WO2018161236A1 - Fluid analysis system in biological science and technology - Google Patents

Abstract

A fluid analysis system in biological science and technology. A base (2) is fixed to the bottom end of a support rod (1), a top cover (3) is fixed to the top end of the support rod (1), and an electric extensible rod (4) is fixed below the top cover (3). A clamping member (12) is fixed at the upper and middle position of the support rod (1), a cantilever sheet (5) is fixed to the clamping member (12) by means of a bolt, and a drop gun (6) is fixed to the tail end of the cantilever sheet (5). A base block (18) is fixed to the side surface of the clamping member (12). An upper shuttle rod (9) and a lower shuttle rod (10) correspondingly penetrate through the upper end and the lower end of the base block (18). A turntable (17) is fixed to the upper shuttle rod (9) and the lower shuttle rod (10) by means of rivets. A rotating shaft (16) is disposed at the center position of the turntable (17). The tail end of the rotating shaft (16) is fixed in a shaft grip rod (14), and the shaft grip rod (14) is hingedly connected to a clamp member (13). The tail end of the clamp member (13) is fixed to the tail end of a rod member of the electric extensible rod (4). The fluid analysis system in biological science and technology has a simple structure and can clearly demonstrate the process of fluid analysis.

Description

 System for biotechnology fluid liquid analysis

 [0001] The present invention relates to a system for biotechnology fluid fluid analysis.

 Background technique

 [0002] Biotechnology uses science and technology and biotechnology to transform agriculture or other aspects. Science uses modern genetic engineering techniques to accurately select genes with certain characteristics of the organism to be transferred to another species, giving new genetically modified organisms the expected specific characteristics. Biotechnology is a well-known term that is translated from English biotechnology. The National Science and Technology Council defines biotechnology as "biotechnology contains a range of technologies that can use organisms or cells to produce the products we need. These new technologies include genetic recombination, cell fusion, and some biological manufacturing processes." The history of humans using organisms or cells to produce the products we need has been very long, such as cultivating 10,000 years ago, grazing to provide a stable source of food, using fermenting techniques to make wine and bread, 6,000 years ago, The use of mold to treat wounds two thousand years ago, the use of smallpox vaccine in 1797, and the antibiotic penicillin in 1928. The scientific community has a deeper understanding of the cells that make up the smallest unit of organisms and genes that control cellular genetics, and the development of genetic recombination and cell fusion technologies in the 1970s. Since these two technologies are more effective in allowing cells or organisms to produce the substances we need and contribute to industrial or agricultural production, an emerging biotech industry has been created since the 1980s! Bill Gates said in 1996 that "biotechnology will change the world like computer software." The modern biotechnology industry has been developed since 1980, and its applications range from pharmaceuticals, agriculture, environmental protection, food processing, and specialty chemicals. In biomedical pharmacy, 155 biotech drugs or vaccines have been approved by the US Food and Drug Administration for the treatment of diabetes, heart disease, cancer, AIDS and other diseases. In agriculture, genetically modified plants such as papaya, tomato, corn, soybeans, etc. are marketed. These genetically modified plants are characterized by strong resistance to pests and diseases and can reduce the use of chemical pesticides.

 technical problem

A system for biotechnology fluid fluid analysis is provided. Problem solution

 Technical solution

 [0004] A biotechnology fluid fluid analysis system, the main structures are: a support rod, a base, a top cover, an electric telescopic rod, a cantilever piece, a drip gun, a solvent-assisted dropper, a scraper, an upper shuttle, a lower shuttle a rod, a solvent-assisted self-flowing groove, a clamping member, a clamp member, a shaft gripping rod, a limiting piece, a rotating shaft, a rotary table, a base block, a bottom portion of the bracket rod is fixed with a base, and a top cover is fixed at the top end, An electric telescopic rod is fixed under the top cover. A clamping member is fixed at an upper position of the bracket rod, and a cantilever piece is fixed on the clamping member by a bolt, and a tipping gun is fixed at the end of the cantilever piece; a base block is fixed on the side of the clamping member, and two upper and lower sides of the base block are The upper end is inserted with an upper shuttle rod and a lower shuttle rod, and a turntable is fixed on the upper shuttle rod and the lower shuttle rod by a rivet, and a rotary shaft is arranged at a center of the rotary disc, and the end of the rotary shaft is fixed in the shaft grip rod, the shaft grip rod and the clamp member The hinges are fixed at the end of the rod of the electric telescopic rod. The upper end of the upper shuttle rod is fixed with a helper dropper; the end of the lower shuttle rod is fixed with a scraper; the side of the drip gun is milled with a solvent-assisted self-flowing trough, and the notch matches the nozzle of the auxiliary solvent dropper. Further, the drip gun is filled with a lysing enzyme. Further, the helper solvent dropper is injected with a co-solvent. Further, the pedestal block is fixed to the finite piece.

 Advantageous effects of the invention

 Beneficial effect

 [0005] A simple, clear process for demonstrating fluid analysis.

 Brief description of the drawing

 DRAWINGS

 1 is a schematic overall structural view of a system for analyzing bio-tech fluids according to the present invention. Fig. 2 is a side view showing the entire structure of a system for analyzing biological fluids in the present invention. Fig. 3 is a view showing the exploded structure of a core component of a system for analyzing biological fluids in the present invention. In the picture, 1-bracket rod, 2-base, 3-top cover, 4-electric telescopic rod, 5-cantilever, 6-drip gun, 7-solvent dropper, 8-scraper, 9-upper rod, 10-lower shuttle, 11- cosolvent self-flowing groove, 12-clamping, 13-clamp, 14-axis grip, 15-stop, 16-turn, 17-turn, 18-base block.

Embodiments of the invention The specific embodiments of the present invention will be described in detail below with reference to FIGS. 1-3. EXAMPLES: A system for bio-tech fluid fluid analysis, the main structures are: a support rod 1, a base 2, a top cover 3, an electric telescopic rod 4, a cantilever piece 5, a drip gun 6, a solvent-assisted dropper 7, and a scraper 8. The upper shuttle rod 9, the lower shuttle rod 10, the co-solvent self-flowing groove 11, the clamping member 12, the clamping member 13, the shaft holding rod 14, the limiting piece 15, the rotating shaft 16, the turntable 17, and the base block 18, The bottom of the bracket rod 1 is fixed with a base 2, and the top end is fixed with a top cover 3, and an electric telescopic rod 4 is fixed under the top cover 3. A clamping member 12 is fixed at an upper position of the bracket rod 1 , and a cantilever piece 5 is fixed on the clamping member 12 by a bolt, and a tipping gun 6 is fixed at the end of the cantilever piece 5; a base block is fixed on the side of the clamping member 12 18, an upper shuttle rod 9 and a lower shuttle rod 10 are inserted into the upper and lower ends of the base block 18, and a turntable 17 is fixed on the upper shuttle rod 9 and the lower shuttle rod 10 by a rivet, and the rotary shaft 16 is disposed at a center of the turntable 17 The end of the rotating shaft 16 is fixed in the shaft grip 14, and the shaft grip 14 is hinged with the clip 13; the end of the clip 13 is fixed to the end of the rod of the electric telescopic rod 4. The auxiliary shuttle pipe 9 is fixed at the end of the upper shuttle rod 9; the scraper 8 is fixed at the end of the lower shuttle rod 10; the side of the drip gun 6 is milled with a solvent-assisted self-flowing tank 11, the notch and the solvent-assisted dropper The nozzles of 7 match each other. The drip gun 6 is filled with a lysing enzyme. The cosolvent dropper 7 is injected with a cosolvent. The base block 18 is externally fixed to the limiting piece 15. The principle process of the present invention is: starting the electric telescopic rod 4 to make the rod end reciprocating piston movement, when the clamp 13 forces the shaft grip 14 to go down, the rotating shaft 16 drives the turntable 1 7 to rotate the needle half In the circle, since the turntable 17 is interlocked with the upper shuttle rod 9 and the lower shuttle rod 10, the upper shuttle rod 9 is retracted, and the lower shuttle rod 10 is extended. Therefore, the squeegee 8 of the squeegee protrudes forward, and during the process of extending the squeegee 8, the electronic detecting device to be dissolved is touched, and the squeegee 8 is extended, and the electronic device is oxidized. Partial erasure, on the other hand, functions as an enzyme localization of the electronic device. The co-solvent pipette 7 is retracted, and the process of retracting is the process of taking the co-solvent. When the rotating shaft 16 drives the turntable 17 to rotate a half turn along the boring needle, the upper shuttle rod 9 is extended, and the lower shuttle rod 10 is retracted. This auxiliary solvent dropper 7 injects a co-solvent into the notch of the side of the drip gun 6 with the help solvent from the launder 1 . After the completion of the help of the solvent on the side of the drip gun 6, the drip gun 6 closes the valve port, and the lysed enzyme in the drip gun 6 is dropped onto the electronic component to be analyzed. The basic principles, main features and advantages of the present invention are shown and described above. It should be understood by those skilled in the art that the present invention is not limited by the foregoing embodiments, and that the present invention is only described in the foregoing embodiments and the description of the present invention, without departing from the spirit and scope of the invention. Various changes and modifications are intended to fall within the scope of the invention as claimed. The scope of the invention is defined by the appended claims and their equivalents.

Claims

 Claim

 [Claim 1] A biotechnology fluid fluid analysis system, the main structures of which are: a support rod (1), a base (2), a top cover (3), an electric telescopic rod (4), a cantilever piece (5), Drip gun (6), solvent dropletper (7), scraper (8), upper shuttle (9), lower shuttle (10), self-flowing tank (11), clamping member (12), clamp (13), shaft grip (14), limit plate (15), shaft (16), turntable (17), base block (18), characterized in that: the base of the bracket rod (1) is fixed with a base (2) A top cover (3) is fixed to the top end, and an electric telescopic rod (4) is fixed under the top cover (3). A clamping member (12) is fixed at an upper position of the bracket rod (1), and a cantilever piece is fixed by a bolt on the clamping member (12)

(5), the cantilever piece (5) is fixed with a little drop gun (6) at the end; the base member (18) is fixed to the side of the clamping member (12), and the upper shuttle rod is inserted at the upper and lower ends of the base block (18) (9), the lower shuttle rod (10), and the turntable (17) is fixed on the upper shuttle rod (9) and the lower shuttle rod (10) by a rivet, and the rotary shaft (16) is arranged at the center of the turntable (17), and the rotating shaft is provided. (16) The end is fixed in the shaft grip (14), and the shaft grip (14) is hinged with the clip (13);

(13) The end is fixed to the end of the rod of the electric telescopic rod (4). The upper shuttle rod (9) is fixed with a solvent droplet pipe (7) at the end; the bottom shuttle (10) has a scraper (8) at the end; the spot gun (6) is side-milled with a solvent self-flowing tank (11), the notch and the nozzle of the co-solvent pipette (7) match each other.

 [Claim 2] A system for biotechnology fluid fluid analysis according to claim 1, characterized in that the drip gun (6) is filled with a lytic enzyme.

[Claim 3] A system for bio-tech fluid fluid analysis according to claim 1, characterized in that the co-solvent pipette (7) is injected with a co-solvent.

[Claim 4] A system for biotechnology fluid fluid analysis according to claim 1, characterized in that the base block (18) externally fixes the limiting piece (15).