, but there are cases where the long filter paper 1 is intermittently conveyed. In this case, at regular time intervals,
For example, the long filter paper 1 is conveyed every two hours by the length of the shape of the dust collecting portion, and the other points are exactly the same. There is also a radioactive dust monitor and a radioactive dust sampler that use fixed filter paper that is cut into the shape of the dust collecting portion without using long filter paper. A radioactive dust sampler is a device for collecting radioactive dust. The filter paper collected by the device for a predetermined period of time is collected and the radiation emitted from the collected dust is measured by another radioactivity measuring means.

[0012]

In the conventional radioactive dust monitor using the long filter paper as described above, the dust trapping portion does not become clogged even at the assumed maximum dust concentration, and The radiation detector can detect radiation normally even at the maximum expected radioactivity concentration,
In order to satisfy the condition, the above-mentioned transport speed of 25 mm / h is set. Therefore, the radioactive dust monitor according to the prior art consumes a large amount of long filter paper and requires a large amount of operating costs. Furthermore, since the long filter paper after measurement becomes radioactive waste, its large consumption is a problem.

The same applies to a radioactive dust monitor and a radioactive dust sampler using a fixed filter paper. In order to alleviate these problems, an object of the present invention is to provide a radioactive dust monitor capable of reducing the consumption of long filter paper while ensuring the condition that the radioactivity concentration in the air to be measured can be measured with a predetermined accuracy. It is to provide a filter paper recycling possibility determination device for radioactive dust monitor that determines whether or not the used filter paper can be reused and recycles the used filter paper (hereinafter,
It is to provide a filter paper recycling determination device).

[0014]

[Means for Solving the Problems] The radioactive dust monitor is
Since this is a device that measures and monitors the radioactive contamination of the air at the monitoring points of radioactive material handling facilities, when the radioactive material handling facilities are operating normally, the amount of dust collected during most of the time It is small and the normal operating state occupies most of the operating time. Therefore, it is highly possible that the filter paper once used can be reused. The condition for reuse of used filter paper is that the radioactive dust monitor works properly even if the filter paper is used, that is, it does not become clogged when reused and the accuracy of the radioactivity concentration to be detected. Can be maintained within a predetermined accuracy. In order to prevent clogging, it is necessary that the amount of dust collected during use is within the allowable limit, in other words, the measured fluid resistance value is within the allowable limit. In order to maintain the inside, it is necessary that the collected amount of radioactive dust is within the allowable limit, in other words, the measured value of radioactivity concentration is within the allowable limit.

The present invention is intended to utilize the high reusability of the filter paper used in the radioactive dust monitor as described above, and determines whether or not the reused filter paper can be reused depending on the above two conditions. judge. The invention of claim 1 relates to a radioactive dust monitor using a long filter paper, and the inventions of claim 2 and subsequent inventions relate to a filter paper recycle determination device for reusing an existing filter paper.

Incidentally, since all the data of the radioactivity concentration measured with the used filter paper are usually stored, is the maximum value of the radioactivity concentration measured value of the used filter paper below the allowable upper limit value for reuse? In many cases, it is possible to determine in advance whether or not it is possible to determine whether most of the used filter paper can be reused by simply measuring the fluid resistance. According to the first aspect of the invention, a suction pump causes air at a monitoring point of a radioactive substance handling facility to pass through a dust collecting portion of a long filter paper that is continuously or intermittently conveyed, and floats in the air. Radioactive dust for collecting dust in the dust collection part, detecting the radiation emitted from the collected dust with a radiation detector, and continuously measuring the radioactivity concentration existing in the air at the monitoring point. A monitor, which is a fluid resistance measuring means for measuring the fluid resistance of the long filter paper through which the air at the monitoring point is passing, and the fluid resistance measurement value by this means and the radioactivity concentration measurement value by the radiation detector. Compared with each allowable upper limit for use, if any measured value is less than or equal to each allowable upper limit, the long filter paper can be reused Comprising a reuse determination unit that determines, by the determination of the re-usable means return the filter paper winding unwinding the elongate filter paper, the.

The radioactive dust monitor is originally equipped with a radiation detector as a radioactivity concentration measuring means. In the present invention, since it is provided with a fluid resistance measuring means, a reusability determination means, and a filter paper rewinding means, In addition to the radioactivity concentration measurement value originally required by the radioactive dust monitor, the fluid resistance measurement value can be acquired over the entire period of use of the long filter paper and compared with the respective allowable upper limit values. Only the long filter papers having the respective allowable upper limit values or less can be judged to be reusable, rewound and reused, and the consumption amount of the long filter papers can be reduced.

The invention according to claim 2 is a used filter paper used in a radiation dust monitor, and the measured value of the radioactivity concentration at the time of use was below the upper limit of the radioactivity concentration for reuse (hereinafter, the radioactivity concentration is below. A filter paper recycling judging device for judging whether or not a used filter paper within the functional contamination limit can be reused by a radioactive dust monitor, and a fluid resistance measuring means for measuring a fluid resistance of the used filter paper, and this fluid. By comparing the fluid resistance measurement value by the resistance measuring means with the allowable upper limit value of the fluid resistance for reuse, if the measured fluid resistance value is less than the allowable upper limit value, the used filter paper can be reused. Reusability determination means for determining.

In the present invention, since the fluid resistance measuring means and the reusability determination means based on the measurement result are provided, the fluid resistance of the used filter paper within the radioactive contamination limit is measured and compared with the allowable upper limit value, Reusability of used filter paper within the radioactive contamination limit can be determined. A third aspect of the present invention is a filter paper recycle determination device for determining whether or not a used filter paper used in a radiation dust monitor can be reused in a radioactive dust monitor, and a fluid for measuring a fluid resistance of the used filter paper. Resistance measurement means, a radioactivity concentration measurement means for measuring the radioactivity concentration of the used filter paper, and the measured values by both means and the respective upper limit for reuse, are compared, any measured value And a reusability determination means for determining that the used filter paper is reusable when the respective upper limit values are equal to or less than the allowable upper limit values.

In the present invention, since the fluid resistance measuring means, the radioactivity concentration measuring means and the reusability judging means are provided, the fluid resistance and the radioactivity concentration of the used filter paper can be measured, and these measured values are measured. It is possible to determine whether or not the reused filter paper can be reused by comparing each of these with the respective allowable upper limit values. The invention of claim 4 is the invention of claim 2 or the invention of claim 3, further comprising a long filter paper transporting mechanism for transporting the long filter paper.

In the present invention, since the long filter paper transport mechanism is provided, it is possible to determine whether or not the long filter paper that has been used can be reused. According to a fifth aspect of the present invention, in the second aspect of the invention or the third aspect of the invention, the fluid resistance measuring means measures a suction pump for sucking air through a used filter paper and an amount of air sucked by the suction pump. It consists of a flow meter and a pressure gauge that measures the pressure loss in the used filter paper due to the suction of air.

In the present invention, since the flowmeter for measuring the amount of air sucked through the filter paper by the suction pump and the pressure gauge for measuring the pressure loss in the filter paper at that time are provided, the fluid resistance of the filter paper is monitored by the radioactive dust monitor. It can be measured under conditions close to those when a filter paper is used. According to a sixth aspect of the present invention, in the fifth aspect of the present invention, the suction air recirculation unit that returns the air sucked by the suction pump to the air suction section of the used filter paper is provided.

In the present invention, since the air sucked by the suction pump through the used filter paper is returned to the air suction portion, the air filtered by the used filter paper is circulated, which is already measured in the fluid resistance value. The amount of dust collected on the used filter paper can be greatly reduced. Claim 7
In the invention of claim 6, in the invention of claim 6, a cooling means for cooling the suction air is provided in the middle of the suction air recirculation means.

The air sucked by the suction pump is heated in the suction pump, and the heated air changes the condition of the filter paper and lowers the accuracy of flow rate measurement. Since the cooling means for cooling the suction air is provided on the way, the air discharged from the suction pump is cooled, the state of the filter paper is stabilized, and the accuracy of flow rate measurement is maintained.

According to the invention of claim 8, in the invention of claim 3, an α-ray detector and a β-ray detector are provided as the radioactivity concentration measuring means. In this invention, since the α-ray detector and the β-ray detector are provided as the radioactivity concentration measuring means, the α-ray detector and the β-ray detector can be detected depending on the type of radiation targeted by the radioactive dust monitor using the filter paper. Either or both of the vessels can be activated to measure the activity concentration of the radiation of interest.

[0026]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of a radioactive dust monitor and a filter paper recycling judging device according to the present invention will be described.
An example will be described. It should be noted that parts having the same functions as those in the prior art are designated by the same reference numerals. [Example of radioactive dust monitor] In this example, a reusability determination function of the used long filter paper and a rewinding function of the long filter paper are added to the function of the conventional radioactive dust monitor using the long filter paper. The dust collection amount (replaced by the fluid resistance value) and the radioactive dust collection amount (replaced by the radioactivity concentration value) were measured over the entire usage time of the long filter paper. The long filter paper that has been below the allowable upper limit value is judged to be reusable, is rewound and reused, and the same long filter paper is repeatedly used while both measured values are below the respective allowable upper limit values.

In the radioactive dust monitor, "count value (cps)" and "radioactivity concentration value (Bq / cm ³ )", "date and time", "flow rate measured value (L / min) ”,“ pressure measurement value (kPa) ”, etc. are displayed on the screen, and they are stored in the memory in the apparatus for the entire usage time of the long filter paper. Therefore, it is possible to determine from these data whether or not the above-mentioned both dust collection amounts are below the respective allowable upper limit values. The radioactivity concentration value (Bq / cm ³ ) is calculated based on the count value (cps) and the flow rate measurement value (L / min).

The configuration and the like of this embodiment will be described below in more detail with reference to the drawings. FIG. 2 is a perspective view showing the appearance of an embodiment of the radioactive dust monitor according to the present invention.
FIG. 3 is a plan view from the AA cross section of FIG. 2. This embodiment comprises a main body 50 and an upper cover 51 covering the upper part thereof. The main body 50 includes various components such as the conveyance mechanism of the long filter paper 1 shown in FIG. 3, the suction head 3, the radiation detector 8 and the like, and a suction pump, a flow meter, a pressure gauge, etc. not shown in FIG. An intake system member, a board computer (CPU), and the like are housed, and a lower maintenance door 52 for maintaining them is provided on the front surface thereof. An LCD operation display 22 and an operation switch 23 are installed on the right side of the upper cover 51, and a filter paper cover 53 serving as a loading / unloading port for the long filter paper 1 is installed on the left side. A transparent acrylic window 54 is attached to the filter paper cover 53 so that the inside can be viewed.

FIG. 1 is a perspective conceptual view showing the internal structure of this embodiment. In this embodiment, the intake head 3,
The intake system including the flow meter 4, the pressure gauge 5, and the suction pump 6 and the radioactivity concentration measuring system including the radiation detector 8 have the same configuration as the conventional technique. However, the following points are different from the related art. 1) A fast feeding function and a rewinding function are added to the transport system of the long filter paper 1, 2) a variable speed transport motor 7a is used to drive the filter paper feed roller 2 for transporting the long filter paper 1. , 3) The tension roller 11 and this drive mechanism are used as means for bringing the long filter paper 1 into close contact with the filter paper feed roller 2 and reliably transporting the long filter paper 1 without slipping. 4) The flow meter 4 and pressure Based on the fluid resistance value of the filter paper calculated from the measurement result of the total 5 and the radioactivity concentration value calculated from the count value of the radiation detector 8, the board computer 20 determines whether or not the long filter paper 1 used can be reused. The judgment result is displayed on the LCD operation display 22, and when it is reusable, the used long filter paper 1 is rewound and reused.

A more detailed description will be given below with reference to FIG. The filter paper feed roller 2 is directly driven by the conveyance motor 7a. An encoder 15 is attached in the middle of the shaft connecting the both, and the feed amount of the filter paper is measured by the encoder 15 and a filter paper feed amount detection sensor (photoelectric sensor) 16 that detects the rotation thereof. The long filter paper 1 is pressed against the filter paper feed roller 2 by the tension roller 11 and is conveyed by the rotation of the filter paper feed roller 2. The tension roller 11 is held by a tension roller holding member 12, and the tension roller holding member 12 is moved to the filter paper feed roller 2 side by a contact pressure spring 13 which is pressed by the excitation of a solenoid 14, and the tension roller 11 is moved by the tension roller 11. The long filter paper 1 is pressed against the filter paper feed roller 2. When replacing, fast-forwarding or rewinding the long filter paper 1, the excitation of the solenoid 14 is stopped and the pressing of the tension roller 11 is released so that the long filter paper 1 can be easily slid. At the time of monitoring of radioactive dust, in order to eliminate the bending of the long filter paper 1, the rewinding motor 17 directly connected to the supply pulley 9 is driven on the supply side, and directly connected to the take-up pulley 10 on the winding side. The fast-forwarding motor 18 is driven. The carrying force of both motors 17 and 18 is set to be smaller than the carrying force of the carrying motor 7a for driving the filter paper feed roller 2 so as not to affect the carrying of the long filter paper 1.

Whether or not the used long filter paper 1 can be reused is determined, as described above, by the fluid resistance value of the filter paper calculated from the measurement results of the flowmeter 4 and the pressure gauge 5, and the radiation detector 8 total. It is determined by the radioactivity concentration value calculated from the numerical value. The radioactive dust monitor is equipped with a flow meter 4 for always confirming that a predetermined air flow rate can be secured and for calculating the suctioned air amount, and the dust collecting portion of the long filter paper 1 is in a clogged state. A pressure gauge 5 is provided to monitor that the predetermined air flow rate cannot be secured. The pressure value measured by the pressure gauge 5 is the pressure loss value at the filter paper position of dust collection concentration, and the flow rate value measured by the flow meter 4 is the flow rate of the air sucked through the filter paper at that time. Since it is a value, the value obtained by dividing the pressure measurement value by the flow rate measurement value is the fluid resistance value at the filter paper position. Therefore, it is possible to obtain the fluid resistance value over the entire length of the long filter paper 1 from the start of use to the end of use of the radioactive dust monitor, and whether or not the fluid resistance value is equal to or less than the allowable upper limit value for reuse. You can figure out.

Further, since the radioactive dust monitor is a device whose purpose is to measure and monitor the radioactivity concentration in the air at the sampling point, it is always radiated from the dust collected on the long filter paper 1. Radiation is counted to measure the radioactivity concentration. Therefore, it is possible to grasp whether or not the radioactivity concentration value over the entire length of the long filter paper 1 from the start of use to the end of use is equal to or less than the allowable upper limit value for reuse.

As is clear from the above description, the radiation dust monitor utilizes the function originally provided, whereby the fluid resistance value and the radioactivity over the entire length of the long filter paper 1 from the start of use to the end of use. Since the density values can be acquired, it is possible to determine whether or not the long filter paper 1 that has been used can be reused if a means for determining whether or not they are equal to or less than the respective allowable upper limit values is provided. Moreover, this determination function can be easily realized by the built-in board computer 20.

Here, the allowable upper limit values of the fluid resistance value and the radioactivity concentration value will be described. The suction pump 6 used for the radioactive dust monitor usually has a capability of collecting dust by maintaining a predetermined air flow rate until the fluid resistance value becomes about 5 times the initial fluid resistance value of the filter paper. Is used, a fluid resistance value that is 2 to 3 times the initial fluid resistance value can be selected as the allowable upper limit value for reuse. That is, if used in this range, the probability of becoming a clogged state at the time of reuse is low. On the other hand, in the case of a radioactive dust monitor that is operated in a normal normal environment, it is often used in a state where almost no radioactive dust is collected, and the radioactivity concentration value is sufficiently lower than the alarm level. , The level is close to the background value. Even if the allowable upper limit of the radioactivity concentration value is set to about 2 to 5 times the background value,
Since this value is sufficiently lower than the alarm setting level, it hardly affects the function as a radioactive dust monitor.

For reference, the actual examples of the pressure loss value and the count value, which are the original data for calculating the fluid resistance value and the radioactivity concentration value, are shown below. The pressure loss value of the long filter paper 1 has an initial value of about 7 kPa at an air flow rate of 130 L / min, and the maximum negative pressure value of the suction pump 6 used is about 30 kPa. The count value corresponding to the background is 10 cps or less, and the alarm level is set to 160 cps, for example.

In such an embodiment, the fluid resistance measurement value and the radioactivity concentration measurement value obtained as described above are stored in the board computer 20 over the entire length of the long filter paper 1 from the start of use to the end of use. Input and compare with each preset allowable upper limit value, and if any measured value is less than or equal to each allowable upper limit value, it is judged that the long filter paper 1 can be reused, and it is for transportation. The motor 7a and the fast-forwarding motor 16 are stopped, the excitation of the solenoid 14 is stopped, the pressure of the tension roller 11 is released, and the long filter paper 1 is rewound on the supply pulley 9 by the rewinding motor 17 for reuse. .

In this embodiment, the long filter paper 1 is used.
Since it is necessary to rewind the paper in a short time, the transport speed during rewind is set to be much faster than the transport speed during monitoring of the radioactivity concentration, so cutting of the long filter paper 1 during rewind is detected. In order to do so, a filter paper out sensor (photoelectric sensor)
19 is provided just before the supply pulley 9. According to this embodiment, when the environmental condition of the sampling point is normal, the same long filter paper 1 can be reused more than once,
The consumption of the long filter paper 1 was able to be reduced significantly.

This example is a radioactive dust monitor using the long filter paper 1. In the case of a radioactive dust monitor using a fixed filter paper, the fluid resistance value measured at the final point of dust collection and The radioactivity concentration value is compared with each allowable upper limit value, and if both measured values are equal to or less than the respective allowable upper limit values, the fixed filter paper may be determined to be reusable and may be reused.

An embodiment of a filter paper recycling judging device for judging whether or not a used filter paper can be reused will be described below. [First Embodiment of Filter Paper Recycling Judgment Device] This embodiment is an embodiment of a filter paper recycling judgment device for judging whether or not a used filter paper within the radioactive contamination limit can be reused with a radioactive dust monitor, FIG. 4 is a perspective conceptual view showing the configuration of this embodiment, which corresponds to the case where the used filter paper within the radioactive contamination limit is a long filter paper.

Since the used filter paper to be judged by this device is a used filter paper within the radioactive contamination limit, it can be reused by inspecting whether or not the fluid resistance value of the used filter paper is below the allowable limit. Therefore, it is provided with a long filter paper conveying means, a fluid resistance measuring means, and a reuse possibility determining means. The conveying means for the long filter paper 1 is a supply pulley 9,
It is composed of a filter paper feed roller 2 and a take-up pulley 10 driven by a transport motor (not shown), and has almost the same structure as the radioactive dust monitor.

The fluid resistance measuring means comprises an intake head 3, a flow meter 4, a pressure gauge 5, a suction pump 6, an intake circulation pipe 30, an air cooler 32 and an intake supply head 31, and the suction pump 6
The air sucked in is returned to the intake supply head 31 through the air cooler 32 in the intake circulation pipe 30, and the suction air is circulated. The reason why the suction air is circulated is to reduce the additional collection of dust on the long filter paper 1 to be inspected during the fluid resistance measurement as much as possible, and the fluid resistance can be measured without circulation. . The air cooler 32 cools the temperature rise of the suction air from the suction pump 6 and maintains the temperature of the air supplied to the long filter paper 1 at room temperature. When the temperature of the suction air is high, the performance of the long filter paper 1 is affected and the measurement accuracy of the flow meter 4 is reduced.

A board computer (not shown) is used as the reusability determination means, as in the radioactive dust monitor. In measuring the fluid resistance, it is sufficient to accurately obtain the flow rate value of the suctioned air and the pressure loss value in the filter paper, so that the transport speed of the long filter paper 1 can be made faster than in the case of the radioactive dust monitor. In the embodiment, the transport speed of the long filter paper 1 is 25 mm / h, which is a normal transport speed in the radioactive dust monitor, to 100 mm / min, which is much higher than that.
Can be set up to. Therefore, it is possible to judge whether or not the reused filter paper within the radioactive contamination limit can be reused in a time much shorter than the time used in the radioactive dust monitor.

FIG. 4 shows a filter paper recycle determination device for a long filter paper 1. If the intake head 3 of FIG. 4 is replaced by the fixed filter paper intake head 3a shown in FIG. It becomes a device. In this case, as a matter of course, since it is not necessary to operate the conveying means for the long filter paper 1, it is also effective not to provide the conveying means for the long filter paper 1 and to use a filter paper recycle determination device dedicated to the fixed filter paper. Is.

The fixed filter paper intake head 3a is an intake head having a structure in which the filter paper holder 40 fitted with the fixed filter paper 1a is fitted, and is used in a radioactive dust monitor or a radioactive dust sampler for the fixed filter paper 1a. Things can be used. In order to firmly hold the fixed filter paper 1a in the filter paper holder 40, a holder cover 41 is fitted on the dust collecting side of the mounted fixed filter paper 1a.

[Second Embodiment of Filter Paper Recycling Judgment Apparatus] This embodiment is a filter paper recycling judgment apparatus for judging whether or not a used filter paper for which no used data remains can be reused. In addition to the long filter paper transporting means, fluid resistance measuring means, and reusability determination means of the embodiment, a radioactive concentration measuring means is provided, and FIG. 6 is a perspective conceptual view showing the configuration of this embodiment. Is.

The radioactive concentration measuring means is composed of a radiation detector 8, a preamplifier 21 and a port computer 20 for processing the detection signal thereof, similar to the radioactive dust monitor shown in FIG. The difference from the radioactive dust monitor is that the installation position of the radiation detector 8 is not limited to the position facing the intake surface of the intake head 3, and in FIG. 6, the radiation detector 8 is supplied from the position of the intake head 3. It is arranged on the pulley 9 side.

In this embodiment, since it is necessary to measure the radioactivity concentration with a predetermined measurement accuracy, it is necessary to count a certain number of counts. In consideration of the measurement accuracy, a long filter paper is required. The maximum transport speed of 1 is determined. For example, the width of the opening of the radiation detector 8 is 50 mm,
If the transport speed of the long filter paper 1 is 100 mm / min and the dose rate at this time is equivalent to 10 cps (normal background value), the time required for the filter paper to pass through the opening of the radiation detector 8 is
It is 30 seconds, the count value during this period is 300 counts,
If the statistical error is σ, then 3σ corresponds to 17.3%. Therefore, in order to make this 3σ smaller than 17.3%, it is necessary to make the conveying speed slower than 100 mm / min.

The radiation to be measured by the radioactive dust monitor has been mainly β rays in the past, but recently α rays have been used.
The number of cases targeting lines is also increasing. for that reason,
As the radiation detector 8, it is also effective to put an α-ray radiation detector together with a β-ray radiation detector. In such a filter paper recycling determination device, both radiation detectors are operated to determine whether or not they can be reused with respect to each radiation, and the measurement results are used according to the type of target radiation of the radioactive dust monitor, It is possible to operate one of the radiation detectors according to the radiation to be used and determine whether or not the radiation can be reused. Even if the radioactivity concentration data at the time of use is stored, if the type of target radiation of the radioactive dust monitor to be reused is different, that data cannot be used to determine whether or not it can be reused. Even in such a case, the filter paper recycling determination device equipped with both radiation detectors is effective.

According to this embodiment, when it is judged whether or not the reused fixed filter paper can be reused, as in the first embodiment,
The suction head 3 may be replaced with the fixed filter paper suction head 3a shown in FIG. 5, and after the fluid resistance value is measured, the suction supply head 31 may be replaced with the radiation detector 8. Further, when the suction air is not circulated, a suction air circulation means is not necessary, and therefore the radiation detector 8 may be constantly installed at the position of the intake supply head 31.

[0050]

According to the first aspect of the present invention, since the fluid resistance measuring means, the reusability determination means, and the filter paper rewinding means are provided, in addition to the radioactive concentration measurement value originally required by the radioactive dust monitor, the fluid Resistance measurements can be taken over the entire length of use of the lengthy filter paper and compared to their respective acceptable upper limit values. It can be rewound and judged to be usable, and can be reused, and the consumption of the long filter paper can be reduced. Therefore, according to the present invention, it is possible to provide the radioactive dust monitor capable of reducing the consumption of the long filter paper while ensuring the condition that the radioactivity concentration in the air to be measured can be measured with a predetermined accuracy.

According to the second aspect of the present invention, since the fluid resistance measuring means and the reusability determination means based on the measurement result are provided, the fluid resistance of the used filter paper within the radioactive contamination limit is measured and the allowable upper limit value is obtained. By comparison, it is possible to determine whether or not the reused filter paper within the radioactive contamination limit can be reused. Therefore, according to the present invention, it is possible to provide a filter paper recycle determination device that determines whether or not a used filter paper within the radioactive contamination limit can be reused and recycles it.

According to the third aspect of the present invention, since the fluid resistance measuring means, the radioactivity concentration measuring means and the reusability judging means are provided, the fluid resistance and the radioactivity concentration of the used filter paper can be measured. It is possible to determine whether or not the reused filter paper can be reused by comparing the measured value of 1 with each allowable upper limit value. Therefore, according to the present invention, it is possible to provide a filter paper recycle determination device that recycles the used filter paper by determining whether or not the used filter paper on which the data of the fluid resistance and the radioactivity concentration is not left can be reused.

According to the fourth aspect of the present invention, since the long filter paper conveying mechanism for conveying the long filter paper is provided, it is possible to determine whether or not the long filter paper can be reused over the entire length. Therefore, according to the present invention, it is possible to provide a filter paper recycle determination device capable of automatically determining whether or not a used long filter paper can be reused. According to the fifth aspect of the present invention, since a flow meter for measuring the amount of air sucked through the filter paper by the suction pump and a pressure gauge for measuring the pressure loss in the filter paper at that time are provided, the fluid resistance of the filter paper is monitored by the radioactive dust monitor. It can be measured under conditions close to those when a filter paper is used. Therefore, according to the present invention, the fluid resistance of the filter paper can be measured in a state close to that used in the radioactive dust monitor.

According to the invention of claim 6, since the suction air recirculation means for returning the air sucked by the suction pump to the air suction portion of the used filter paper is provided, the air filtered by the used filter paper is circulated. In the measurement of the fluid resistance value, the amount of dust collected on the used filter paper can be significantly reduced. Therefore, according to the present invention, it is possible to determine the reusability of the used filter paper in a state close to the state at the end of use.

In the invention of claim 7, since the cooling means for cooling the suction air is provided in the middle of the suction air recirculation means, the air sucked by the suction pump and heated in the suction pump is cooled. By means of the means, the condition of the filter paper is stabilized and the accuracy of flow rate measurement is maintained. Therefore,
According to the present invention, it is possible to more accurately determine whether or not a reused filter paper can be reused.

According to the eighth aspect of the present invention, since the α-ray detector and the β-ray detector are provided as the radioactivity concentration measuring means, the α-ray detector is used depending on the type of radiation targeted by the radioactive dust monitor using the filter paper. Either or both the detector and the β-ray detector can be activated to measure the activity concentration of the radiation of interest. Therefore, according to the type of radiation targeted by the radioactive dust monitor,
It is possible to determine whether or not the radioactivity concentration of the used filter paper is less than or equal to the allowable upper limit value.

[Brief description of drawings]

FIG. 1 is a perspective conceptual view showing an internal configuration of an embodiment of a radioactive dust monitor according to the present invention.

FIG. 2 is a perspective view showing the appearance of a radioactive dust monitor according to the present invention.

FIG. 3 is a plan view taken along the line AA in FIG.

FIG. 4 is a first filter paper recycling judging device according to the present invention.
Perspective view showing the internal structure of the embodiment

FIG. 5 is a perspective view showing a configuration of an air intake portion for a fixed filter paper.

FIG. 6 is a perspective conceptual diagram showing an internal configuration of a second embodiment of the filter paper recycling determination device.

FIG. 7 is a perspective conceptual view showing a configuration of an example of a dust collecting unit of a conventional radioactive dust monitor.

FIG. 8 is an explanatory view showing a dust collecting state of a long filter paper of a conventional radioactive dust monitor.

FIG. 9 is a diagram showing a suction negative pressure-flow rate characteristic of a suction pump.

[Explanation of symbols]

1 long filter paper 101 Dust collection area 102 Collection start position 103 Part collecting dust 1a Fixed filter paper 2 Filter paper feed roller 3 intake head 3a Intake head for fixed filter paper 4 Flowmeter 5 Pressure gauge 6 Suction pump 7 Motor 7a Transport motor 8 Radiation detector 9 Supply pulley 10 Take-up pulley 11 Tension roller 12 Tension roller holding member 13 Contact spring 14 Solenoid 15 encoder 16 Filter paper feed amount detection sensor 17 Rewinding motor 18 Rapid traverse motor 19 Filter paper out sensor 20 board computer 21 preamplifier 22 LCD operation display 23 Operation switch 30 Intake circulation piping 31 Intake supply head 32 air cooler 40 Filter paper holder 41 Holder cover 50 Main body 51 Top cover 52 Lower maintenance door 53 Filter paper cover 54 acrylic window

Continued front page    (72) Inventor Katsuto Ito             1-1 Tanabe Nitta, Kawasaki-ku, Kawasaki-shi, Kanagawa             Within Fuji Electric Co., Ltd. F term (reference) 2G088 EE12 HH03

Claims (8)

[Claims] 1. A suction pump that allows air at a monitoring point of a radioactive material handling facility to pass through a dust collecting portion of a long filter paper that is continuously or intermittently conveyed,
Dust floating in the air is collected in the dust collecting part,
A radioactive dust monitor that detects the radiation emitted from the collected dust with a radiation detector and continuously measures the radioactivity concentration existing in the air at the monitoring point. The fluid resistance measuring means for measuring the fluid resistance of the long filter paper, the fluid resistance measurement value by this means, the radioactivity concentration measurement value by the radiation detector and the respective allowable upper limit values for reuse. By comparison, if any measured value is less than or equal to the allowable upper limit value, the long filter paper is judged to be reusable, and the length is judged by the reusability judgment of this means. And a filter paper rewinding means for rewinding the lengthy filter paper. 2. Is it possible to reuse the used filter paper, which was used in the radiation dust monitor and whose measured radioactivity concentration during use was less than the upper limit of the radioactivity concentration for reuse, in the dust monitor? A device for determining whether or not to recycle a filter paper for a radioactive dust monitor for determining whether or not the fluid resistance measuring means for measuring the fluid resistance of the already used filter paper, and a fluid resistance measurement value by the fluid resistance measuring means and for reuse. And a reusability determination means for determining that the used filter paper is reusable when the fluid resistance measurement value is equal to or less than the permissible upper limit value by comparing with the permissible upper limit value of the fluid resistance. A characteristic device for determining whether or not filter paper can be recycled for radioactive dust monitors. 3. A filter paper recyclability determination device for radioactive dust monitor for determining whether or not a used filter paper used in a radiation dust monitor can be reused in a dust monitor, the fluid resistance of the used filter paper being measured. Fluid resistance measuring means, which measures the radioactivity concentration of the used filter paper, and the radioactivity concentration measuring means, which compares the measurement values by both means and the respective upper limit values for reuse, and which measurement A filter paper recyclability determination device for radioactive dust monitor, comprising: a reusability determination means for determining that the used filter paper is reusable when the values are also below the respective allowable upper limit values. 4. The filter paper recyclability determination device for radioactive dust monitor according to claim 2, further comprising a long filter paper transport mechanism for transporting the long filter paper. 5. The fluid resistance measuring means comprises a suction pump for sucking air through a used filter paper, a flow meter for measuring the amount of air sucked by the suction pump, and a pressure loss in the used filter paper due to suction of air. It comprises with the pressure gauge to measure, The filter paper recyclability judgment apparatus for radioactive dust monitors of Claim 2 or Claim 3 characterized by the above-mentioned. 6. The filter paper recyclability determination device for radioactive dust monitor according to claim 5, further comprising suction air recirculation means for returning the air sucked by the suction pump to the air suction portion of the used filter paper. . 7. The filter paper recyclability determination device for radioactive dust monitor according to claim 6, further comprising a cooling means for cooling the suction air in the middle of said suction air recirculation means. 8. The apparatus for determining the recyclability of filter paper for radioactive dust monitor according to claim 3, wherein an α-ray detector and a β-ray detector are provided as the radioactivity concentration measuring means.