KR102145749B1 - Automatic evaporation device for radioactive liquid sample - Google Patents

Abstract

The present invention relates to an automatic evaporation apparatus for a radioactive liquid sample, and more particularly, when a liquid sample for radioactivity is evaporated, a liquid sample can be automatically supplied. In particular, a liquid sample is measured by measuring the amount of the liquid sample remaining in the evaporation process. It relates to a radioactive liquid sample automatic evaporation device capable of automatically supplying, and precisely evaporating a liquid sample as much as desired by a user. To this end, the automatic evaporation apparatus for a radioactive liquid sample according to an embodiment of the present invention includes a sample portion containing a radioactive liquid sample, a heating portion for heating a liquid sample contained in the sample portion, and a liquid sample contained in the sample portion to the heating portion. However, it includes a supply unit that automatically supplies according to the amount of the liquid sample remaining in the heating unit.

Description

Automatic evaporation device for radioactive liquid sample

The present invention relates to an automatic evaporation apparatus for a radioactive liquid sample, and more particularly, when a liquid sample for radioactivity is evaporated, a liquid sample can be automatically supplied. In particular, a liquid sample is measured by measuring the amount of the liquid sample remaining in the evaporation process. It relates to a radioactive liquid sample automatic evaporation device capable of automatically supplying, and precisely evaporating a liquid sample as much as desired by a user.

In accordance with the Regulation on Radiation Environment Survey and Radiation Environment Impact Assessment around Nuclear Facilities (Nuclear Safety Committee Notice No. 2017-17), environmental radiation activity among environmental samples around facilities should be measured. The environmental radioactivity analysis method must satisfy the lower limit of detection required by the notification, that is, the minimum measurable radioactivity concentration.

In order to satisfy the lower limit of detection among liquid samples of gamma nuclides, Co-60, Cs-137, and I-131, a sample of at least 20L or more is required. According to the formula for calculating the measurable minimum detectable radioactivity concentration (MDA), the lower the detector background coefficient and the higher the measurement efficiency, the lower the minimum detectable radioactivity concentration, which is determined by the detector performance. Sample size is currently the most decisive variable under optimal detector conditions. For that reason, about 20L or more of a sample is required for the analysis of gamma nuclides in liquid samples.

The sample suitable for the detector is about 500ml, and the method of concentrating 20L of a liquid sample to 500ml is by evaporation. Transfer and heat a liquid sample such as groundwater (or surface water) to a container made of 2L SUS, and check how much the liquid sample has evaporated. This is because the evaporation rate varies depending on the amount of sample remaining in the container. For example, since the evaporation rate from 2L to 1.5L and the evaporation rate from 800ml to 300ml are different, if you do not pay attention, the amount of the liquid sample remaining in the container will decrease more than expected. In order to evaporate 20L of the liquid sample to the final 500ml, it is necessary to check how much evaporation has been performed more than 10 times out of the total required time of 8 hours, and there is a trouble of refilling the liquid sample as long as it has evaporated.

In addition, as in Patent Document 1, some studies on an evaporation system for concentrating water have been conducted, but there is a limitation in application because the structure is complex and the evaporation amount of water cannot be accurately identified.

Therefore, there is a need for improvement.

Korean Patent Application Publication No. 10-1997-7000530 (published on Feb. 12, 1997)

The technical problem to be solved in the present invention is that a liquid sample can be automatically supplied when a liquid sample is evaporated for radioactivity detection, and in particular, a liquid sample can be automatically supplied by measuring the amount of the liquid sample remaining in the evaporation process. It is to provide an automatic radioactive liquid sample evaporation device capable of accurately evaporating a liquid sample as much as desired.

In order to solve the above technical problem, an automatic evaporation apparatus for a radioactive liquid sample according to an embodiment of the present invention includes a sample unit receiving a radioactive liquid sample, a heating unit for heating a liquid sample accommodated in the sample unit, and a heating unit accommodated in the sample unit. A liquid sample is supplied to the heating unit, and includes a supply unit for automatically supplying the liquid sample according to the amount of the liquid sample remaining in the heating unit.

The automatic evaporation apparatus for a radioactive liquid sample according to an embodiment of the present invention having the above configuration is configured to automatically supply the liquid sample accommodated in the sample unit to the heating unit through the supply unit, so that the user has to refill the liquid sample. Can be less.

In addition, since the amount of liquid sample remaining in the heating unit is measured, and the liquid sample is automatically supplied by reflecting this, the user does not need to cumbersomely check the evaporation amount of the liquid sample while the operation is in progress. It can be less, and the overall work efficiency can be improved because the user can do other work while the work is in progress.

In addition, since the operation of the device is automatically stopped when the target evaporation amount input by the user is satisfied, the liquid sample can be evaporated only as much as the user wants, thereby improving the accuracy of the operation.

1 and 2 are perspective views illustrating an apparatus for automatically evaporating a radioactive liquid sample according to an embodiment of the present invention, and FIG. 1 is a view showing the front side, and FIG. 2 is a view showing the rear side.
3 is a perspective view showing a heating unit and a supply unit of an apparatus for automatically evaporating a radioactive liquid sample according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those of ordinary skill in the art can easily implement the present invention. The present invention may be implemented in various forms and is not limited to the embodiments described herein. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and the same reference numerals are assigned to the same or similar components throughout the specification.

In the present specification, terms such as "comprise" or "have" are intended to designate the presence of features, numbers, steps, actions, components, parts, or combinations thereof described in the specification, but one or more other features. It is to be understood that the possibility of addition or presence of elements or numbers, steps, actions, components, parts, or combinations thereof is not preliminarily excluded. Further, when a part such as a layer, film, region, plate, etc. is said to be "on" another part, this includes not only the case where the other part is "directly above" but also the case where there is another part in the middle. Conversely, when a part such as a layer, film, region, plate, etc. is said to be "under" another part, this includes not only the case where the other part is "directly below", but also the case where there is another part in between.

1 and 2 are perspective views illustrating an apparatus for automatically evaporating a radioactive liquid sample according to an embodiment of the present invention, and FIG. 1 is a view showing a front side, and FIG. 2 is a view showing a rear side. 3 is a perspective view showing a heating unit and a supply unit of an apparatus for automatically evaporating a radioactive liquid sample according to an embodiment of the present invention.

The apparatus for automatically evaporating a radioactive liquid sample according to an embodiment of the present invention heats a sample unit 100 in which a radioactive liquid sample is accommodated and a liquid sample accommodated in the sample unit 100 as shown in FIGS. 1 to 3. A heating unit 200 and a liquid sample accommodated in the sample unit 100 are supplied to the heating unit 200, but include a supply unit 300 that automatically supplies according to the amount of the liquid sample remaining in the heating unit 200 do.

The sample unit 100 accommodates a liquid sample for analyzing gamma nuclides, and is formed in a size capable of accommodating about 20L of a liquid sample.

In order to concentrate the liquid sample, the liquid sample accommodated in the sample unit 100 is supplied to the heating unit 200, and the heating unit 200 heats the liquid sample to evaporate water contained in the liquid sample.

In this case, a supply unit 300 for supplying the liquid sample accommodated in the sample unit 100 to the heating unit 200 is provided. Since the supply unit 300 automatically supplies the liquid sample accommodated in the sample unit 100 to the heating unit 200, it is possible for a user to fill the heating unit 200 with a liquid sample.

In addition, since the supply unit 300 automatically supplies a liquid sample from the sample unit 100 according to the amount of the liquid sample remaining in the heating unit 200, the user can determine the evaporation amount of the liquid sample while the operation of evaporating the liquid sample is in progress. Since there is no need to check cumbersomely, the user's effort and labor can be reduced, and the user can perform other tasks while the task is in progress, thereby improving work efficiency.

The heating unit 200 includes a container member 210 in which a liquid sample to be supplied is accommodated, and a heating member 220 that heats the container member 210. That is, the liquid sample supplied from the sample unit 100 through the supply unit 300 is supplied to the container member 210. The container member 210 may be made of stainless steel (SUS).

In addition, when the evaporation of the liquid sample is completed, the liquid sample contained inside is transferred to a detector (not shown) to detect gamma nuclides, so that the liquid sample contained in the container member 210 can be automatically moved to the detector. It is also possible to configure or move the container member 210 directly to move the liquid sample to the detector. At this time, the container member 210 may be provided with a handle so that the user can directly move the container member 210.

As described above, the supply unit 300 automatically supplies the liquid sample accommodated in the sample unit 100 to the heating unit 200 according to the amount of the liquid sample remaining in the heating unit 200. To this end, the supply unit ( It is preferable that the sensing member 310 for measuring the amount of the liquid sample remaining in the container member 210 is provided in the 300).

The sensing member 310 measures the amount of the liquid sample remaining in the container member 210, and a method of continuously measuring the level of the liquid sample is used, or the level of the liquid sample reaches a certain level. If so, you can use a method of measuring it.

In this case, the sensing member 310 using ultrasonic waves may be used to measure the amount of the liquid sample. When using ultrasonic waves, it can be used not only for liquid but also for gaseous or solid samples, and a transducer is mounted on the container member 210, and ultrasonic pulses generated therefrom are used.

Alternatively, it is possible to configure the sensing member 310 to measure the amount of the liquid sample by using the change in capacitance according to the amount of the liquid sample.

The sensing member 310 according to an exemplary embodiment of the present invention may be provided with a first level sensor 311 for limiting a lower limit of a liquid sample and a second level sensor 312 for limiting an upper limit of a liquid sample.

That is, the first level sensor 311 and the second level sensor 312 detect whether the level of the liquid sample reaches a certain level. When the evaporation operation of the liquid sample proceeds, the level of the liquid sample gradually decreases, and when the level of the liquid sample reaches the first level sensor 311, the first level sensor 311 generates a signal. When such a signal is input, the control unit 500 to be described later operates the supply unit 300 to control the liquid sample accommodated in the sample unit 100 to be supplied to the container member 210.

In addition, as the liquid sample is supplied into the container member 210, the level of the liquid sample rises, and when the level of the liquid sample reaches the second level sensor 312, the second level sensor generates a signal. , The control unit 500, which will be described later, receives such a signal and stops the operation of the supply unit 300 so that the liquid sample is not supplied into the container member 210.

The supply unit 300 further includes a flow path member 320 for communicating the sample unit 100 and the heating unit 200 to each other, and a pump member 330 for pressing a liquid sample moving inside the flow path member 320. Can include.

The flow path member so that the sample part 100 and the heating part 200 communicate with each other through the flow path member 320 described above, and the liquid sample discharged through the flow path member 320 is stably supplied into the container member 210. It is preferable that a fixed frame 10 for fixing and supporting the 320 is provided. It is also possible to fix the above-described first level sensor 311 and second level sensor 312 together on the fixing frame 10.

In addition, the fixed frame 10 is preferably configured to be rotated upward by a certain angle. That is, as shown in Figure 2, the fixed frame 10 is provided with a support bar 11 to which the position is fixed, and a rotation bar 12 connected to the support bar 11 and capable of rotating upward by a predetermined angle. Since one side of the pivoting bar 12 is hinged to the support bar 11, the other side of the pivoting bar 12 rotates upward by a certain angle around one side of the pivoting bar 12. As described above, when the user separates the container member 210 to directly transfer the liquid sample to the detector, if the flow path member 320 or the first and second level sensors 311 and 312 are fixedly disposed in the correct position, the container This is because it may not be easy to separate the member 210. Therefore, when the fixed frame 10 is rotated upward by a certain angle, the flow path member 320 or the first and second level sensors 311 and 312 fixed to the fixed frame 10 are also moved upward, through which the container member ( 210) can be easily separated.

In addition, when the pump member 330 is provided to pressurize the liquid sample moving inside the flow path member 320, the liquid sample is smoothly supplied even if the sample unit 100 is disposed at a position relatively lower than the heating unit 200. It becomes possible to supply it properly.

At this time, the weight measurement unit 400 for measuring the weight of the liquid sample accommodated in the sample unit 100 in real time, and the heating unit 200 and the supply unit 300 according to the weight of the liquid sample input from the weight measurement unit 400 A control unit 500 for controlling the operation of) may be provided. As shown in FIG. 2, the sample unit 100 is mounted and disposed on the weight measurement unit 400 to be detachable.

The weight measurement unit 400 measures the weight of the liquid sample in real time, and the measured weight of the liquid sample is input to the control unit 500. In addition, the control unit 500 controls the operation of the heating unit 200 and the supply unit 300 according to the weight of the liquid sample input in real time. If configured in this way, the user can perform the evaporation operation of the liquid sample. Since there is no need to cumbersomely check the evaporation amount of the liquid sample, the effort and labor of the user for this can be reduced. In addition, since the user can perform other tasks while these tasks are in progress, overall work efficiency can be improved.

When the evaporation amount of the liquid sample becomes the same as the target evaporation amount input by the user, the control unit 500 stops the operation of the heating unit 200 and the supply unit 300.

That is, after checking the total weight of the sample unit 100, the user inputs a target evaporation amount for how much of the liquid sample to evaporate. When the target evaporation amount is input, the controller 500 The heating unit 200 and the supply unit 300 are operated until the real-time evaporation amount of is equal to the target evaporation amount, and when the target evaporation amount and the real-time evaporation amount of the liquid sample become the same, the controller 500 controls the heating unit 200 and the supply unit ( 300) stops the operation.

When the operation of the heating unit 200 and the supply unit 300 is stopped by the control unit 500, a notification member (not shown) may be used to notify such a situation.

In this case, the control unit 500 may calculate the evaporation amount of the liquid sample by using the difference between the initial weight of the liquid sample and the weight of the liquid sample measured in real time.

That is, when the weight measurement unit 400 measures the weight of the sample unit 100 for the first time, this information is input to the control unit 500, and the control unit 500 determines the initial weight of the liquid sample and the liquid sample measured in real time. The evaporation amount is calculated by using the difference in the weight of and, as described above, when the real-time evaporation amount of the liquid sample and the target evaporation amount become the same, the operation of the heating unit 200 and the supply unit 300 is stopped.

However, since the weight measurement unit 400 measures the weight of the sample unit 100 in real time, when the liquid sample is moved from the sample unit 100 to the heating unit 200 through the supply unit 300, the control unit 500 ) Can be determined that the liquid sample in the sample unit 100 has been evaporated by the target evaporation amount simply by changing the weight of the sample unit 100. In particular, if the operation of the heating unit 200 is stopped even though the liquid sample in the heating unit 200 is not evaporated, there may be a problem that a large amount of the liquid sample remains in the heating unit 200. Therefore, the control unit 500 first stops only the operation of the supply unit 300 when the weight change of the sample unit 100 input through the weight measurement unit 400 becomes the same as the target evaporation amount input by the user, and the heating unit 200 It is preferable to control the heating unit 200 to operate until a certain amount of the liquid sample supplied to the inside evaporates. As such, whether a certain amount of the liquid sample in the heating unit 200 has evaporated may be determined based on information input through the first level sensor 311 described above.

As described above, when the target evaporation amount input by the user is satisfied, the operation of the device is automatically stopped, so that the liquid sample can be evaporated only as much as the user wants, thereby improving the accuracy of the operation.

In addition, during the initial operation, the controller 500 controls not to operate the heating unit 200 until a predetermined amount of a liquid sample is supplied into the heating unit 200. If the heating unit 200 is operated while a small amount of the liquid sample is supplied to the heating unit 200, a small amount of the liquid sample may be rapidly evaporated and the specimen for radioactivity detection may be deteriorated. Since there is a possibility that a fire may occur due to a rapid increase in the temperature of the heating unit 200, it is preferable to operate the heating unit 200 after a predetermined amount of a liquid sample is supplied to the heating unit 200.

Although an embodiment of the present invention has been described above, the spirit of the present invention is not limited to the embodiment presented in the present specification, and those skilled in the art who understand the spirit of the present invention can add components within the scope of the same idea. It will be possible to easily propose other embodiments by changing, deleting, adding, etc., but it will be said that this is also within the scope of the present invention.

10: fixed frame 100: sample portion
200: heating unit 210: container member
220: heating member 300: supply unit
310: sensing member 311: first level sensor
312: second level sensor 320: flow path member
330: pump member 400: weight measuring unit
500: control unit

Claims (8)

A sample portion containing a radioactive liquid sample;
A heating unit provided with a detachable container member for receiving a liquid sample supplied from the sample unit, and a heating member for heating the container member;
A flow path member communicating with the sample part and the heating part to supply a liquid sample accommodated in the sample part to the heating part, a pump member for pressing a liquid sample moving inside the flow path member, and an inside of the container member A supply unit provided with a sensing member for measuring the amount of the remaining liquid sample, and automatically supplying according to the amount of the remaining liquid sample in the heating unit; And
Further comprising a weight measuring unit for measuring the weight of the liquid sample accommodated in the sample unit in real time, and a control unit for controlling the operation of the heating unit and the supply unit according to the weight of the liquid sample input from the weight measuring unit,
The sample part is detachably seated and disposed on the weight measuring part
A fixed frame for supporting the flow path member and the sensing member is provided
The fixing frame is provided with a support bar whose position is fixed, and a rotation bar connected to the support bar and capable of rotating upward by a predetermined angle,
The control unit,
During the initial operation, after a certain amount of a liquid sample is supplied into the heating unit, the heating unit is operated,
In the process of evaporating the liquid sample, when the evaporation amount of the liquid sample becomes the same as the target evaporation amount input by the user, the operation of the heating unit and the supply unit is stopped,
When a liquid sample remains inside the heating unit, only the operation of the supply unit is first stopped and the heating unit is operated until a predetermined amount of the liquid sample remaining inside the heating unit evaporates. delete The method of claim 1,
The sensing member includes a first level sensor for limiting a lower limit of the liquid sample, and a second level sensor for limiting an upper limit of the liquid sample. delete delete delete The method of claim 1,
The control unit is a radioactive liquid sample automatic evaporation device that calculates the evaporation amount of the liquid sample by using the difference between the initial weight of the liquid sample and the weight of the liquid sample measured in real time. delete

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