RU2685644C1 - Method of sampling and delivering samples of radioactive solutions and device for its implementation - Google Patents

Abstract

FIELD: radiochemistry; nuclear physics and equipment.SUBSTANCE: invention relates to radiochemistry, specifically to handling radioactive solutions when processing irradiated nuclear fuel. Method of sampling and delivering samples of radioactive solutions, involving sampling with the help of a sampling device, introducing a solution sample into the capillary transport tube, creating a positive pressure drop of the gas phase in the transport tube before and after the sample in the direction of movement thereof, controlling the value of the positive pressure drop to limit the rate of movement of the sample along the transport tube and receiving the sample into the sampling container, wherein the sampling device is a sampling tube, the free end of the transfer tube is connected to the inner cavity of the sampling tube above the free end of the latter, vertically immersing the free end of the sampling tube into the radioactive solution, performing pre-filling with radioactive solution of sampling tube above point of its connection with free end of transport tube, creating appropriate rarefaction of gas phase in sampling tube relative to pressure in solution near free end of sampling tube, then, a portion of a sample of the radioactive solution is introduced into the transport tube, increasing the vacuum of the gas phase in the transport tube at a predetermined rate to a given value, thereafter, reducing the vacuum of the gas phase in the sampling tube so that the level of radioactive solution in the sampling tube is set below the free end of the transport tube, and transferring the sample along the transport tube with further sampling into the sampling container. Disclosed also is a device for sampling and delivering samples of radioactive solutions.EFFECT: high reliability of sampling and delivery of samples of medium- and low-activity radioactive solutions.13 cl, 2 dwg

Description

The invention relates to the field of radiochemistry, namely, the treatment of radioactive solutions during the processing of irradiated nuclear fuel (SNF), and can be used in the selection and delivery of portions of these solutions from the place of their selection to the composition analyzers that are at a distance personnel protection.

It is known that radiochemical plants in Russia use a method of sampling radioactive process solutions, based on discharging a certain volume of solution (sample) into a special container (see, for example, the article “The remote sampling system for EDC”, by Ya.V. Kolovsky, A. .I. Lansky, N.N. Mishin, S.V. Podoinitsyn, I.O. Shumkov, Collection of Reports of the Scientific and Technical Conference Treatment of Spent Nuclear Fuel in Russia, Krasnoyarsk Branch of Federal State Unitary Enterprise FSUE, 2012, Zheleznogorsk ., p. 168-173). In this case, sampling is carried out in a radiation protection chamber equipped with impulse lines equipped with a manipulator and a viewing window. Before taking a sample for washing, the technological radioactive solution is circulated for a short time by means of a pump along impulse lines, after which the solution sample is taken into a special container in the protective chamber, which is then sealed. Delivery of samples of radioactive solutions to the analytical laboratory is carried out using pneumatic mail or conveyor.

A large amount of technological solution (1 ÷ 10 liters) required to fill traditional impulse lines prevents the use of the above-described sampling method for controlling technological processes in modern centrifugal extraction installations, characterized, in contrast to settling mixers, by the absence of accumulation zones of controlled solutions. In addition, a significant amount of radioactive solution at the sampling site requires an expensive protective chamber. The disadvantages of the above-described method of sampling and delivery of samples also include the use of special pneumatic mail or a conveyor for the delivery of samples of radioactive solutions that are not reliable enough and require large material costs during their creation.

A known method of sampling and delivery of samples of radioactive solutions according to the patent of the Russian Federation for the invention №2485473, IPC G01N 1/10, publ. 06.20.2013, in which two combined operations are carried out: the selection and dilution of a portion of the radioactive solution, while sampling can be carried out directly from the process unit, pipeline or transfer tank. The method of transfer of the sample is the issuance of a predetermined volume of the diluted sample from the device through a special issue line for a distance of no more than 2-4 meters. The main advantage of the device for the implementation of this method is that the solution, which is diluted 30-100 times, is not removed from the zone of the location of the process equipment. A small portion of a highly active solution with a volume of 0.2-0.5 ml is taken from the process, which significantly reduces the cost of measures to protect personnel from harmful radiation.

The disadvantages of the device is the need to use special sealed transport containers, which are delivered to the analytical laboratory using pneumatic mail or conveyor. Compared with the above-mentioned delivery of samples of highly active undiluted solutions in this case, less personnel protection is required, which reduces material costs when creating a pneumatic post or conveyor, but does not eliminate them. Sample transfer time is practically not reduced and remains fairly large. A significant limitation is imposed on the allowable elevation difference between the nodes of the device - no more than 3 ÷ 5 meters, which prevents the use of the device for sampling from technological equipment of radiochemical plants located in deep canyons.

The closest in technical essence to the claimed is a method of sampling and delivery of samples of radioactive solutions and the corresponding device according to the patent of the Russian Federation for invention No. 2569556, IPC G01N 1/10, publ. November 27, 2015, which are taken as a prototype.

A device for implementing the method includes a device for sampling and dilution of portions of a radioactive solution installed on the process pipeline, a controlled three-way valve connected through a transport tube with a sampling container. The device also includes a gas phase flow sensor with a blow tube, a pressure-vacuum regulator, the output of which is connected to the outlet of the transport tube through the receiving tank. A pressure-vacuum sensor is installed at the regulator outlet, and a solution is installed at the end of the transport tube in the cross section of the tube, while the outputs of the pressure-vacuum sensor and the alarm device are connected to the measurement inputs of the controller, to which the gas flow sensor is also connected. The first control output of the controller is connected to the control input of the device for selecting and diluting portions of the radioactive solution, the second output is connected to the vacuum regulator.

The method is as follows. At the command of the controller, the device for the selection and dilution of portions of the radioactive solution takes a small portion of the radioactive solution from the pipeline or process apparatus - no more than 0.5 ml. The specified initial portion is diluted in the device for sampling and dilution 20 ÷ 100 times, and part of the diluted radioactive solution is returned to the pipeline (or technological device). Part of the diluted radioactive solution is a sample with a volume of 5 ÷ 20 ml, through a three-way valve enters the transport tube, after which the three-way valve at the command of the controller switches and connects the input of the transport tube with the gas phase flow sensor. At the command of the controller, the regulator creates a vacuum in the receiving tank and at the exit of the transport tube. Due to the positive pressure drop of the gas phase in the transport tube before and after the sample in the direction of the receiving tank, the sample begins to move. At the entrance of the transport line through the blow, the gas phase flow sensor and the three-way valve begins to flow air. The amount of air flow and sensor output is proportional to the speed of the sample. The controller registers the specified signal and, by its deviation from the setpoint, regulates the amount of vacuum at the regulator output so that the sample moving speed through the transport tube is kept approximately constant and does not exceed the setpoint, in particular, it should be no more than 200 ÷ 500 m / hour.

The disadvantage of the aforementioned method and device is sampling using an expensive and complex device for taking and diluting portions of a radioactive solution, the use of which is also limited by the allowable height difference between its nodes and the sampling point - no more than 3 ÷ 5 m. On the other hand, The procedure of diluting the solution directly during sampling gives a significant effect only for 5 ÷ 10 percent of the sampling points of the most highly active solutions in the technological scheme for processing SNF. For the remaining medium and low technology products, it is quite effective from the point of view of personnel protection from gamma radiation of a sample that limits the volume of the sample transmitted to the location of the receiving tank.

The invention solves the problem of sampling a small volume with a large elevation difference between the sampling point and the nodes of the device that performs it, creating a more reliable and cheap way to deliver samples of medium and low-level technological products from process equipment to the analytical laboratory using an extended transport tube, and implementation of sampling control at intermediate points of centrifugal extraction plants, which is essential for optimizing extraction technological processes and detection of emergency situations.

The technical result from the use of the claimed invention is a significant increase in the reliability of sampling and delivery of samples of medium and low level radioactive solutions from process equipment, in particular from equipment located in deep canyons, by limiting the amount of radioactive solution transported during sampling and delivery operations, and ensuring a sufficiently high degree of personnel safety with respect to radiation exposure.

The technical result obtained from the implementation of the claimed invention is achieved by the fact that for sampling and delivery of samples of radioactive solutions by a method including sampling using a sampling device, introducing the sample into the capillary transport tube, creating a positive pressure drop of the gas phase in the transport tube before and after the sample in the direction of its movement, the regulation of the magnitude of the positive pressure drop in order to limit the speed of movement of the sample through the transport tube and the reception of the sample in the test sample According to the claimed method, a sampling tube is used as a sampling device, the free end of the transport tube is previously connected to the internal cavity of the sampling tube above the free end of the latter, after which the free end of the sampling tube is vertically immersed in a radioactive solution, the preliminary tube is filled with a radioactive solution above the point of its connection with the free end of the transport tube, creating an appropriate vacuum g the gas phase in the sampling tube relative to the pressure in the solution at the free end of the sampling tube, then a portion of the radioactive solution is introduced into the transport tube, increasing the negative pressure of the gas phase in the transport tube at a given speed to a predetermined value, and then reducing the negative pressure of the gas phase in the sampling tube the level of the radioactive solution in the sampling tube is set below the free end of the transport tube, and proceed to moving the sample Sportna tube followed by administration of a sample probopriemnuyu container.

In this case, the regulation of the value of the positive pressure drop while moving the sample is carried out by changing the amount of vacuum in the gas phase of the transport tube and / or the value of the excess pressure in the sampling tube.

In the device for the implementation of the claimed method, including a sampling device installed in the process apparatus or in the pipeline, the gas phase flow sensor, a capillary transport tube, the output of which is equipped with a solution presence detector and connected to a sampling tank, which, in turn, is connected to a pressure regulator negative pressure and negative input of the differential pressure sensor, the electrical input of the pressure-vacuum regulator is connected to the output of the control controller, and the inputs The controller is connected to the electrical outputs of the solution detector, differential pressure sensor and gas phase flow sensor in accordance with the invention. A sampling tube and a second pressure-vacuum regulator connected to its upper part, the electrical input of which is connected to the second output of the controlling controller, is used as a sampling device. The free end of the transport tube is sealed to the internal cavity of the sampling tube above its free end, immersed in a tube. control solution, the upper part of the sampling tube is connected to the negative input of the second differential pressure sensor, which is additionally equipped with the device, and the electrical output of the sensor is connected to the auxiliary input of the control controller.

In this case, the upper part of the sampling tube is connected to the second pressure-vacuum regulator through a gas phase flow sensor electrically connected to the control controller.

In addition, the positive input of the first differential pressure sensor is connected to the upper part of the sampling tube, and the positive input of the second differential pressure sensor is connected to the gas phase of the process apparatus.

In addition, the device is equipped with a second solution presence detector, installed at the initial part of the transport tube above its connection to the sampling tube, and the output of the detector is connected to the input of the controlling controller.

In addition, the free end of the sampling tube, which is in a controlled solution, can be equipped with a filter, and part of the initial portion of the transport tube in order to increase the internal volume of the specified portion without increasing the difference in height of its beginning and end can be made in the form of a spiral.

In addition, in the embodiment of the device, the upper part of the sampling tube can be made with an extension designed to install a sensor monitoring the composition of the process solution. At the same time, the transport capacity is used as the sample-receiving capacity, designed to deliver the sample of medium and low-level radioactive solutions to an analytical instrument.

In addition, in the embodiment of the device, the upper part of the transport tube can also be made with an extension designed to install a sensor monitoring the composition of the process solution. In this case, the expanded upper part of the transport tube is used as the sample-receiving vessel, around which an additional shell is installed to provide radiation protection to personnel.

The invention is illustrated by drawings, in which FIG. 1 shows a block diagram of an apparatus for implementing a method for sampling and delivering samples of medium and low-level technological products, in which the upper part of the sampling tube is made with expansion; in fig. 2 is a block diagram of another embodiment of the device in which the upper part of the transport tube is made with the extension used as a sample receptacle.

The device shown in figure 1, contains a transport capillary tube 1, the output of which is equipped with a signaling device 2 of the presence of the solution and connected to the test-receiving tank 3, which, in turn, is connected to the pneumatic output of the pressure-vacuum regulator 4 and the negative input of the differential pressure sensor 5 . The free end of the transport tube 1 is connected to the internal cavity of the vertical sampling tube 6 at a height h1 relative to the free end of the latter, also equipped with an inlet filter 7. The sampling tube 6 is installed through the overlap 8 in the process device 9 located in the canyon 10. To the upper part of the internal cavity of the sampling tube 6 is connected to the negative input of the second differential pressure sensor 11, the positive input of the first differential pressure sensor 5 and, through the sensor 12 of the gas phase flow, Torah-pressure regulator 13 dilution. The positive input of the second differential pressure sensor 11 is connected to the gas phase of the process apparatus 9. The initial portion of the transport tube 1 is located in close proximity to the sampling tube 6 and is equipped with a solution presence indicator 14 located at a height h2 relative to the tube connection point.

If necessary, in the production version of the device, part of the specified initial section of the transport tube 1 can be made in the form of a spiral. Such a constructive decision can be made due to the fact that the permissible difference in the heights of the beginning and end of the section of the capillary filled with a solution is limited due to the maximum possible vacuum (vacuum) required to lift the solution up. If the section is vertical, then the length of the capillary is equal to the maximum height difference, which, for a given internal diameter of the capillary, limits the volume of the sample. If it is necessary to increase the volume of the sample in the same height limits, then the vertical segment can be made in the form of a spiral, thereby increasing the capillary length and the volume of the sample while maintaining the allowable difference in height.

The electrical outputs of the sensors 5 and 11 of differential pressure, signaling devices 2 and 14 of the presence of the solution, as well as the sensor 12 of the gas phase flow are connected to the inputs of the control controller 15. One control output of the controller 15 is connected to the control input of the pressure-depression regulator 4, the second - to the control input regulator 13 pressure-dilution. Each of these regulators 4 and 13 can be performed, for example, in the form of a reversible peristaltic pump. In the embodiment shown in FIG. 1, in addition, at or near the top of the sampling tube 6, a sensor 16 for monitoring the composition of the process solution can be placed. In this case, the upper part of the sampling tube 6 can be made with the extension 17.

In accordance with another embodiment of the device (see FIG. 2), the transport tube 1 can be placed inside the sampling tube 6, and its upper part can be made with the extension used as the sample receiving container 3, which houses the sensor 16 for monitoring the composition of the process solution. If the probe receptacle 3 is located above the ceiling 8, an additional shell 18 may be installed around it to provide radiation protection to personnel.

The method of sampling and delivery of samples is carried out by the device in accordance with the following sequence of actions performed by the commands of the controlling controller.

Preliminarily, a portion of air is introduced into the sampling tube 6 by means of a pressure-depression regulator 13, after which the differential pressure sensor 11 measures the difference in pressure in the sampling tube 6 and in the gas phase of the process apparatus 9. During the measurements, regulators 4 and 13 are disconnected the outputs are blocked. If a solution was present in the sampling tube 6, then it is forced out of the tube 6 through the filter 7 by the excess air pressure, while the pressure difference slowly decreases. The rate of pressure drop is determined by the pressure drop across the filter 7 and its hydrodynamic resistance. Upon expiration of the solution from the tube 6 through the filter 7, an excess of air passes from the tubes 6 and 1 into the solution, the above-mentioned pressure difference drops to the value of P _H corresponding to the hydrostatic pressure of the column of the controlled solution with height H:

where: g - acceleration of gravity, 9.8 m / s ² ;

ρ _p - the density of the controlled solution, kg / m ³

H - the level of the controlled solution relative to the filter 7, m

Based on the duration of the emptying of the sampling tube 6 from the solution and the excess amount of air, the controller 15 preliminarily diagnoses the condition of the filter 7. If the specified durations are more than the specified limits, the device performs an auxiliary operation for washing the filter.

Actually sampling from the technological apparatus (or pipeline) 9 begins with the receipt of the solution in the sampling tube 6 using the regulator 13, which gradually increases in the tubes 6 and 1 the vacuum relative to the pressure of the solution at the inlet of the filter 7, while the solution from the apparatus 9 rises through the tube 6 up. At the beginning of the lifting solution of the sensor signal 5, proportional to the pressure difference in the sampling tube 6 and in the transport tube 1, is zero. At some point, the solution closes the free opening of the transport tube 1, the controller 15 detects the difference between the signal from sensor 5 and turns off the regulator 13. Since the growth rate of the hydrostatic pressure of the solution column received in the sampling tube 6, lagged behind the rate of negative pressure in the sampling tube 6 then after the regulator 13 is turned off, the solution rises above the level of the free opening of the transport tube 1. In the latter, a vacuum is created relative to the tube 6, which is fixed by the sensor 5, n After that, the regulator 13 turns on in the opposite direction and slowly decreases the vacuum in the tube 6 until the pressure difference returns to zero in the sampling tube 6 and in the transport tube 1. After fixing the zero signal of the sensor 5, the value of the vacuum value P _{h1 is} remembered by the sensor 11, corresponding to the hydrostatic pressure of the controlled solution column with height (h1-Н):

Based on the measured values of pressure P _H , vacuum P _h1 , known height h1, taking into account expressions (1) and (2), using the controller 15, determine the density ρ _p and the level H of the solution in the process apparatus 9:

Determining the density ρ _p and the level H of the solution in the apparatus 9 makes it possible to obtain useful technological information during the sampling procedure at no additional cost and in the absence of sensors in the technological apparatus with radioactive solution. In addition, the obtained density value ρ _{p is} used to control the subsequent actions for the selection and transfer of the sample.

After fixing the level of the solution in the tube 6 at the height h1 of the free end of the tube 1, a portion of the solution is additionally received into the sampling tube 6 by means of the regulator 13. If the sensor 16 is installed in the upper part of the sampling tube 6 or next to it, including in the version with extension 17, the level of the solution adopted into the tube 6 should be above the sensor element of the sensor 16. The moment the solution reaches the specified level and the end of the solution reception procedure is determined the nature of the sensor signal 16 changes in the course of receiving solution. If the sensor 16 is missing, then a portion approximately equal to the specified volume of the sample being taken V _pr (ml) is taken into the sampling tube 6. To this end, the vacuum in the tube 6 is increased by the value of ΔP ₆ , after which the vacuum value is stabilized using the regulator 13:

where: S ₆ is the free cross-sectional area of the tube 6, (cm ² ).

In the absence of the sensor 16, the end of the reception of the solution in the sampling tube 6 is fixed upon reaching the pressure difference in the tubes 1 and 6 of an approximate equality of ΔP ₆ . Then in the transport tube 1 for subsequent transfer to the sample container 3 take a portion of the solution, equal to the specified volume V _CR . To this end, the regulator 4 increases the vacuum in the transport tube 1. The required value of the vacuum increment ΔP ₁ in the transport tube 1 is defined as:

where: S ₁ is the free cross-sectional area of tube 1, (cm ² ).

The ratio of the areas of free sections of the sampling tube 6 and the transport tube 1 can be from 10 to 100, respectively, the upper level h ₂ samples of a given volume in the vertical transport tube 1 relative to its free end may be 10 ÷ 100 times higher than the level of the solution in the sampling tube 6 . However, if the process unit 9 communicates with the atmosphere and there is no overpressure, the solution level h _max in a transport pipe 1 with respect to the surface level of the solution in the apparatus 9 is limited techn Kim maximum vacuum, which is approximately 80 psi (100 kPa - full vacuum). Respectively:

For example, for ρ = 1500 kg / m ^{3, the} value of h _max should not exceed 5.5 m. In this case, when the internal diameter of the transport tube 1 is equal to, for example, 1.5 mm, and when the free end of the tube 1 is approximately at the level solution in the apparatus of the limit on the volume of the sample will be 9 ml. To increase the volume of the sample, if necessary, the initial part of the transport tube 1 can be performed, for example, in the form of a vertical ascending spiral, which provides an increase in the specified volume with a constant internal diameter of the transport tube 1 and the level of the solution is not higher than the allowable one. If at a height of h ₂ in the vertical section of the transport tube 1 is installed a detector 14 for the presence of a solution, then the sample is taken into the transport tube 1 until the moment when the detector 14 triggers.

After receiving the sample in the transport tube 1, the amount of vacuum in the sampling tube 6 by means of the regulator 13 is reduced, in the tube 6 the level of the solution is gradually reduced. The level of the solution in the transport tube 1 relative to the level in the apparatus 9 remains unchanged, the amount of vacuum in the transport tube 1 relative to its free end is also unchanged and equal to the hydrostatic pressure of the solution column in the transport tube 1, and the vacuum in tube 1 relative to the tube 6 simultaneously increases. After the amount of vacuum in the sampling tube 6 becomes less than the hydrostatic pressure of the solution column with height h1, the level of the solution in the sampling tube 6 drops below the free end of tube 1.

After removing the solution from the zone of connection of the sampling tube 6 with the transport tube 1, the vacuum in the sampling tube 6 is stabilized by means of the regulator 13, while the level of the solution in the sampling tube 6 is less than h1 and remains constant. The pressure difference between the upper surface of the solution in the tube 1 and the surface of the solution in the free end of the transport tube 1 exceeds the hydrostatic pressure of the sample portion in the tube 1, the sample solution begins to move along the tube 1 in the direction of the sample container 3 in the form of an extended liquid “tube” is determined by its volume and the free cross-sectional area of the tube 1. At this point, the signal of the sensor 12 determines the flow rate of air entering the transport tube 1 through the sampling tube 6. C The rate of movement of the sample is proportional to the value of the indicated flow rate, which is regulated by the change in vacuum in the gas phase of the receiving tank 3 in order to stabilize the sample speed within 200 ÷ 500 m / h. If the movement speed is too high, the “plug” of the solution in the transport tube 1 may burst into several “plugs” interleaved by air bubbles, with the result that some solution may remain on the walls of tube 1 after passing the sample. This will lead to a decrease in the volume of the sample taken into the container 3. In addition, when transmitting the next sample, it will mix in tube 1 with the remnants of the previous one, which will affect the representativeness of the results of the determination of the composition.

The rate of movement of the sample is influenced by the magnitude of the drop in height of the beginning and end of the “plug” of the solution, as well as the hydrodynamic resistance of tube 1, which, in turn, depends on the length of the “plug” of the solution. In particular, after the beginning of the “plug” reaches the receiving tank 3 and the solution begins to flow into the container 3, the hydrodynamic resistance starts to decrease rapidly and the speed of movement increases. The moment of the beginning of reception is recorded in the controller 15 by the signal of the detector 2 of the presence of the solution and the corresponding adjustment of the speed control algorithm is made. The end of the reception of the solution into the container 3 is fixed both by the signal of the sensor 2 and by the pressure jump in the receiving tank 3. The speed of the solution moving during its reception into the container 3 can also be implemented using an additional solenoid valve (not shown in Fig. 1 ), installed on the line of the tube 1 in front of the container 3. According to the commands of the controller 15, the valve is periodically closed when exceeding the speed of movement of a given value.

In the embodiment of the device (see FIG. 2), the sample is received in the expanded upper part of the transport tube 1, used as the sample container 3, in which the sensor 16 for monitoring the composition of the process solution is placed. In this case, the control of the process of entering the solution into the sample container 3 is performed by the signal of the detector 2 of the presence of the solution, the filling level of the container 3 is fixed by the sensor and then maintained unchanged by means of the regulator 4. The sample portion is almost completely in the sample receiving container 3, therefore the vacuum required to maintain the level of the solution in the vicinity of the detector 2 is small, approximately 5 ÷ 15 kPa. Under these conditions, it is possible to take a sample from the tank 3 with the subsequent dilution and issue of a diluted sample, for example, in accordance with the known method of sampling and delivering samples of radioactive solutions in accordance with the RF patent for invention No. 2485473.

In principle, in one embodiment, the device can be additionally equipped with a normally open controlled shut-off valve placed on the sampling tube 6 between the filter 7 and the free end of the transport tube 1 (not shown in the drawings). In this case, in the sampling tube 6 by means of the regulator 13, the solution is taken to a level that provides the specified sample volume above the free end of the transport tube 1. Before transferring the sample, the valve closes the lower part of the sampling tube 6, and in its upper part an overpressure is created using the regulator 13 , which can significantly exceed the above value of 80 kPa and be sufficient to transfer a sample of large volume to a predetermined height. Managed valve can be performed with the transfer of mechanical force from the pneumatic actuator, placed above the upper end of the sampling tube 6, through a long vertical thrust to the locking actuator. On the other hand, the use of a check valve complicates the design of the device and reduces its reliability.

Thus, in terms of the canyon placement of technological equipment, characterized by a significant elevation difference between the place of issue of the sample over the canyon overlap and the sampling point in the technological device, the proposed solution eliminates additional equipment for lifting the controlled process solution to the sampling point, which increases the reliability of the sampling procedure.

In addition, the invention makes it possible to ensure the maintainability of the device for sampling and delivery of samples due to the fact that its critical nodes are above the overlap of the canyon. At the same time, the use of the claimed invention allows to significantly reduce the cost of the most frequent sampling control of medium and low-level technological products of the processing of spent nuclear fuel.

The significant advantages of the claimed invention compared with the method currently used in radiochemical plants for the selection and delivery of samples also include the possibility of sampling on the overflows between the stages of centrifugal extraction devices. Additional information on the density of the monitored solution and its level in the process apparatus will allow excluding the cost of individual devices designed to determine the specified parameters at the sampling points.

In addition, the inclusion of a solution composition sensor in the cyclically operating sampling device of the sensor for monitoring the composition of the solution significantly expands the possibilities of operational analytical control of the technological process for processing the SNF. The latter is due to the fact that the placement of accurate and selective sensors for monitoring the composition in the installation area of the process equipment is almost impossible due to the presence of intense gamma radiation and the complexity of their remote maintenance. The removal of sensors for monitoring the composition from the canyon allows both maintenance and protection from gamma radiation of large volumes of technological solutions.

Claims (13)

1. A method of sampling and delivering samples of radioactive solutions, including sampling using a sampling device, introducing a sample of the solution into a capillary transport tube, creating a positive pressure drop of the gas phase in the transport tube before and after the sample in the direction of its movement, adjusting the positive differential pressure for limit the speed of movement of the sample through the transport tube and the reception of the sample in the sampling tank, characterized in that as a sampling device using sampling The first tube, the free end of the transport tube is connected to the internal cavity of the sampling tube above the free end of the latter, the free end of the sampling tube is vertically immersed in a radioactive solution, and the sample tube is filled with a radioactive solution above the free end of the transport tube, creating a corresponding gas depression. phase in the sampling tube relative to the pressure in the solution at the free end of the sampling tube, then A portion of the sample of the radioactive solution is introduced into the transport tube, increasing the gas phase vacuum in the transport tube with a given speed to a given value, and then decreasing the gas phase vacuum in the sampling tube so that the level of the radioactive solution in the sampling tube is set below the free end transport tube, and proceed to moving the sample through the transport tube, followed by receiving the sample in the sampling tank. 2. The method according to p. 1, characterized in that the regulation of the magnitude of the positive pressure drop when moving the sample is carried out by changing the magnitude of the vacuum in the gas phase of the transport tube and / or the magnitude of the excess pressure in the sampling tube. 3. A device for sampling and delivering samples of radioactive solutions, including a sampling device installed in the process apparatus or in the pipeline, a gas phase flow sensor, a transport capillary tube, the output of which is equipped with a solution presence detector and connected to the sampling tank, which, in turn, connected to a pressure-depression regulator and a negative input of a differential pressure sensor; an electrical input of a pressure-vacuum regulator is connected to the output of a control controller The controller’s inputs are connected to the electrical outputs of the solution presence detector, differential pressure sensor and gas phase flow sensor, characterized in that a sampling tube and a second pressure-vacuum regulator connected to its upper part, the electrical input of which is connected to the second output of the control controller, the free end of the transport tube is hermetically connected to the internal cavity of the sampling tube above its free end, In the controlled solution, the upper part of the sampling tube is connected to the negative input of the second additional differential pressure sensor, the electrical output of which is connected to the additional input of the controlling controller. 4. The device according to claim 3, characterized in that the upper part of the sampling tube is connected to the second pressure-vacuum regulator through a gas phase flow sensor electrically connected to the control controller. 5. The device according to p. 3, characterized in that the positive input of the first differential pressure sensor is connected to the upper part of the sampling tube, and the positive input of the second differential pressure sensor is connected to the gas phase of the process apparatus. 6. The device according to p. 3, characterized in that the device is equipped with a second solution presence detector, installed in the initial part of the transport tube above its connection point to the sampling tube, and the output of the detector is connected to the input of the control controller. 7. The device according to p. 3, characterized in that the free end of the sampling tube, which is in a controlled solution, is provided with a filter. 8. The device according to p. 3, characterized in that part of the initial section of the transport tube is made in the form of a spiral. 9. The device according to p. 3, characterized in that the upper part of the sampling tube is made with the extension, which additionally has a sensor for monitoring the composition of the technological solution. 10. The device according to p. 9, characterized in that the transport capacity is used as a sampling container for delivering a sample of radioactive solutions to an analytical instrument. 11. The device according to p. 3, characterized in that the upper part of the transport tube is made in the form of an extension, which is used as a sample receiver. 12. The device according to p. 11, characterized in that in the expansion of the upper part of the transport tube additionally installed sensor control composition of the solution. 13. The device according to claim 11, characterized in that an additional shell is installed around the probe-receiving container for radiation protection of personnel.

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