CN220650408U - Flow cytometer of ration liquid feeding - Google Patents
Flow cytometer of ration liquid feeding Download PDFInfo
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- CN220650408U CN220650408U CN202322263125.0U CN202322263125U CN220650408U CN 220650408 U CN220650408 U CN 220650408U CN 202322263125 U CN202322263125 U CN 202322263125U CN 220650408 U CN220650408 U CN 220650408U
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- 239000007788 liquid Substances 0.000 title claims abstract description 15
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- 235000015334 Phyllostachys viridis Nutrition 0.000 claims 1
- 239000011425 bamboo Substances 0.000 claims 1
- 239000000463 material Substances 0.000 abstract description 27
- 238000004364 calculation method Methods 0.000 abstract description 3
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- 238000000684 flow cytometry Methods 0.000 abstract description 2
- 239000000523 sample Substances 0.000 description 8
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Abstract
The utility model provides a quantitative liquid-adding flow cytometer, which relates to the technical field of flow cytometry and comprises a bearing part and a quantitative part, wherein the output end of the bearing part is connected with the quantitative part in a sleeved mode, the output end of the quantitative part is connected with a detection mechanism in a sleeved mode, the quantitative part comprises a first pump body, a driving motor, a first valve block, a quantitative container, a second valve block and a second pump body, the first pump body is arranged at the output end of the bearing part, and the first pump body is connected with the output end of the driving motor; the utility model mainly utilizes the quantitative component to temporarily store and mix materials, and inputs the materials into the detection mechanism, and under the common cooperation of the detection cabin, the bearing seat, the output shaft, the turning blade and the detection sensor, the material liquid can transmit data to the detection sensor by utilizing the action of concentration and flow, and the data is fed back on the control panel after calculation, so that the detection accuracy is ensured.
Description
Technical Field
The utility model relates to the technical field of flow cytometry, in particular to a quantitative liquid-adding flow cytometer.
Background
The flow cytometer may be used to analyze sample fluids with samples or particles, and identify the characteristics of the samples or particles contained in the fluids, which may be biological samples or physical samples collected for analysis and/or separation, mix the samples with sheath fluid to deliver the samples or particles through the flow cytometer, where the particles may include biological samples, calibration beads, physical sample particles, or other particles of interest, and obtain specific information of the samples by analysis through an optical system, where the optical system is composed of a laser, an optical lens, an optical fiber, an optical filter, a photodetector, and the like, where the laser emits a laser beam to change the laser beam that irradiates the photodetector when the particles in the samples at the outlet of the flow cell pass through the laser beam to obtain a sensing signal, and obtain information of the samples by analyzing the sensing signal, and by controlling the speed of pushing the samples by controlling the plunger feed of the quantitative pump, the speed of detecting the sample flow may be controlled, and various different detection speeds from "low speed" to "high speed may be formed.
When the existing flow cytometer is used, such as application number CN201921697217.7 relates to the technical field of cell detection, in particular to a flow cytometer, which comprises: the liquid flow system comprises a sample cavity, and the sample cavity is connected with the nozzle through a sample adding pipeline; the nozzle is also connected with the sheath liquid bottle through a sheath liquid adding pipe; a first reversing valve is arranged on the sample adding pipeline, and one end of the first reversing valve is connected with the sample adding pipeline; however, in the above-mentioned technology, the material liquid is separately and jointly detected, so that a certain differential speed and concentration difference can be generated in the flow velocity process, and the problem that the detection result is affected is generated.
Disclosure of Invention
In view of the above problems, the present utility model provides a quantitative liquid-feeding flow cytometer, which mainly uses a quantitative component to temporarily mix materials, and then inputs the materials to a detection mechanism, and under the cooperation of a detection cabin, a bearing seat, an output shaft, a turning blade and a detection sensor, the materials and liquid can transmit data to the detection sensor by using the functions of concentration and flow, and then feedback is performed on a control panel after calculation, so as to ensure the detection accuracy.
In order to achieve the purpose of the utility model, the utility model is realized by the following technical scheme: the flow cytometer for quantitative liquid adding comprises a bearing component and a quantitative component, wherein the output end of the bearing component is connected with the quantitative component in a sleeved mode, and the output end of the quantitative component is connected with a detection mechanism in a sleeved mode;
the quantitative component comprises a first pump body, a driving motor, a first valve block, a quantitative container, a second valve block and a second pump body, wherein the first pump body is arranged at the output end of the bearing component, the first pump body is connected with the output end of the driving motor, the output end of the first pump body is connected with the first valve block, the output end of the first valve block is connected with the quantitative container, one end of the quantitative container is provided with the second valve block, and the output end of the second valve block is connected with the second pump body in a sleeved mode.
As a preferred embodiment of the present utility model, the central axes of the first valve block and the second valve block are symmetrically distributed with the central axis of the quantitative container, and the quantitative container has a container structure.
As a preferred embodiment of the present utility model, the bearing component comprises a cushion block, a long base, a bearing tank and a sleeve pipe, the long base is arranged on the top side of the cushion block, the bearing tank is arranged above one end of the long base, and the sleeve pipe which is sleeved and installed is arranged on the top side of the bearing tank.
As a preferred embodiment of the utility model, the detection mechanism comprises an end connecting pipe, a node, a detection cabin, a bearing seat, an output shaft, a turning blade, a detection sensor, a connecting frame, a control panel, a lower connecting pipe, a third valve block, an output pipe and a bearing cylinder, wherein the end connecting pipe is arranged at the output end of the second pump body, one end of the end connecting pipe is provided with the node, and the output end of the node is connected with the detection cabin.
As a preferred implementation mode of the utility model, a bearing seat is arranged in the detection cabin, an output shaft is arranged on one side of the bearing seat, a turning blade is arranged on the side of the output shaft, a detection sensor is arranged at one end of the detection cabin, and a connecting frame for installing a control panel is connected to one end of the detection sensor.
As a preferred implementation mode of the utility model, the output end of the detection cabin is connected with a lower connecting pipe, the lower connecting pipe is connected with an output pipe in a sleeved mode through a third valve block, and a bearing cylinder is arranged outside the output pipe.
The beneficial effects of the utility model are as follows:
the utility model mainly utilizes the quantitative component to temporarily store and mix materials, and inputs the materials into the detection mechanism, and under the common cooperation of the detection cabin, the bearing seat, the output shaft, the turning blade and the detection sensor, the material liquid can transmit data to the detection sensor by utilizing the action of concentration and flow, and the data is fed back on the control panel after calculation, so that the detection accuracy is ensured.
Drawings
FIG. 1 is a schematic perspective view of the present utility model;
FIG. 2 is a schematic bottom perspective view of the present utility model;
fig. 3 is a schematic structural diagram of a detection mechanism according to the present utility model.
Wherein: 1. a carrier member; 101. a cushion block; 102. a long base; 103. a carrying tank; 104. a ferrule; 2. a dosing unit; 201. a first pump body; 202. a driving motor; 203. a first valve block; 204. a dosing container; 205. a second valve block; 206. a second pump body; 3. a detection mechanism; 301. an end connecting pipe; 302. a node; 303. a detection cabin; 304. a bearing seat; 305. an output shaft; 306. turning over the leaves; 307. a detection sensor; 308. a connecting frame; 309. a control panel; 3010. a lower connecting pipe; 3011. a third valve block; 3012. an output pipe; 3013. a carrying cylinder.
Detailed Description
The present utility model will be further described in detail with reference to the following examples, which are only for the purpose of illustrating the utility model and are not to be construed as limiting the scope of the utility model.
According to the fig. 1-3, this embodiment provides a quantitative liquid feeding flow cytometer, which includes a bearing component 1 and a quantitative component 2, wherein the output end of the bearing component 1 is connected with the quantitative component 2 in a sleeved mode, and the output end of the quantitative component 2 is connected with a detection mechanism 3 in a sleeved mode;
the quantifying component 2 comprises a first pump body 201, a driving motor 202, a first valve block 203, a quantifying container 204, a second valve block 205 and a second pump body 206, wherein the first pump body 201 is arranged at the output end of the bearing component 1, the first pump body 201 is connected with the output end of the driving motor 202, the output end of the first pump body 201 is connected with the first valve block 203, the output end of the first valve block 203 is connected with the quantifying container 204, one end of the quantifying container 204 is provided with the second valve block 205, and the output end of the second valve block 205 is sleeved with the second pump body 206.
The central axes of the first valve block 203 and the second valve block 205 are symmetrically distributed with the central axis of the quantitative container 204, and the quantitative container 204 is of a container structure.
In this embodiment, when the quantitative output is required, the first valve block 203 is opened, and the driving motor 202 is started to output power to drive the output end to operate, so that after the driving motor 202 outputs power to drive the first pump body 201 to perform output transmission, the first pump body 201 extracts the material in the bearing tank 103 by using the sleeve pipe 104 and inputs the material into the quantitative container 204 for temporary storage, and after the temporary storage is completed, the second valve block 205 is opened and the second pump body 206 is started to output power to drive the material at the output end to be input into the end connecting pipe 301.
The bearing component 1 comprises a cushion block 101, a long base 102, a bearing tank 103 and a sleeve pipe 104, wherein the long base 102 is arranged on the top side of the cushion block 101, the bearing tank 103 is arranged above one end of the long base 102, and the sleeve pipe 104 which is sleeved and installed is arranged on the top side of the bearing tank 103.
In the present embodiment, in use, after the apparatus is placed at a processing site by the pad 101 and the long base 102, a substance to be detected is filled by the carrier tank 103, and then the quantitative part 2 is sleeved with the sleeve 104.
The detection mechanism 3 includes an end connecting pipe 301, a node 302, a detection chamber 303, a bearing seat 304, an output shaft 305, a turning blade 306, a detection sensor 307, a connecting frame 308, a control panel 309, a lower connecting pipe 3010, a third valve block 3011, an output pipe 3012 and a bearing barrel 3013, wherein the end connecting pipe 301 is arranged at the output end of the second pump body 206, one end of the end connecting pipe 301 is provided with the node 302, and the output end of the node 302 is connected with the detection chamber 303.
In this embodiment, after the material enters the end connection pipe 301, the material flows through the output end of the node 302 into the detection chamber 303 under the flow guidance of the line.
The inside of detection cabin 303 is provided with bearing frame 304, and one side of bearing frame 304 is provided with output shaft 305, and the avris of output shaft 305 is provided with turning vane 306, and the one end of detection cabin 303 is provided with detection sensor 307, and the one end of detection sensor 307 is connected with the even frame 308 of installation control panel 309.
In this embodiment, after the material flows into the detection chamber 303, the turning blade 306 and the output shaft 305 are driven to rotate by the flowing kinetic energy, so as to achieve the detection function on the data under the detection of the utilization time, the rotation speed and the material concentration, and the detected structure is input into the control panel 309 installed on the connecting frame 308 through the detection sensor 307 for display.
The output end of the detection cabin 303 is connected with a lower connecting pipe 3010, the lower connecting pipe 3010 is connected with an output pipe 3012 in a sleeved mode through a third valve block 3011, and a bearing barrel 3013 is arranged outside the output pipe 3012.
In this embodiment, when the material is required to be discharged, the third valve block 3011 is opened, and the material is input into the bearing barrel 3013 for bearing under the flow guidance of the lower connecting pipe 3010 and the output pipe 3012, so as to achieve the effect of outputting the product.
The flow cytometer of this ration liquid feeding theory of operation is: when in use, after the equipment is placed at a processing place through the cushion block 101 and the long base 102, the material to be detected is filled by the bearing tank 103, the sleeve pipe 104 is sleeved on the quantifying component 2, when quantitative output is needed, the first valve block 203 is opened, the driving motor 202 is started to output power to drive the output end to operate, the driving motor 202 is started to output power to drive the first pump body 201 to output and drive, the first pump body 201 is used for extracting and inputting the material in the bearing tank 103 into the quantifying container 204 through the sleeve pipe 104 for temporary storage, after temporary storage is completed, the second valve block 205 is opened, the second pump body 206 is started to output power to drive the material at the output end to be input into the end connecting pipe 301, after the material enters the end connecting pipe 301, the material enters the detection cabin 303 through the output end of the node 302 under the flow guide of the line to flow, after the material flows into the detection cabin 303, the turning blades 306 and the output shaft 305 are driven to rotate by the flowing kinetic energy, so that the detection effect on data is formed under the detection of the utilization time, the rotation speed and the material concentration, the detected structure is input into the control panel 309 installed on the connecting frame 308 through the detection sensor 307 to be displayed, and when the material is required to be discharged, the third valve block 3011 is opened and is input into the bearing cylinder 3013 under the flow guide of the lower connecting pipe 3010 and the output pipe 3012 to be borne, so that the effect of outputting the product is achieved.
The foregoing has shown and described the basic principles, principal features and advantages of the utility model. It will be understood by those skilled in the art that the present utility model is not limited to the embodiments described above, and that the above embodiments and descriptions are merely illustrative of the principles of the present utility model, and various changes and modifications may be made without departing from the spirit and scope of the utility model, which is defined in the appended claims. The scope of the utility model is defined by the appended claims and equivalents thereof.
Claims (6)
1. The utility model provides a flow cytometer of ration liquid feeding, includes carrier part (1) and quantitative part (2), its characterized in that: the output end of the bearing component (1) is connected with a quantitative component (2) in a sleeved mode, and the output end of the quantitative component (2) is connected with a detection mechanism (3) in a sleeved mode;
the quantitative component (2) comprises a first pump body (201), a driving motor (202), a first valve block (203), a quantitative container (204), a second valve block (205) and a second pump body (206), wherein the first pump body (201) is arranged at the output end of the bearing component (1), the first pump body (201) is connected with the output end of the driving motor (202), the output end of the first pump body (201) is connected with the first valve block (203), the output end of the first valve block (203) is connected with the quantitative container (204), one end of the quantitative container (204) is provided with the second valve block (205), and the output end of the second valve block (205) is sleeved with the second pump body (206).
2. A quantitative liquid-feeding flow cytometer according to claim 1, wherein: the central axes of the first valve block (203) and the second valve block (205) are symmetrically distributed with the central axis of the quantitative container (204), and the quantitative container (204) is of a container structure.
3. A quantitative liquid-feeding flow cytometer according to claim 1, wherein: the bearing component (1) comprises a cushion block (101), a long base (102), a bearing tank (103) and a sleeve pipe (104), wherein the long base (102) is arranged on the top side of the cushion block (101), the bearing tank (103) is arranged above one end of the long base (102), and the sleeve pipe (104) which is sleeved and installed is arranged on the top side of the bearing tank (103).
4. A quantitative liquid-feeding flow cytometer according to claim 1, wherein: detection mechanism (3) include end connecting pipe (301), node (302), detect cabin (303), bearing frame (304), output shaft (305), flip leaf (306), detect sensor (307), even frame (308), control panel (309), down connect pipe (3010), third valve piece (3011), output tube (3012) and bear a section of thick bamboo (3013), end connecting pipe (301) set up the output of second pump body (206), the one end of end connecting pipe (301) is provided with node (302), just the output of node (302) is connected with detects cabin (303).
5. The quantitative liquid feeding flow cytometer of claim 4, wherein: the inside of detection cabin (303) is provided with bearing frame (304), just one side of bearing frame (304) is provided with output shaft (305), the avris of output shaft (305) is provided with turning vane (306), the one end of detection cabin (303) is provided with detection sensor (307), just the one end of detection sensor (307) is connected with even frame (308) of installation control panel (309).
6. The quantitative liquid feeding flow cytometer of claim 4, wherein: the output end of the detection cabin (303) is connected with a lower connecting pipe (3010), the lower connecting pipe (3010) is connected with an output pipe (3012) in a sleeved mode through a third valve block (3011), and a bearing barrel (3013) is arranged outside the output pipe (3012).
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN202322263125.0U CN220650408U (en) | 2023-08-22 | 2023-08-22 | Flow cytometer of ration liquid feeding |
Applications Claiming Priority (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN202322263125.0U CN220650408U (en) | 2023-08-22 | 2023-08-22 | Flow cytometer of ration liquid feeding |
Publications (1)
| Publication Number | Publication Date |
|---|---|
| CN220650408U true CN220650408U (en) | 2024-03-22 |
Family
ID=90292407
Family Applications (1)
| Application Number | Title | Priority Date | Filing Date |
|---|---|---|---|
| CN202322263125.0U Active CN220650408U (en) | 2023-08-22 | 2023-08-22 | Flow cytometer of ration liquid feeding |
Country Status (1)
| Country | Link |
|---|---|
| CN (1) | CN220650408U (en) |
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2023
- 2023-08-22 CN CN202322263125.0U patent/CN220650408U/en active Active
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