CN112033863A - Device and method for measuring uranium migration in small column simulation soil - Google Patents
Device and method for measuring uranium migration in small column simulation soil Download PDFInfo
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- CN112033863A CN112033863A CN202010971905.9A CN202010971905A CN112033863A CN 112033863 A CN112033863 A CN 112033863A CN 202010971905 A CN202010971905 A CN 202010971905A CN 112033863 A CN112033863 A CN 112033863A
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- G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
- G01N13/00—Investigating surface or boundary effects, e.g. wetting power; Investigating diffusion effects; Analysing materials by determining surface, boundary, or diffusion effects
Abstract
The invention belongs to the technical field of experimental devices, and discloses a device and a method for determining uranium migration in small column simulated soil, wherein the device for determining uranium migration in small column simulated soil is provided with a simulated soil gas heating unit, a gas circulating pump and one or more simulated soil medium units; the simulated soil gas heating unit is provided with a PVC pipe, a disturbance fan is arranged inside the PVC pipe, an upper pipe cover is buckled at the upper end of the PVC pipe, a lower pipe cover is buckled at the lower end of the PVC pipe, and an electric heating wire is arranged inside the lower pipe cover; the simulation soil medium unit is provided with the PVC pipe, and the inside of PVC pipe is filled with even ground medium, and ground medium bottom is filled with and contains the uranium substrate, and the upper end lock is installed the upper tube cap, and the lower extreme lock is installed the lower tube cap. When the device is used, uranium elements can penetrate through a rock-soil medium in the model, so that observable uranium content is formed in the sampling gas in the PVC pipe at the upper end of the rock-soil medium, and the original observation time is greatly shortened.
Description
Technical Field
The invention belongs to the technical field of experimental devices, and particularly relates to a device and a method for determining uranium migration in small column simulation soil.
Background
Uranium is a natural radioactive element and is currently the most predominant nuclear source. In the application process of nuclear energy and nuclear technology, the nuclear energy and the nuclear technology are likely to diffuse into the environment, and the soil is polluted through migration and deposition, so that the health of human beings is harmed. Because the medium environment and the fluid environment in the actual soil are complex, the research on the migration rule of uranium in the soil is difficult, and the influence conditions of uranium nuclide migration cannot be accurately known. Meanwhile, migration of uranium in soil is a long-term and slow process, and distribution change of uranium in a soil medium in a large range is difficult to observe in a short time.
At present, the research on uranium element migration is mostly carried out by a numerical simulation method, and only a few researchers put uranium ores in the air of a wide-mouth glass bottle or put uranium-containing media in river sand to research the migration behavior of uranium in the air or in pores.
In summary, the problems of the prior art are as follows:
the migration of uranium in soil is a slow and complex process, and the research on the environmental impact on the migration process is difficult to a certain extent, so that the research method or device proposed by scholars in the field at present can not meet the requirements of soil uranium migration controllability and short-time experiment.
Disclosure of Invention
Aiming at the problems in the prior art, the invention provides a device and a method for determining uranium migration in small column simulation soil.
The device is realized in such a way that the device for measuring the uranium migration in the small column simulated soil is provided with a simulated soil gas heating unit, a gas circulating pump and one or more simulated soil medium units;
the simulated soil gas heating unit is provided with a PVC pipe, a disturbance fan is arranged inside the PVC pipe, an upper pipe cover is buckled at the upper end of the PVC pipe, a lower pipe cover is buckled at the lower end of the PVC pipe, and an electric heating wire is arranged inside the lower pipe cover;
the simulation soil medium unit is provided with the PVC pipe, and the inside of PVC pipe is filled with even ground medium, and ground medium bottom is filled with and contains the uranium substrate, and the upper end lock is installed the upper tube cap, and the lower extreme lock is installed the lower tube cap.
Furthermore, a temperature sensor is arranged in a PVC pipe at the lower end of the disturbance fan of the simulated soil gas heating unit, and the fan and the temperature sensor are respectively connected with an external DC +12V power supply and a temperature controller through leads.
Further, the rock-soil medium and the uranium-containing base material are placed on a porous bearing plate in the simulated soil medium unit PVC pipe, and the porous bearing plate is horizontally fixed in the simulated soil medium unit PVC pipe through a bolt.
Furthermore, a group of pagoda joints are arranged on the pipe wall at the lower end of the PVC pipe of the simulated soil gas heating unit.
Furthermore, a group of pagoda joints are respectively arranged on the pipe walls of the upper end and the lower end of the PVC pipe of the soil medium simulating unit.
Furthermore, two groups of pagoda joints at the upper end and the lower end of the simulated soil gas heating unit PVC pipe and the simulated soil medium unit PVC pipe are respectively arranged on the same horizontal straight line.
Another object of the present invention is to provide a method for measuring uranium migration in pillar simulated soil of the apparatus for measuring uranium migration in pillar simulated soil, the method for measuring uranium migration in pillar simulated soil comprising:
(1) preparing a uranium-containing base material and a rock-soil medium;
(2) a combined model unit;
(3) carrying out experimental measurement;
(4) and (5) analyzing an experimental result.
Further, the steps of preparing the uranium-containing base material and the rock-soil medium comprise:
1) weighing 150g of 60-mesh dry mud powder by using a precision electronic balance, putting the 150g of dry mud powder into a container, injecting 20g of distilled water, and uniformly stirring the mud powder and the water;
2) putting the evenly stirred yellow mud into a mould, and putting the mould into a hydraulic press;
3) applying pressure to the die through a hydraulic machine, and keeping for 5 minutes after the pressure applied by the hydraulic machine reaches the target pressure;
4) releasing the pressure of the hydraulic press, taking down the mold, and putting the mold and the rock-soil medium into a constant temperature box for baking until the rock-soil medium is separated from the mold;
5) the geotechnical media is removed and baked on to dry weight.
Further, the experimental measurement step includes:
1) opening the temperature controller, and heating the gas in the simulated soil gas heating unit to a target constant temperature;
2) starting a circulating air pump to enable heated air in the simulated soil air heating units to circulate in the bottom cavity of each simulated soil medium unit for a period of time;
3) recording the starting cycle time of the air pump as the starting time of the experiment;
4) sampling the upper chamber of the simulated soil medium unit by using a nitric acid solution and a miniature air pump at intervals, wherein the nitric acid solution is prepared by using ultrapure water and commercially available superior pure nitric acid, and a buffer bottle is connected between the air pump and the sampling bottle;
5) drawing a standard curve for analyzing the uranium content by spectrophotometry;
6) analyzing the uranium content in each nitric acid solution collected sample, measuring each sample twice to calculate an average value, and carrying out third measurement when the content difference value of the two times exceeds +/-15% of the first measurement value;
7) data were recorded and plotted.
Further, a nitric acid solution and a miniature air pump are adopted to collect samples in the upper cavity of the simulated soil medium unit at intervals, the nitric acid solution is prepared from ultrapure water and market-sold superior pure nitric acid, the concentration of the solution nitric acid is 2.0mol/L, the dosage of the nitric acid solution is 5ml each time, the flow of the air pump is set to be 1L/min during air suction, the air suction time is 15min, and a buffer bottle is connected between the air pump and the sampling bottle.
The invention has the advantages and positive effects that: the device for measuring uranium migration in the small column simulated soil can prove that the temperature of the simulated soil gas circulating in the device can be stably controlled in the experimental observation process;
the uranium element can migrate in the rock-soil medium along with the simulated soil airflow, the porosity of the rock-soil medium has an important influence on the migration of the uranium element in the rock-soil medium, and the larger the porosity of the rock-soil medium is, the more beneficial the migration of the uranium element is;
according to the experimental result, after about 18 days, the uranium element can penetrate through the rock-soil medium in the model, so that observable uranium content is formed in the sampling gas in the PVC pipe at the upper end of the rock-soil medium, and the original observation time is greatly shortened.
Drawings
FIG. 1 is a schematic structural diagram of a simulated soil gas heating unit of a small column simulated soil uranium migration measuring device provided by an embodiment of the invention;
fig. 2 is a schematic structural diagram of a simulated soil medium unit of the uranium migration determination device in pillar simulated soil according to the embodiment of the invention;
FIG. 3 is a schematic diagram of an appearance structure of a simulated soil gas heating unit and a simulated soil medium unit of the device for measuring uranium migration in small column simulated soil provided by the embodiment of the invention;
fig. 4 is a schematic view of a pipeline connection of a uranium element migration simulation experiment of the uranium migration determination device in pillar simulation soil according to the embodiment of the present invention;
fig. 5 is a schematic connection diagram of a uranium-containing gas sampling pipeline of the uranium migration determination device in the pillar simulation soil provided by the embodiment of the invention;
fig. 6 is a uranium standard curve for measuring the uranium content in the sampling gas of the uranium migration determination device in the small column simulated soil according to the embodiment of the invention;
fig. 7 is a diagram showing a detection result of uranium content in sample gas in an upper chamber of each model unit of the device for determining uranium migration in pillared simulated soil provided by the embodiment of the invention;
in fig. 1: 1. simulating an upper pipe cover of the soil gas heating unit; 2. simulating a soil gas heating unit PVC pipe; 3. a disturbing fan; 4. simulating a lower pipe cover of the soil gas heating unit; 5. an electric heating wire; 6. an air inlet pagoda joint; 7. a gas outlet pagoda joint; 8. a temperature sensor;
in fig. 2: 9. simulating an upper pipe cover of the soil medium unit; 10. simulating a soil medium unit PVC pipe; 11. a geotechnical medium; 12. simulating a lower pipe cover of the soil medium unit; 13. a pagoda joint at the circulating air outlet; 14. a recirculating air inlet pagoda joint; 15. a porous carrier plate; 16. sampling an air inlet pagoda; 17. sampling an air outlet pagoda; 18. a uranium-containing substrate.
Detailed Description
In order to further understand the contents, features and effects of the present invention, the following embodiments are illustrated and described in detail with reference to the accompanying drawings.
The structure of the present invention will be described in detail below with reference to the accompanying drawings.
As shown in fig. 1 to 7, the apparatus for determining uranium migration in simulated soil of a small column comprises a simulated soil gas heating unit and one or more simulated soil medium units;
the simulated soil gas heating unit is provided with a simulated soil gas heating unit PVC pipe 2, a disturbance fan 3 is clamped inside the simulated soil gas heating unit PVC pipe 2, a temperature sensor 8 is installed inside the simulated soil gas heating unit PVC pipe 2 at the lower end of the disturbance fan 3, the disturbance fan 3 is connected with an external DC +12V power supply through a lead, and the temperature sensor 8 is connected with an external temperature controller through a signal wire;
the upper end of the simulated soil gas heating unit PVC pipe 2 is buckled with a simulated soil gas heating unit upper pipe cover 1, the lower end of the simulated soil gas heating unit PVC pipe 2 is provided with a simulated soil gas heating unit lower pipe cover 4, an electric heating wire 5 is arranged inside the simulated soil gas heating unit lower pipe cover 4, and the electric heating wire 5 is connected with an external temperature controller through a lead;
an air inlet pagoda joint 6 and an air outlet pagoda 7 are arranged on the lower pipe wall of the simulated soil gas heating unit PVC pipe 2;
the simulation soil medium unit is provided with simulation soil medium unit PVC pipe 10, even ground medium 11 is filled in simulation soil medium unit PVC pipe 10, uranium-containing base material 18 is filled in ground medium 11 bottom, ground medium 11 and uranium-containing base material 18 are placed on porous bearing board 15 in simulation soil medium unit PVC pipe 10, porous bearing board 15 is fixed in simulation soil medium unit PVC pipe 10 through bolt level.
As a preferred embodiment of the invention, the air inlet pagoda joint 6 and the air outlet pagoda 7 on the lower pipe wall of the PVC pipe 2 of the simulated soil gas heating unit are arranged on the same horizontal straight line which is about 3.5cm away from the bottom of the lower pipe cover 4 of the simulated soil gas heating unit; the air outlet pagoda 16 and the air outlet pagoda 17 on the upper end pipe wall of the simulated soil medium unit PVC pipe 10 are arranged on the same horizontal straight line which is about 3.5cm high from the bottom of the upper pipe cover 9 of the simulated soil medium unit, and the air inlet pagoda joint 13 and the air inlet pagoda joint 14 on the lower end pipe wall are arranged on the same horizontal straight line which is about 3.5cm high from the bottom of the lower pipe cover 4 of the simulated soil gas heating unit;
a certain heat insulation material is wrapped outside the simulated soil gas heating unit PVC pipe 2, the electric heating wire 5 is used for heating air in the simulated soil gas heating unit PVC pipe 2, and the heated air is conveyed to a cavity at the lower end of a rock soil medium 11 in the simulated soil medium unit PVC pipe 10 by an air circulating pump to form simulated soil gas; the temperature sensor 8 and the electric heating wire 5 are connected with an external temperature controller through leads for accurately controlling the gas temperature in the PVC pipe 2 of the simulated soil gas heating unit;
fully sealing the rock soil medium 11 in the simulated soil medium unit PVC pipe 10 and the inner wall of the simulated soil medium unit PVC pipe 10;
when the experiment is carried out, the air inlet pagoda joint 6, the air outlet pagoda joint 7 and one or more of the soil gas heating unit simulated by the uranium migration measuring device in the small column simulated soil are connected end to end through the silica gel hose to form a closed loop, wherein the air inlet pagoda joint 13 and the air outlet pagoda joint 14 are arranged at the bottom of the soil medium unit simulated by the uranium migration measuring device in the small column simulated soil.
The working principle of the invention is as follows:
1. preparation of uranium-containing base material and rock-soil medium
1) Weighing 150g of 60-mesh dry mud powder by using a precision electronic balance, putting the 150g of dry mud powder into a container, injecting 20g of distilled water, and uniformly stirring the mud powder and the water;
2) putting the evenly stirred yellow mud into a mould, and putting the mould into a hydraulic press;
3) applying pressure to the die through a hydraulic machine, and keeping for 5 minutes after the pressure applied by the hydraulic machine reaches the target pressure;
4) releasing the pressure of the hydraulic press, taking down the mold, and putting the mold and the rock-soil medium into a constant temperature box for baking until the rock-soil medium is separated from the mold;
5) taking down the rock-soil medium and continuously baking the rock-soil medium to dry weight;
the purpose of manufacturing different rock-soil medium porosity sizes is achieved by controlling the pressing pressure of a hydraulic press in the rock-soil medium preparation process;
the preparation process of the uranium-containing base material is the same as that of a rock-soil medium, except that a circular groove with the diameter of 4cm is reserved in the center of yellow mud when the yellow mud which is uniformly stirred is placed into a mould, and 50g of uranium ore powder with the size of 200 meshes is placed into the circular groove.
2. Combined model unit
Placing a uranium-containing base material and a rock-soil medium on a porous bearing plate in a PVC pipe of a simulated soil medium unit, sealing the rock-soil medium and the inner wall of the PVC pipe by using silicone grease, and simultaneously respectively bonding an upper bottom cover and a lower bottom cover at the upper end and the lower end of the PVC pipe by using glue for sealing;
installing each part of the simulated soil gas heating unit according to a structure shown in the figure, connecting a temperature sensor, an electric heating wire and an external temperature controller through a lead, sealing a wire hole on the PVC pipe wall of the simulated soil gas heating unit, and wrapping the outer wall of the PVC pipe of the simulated soil gas heating unit by adopting materials such as heat preservation cotton;
and connecting the air inlet pagoda joint and the air outlet pagoda joint of the simulated soil gas heating unit, the air inlet pagoda joint and the air outlet of one or more simulated soil medium units at the bottom, and the air inlet and the air outlet of an air circulating pump end to end through silica gel hoses to form a closed loop.
Installing an air pressure gauge and a pressure regulating valve on the pipe wall above the rock and soil media of each simulated soil media unit, and regulating the pressure difference between the upper chamber and the lower chamber of each simulated soil media unit during the experiment;
the device for measuring uranium migration in the connected small column simulated soil is shown in figure 4.
3. Experimental measurement procedure
1) Opening the temperature controller, and heating the gas in the simulated soil gas heating unit to a target constant temperature;
2) starting an air circulating pump to circulate the heated gas in the simulated soil gas heating units in the bottom cavity of each simulated soil medium unit for a period of time;
3) recording the starting circulation time of the air circulation pump as the starting time of the experiment;
4) collecting gas samples in the upper cavity of the simulated soil medium unit by using a nitric acid solution and an air pump at intervals (as shown in figure 5), wherein the nitric acid solution is prepared from ultrapure water and commercially available superior pure nitric acid, the concentration of the nitric acid solution is 2.0mol/L, the dosage of the nitric acid solution is 5ml each time, the flow of the air pump is set to be 1L/min during air suction, the air suction time is 15min, and a buffer bottle is connected between the air pump and the sampling bottle to prevent the nitric acid from being sucked into the air pump;
5) drawing a standard curve for analyzing the uranium content by spectrophotometry;
6) analyzing the uranium content in each nitric acid solution collected sample, measuring each sample twice to calculate an average value, and carrying out third measurement when the content difference value of the two times exceeds +/-15% of the first measurement value;
7) data were recorded and plotted.
4. Results of experimental analysis
Four simulated soil medium units are arranged in the experiment, wherein a unit # 1, a unit # 2 and a unit # 3 are used for a comparison test, and the porosity of each unit rock-soil medium is sequentially from small to large from #1 to #2 to # 3; the #4 unit adopts an RTM1688-2 radon measuring instrument to measure the radon concentration for a long time. The standard curve for uranium content analysis by spectrophotometry used this time is shown in FIG. 6, and the goodness of fit R of the standard curve2Is 0.997, which shows that the relative absorbance value measured in the range of 0-4 mug/ml of uranium concentration has a good linear relation.
Uranium content analysis is performed on the air-collected nitric acid solution samples in the upper chambers of the simulated soil medium units # 1, #2 and #3 by using the uranium standard curve in fig. 6, and the results of the change of the uranium content of the air-collected nitric acid solution samples in the upper chambers of the units are shown in fig. 7.
As can be seen from FIG. 7, the uranium content of the samples collected in the upper chambers of the three simulated soil medium units shows a consistent change relationship, and after diffusion for a period of time, the uranium content gradually begins to increase in the air of the upper sampling chamber. Because the last sampling operation destroys the tightness of the upper cavity, the uranium element content in the sampling cavities of the model No. 2 and the model No. 3 is reduced. Compared with the model # 1, the sample uranium content values detected by the units # 2 and #3 at the same time are larger than those of the unit # 1, because the larger the porosity of the capping layer is, the more the migration of uranium elements in the gaps of the geotechnical medium is facilitated.
The time-varying results of the uranium elements of the samples collected in the upper chambers of the units prove that the uranium elements can be carried and penetrate through the porous covering layer medium under the action of weak airflow, and simultaneously the diffusion behavior of the airflow is influenced by the porosity of the covering layer medium. Furthermore, in the experiment, the fluid medium only has a gas phase, and a liquid phase carrier which can dissolve uranium and related elements does not exist, so the experiment result can also prove that the migration form of uranium and other metal elements is nanoparticles or other cluster particles.
The above description is only for the preferred embodiment of the present invention, and is not intended to limit the present invention in any way, and all simple modifications, equivalent changes and modifications made to the above embodiment according to the technical spirit of the present invention are within the scope of the technical solution of the present invention.
Claims (10)
1. A device for measuring uranium migration in small column simulated soil is characterized in that the device for measuring uranium migration in small column simulated soil is provided with a simulated soil gas heating unit, a gas circulating pump and one or more simulated soil medium units;
the simulated soil gas heating unit is provided with a PVC pipe, a disturbance fan is arranged inside the PVC pipe, an upper pipe cover is buckled at the upper end of the PVC pipe, a lower pipe cover is buckled at the lower end of the PVC pipe, and an electric heating wire is arranged inside the lower pipe cover;
the simulation soil medium unit is provided with the PVC pipe, and the inside of PVC pipe is filled with even ground medium, and ground medium bottom is filled with and contains the uranium substrate, and the upper end lock is installed the upper tube cap, and the lower extreme lock is installed the lower tube cap.
2. The apparatus for measuring uranium migration in pillar simulated soil as claimed in claim 1, wherein a temperature sensor is installed in the PVC pipe at the lower end of the disturbing fan of the simulated soil gas heating unit, and the fan and the temperature sensor are respectively connected with an external power supply and a temperature controller through wires.
3. The apparatus for measuring uranium migration in pillared simulated soil according to claim 1, wherein the geotechnical media and the uranium-containing base material are placed on a porous bearing plate in a PVC pipe of the simulated soil media unit, and the porous bearing plate is horizontally fixed in the PVC pipe through a bolt.
4. The apparatus for measuring uranium migration in simulated soil with small columns as claimed in claim 1, wherein a set of pagoda joints are installed on the wall of the lower end of the PVC pipe of the simulated soil gas heating unit.
5. The apparatus for measuring uranium migration in pillar simulated soil according to claim 1, wherein a set of pagoda joints are respectively installed on the pipe walls of the upper and lower ends of the PVC pipe of the simulated soil medium unit.
6. The apparatus for determining uranium migration in pillar simulation soil according to claim 5, wherein two sets of pagoda joints at the upper end and the lower end of the PVC pipe of the simulation soil medium unit are respectively installed on the same horizontal straight line.
7. The method for determining uranium migration in pillar simulated soil of the apparatus for determining uranium migration in pillar simulated soil according to claim 1, wherein the method for determining uranium migration in pillar simulated soil comprises:
(1) preparing a uranium-containing base material and a rock-soil medium;
(2) a combined model unit;
(3) carrying out experimental measurement;
(4) and (5) analyzing an experimental result.
8. The method for determining uranium migration in small column simulated soil according to claim 7, wherein the step of preparing the uranium-containing base material and the geotechnical medium comprises:
1) weighing 150g of 60-mesh dry mud powder by using a precision electronic balance, putting the 150g of dry mud powder into a container, injecting 20g of distilled water, and uniformly stirring the mud powder and the water;
2) putting the evenly stirred yellow mud into a mould, and putting the mould on a bearing platform of a hydraulic press;
3) applying pressure to the die through a hydraulic machine, and keeping for 5 minutes after the pressure applied by the hydraulic machine reaches the target pressure;
4) releasing the pressure of the hydraulic press, taking down the mold, and putting the mold and the rock-soil medium into a constant temperature box for baking until the rock-soil medium is separated from the mold;
5) the geotechnical media is removed and baked on to dry weight.
9. The method for determining uranium migration in pillar simulated soil according to claim 7, wherein the experimental measurement step comprises:
1) opening the temperature controller, and heating the gas in the simulated soil gas heating unit to a target constant temperature;
2) starting a circulating air pump to enable heated air in the simulated soil air heating units to circulate in the bottom cavity of each simulated soil medium unit for a period of time;
3) recording the starting cycle time of the air pump as the starting time of the experiment;
4) collecting gas samples in the upper cavity of the simulated soil medium unit by using a nitric acid solution and a miniature air pump at intervals, wherein the nitric acid solution is prepared by using ultrapure water and commercially available superior pure nitric acid, and a buffer bottle is connected between the air pump and the sampling bottle;
5) drawing a standard curve for analyzing the uranium content by spectrophotometry;
6) analyzing the uranium content in each nitric acid solution collected sample, measuring each sample twice to calculate an average value, and carrying out third measurement when the content difference value of the two times exceeds +/-15% of the first measurement value;
7) data were recorded and plotted.
10. The method for determining uranium migration in small column simulated soil according to claim 9, wherein a nitric acid solution and a micro air pump are used for collecting samples from the upper chamber of the simulated soil medium unit at intervals, the nitric acid solution is prepared from ultrapure water and commercially available superior pure nitric acid, the concentration of the solution nitric acid is 2.0mol/L, the dosage of the nitric acid solution is 5ml each time, the flow of the air pump is set to be 1L/min during air suction, the air suction time is 15min, and a buffer bottle is connected between the air pump and the sampling bottle.
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Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
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CN113866355A (en) * | 2021-09-13 | 2021-12-31 | 中国人民解放军63653部队 | Water-rock action and nuclide migration simulation experiment method in multiple barriers of disposal reservoir |
CN114994280A (en) * | 2022-05-24 | 2022-09-02 | 东华理工大学 | Experimental method and experimental device for nuclide rapid adsorption and migration micro-column |
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2020
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Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
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CN113866355A (en) * | 2021-09-13 | 2021-12-31 | 中国人民解放军63653部队 | Water-rock action and nuclide migration simulation experiment method in multiple barriers of disposal reservoir |
CN113866355B (en) * | 2021-09-13 | 2023-10-10 | 中国人民解放军63653部队 | Simulation experiment method for water rock action and nuclide migration in multiple barriers of treatment library |
CN114994280A (en) * | 2022-05-24 | 2022-09-02 | 东华理工大学 | Experimental method and experimental device for nuclide rapid adsorption and migration micro-column |
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