BE1029178B1 - Isotope fractionation apparatus in ice freezing and melting process - Google Patents

Abstract

The patent of the invention relates to the technical field of fractionation equipment and discloses an isotopic fractionation device in the process of forming ice by freezing and melting, comprising an isotopic fraction detecting device, a first transport pipe being fixedly connected to one side of the isotopic fraction detection device, and a second transport pipe being fixedly connected to one end of the first pipe remote from the device. The front upper part of the second transport tube is fixedly connected with a servo motor, the position of the second transport tube near the back is fixedly connected with a finite position tube, the back of the finite position tube is fixed with an annular tube, and the back of the ring tube is attached to a sampling tube. Improve sample freshness, improve detection accuracy, help avoid erroneous results of late detection, help to further improve sample holding time, and help real-time detection.

Description

Isotope fractionation apparatus in ice freezing and melting process

Technical areas

The patent of the invention concerns the technical field of fractionation equipment and more particularly an isotopic fractionation device during freezing and melting into ice.

Background technique

The phenomenon that isotopes of an element are distributed in different proportions among different substances during physical, chemical, and biological reactions is called isotope fractionation, which can correct the error of metabolic differences between modern reference materials and reference materials. 'sample. Among them, the detection of the phenomenon of freezing and melting into ice in the natural environment is often used in the design of the scientific research process because of its simplicity.

Existing isotope fractionation devices, when used, often require advance sampling and sample protection, and must maintain the sample in the required environment at all times, so they can cause errors in detection results when they are not fresh enough, leading to later printing calculations and erroneous results later; When existing isotope fractionation devices are used, they often become contaminated with dust or other substances after sample extraction, which leads to errors in later test results and affects later conclusions, making waste a lot of time in subsequent calculations and affects the user experience.

Content of the invention patent

In order to overcome the aforementioned shortcomings of the prior art, the patent of the invention provides an isotopic fractionation device in the process of freezing and melting into ice to solve the existing problems in the aforementioned background art.

The patent of the invention provides the following technical diagram: a device for fractionating isotopes in the process of freezing and melting into ice, comprising an isotope fractionation detection device, a first transport pipe being arranged on a side of the isotope fraction detection device, and a second transport pipe being attached to an end of the first pipe remote from the isotope fraction detection device, The front top of the second transport pipe is fixedly connected to a servo motor , the position of the second transport tube near the back is fixedly connected with a finite position tube, the position of the back of the limitation tube is fixedly connected with a ring tube, and the back of the ring tube is fixedly connected with a d sampling tube, and the sampling tube position fixing sleeve near the outside of the back is connected to an analog box, and The bottom of the power supply cover is fixedly connected to an upper cover near the inside, the center of the bottom of the top cover is fixedly connected with a precipitation nozzle, the bottom of the top cover is fixed near the top four corners with a fluorescent lamp, and the two sides of the fluorescent lamp away from the center are fixedly connected on all four sides of the analog box. The interior of the simulation box is fixedly connected to a thermostat in a position near the middle of a side far from the isotopic fractionation detection device.

Further, the inner bottom of the simulation box is fixedly connected with a simulated ground, and the top of the simulated ground is embedded at a position close to the middle to generate a simulated mountain.

Furthermore, the part of the simulation box close to the front face is provided with an adaptation hole whose internal diameter is adapted to the external diameter of the sampling tube.

In addition, the simulation box is made of transparent glass as a whole, and the fluorescent lamp, precipitation nozzle and temperature controller are connected to an external power source through a power cover.

Further, said sampling tubes are respectively placed at the location of the top of the simulated ground near the top cover, at the location of the top of the simulated ground near the simulated ground, inside the simulated mountain at near the summit, and to the simulated mountain near the interior of the bottom on one side of the isotopic fractionation detection device.

In addition, the rear transmission of the booster is connected with a connecting rod, and the connecting rod is fixedly connected with a turbine plate outside the booster, and the turbine plate is located inside the transmission tube. limitation near the front face and the middle.

The technical effects and advantages of the invention patent: 1. The invention patent is conducive to simulating the natural environment of freezing and thawing, sampling at any time, improving the sample freshness, detection accuracy, avoid getting erroneous results in subsequent detection, further improve sample holding time, and real-time detection. 2. The invention patent has a first transport tube and a turbine plate, which is conducive to further improve the overall closure, improve the overall purity of the sample, avoid contamination some debris during sampling, which affects the later results, to further improve the detection accuracy and avoid wasting a lot of time in the later calculation due to the erroneous detection results.

Description of attached drawings

Figure 1 is a diagram of the overall patent structure of the invention.

Figure 2 is a diagram of the explosion of the overall patent structure of the invention.

Figure 3 is a diagram of the structure of the patented analog box of the invention.

Figure 4 is a diagram of the structure of a patented turbine plate according to the invention.

The drawings are marked as follows: 1. Isotope fractionation detection device; 2. The first transport pipe; 3. Second transport pipe; 4. Servo motor; 5. Restrictor tube; 6. Sampling tube; 7. Simulation box; 8. Power supply cover; 9. Environmental management; 10. Turbine sheet; 11. Top cover; 12. Fluorescent lamps; 13.

Precipitation sprinkler; 14. Temperature controller; 15. Simulated mountain; 16.

Simulate the ground; 17. Adapter hole; 18. Connection bar.

Specific implementation modalities

The technical diagrams of the patent of the invention will be described in a clear and complete manner in combination with the drawings annexed to the patent of the invention. In addition, the morphology of each structure recorded in the following embodiments is only an example, and the isotopic fractionation device in the ice freezing and thawing process covered by the invention patent is not limited to structures recorded in the following embodiments.

All other embodiments acquired by one skilled in the art without creative labor fall within the patent protection of the invention.

Referring to figures 1 to 4, the patent of the invention provides a device for isotopic fractionation during the formation of ice by freezing and melting, comprising an isotopic fractionation detection device 1, a first transport pipe 2 being arranged on one side, and a second transport pipe 3 being attached to a remote end of the isotopic fraction detecting device 1. A servo motor 4 is attached to the top of the front face of the second transport tube 3, a limiting pipe 5 is attached at the position of the second transport tube 3 near the back, an annular pipe 9 is attached to the back of the sample pipe 6, an analog box 7 is attached at the position of the sample tube 6 near the outside of the 5 back, and an upper mobile board of the analog box 7 is connected with a power supply cover The bottom of the power supply cover 8 is fixedly connected inside with an upper cover 11, the center of the bottom of the upper cover 11 is fixedly connected with the precipitation sprinkler 13, the bottom of the upper cover 11 is fixed near the upper four corners with a fluorescent lamp 12, the two sides of the fluorescent lamp 12 away from the center are fixed to the four sides of the analog box 7. The thermostat 14 is fixedly connected inside the simulation box 7, away from the isotopic fractionation detection device 1, near the middle, which facilitates the simulation of the natural freezing and thawing environment, the sampling at any time and improving sample freshness.

Referring to Fig. 2, the inner bottom of the simulation box 7 is fixedly connected with a simulation ground 16, and the top of the simulation ground 16 near the middle is integrated to generate a simulation mountain 15, which improves detection accuracy and avoids getting erroneous results in subsequent detection.

Referring to Figure 3, the part of the analog box 7 close to the front face is provided with an adaptation hole 17 whose internal diameter is adapted to the external diameter of the sampling tube 6, which allows further improve sample retention time and facilitate real-time detection.

Referring to Figure 3, the simulation box 7 is made of transparent glass as a whole, and the fluorescent lamp 12, the precipitation sprinkler 13 and the thermostat 14 are connected to an external power supply through the power supply cover.

8, which is conducive to further observation and improving the overall stability.

Referring to Figure 3, the sample tubes 6 are placed respectively where the top of the simulated soil 16 is close to the cover 11, where the top of the simulated soil 16 is close to the simulated soil 16, inside the simulated hill 15 near the top and to the simulated hill 15 near the bottom on the side of the isotope fractionation detection apparatus 1. The detection accuracy is improved by separate sampling, which improves again the degree of adaptation of the sample.

Referring to Figure 4, the rear transmission of the booster 4 is connected to a connecting rod 18, and the connecting rod 18 is fixedly connected to the outside of the booster 4 with a turbine plate 10, which is located at the inside of the 5 limiting tube near the front face and the middle, which is conducive to further improve the overall tightness, improve the overall purity of the sample, and avoid contaminating some debris when It affects the results later.

Invention patent working principle: before use, the servo motor 4 must be turned on to connect the external power supply to the fluorescent lamp 12, the precipitation sprinkler 13 and the thermostat 14, and provide a water source to the precipitation sprinkler 13.

In use, light is supplied inside the analog box 7 by the fluorescent lamp 12, rainwater is supplied inside the precipitation nozzle 13, and the temperature is transformed to the exterior of the analog box 7 by the temperature controller 14, which creates a small ecological environment of freezing and thawing in the analog box 7, and the temperature is lowered at night by turning off the fluorescent lamp 12 and the controller of the yellow river inside the simulation box 7 is lowered, so that the frozen ground appears inside the simulation mountain 15 and the simulation ground 16, that the body of water on top of the ground of simulation 16 is frozen, and the overall temperature is increased during the day by the lighting and the temperature controller 14 after the fluorescent lamp 12 is turned on, so that the internal temperature of the simulation box 7 is increased, and that the frozen ground To simulate the occurrence of freezing and thawing, water is supplied inside the simulation box 7 by the precipitation sprinkler 13, so that the formation of underground ice occurs at the interior of the simulation mountain 15 and the simulation ground 16, and the migration of water occurs in the simulation mountain 15 by the heating effect of the temperature controller 14 during the day and then by the heating of the temperature regulator 14. The evaporation of the mass of water at the top of the simulated ground 16 allows the detection of stable isotopes, the taking of samples in the positions to be detected by the sampling tube 6, the rotation of the connecting rod 18 by the booster 4, so that the connecting rod 18 causes the rotation of the turbine 10,

Through the rotation of the turbine plate 10, the suction force is generated inside the limiting tube 5, the annular tube 9 and the sampling tube 6, which makes it possible to quickly sample the interior of the simulation box 7, so that the sealing until the detection is still in a closed environment, which is conducive to improving the overall purity of the sealing and avoiding In order to further improve the precision of the detection, after having sucked the sample at the edge of the second transport tube 3 via the connecting rod 18, the sample is thrown inside the second transport tube 3 by the centrifugal force of the connecting rod 18 and transmitted to the isotopic fractionation detection device 1 via the first transport tube 2 to carry out the fractionation detection.

The last points to be clarified are the following: first of all, in the description of the present application, it should be specified that, unless otherwise indicated and qualified, the terms "installation", "connection", "connection" must be understood in the broad sense and can be mechanical or electrical connections, or internal connections of two elements, which can be directly connected, "Up", "Down", "Left", "Right" etc. are only used to indicate the relative position relationship, when the absolute position of the described object changes, the relative position relationship may change;

Second: In the drawings attached to the exemplary embodiment of the patent disclosure of the invention, only the structure concerned by the exemplary embodiment of the disclosure is concerned, other structures may be designed with reference to the design usual, and the same patent embodiment of the invention and different embodiments can be combined with each other without conflict;

Finally: the above is only a preferred embodiment of the patent of the invention and is not intended to limit the patent of the invention, any modification, equivalent substitution, improvement, etc. which is in the spirit and the principle of the patent of the present invention must be covered by the protection of the patent.

Claims (6)

Claims 1. Apparatus for fractionating isotopes in the process of freezing and melting into ice, comprising an isotope fractionation detecting device (1), characterized in that a first transport pipe (2) is provided to be connected to one side of said isotope fraction detecting device (1), and a second transport pipe (3) is fixedly connected to one end of the first pipe remote from said device. A servo motor (4) is fixedly connected to the top of the front face of the second transport tube (3), a limit tube (5) is fixedly connected to the position of the second transport tube (3) close to the back, the back of the limit tube (5 ) is attached to a ring tube (9), the back of the ring tube (9) is attached to a sample tube (6), The sample tube (6) is attached to an analog box (7) in a position close to the outside of the back, the upper mobile board of the analog box (7) is fixed to a power supply cover (8), the bottom of the power supply cover (8) in a position close to the inside is fixed to an upper cover (11), the bottom center of the upper cover (11) is fixedly connected with a precipitation nozzle (13) The bottom of the upper cover (11) is equipped with a fluorescent lamp (12) near the upper four corners, the two sides of the fluorescent lamp (12) away from the center are fixedly connected with the four sides of the analog box (7), and the inner side of the analog box (7) away from the device Isotope fractionation detection (1) is fixedly connected to a thermostat (14) close to the medium. 2. Device for splitting isotopes in the process of freezing and melting into ice according to claim 1, characterized in that the inner bottom of the simulation box (7) is fixedly connected to a simulation ground (16), and the top of the simulation ground (16) is integrally formed near the middle with a simulation mountain (15). 3. Device for isotopic fractionation during the formation of ice by freezing according to claim 1, characterized in that a matching hole (17) is opened near the front face of the simulation box (7), the diameter internal diameter of the adaptation hole (17) being adapted to the external diameter of the sampling tube (6). 4. Device for fractionating isotopes in the process of freezing and thawing in ice according to claim 1, characterized in that the simulation box (7) is made of transparent glass as a whole, and the fluorescent lamp (12), the precipitation sprinkler (13) and the temperature controller (14) are all connected to an external power source via a power cover (8). 5. Apparatus for isotopic fractionation in the process of freezing and melting in ice according to claim 1, It is characterized in that the sampling tubes (6) are placed respectively at the place where the top of the simulated ground (16 ) is close to the top cover (11), where the top of the simulated ground (16) is close to the simulated ground (16), the simulated mountain (15) is close to the inside of the top and the simulated mountain (15) is close to the interior of the simulated soil (16) of the bottom on one side of the isotopic fractionation detection device (1). 6. Device for fractionating isotopes in the ice freezing and thawing process according to claim 1, characterized in that: the rear transmission of the servomotor (4) is connected to a connecting rod (18), the link (18) is fixedly connected outside the booster (4) with a turbine plate (10), The turbine plate (10) is located inside the limiting tube (5) close to the face front and middle.