CN215866722U

CN215866722U - Sample preparation device of flow analyzer

Info

Publication number: CN215866722U
Application number: CN202120170318.XU
Authority: CN
Inventors: 陈良清; 李天宇; 李为公
Original assignee: Shenzhen Weigong Biotechnology Co ltd
Current assignee: Shenzhen Weigong Biotechnology Co ltd
Priority date: 2021-01-21
Filing date: 2021-01-21
Publication date: 2022-02-18
Anticipated expiration: 2031-01-21

Abstract

The utility model discloses a sample preparation device of a flow analyzer, which comprises: the device comprises an automatic sample injector component for a sample to be detected, a sample transmission component for the sample to be detected, a flow type sample reaction container component, a flow type reagent I transmission component, a flow type reagent II transmission component and a flow type sample mixing component; adding a sample to be detected into the flow type sample reaction container assembly by the sample to be detected transmission assembly; the flow reagent I transport assembly adds flow reagent I to the flow sample reaction vessel assembly; the flow reagent II transport assembly adds flow reagent II to the flow sample reaction vessel assembly; and the flow type sample mixing component uniformly mixes the sample to be lateral, the flow type reagent I and the flow type reagent II. The instrument replaces manual operation, the sample adding precision is high, the consistency is good, a user only needs to place a sample container to be detected on a sample frame to be detected, and the utility model can automatically complete all sample preparation operations according to a set flow.

Description

Sample preparation device of flow analyzer

Technical Field

The utility model relates to the field of sample preparation of flow cytometry, in particular to a sample preparation device of a flow analyzer.

Background

Flow Cytometry (FCM) is a flow cytometer that is used to count and quantify various biological and physical and biochemical characteristics of blood, various body fluids, bone marrow, biopsy materials, single cell suspensions of animals and plants, paraffin-embedded tissues, including cells, platelets, organelles, sperm, microorganisms, and artificially synthesized microspheres, etc.

With the progress and popularization of scientific technology, flow analyzers gradually move into the field of medical clinical application, and the current flow analyzer technology plays an important role in the assessment of human cellular immune function and the diagnosis and treatment of various blood diseases and tumors, and plays a key role in the diagnosis, disease condition monitoring, prognosis judgment and medication opportunity assessment of diseases such as AIDS, leukemia and tumors.

Before the flow analysis detection is carried out, necessary processing and preparation must be carried out on a sample to be detected, wherein the quality of the preparation of the sample to be detected directly influences the effectiveness and accuracy of data detection.

At present, a sample to be measured of a flow analyzer is usually processed by a human before measurement, and the preparation process is very complicated and roughly as follows:

the method comprises the steps of firstly, manually reversing and uniformly mixing a sample to be detected, manually opening a cover to sample, adding the sample into a flow type tube (sample reaction container), manually sucking an antibody reagent (flow type reagent I) and adding the antibody reagent into the flow type tube, holding the flow type tube by a hand, putting the vortex mixing instrument for uniformly mixing, putting the flow type tube added with the sample to be detected and the antibody reagent on a test tube rack, and putting the test tube rack into a dark box for carrying out primary reaction incubation. After the requirement of the first reaction incubation time is met, a hemolytic agent (flow type reagent II) is manually added, the flow type tube is held by a hand and put on a vortex instrument to be uniformly mixed again, and then the mixture is put in a dark box to carry out second reaction incubation. And only the conventional hemolytic agent (a flow reagent II) can be added manually, and the incubation time is long.

The operators, especially the operators of disease control centers, are often contacted with high-risk infectious samples. Especially when the vortex mixing, the liquid level vibrates and can lead to the sample to splash, and the operator has high biological risk.

The manual operation steps are complicated and easy to make mistakes, different operators mix the samples, and the use habits of operating the pipettor and the mixing vortex mixing instrument are inconsistent, so that the risk of inconsistent flow detection results is frequently caused.

In addition, the quick hemolytic agent (another flow type reagent II) has short hemolytic incubation reaction time, and usually consists of two reagents (e.g. solution a and solution B), after the solution a is added, solution B needs to be added in about 5 seconds, and the two times of the addition need vortex and shake for mixing, and the operation cannot be performed accurately within the specified time by hand.

In summary, the existing manual sample preparation has the defects of operator susceptibility, complicated steps, result deviation caused by inconsistent habits of operators, fatigue of operators when a large number of samples are processed and the like, and especially, the flow-type detection result is inaccurate due to lack of operation experience or unskilled of operators in medium and small hospitals or institutions for manually preparing samples, so the existing manual sample preparation needs to be improved.

In recent years there have also been many attempts to replace manual sample preparation by machine methods, such as patent CN 107422138A. The device disclosed in this patent does not completely solve the entire manual operation, and still requires the manual mixing of the sample to be tested (blood sample in the evacuated blood collection tube), and in particular still requires the manual opening of the sealing cap of the container of the sample to be tested (sealing cap of the evacuated blood collection tube), and the pipette is used to suck the sample to be tested (for example, 50-150uL) into the sample loading position. Operators, especially those in disease control centers, remain exposed to high risk, infectious specimens, exposing them to potential biological risks. The device does not automate the mixing and transmission of the sample to be detected, and is only a semi-automatic instrument operation.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a full-automatic flow type sample preparation device to be tested for flow analysis, which automatically mixes a sample to be tested, automatically obtains the sample to be tested from a sample container to be tested, automatically adds the sample to be tested into a sample reaction container to be tested, automatically adds a plurality of required flow type reagents, automatically mixes a mixture of the sample to be tested and various antibody reagents, ensures the quality of the reaction and incubation processes of the sample and the reagents, avoids any manual intervention, and eliminates the exposure of operators to the biological risks of high-risk and easy infection.

In order to solve the problem of preparation of the sample to be tested in the flow analysis, the utility model discloses a sample preparation device of a flow analyzer, which comprises:

the device comprises an automatic sample injector component for a sample to be detected, a sample transmission component for the sample to be detected, a flow type sample reaction container component, a flow type reagent I transmission component, a flow type reagent II transmission component and a flow type sample mixing component;

the automatic sample injector component for the samples to be detected is provided with one or a plurality of sample container racks for the samples to be detected, the sample container racks for the samples to be detected move on the automatic sample injector component for the samples to be detected, and one or a plurality of sample containers for the samples to be detected are arranged on the sample container racks for the samples to be detected.

Preferably, the to-be-detected sample autosampler assembly is arranged at the front side, the flow-type sample reaction container assembly is arranged at the rear side of the to-be-detected sample autosampler assembly, and the to-be-detected sample transmission assembly is used for adding the to-be-detected sample in the to-be-detected sample autosampler assembly into the flow-type sample reaction container assembly;

preferably, the flow reagent I assembly is positioned at one side of the flow sample reaction container assembly, and the flow reagent I transmission assembly is used for adding the flow reagent I of the flow reagent I assembly into the flow sample reaction container assembly;

preferably, the flow reagent II assembly is positioned at one side of the flow sample reaction container assembly, and the flow reagent II transmission assembly is used for adding the flow reagent II in the flow reagent II assembly into the flow sample reaction container assembly;

preferably, the flow sample mixing assembly is located at one side of the flow sample reaction container assembly, and the flow sample mixing assembly is used for uniformly mixing the added sample to be lateral and the flow reagent I in the flow sample reaction container assembly, or the added sample to be lateral, the flow reagent I and the flow reagent II.

The sample to be detected transmission assembly is used for adding a sample to be detected at a specific position in the automatic sample injector assembly into the flow type sample reaction container assembly;

furthermore, the sample transmission assembly to be tested is provided with a mixing puncture beam, and the mixing puncture beam is provided with a sample container mixing assembly to be tested and a puncture assembly.

Furthermore, a turnover shaft and a sample container gripper to be detected are arranged on the sample container blending assembly to be detected, and the sample container gripper to be detected is arranged on the turnover shaft.

Preferably, the puncture assembly is provided with a puncture needle and a puncture needle cleaning device, and the puncture needle cleaning device can clean the puncture needle;

furthermore, the puncture needle is connected with a sample transmission pump to be detected through a pipeline.

The flow type sample reaction container component is provided with a flow type sample reaction container bracket mechanism and a bracket mechanism moving mechanism, wherein the flow type sample reaction container bracket mechanism is provided with a flow type sample reaction container structure, and the flow type sample reaction container bracket mechanism is arranged on the bracket mechanism moving mechanism.

Preferably, the carrier mechanism moving mechanism includes a rotary driving mechanism and a horizontal driving mechanism, the flow sample reaction vessel carrier mechanism is provided on the rotary driving mechanism, and the rotary driving mechanism is provided on the horizontal driving mechanism.

Furthermore, the flow type sample reaction container structure is provided with a flow type sample reaction container frame, and the flow type sample reaction container frame is provided with a plurality of annularly arranged flow type sample reaction containers.

The flow type reagent I component is provided with a flow type reagent I container bracket mechanism and a movement mechanism, wherein a flow type reagent I container is arranged on the flow type reagent I container bracket mechanism, and the flow type reagent I container bracket mechanism is arranged on the movement mechanism.

Further, the flow type reagent I assembly is provided with a temperature control mechanism.

Preferably, the moving mechanism is a rotating mechanism, the flow reagent I container is provided with one or more reagent containers arranged in a ring shape, and the flow reagent I in the reagent container is one antibody reagent or a mixed reagent of two or more different antibody reagents.

Furthermore, the flow type reagent I transmission assembly is provided with a flow type reagent I transmission needle and a flow type reagent I transmission needle movement mechanism, and the flow type reagent I transmission needle is connected with a flow type reagent I transmission pump through a pipeline.

Preferably, the moving mechanism of the flow reagent I transfer needle is a rocker arm lifting mechanism and a rocker arm rotating mechanism, the rocker arm rotating mechanism is arranged on the rocker arm lifting mechanism, and the flow reagent I transfer needle is arranged on the rocker arm rotating mechanism.

Furthermore, the device also comprises a cleaning pool for cleaning the flow type reagent I transmission needle, and the cleaning pool is positioned beside the reagent I transmission assembly.

The flow type reagent II assembly is provided with a flow type reagent II container, and the flow type reagent II container is connected with a flow type reagent II delivery pump through a pipeline.

Preferably, the flow reagent II in the flow reagent II container is one hemolysis reagent or a mixture of two or more different hemolysis reagents.

In the sample preparation device of the flow analyzer, the flow reagent II transmission assembly is provided with a flow reagent II sample adding needle, a reagent II sample adding movement mechanism and a sample adding needle cleaning device, and further, the flow reagent II sample adding needle is arranged on the reagent II sample adding movement mechanism.

The sample preparation device of the flow analyzer further comprises a flow sample blending assembly. Further, STREAMING sample mixing subassembly includes mixing rotary drive mechanism, the vertical actuating mechanism of mixing jack-up, mixing top and mixing end top cap, mixing rotary drive mechanism locates on the vertical actuating mechanism of mixing jack-up. Preferably, the blending top is arranged on the blending rotary driving mechanism, and the blending stop cover is positioned above the blending top.

Preferably, the mixing stop cap is arranged on the reagent II sample adding movement mechanism where the fluid reagent II sample adding needle is arranged, and the mixing stop cap is arranged on the sample adding needle cleaning device.

Preferably, in combination with the above technical solution, the operation steps of the sample preparation apparatus are as follows:

firstly, placing a flow type reagent I container containing a flow type reagent I assembly on a bracket of a reagent I container moving mechanism;

simultaneously, a flow type reagent II container of the flow type reagent II assembly is filled with a flow type reagent II;

then placing the flow sample reaction vessel on the flow sample reaction vessel assembly;

and finally, placing the to-be-detected sample container frame with the to-be-detected sample on the to-be-detected sample autosampler.

The flow reagent I container in the sample preparation device of the flow analyzer moves the required flow reagent I to a specific position where the flow reagent I can be obtained through the flow reagent I conveying component through the moving mechanism of the flow reagent I container;

the automatic sample injector for the sample to be detected moves the sample to be detected to specific mixing and puncturing positions in sequence;

if the sample to be detected is placed in a sealed container, after the sample to be detected is uniformly mixed by a mixing component in a sample transmission component to be detected, the puncture needle moves to the position below the liquid level of the sample to be detected, and the sample to be detected is sucked by the sample transmission component to be detected through a transmission pump connected with the sample transmission component;

if the sample to be detected is placed in the open container, the puncture needle in the sample transmission assembly to be detected moves to the position below the liquid level of the sample to be detected, and the sample to be detected is sucked by the sample transmission assembly to be detected through the transmission pump connected with the sample transmission assembly;

the flow type sample reaction container assembly moves the flow type sample reaction container to a specific sample reaction and sample adding position to be detected;

the puncture needle moves to a specific flow type sample reaction and sample adding position on the uniform mixing puncture beam, and the sample to be detected is added into the flow type sample reaction container by the sample transmission assembly to be detected through the transmission pump connected with the sample transmission assembly;

moving the container added with the sample to be detected of the flow type sample reaction container assembly to a specific flow type reagent I adding position;

moving a flow type reagent I transmission needle to a specific flow type reagent I acquisition position through a rocker arm rotating mechanism and a rocker arm lifting mechanism in a flow type reagent I transmission assembly, then moving the flow type reagent I transmission needle to a position below the liquid level of the flow type reagent I, and acquiring the flow type reagent I through a transmission pump connected with the flow type reagent I;

moving a flow type reagent I transmission needle to a flow type reagent I adding position through a rocker arm rotating mechanism and a rocker arm lifting mechanism in a flow type reagent I transmission assembly, moving the flow type reagent I transmission needle into a container of a sample to be detected, and adding a flow type reagent I through a transmission pump connected with the flow type reagent I transmission needle;

carrying out necessary cleaning on the flow type reagent I transmission needle according to the next flow type reagent I type to be transmitted;

the flow type sample reaction container assembly moves the flow type sample reaction container added with the sample to be detected and the flow type reagent I to a specific flow type sample mixing position, and the sample is mixed by the flow type sample mixing assembly;

waiting for the time required by the reaction of the sample to be detected and the flow type reagent I;

the flow sample reaction container assembly moves the flow sample reaction container added with the sample to be detected and the flow reagent I to a specific flow reagent II adding position;

adding a flow reagent II into a flow sample reaction container added with a sample to be detected and a flow reagent I by a flow reagent II transmission assembly;

adding a flow type reagent II into a flow type sample reaction container added with a sample to be detected and a flow type reagent I by a flow type reagent II transmission assembly, and uniformly mixing the sample by a flow type sample uniformly mixing assembly;

or the flow type reagent II transmission component adds two or more than two flow type reagents II to the flow type sample reaction container added with the sample to be detected and the flow type reagent I, and the samples are uniformly mixed through the flow type sample uniformly mixing component;

waiting for the incubation time required for the reaction to which the sample to be measured, flow reagent I and flow reagent II have been added.

Preferably, in combination with the above technical solution, another operation of the sample preparation device is as follows

Firstly, an operator places a flow reagent I container provided with a flow reagent I assembly in a bracket of a reagent I container moving mechanism;

finally, placing the to-be-detected sample container rack with the to-be-detected sample on the to-be-detected sample automatic sampler; the flow reagent I container in the sample agent preparation device of the flow analyzer moves the required flow reagent I to a specific position where the flow reagent I can be obtained through the flow reagent I conveying component through the moving mechanism of the flow reagent I container;

the flow type sample reaction container assembly moves the container added with the sample to be detected to a specific flow type reagent I adding position;

the automatic sample injector for the sample to be detected moves the next sample to be detected to a specific mixing and puncturing position in sequence, and the steps of adding the flow type reagent I, adding the sample to be detected and mixing the flow type reagent I and the sample to be detected are repeated until all the samples to be detected are completed or the provided flow type sample reaction container is used up;

the flow sample reaction container assembly moves the flow sample reaction container which is added with the sample to be detected and the flow reagent I and meets the required reaction time to a specific flow reagent II adding position;

adding a flow reagent II to a flow sample reaction container added with a sample to be detected and a flow reagent I by a flow reagent II transmission assembly;

adding a flow type reagent II into a flow type sample reaction container added with a sample to be detected and a flow type reagent I by a flow type reagent II transmission assembly, and uniformly mixing the sample by a flow type sample uniformly mixing assembly; or

Adding two or more than two flow reagents II into a flow sample reaction container added with a sample to be detected and a flow reagent I by a flow reagent II transmission assembly, and uniformly mixing the sample by a flow sample uniformly mixing assembly;

and repeating the previous step until the flow reagent II transmission assembly finishes adding the flow reagent II into all the flow sample reaction containers which are added with the sample to be detected and the flow reagent I and meet the reaction incubation time.

The utility model aims to provide a full-automatic flow type sample preparation device to be tested for flow analysis, which automatically mixes a sample to be tested, automatically obtains the sample to be tested from a sample container to be tested, automatically adds the sample to be tested into a sample reaction container to be tested, automatically adds a plurality of required flow type reagents, automatically mixes a mixture of the sample to be tested and various antibody reagents, ensures the quality of the reaction and incubation processes of the sample and the reagents, completely avoids any manual intervention, and eliminates the exposure of operators to the biological risks of high-risk and easy infection.

By adopting the technical scheme, the utility model replaces manual operation, has high sample adding precision and good consistency, and a user only needs to add a sample to be detected, a sample container to be detected, a reagent to be detected I or reagents to be detected I and II.

Drawings

FIG. 1 is a schematic perspective view of the present invention;

FIG. 2 is a schematic plan view of the present invention;

FIG. 3 is a plan view of the sample injector assembly of the present invention;

FIG. 4 is a schematic view of a sample transport assembly of the present invention;

FIG. 5 is a schematic view of a flow sample reaction vessel assembly of the present invention;

FIG. 6 is a schematic view of a flow reagent I delivery assembly of the present invention;

FIG. 7 is a schematic view of a flow sample mixing assembly of the present invention.

Description of the reference numerals

100-a sample autosampler assembly to be tested;

200-a flow sample reaction vessel assembly;

300-flow reagent I module;

400-flow reagent I needle cleaning position;

500-a flow reagent I transport assembly;

600-a flow sample mixing assembly;

700-a sample to be tested transport assembly;

110-sample container rack to be tested;

120-sample container to be tested;

130-bar code scanning and whether the sample container to be detected has an identification position or not;

140-uniformly mixing and taking a sample to be detected;

150-sample puncture site to be tested;

160-Y direction position sensor;

201-horizontal running track of a flow type sample reaction vessel frame;

202, placing and taking a flow type sample reaction container;

203-working position of the flow sample reaction vessel rack;

204-the rotation direction of the working position of the flow sample reaction vessel frame;

205-adding a sample to be detected into a reaction container;

206-sample adding position of a flow type reagent I needle;

207-mixing in a reaction container, and adding a flow type reagent II;

208-flow sample reaction vessel;

210-a flow sample reaction vessel assembly rotation mechanism;

220-flow sample reaction vessel assembly horizontal mechanism;

230-a flow sample reaction vessel carrier mechanism;

240-detecting the position of the sample reaction container;

250-flow sample reaction vessel rack;

301-direction of rotation of flow reagent I assembly;

302-flow reagent I needle aspiration site;

303-flow reagent I storage container;

304-flow reagent I storage container carrier;

501-rotating track of a flow reagent I needle;

510-a streaming reagent I transport assembly lifting mechanism;

511-a motor of a lifting mechanism of a flow reagent I conveying assembly;

520-a flow reagent I transport assembly rotation mechanism;

521-a motor for rotating a mechanism of a flow type reagent I transmission assembly;

530-flow reagent I delivery needle;

600-a flow sample mixing assembly;

610-a flow type sample mixing and rotating motor;

620-flow sample mixing lifting motor;

630-flow sample mixing ejector rod;

640-flow reagent II delivery needle;

650-flow reagent II needle cleaning device;

710-a sample mixing component to be detected;

711-uniformly mixing a sample to be detected with a shaft sleeve;

712-a sample to be tested mixing hand grip;

713-sample mixing motor to be measured;

714, uniformly mixing an upper sliding block seat and a lower sliding block seat of a sample to be detected;

715-uniformly mixing the sample to be detected with an upper motor and a lower motor;

720-a sample puncture assembly to be tested;

721, a sample puncture needle to be detected;

722-a sample puncture needle cleaning device to be detected;

723-upper and lower slide block seats of the puncture needle for the sample to be tested;

724-a sample puncture needle motor to be tested;

730-a motor before and after the transmission of the sample to be detected;

800-flow reagent II revolving door;

810-flow reagent II container a;

810-flow reagent II container B;

900-transfer pump;

910 — transfer pump a;

920-transfer pump B;

Detailed Description

For a better understanding of the disclosed apparatus, the disclosed apparatus will be described in detail and fully with reference to the accompanying drawings in which embodiments of the utility model are shown, and in which the described embodiments are merely exemplary embodiments, and are not to be construed as limiting the utility model. The following detailed description is provided to facilitate a more thorough understanding of the present disclosure, and the terms of orientation and direction, including upper, lower, left, right, clockwise, counterclockwise, etc., are used solely for the purpose of describing the illustrated structure in terms of position within the accompanying figures.

Based on the embodiments of the present invention, a person skilled in the art to which the present invention pertains may make several simple deductions or substitutions without departing from the concept of the present invention. Such deductions and substitutions are intended to fall within the scope of the present invention.

Example one

The utility model will be described in detail and illustrated in the accompanying drawings.

Referring to fig. 1 and 2, the present embodiment provides a sample preparation device of a flow analyzer, which includes a sample to be tested auto-injector assembly 100, a sample to be tested transport assembly 700, a flow sample reaction container assembly 200, a flow reagent I assembly 300, a flow reagent I transport assembly 500, a flow reagent II assembly, a flow reagent II transport assembly, and a flow sample mixing assembly 600.

As shown in fig. 1 and 2, the sample auto-sampler assembly 100 to be tested is disposed at the front side, the flow sample reaction container assembly 200 is disposed at the rear side of the sample auto-sampler assembly 100 to be tested, and the sample transmission assembly 700 to be tested is disposed above the sample auto-sampler assembly 100 to be tested and the flow sample reaction container assembly 200. The flow reagent I assembly 300 is located on one side of the flow sample reaction vessel assembly 200 and the flow reagent I transport assembly 500 is located behind the flow reagent I assembly 300 and the flow sample reaction vessel assembly 200.

As shown in fig. 1, the flow reagent II assembly includes a flow reagent II container a 810, a flow reagent II container B820, a rotary gate 800 suspended from the flow reagent II, and located at one side of the flow sample reaction container assembly 200, and a flow reagent II transfer assembly including a transfer pump a 910, a transfer pump B920, and a flow reagent II needle 640 located behind the flow sample reaction container assembly 200.

The flow sample mixing assembly 600 is located behind the flow sample reaction vessel assembly 200.

As shown in fig. 3, the sample to be tested is placed in the sample container 120 to be tested, and the sample container 120 to be tested may be closed or not. The sample container 120 to be tested is placed on the sample container rack 110, and the sample container rack 110 to be tested is placed on the auto-sampler component 100 to be tested, and the right side is in and out of the left side.

As shown in fig. 3, the auto-injector 100 for sample to be tested is placed with one or more sample containers 110, the sample containers 110 are moved on the auto-injector 100 for sample to be tested, and one or more sample containers 120 are placed on the sample containers 110. The auto-sampler 100 moves the sample container 110 in the Y direction and then in the X direction. The Y-direction motion is the whole frame translation along the Y direction. In the process of moving along the X direction, the sample container position to be measured is moved one at a time, which facilitates the blending and puncturing operations of the sample transport assembly 700 to be measured.

Referring to fig. 3, the auto sampler assembly 100 for samples to be tested is provided with a barcode scanning and identification position 130 for the presence or absence of a sample container to be tested, a sample container mixing pick-and-place position 140 for samples to be tested, and a sample puncturing position 150 for samples to be tested. After the sample container holder 110 to be tested is moved to the inner side along the Y direction and the Y-direction in-place sensor 160 is triggered, the sample container holder 110 to be tested moves along the X direction, and moves one sample container position to be tested along the X direction each time. Each sample container to be tested is moved to the barcode scanning position 130 first, and test tube presence and barcode scanning detection is performed. Then, a sample container position to be tested is moved along the X direction to reach the sample blending taking and placing position 140, and the sample to be tested is taken out by the sample transmission assembly 700, inverted and blended, and then placed back. Then, the sample container rack 110 moves one sample container position along the X direction to reach the sample container puncturing position 150, where the sample transmission assembly 700 punctures and samples the sample container. Each sample container 120 to be tested passes through the 3 positions (130, 140, 150) in sequence under the driving of the sample container rack 110 to be tested. When the sample autosampler assembly 100 moves to the left side along the X direction, the sample container rack 110 to be tested is driven to leave the X direction by the rotation of the sample container rack pusher (not shown) along the R direction, and the sample container rack pusher (not shown) to be tested resets along the R direction after each sample container rack 110 to be tested is pushed open.

As shown in fig. 4, the sample to be tested transmission assembly 700 is provided with a mixing puncture beam, and the mixing puncture beam is provided with a sample to be tested mixing assembly 710, a sample to be tested puncture assembly 720, and a front and rear sample to be tested transmission motor 730.

The sample blending assembly 710 to be tested is provided with a sample blending shaft sleeve 711 to be tested and a sample hand grip 712 to be tested. The sample gripper 712 is arranged on the sample blending shaft sleeve 711. The sample mixing shaft sleeve 711 to be tested is arranged on a motor rotating shaft of the sample mixing motor 713 to be tested. The sample mixing motor 713 to be tested is arranged on the sample mixing upper and lower sliding block seats 714, and the sample mixing upper and lower motor 715 to be tested is arranged on the frame of the sample mixing component 710 to be tested.

The sample puncture assembly 720 to be tested is provided with a sample puncture needle 721 to be tested and a sample puncture needle cleaning device 722 to be tested, and the sample puncture needle cleaning device 722 to be tested is fixed on the frame of the sample puncture assembly 720 to be tested and is sleeved on the sample puncture needle 721 to be tested; the sample puncture needle 721 to be tested is connected with a sample transmission pump 900 (see fig. 1) to be tested through a pipeline; the sample puncture needle 721 to be tested is fixed on the upper and lower slider seat 723 of the sample puncture needle, and the sample puncture needle motor 724 to be tested is fixed on the frame of the sample puncture assembly 720 to be tested.

As shown in fig. 4, the sample blending assembly 710 to be tested and the puncturing assembly 720 are driven by the motor 730 before and after the sample is transferred, and can move back and forth along the blending puncturing beam, and the initial position is in front of the frame of the sample blending assembly 710 to be tested. The sample blending hand grip 712 moves from the initial position to the position right behind and above the sample blending taking and placing position 140 (see fig. 2), the sample blending upper and lower motors 715 drive the sample blending upper and lower slider seats 714 to move downwards, and the sample blending hand grip 712 moves right behind the sample container 120 under the driving of the sample blending upper and lower slider seats 714. The sample blending assembly 710 and the puncture assembly 720 move forward together under the driving of the motor 730 before and after the transmission of the sample to be tested, and the sample blending hand grip 712 grips the sample container 120 to be tested under the action of the hand grip spring. The sample blending upper and lower motors 715 drive the sample blending upper and lower slider seats 714 to move upward, the sample blending hand 712 is driven by the sample blending upper and lower slider seats 714 to move upward, and the sample blending hand 712 grips the sample container 120 to be tested and leaves the sample container rack 110. The blending assembly 710 and the puncturing assembly 720 move backwards together to reverse the blending position of the sample container 120 under the driving of the motor 730 before and after the transmission of the sample to be tested. The sample mixing motor 713 to be tested drives the sample mixing shaft sleeve 711 to be tested to rotate in the direction of M, and the sample mixing shaft sleeve 711 to be tested drives the sample container 120 to be tested clamped by the sample mixing gripper 712 to be tested to perform overturning motion, so that manual reversing and mixing are simulated. After blending, the clamped sample container 120 to be tested is kept in a vertical state, the bottom of the sample container 120 to be tested faces downwards, the sample container 120 to be tested is placed back to the sample container to be tested blending taking and placing position 140 according to the reverse motion, and the sample blending hand grip 712 to be tested moves backwards to leave the sample container to be tested and then upwards resets to the initial position.

The sample container 120 to be tested moves one sample container position in the X direction and reaches the sample piercing position 150.

The sample mixing assembly 710 and the sample puncturing assembly 720 are driven by the motor 730 before and after the transmission of the sample to be tested, so that the sample puncturing needle 721 moves to a position right above the sample puncturing position 150. The sample puncture needle motor 724 to be tested drives the sample puncture needle upper and lower slider seat 723 to be tested to move downwards, the sample puncture needle upper and lower slider seat 723 to be tested drives the sample puncture needle 721 to be tested to penetrate through the container cover of the sample container 120 to be tested, the sample puncture needle 721 to be tested runs to the position below the liquid level of the sample container 120 to be tested, and the transmission pump 900 connected with the sample puncture needle 721 to be tested sucks the sample of the sample container 120 to be tested. The sample puncture needle 721 to be tested moves upward under the driving of the sample puncture needle motor 724 to be tested, and simultaneously the sample puncture needle cleaning device 722 cleans the outer wall of the sample puncture needle 721 to be tested. After the sample puncture needle 721 to be tested is moved to the upper position, the sample blending assembly 710 to be tested and the puncture assembly 720 are driven by the motor 730 before and after the sample to be tested is transferred, so that the sample puncture needle 721 to be tested moves to a position right above the position 205 (as shown in fig. 2) where the sample to be tested is added into the reaction container. The sample puncture needle 721 to be tested is driven by the sample puncture needle 724 to move downwards, and the transmission pump 900 connected with the sample puncture needle 721 to be tested transmits the sample to be tested to the flow type sample reaction container 208 on the sample adding reaction container position 205.

Certainly, the blending step is to seal the sample container 120 to be tested, and if the sample container 120 to be tested has no sealing cover, the blending cannot be performed, so as to prevent the sample to be tested from flowing out, and the puncturing and sucking step is performed by skipping the blending step.

As shown in fig. 5, the flow sample reaction vessel assembly 200 is provided with a flow sample reaction vessel carrier mechanism 230, and the flow sample reaction vessel carrier mechanism 230 is provided on the carrier mechanism moving mechanism. The bracket mechanism moving mechanism comprises a rotary driving mechanism 210 and a horizontal driving mechanism 220, wherein the flow sample reaction container bracket mechanism 230 is arranged on the rotary driving mechanism 210, and the rotary driving mechanism 210 is arranged on the horizontal driving mechanism 220.

The flow sample reaction container bracket mechanism 230 is provided with a flow sample reaction container structure, the flow sample reaction container structure is provided with a flow sample reaction container rack 250, the flow sample reaction container rack 250 is provided with a plurality of annularly arranged holes, and the plurality of annularly arranged holes can be inserted into the flow sample reaction container 208.

As shown in fig. 5, the horizontal driving mechanism 220 drives the rotary driving mechanism 210 to move left and right. As shown in fig. 2, the flow sample reaction vessel rack is placed in the flow sample reaction vessel rack placing and taking position 202, and moves along the horizontal movement track 201 of the flow sample reaction vessel rack to the flow sample reaction vessel rack working position 203;

as shown in fig. 2 and 5, the rotation driving mechanism 210 drives the flow sample reaction vessel rack 250 disposed thereon to rotate in the flow sample reaction vessel rack working position rotation direction 204. The flow sample reaction vessel holder mechanism 230 is further provided with a flow sample reaction vessel holder position detection optical coupler 240 for detecting the moving position of the flow sample reaction vessel holder 250.

As shown in fig. 2, when the flow sample reaction vessel rack 250 is in the flow sample reaction vessel rack operating position 203, three operating positions are provided: a sample to be detected is added into the reaction container position 205, the flow type reagent I needle adding position 206 and the reaction container mixing and adding flow type reagent II position 207, and any sample to be detected reaction container 208 can be switched among three stations along the working position rotating direction 204 by the flow type sample reaction container frame 250.

As shown in fig. 1 and 2, the flow reagent I assembly 300 is provided with a flow reagent I receptacle holder 304 and a movement mechanism, the flow reagent I receptacle holder 304 being provided with a circular arrangement of holes, the flow reagent I receptacles 303 being placed in the circular arrangement of holes of the flow reagent I receptacle holder 304, the flow reagent I receptacle holder 304 being provided on the movement mechanism. As shown in fig. 2, the flow reagent I assembly 300 is provided with a flow reagent I needle aspiration site 302. The moving mechanism is provided as a rotating mechanism, the flow reagent I container carrier 304 rotates in the flow reagent I assembly rotating direction 301 in fig. 2, and the flow reagent I container 303 placed in any circular arrangement of wells can move to the flow reagent I needle aspirating position 302. The flow reagent I in the flow reagent I container is one antibody reagent or a mixed reagent of two or more different antibody reagents.

The flow reagent I assembly 300 is further provided with a temperature control mechanism for temperature controlling the flow reagent I in the flow reagent I container 303 to ensure long term activity of the flow reagent I.

The flow reagent I assembly 300 is further provided with a mixing mechanism for mixing the flow reagent I in the flow reagent I container 303.

As shown in fig. 6, the flow type reagent I transferring assembly 500 is provided with a flow type reagent I transferring needle 530, a rocker arm lifting mechanism 510 and a rocker arm rotating mechanism 520, wherein the rocker arm lifting mechanism 510 and the rocker arm rotating mechanism 520 form a flow type reagent I transferring needle moving mechanism which can drive the flow type reagent I transferring needle 530 to move up and down and in the horizontal direction, and the flow type reagent I transferring needle 530 is connected with the transferring pump 900 through a pipeline. The rocker arm rotating mechanism 520 and the rocker arm lifting mechanism 510 are arranged on the frame of the flow reagent I transmission assembly 500, the flow reagent I transmission assembly lifting mechanism motor 511 drives the rocker arm lifting mechanism 510 to lift, and the flow reagent I transmission assembly rotating mechanism motor 521 drives the rocker arm rotating mechanism 520 to rotate. The flow reagent I transmission needle 530 is arranged on the rocker arm rotating mechanism 520, and the flow reagent I transmission needle 530 can simultaneously lift and rotate.

As shown in fig. 2, the flow reagent I transfer needle 530 can move along the flow reagent I needle rotation track 501, the flow reagent I transfer needle 530 first rotates from the flow reagent I needle cleaning position 400 (initial position) to the flow reagent I needle suction position 302, and then moves downward, the flow reagent I transfer needle 530 enters the flow reagent I container 303 to perform liquid level detection, the flow reagent I transfer needle 530 is lowered below the liquid level, and the flow reagent I is sucked under negative pressure by the transfer pump 900. The flow reagent I transfer needle 530 moves upward and then rotates to the flow reagent I needle loading position 206, the flow reagent I transfer needle 530 moves downward, the transfer needle approaches the bottom of the sample reaction container 208 to be tested, and the flow reagent I is transferred into the sample reaction container 208 to be tested by the transfer pump 900. The flow reagent I transmission needle 530 moves upwards and then rotates to the flow reagent I needle cleaning position 400, and the flow reagent I transmission needle 530 moves downwards and enters the cleaning pool for cleaning and drying. The flow reagent I transfer needle 530 moves upward and returns to the original position.

As shown in FIG. 2, the sample to be tested is added at the 205 position, the flow reagent I is added at the 206 position, and then the reaction vessel is rotated to mix the sample and the flow reagent II is added at the 207 position.

As shown in fig. 7, the flow sample mixing assembly 600 includes a mixing rotation driving mechanism 610, a mixing jack-up vertical driving mechanism 620, a mixing jack 630 and a flow reagent II needle cleaning device 650, the mixing rotation driving mechanism 610 is disposed on the mixing jack-up vertical driving mechanism 620, the mixing jack 630 is disposed on the mixing rotation driving mechanism, the flow reagent II needle cleaning device 650 is located above the mixing jack and has a spring to pull the flow reagent II needle cleaning device 650 downward. The flow type reagent II needle cleaning device 650 is sleeved on the flow type reagent II sampling needle 640, and the flow type reagent II sampling needle 640 is fixed on the frame of the flow type sample mixing assembly 600. The flow type reagent II sampling needle 640, the flow type reagent II needle cleaning device 650 and the mixing top 630 are on the same axis, and the flow type reagent II needle cleaning device 650 and the mixing top 630 are installed on the same guide rail and can move up and down along the same guide rail.

As shown in fig. 2 and 7, the mixing top 630 ejects the flow sample reaction container 208 at the flow reagent II position 207, the flow reagent II needle cleaning device 650 clamps the upper opening of the flow reaction container 208, the sample reaction container 208 to be measured is ejected out of the flow sample reaction container holder 250, the flow sample reaction container 208 is clamped between the flow reagent II needle cleaning device 650 and the mixing top 630, and the mixing rotation driving mechanism drives the flow sample reaction container 208 to rotate and mix the sample to be measured and the flow reagent I. After the completion of the mixing, the mixing tip 630 moves downward, and the mixing tip 630 and the flow reagent II needle cleaning device 650 clamp the flow sample reaction container 208 and return to the flow sample reaction container holder 250.

After the sample to be tested and the flow type reagent I are added and mixed uniformly in sequence, the flow type reaction container 208 filled with the mixture of the sample to be tested and the flow type reagent I is placed still on the flow type sample reaction container frame 250 for incubation.

As shown in fig. 1, the flow type reagent II assembly includes a flow type reagent II container a 810, a flow type reagent II container B820, which is suspended on the flow type reagent II rotary door 800 and located at one side of the flow type sample reaction container assembly 200, the flow type reagent II transport assembly includes a transport pump a 910, a transport pump B920, and a flow type reagent II transport needle 640, the flow type reagent II container a 810 is connected to ports a of the transport pump a 910 and the flow type reagent II needle 640 through a pipeline and a control valve, and the flow type reagent II container B810 is connected to ports B of the transport pump B920 and the flow type reagent II needle 640 through a pipeline and a control valve.

The transfer pump A910, as shown in FIG. 1, draws the flow reagent II from the flow reagent II reservoir A810 and then injects it through port A of the flow reagent II transfer needle 640. The transfer pump B920 sucks the flow reagent II from the flow reagent II container B820 and then injects it through the port B of the flow reagent II transfer needle 640.

As shown in fig. 2, the flow reaction container 208 containing the mixture of the sample to be tested and the flow reagent I after incubation runs to the reaction container mixing and flow reagent II adding position 207, the mixing top 630 pushes the flow reaction container 208 containing the mixture out of the flow reaction container 250, the required flow reagent II is added according to the above description, and then the mixture is mixed according to the above description. After the mixing, the flow reaction container 208 containing the sample to be tested, the flow reagent I and the flow reagent II is returned to the flow reaction container rack 250 for incubation.

As shown in fig. 2, after all the incubations after adding the flow reagent II are completed, the flow sample reaction container rack 250 is retracted to the flow sample reaction container rack pick-and-place position 202 along the horizontal movement track 201 of the flow sample reaction container rack.

Example two

Referring to fig. 2 and 3, a procedure for the operation of the apparatus according to the structure of the first embodiment will be described.

S1, placing the flow reagent I in the flow reagent I container 303 of the flow reagent I assembly 300;

s2, loading the flow type reagent II in the flow type reagent II container of the flow type reagent II

assemblies

910 and 920;

s3, placing the to-be-detected sample container rack 120 filled with the to-be-detected sample on the to-be-detected sample autosampler assembly 100;

s4, placing the flow sample reaction vessel 208 on the flow sample reaction vessel assembly 200;

s5, the flow reagent I container 303 moves the required flow reagent I to the specific position 302 where the flow reagent I can be obtained by the flow reagent I transport assembly 500 through its moving mechanism;

s6, the sample autosampler 100 moves the sample to be tested to the specific bar code scanning and identification position 130, blending position 140 and puncture position 150 of the sample container to be tested;

a) if the sample to be detected is placed in a sealed container, after the sample to be detected is uniformly mixed by the mixing component in the sample transmission component 700 to be detected, the puncture needle 721 moves to the position below the liquid level of the sample to be detected, and the sample transmission component 700 to be detected sucks 0.5-2000uL of the sample to be detected through the transmission pump 900 connected with the sample transmission component;

b) if the sample to be detected is placed in the open container, the puncture needle 721 in the sample transmission assembly 700 to be detected moves to the position below the liquid level of the sample to be detected, and the sample transmission assembly 700 to be detected sucks 0.5-2000uL of the sample to be detected through the transmission pump 900 connected with the sample transmission assembly 700 to be detected;

s7, the flow sample reaction container assembly 200 moves the flow sample reaction container 208 to the specific sample reaction loading position 205 to be tested;

s8, moving to the specific flow sample reaction sample adding position 205 on the mixing puncture beam through the puncture needle 721, and adding the sample to be detected into the flow sample reaction container 208 by the sample transmission assembly 700 through the transmission pump 900 connected thereto;

s9, the flow sample reaction container assembly 200 moves the container 208 to which the sample to be tested has been added in S8 to the specific flow reagent I addition site 206;

s10, moving the flow reagent I transmission needle 530 to a specific flow reagent I acquisition position 302 through a rocker arm rotating mechanism and a rocker arm lifting mechanism in the flow reagent I transmission assembly 500, then moving the flow reagent I transmission needle 530 to be below the liquid level of the flow reagent I, and acquiring that the flow reagent I is 0.4-1000uL through a transmission pump 900 connected with the flow reagent I;

s11, moving the flow reagent I transferring needle 530 to the flow reagent I adding position 206 in S9 by the rocker arm rotating mechanism and the rocker arm elevating mechanism in the flow reagent I transferring assembly 500, moving the flow reagent I transferring needle 530 to the bottom of the container 208 of the sample to be tested, and adding the flow reagent I by the transferring pump 900 connected thereto;

s12, carrying out necessary cleaning on the flow type reagent I transmission needle 530 at the position 400 according to the next flow type reagent I to be transmitted;

s13, the flow sample reaction container assembly 200 moves the flow sample reaction container 208 to which the sample to be detected and the flow reagent I have been added to the specific flow sample mixing position 207, and mixes the sample by the flow sample mixing assembly 600;

s14, waiting for the incubation time required by the reaction of the flow reagent I, and incubating for 5-120 minutes;

s15, the flow sample reaction container assembly 200 moves the flow sample reaction container 208 to which the sample to be measured and the flow reagent I have been added to the specific flow reagent II addition site 207.

S16, sucking the reagent in the flow reagent II

container

810 or 820 by the flow reagent II assembly through a

transfer pump

910 or 920, and adding the flow reagent II to the flow sample reaction container 208 to which the sample to be detected and the flow reagent I are added through a

needle

640, 910 or 920;

a) the flow type reagent II assembly adds a flow type reagent II of 100 and 2000uL to the flow type sample reaction container 208 added with the sample to be detected and the flow type reagent I, and the sample is uniformly mixed through the flow type sample uniformly mixing assembly 600;

b) the flow type reagent II assembly adds two or more than two flow type reagents II to the flow type sample reaction container 208 added with the sample to be detected and the flow type reagent I, wherein the flow type reagents II are respectively 100 and 2000uL, and the samples are uniformly mixed through the flow type sample uniformly-mixing assembly 600;

s17, waiting for the incubation time required by the reaction of the flow reagent II.

EXAMPLE III

Referring to fig. 2 and 3, another step for the operation of the apparatus is described below according to the structure of the first embodiment.

S1, placing the flow reagent I in the flow reagent I container 303 of the flow reagent I assembly 300, and placing the flow reagent I container 303 on a bracket of a reagent I container moving mechanism;

assemblies

910 and 920;

s6, the sample to be detected is moved to a specific mixing and puncturing position by the automatic sample injector 100;

s7, the flow sample reaction container assembly 200 moves the flow sample reaction container to the specific sample reaction loading position 205 to be tested;

s8, moving to the specific flow sample reaction and sample addition position 205 on the mixing puncture beam through the puncture needle 721, and adding the sample to be detected into the flow sample reaction container 208 by the sample transmission assembly 700 through the transmission pump 900 connected thereto;

s9, the flow sample reaction container assembly 200 moves the container 208 to which the sample to be tested has been added in S8 to the specific flow reagent I addition position 206;

s10, moving the flow reagent I transmission needle 530 to a specific flow reagent I acquisition position 302 through a rocker arm rotating mechanism and a rocker arm lifting mechanism in the flow reagent I transmission assembly 500, then moving the flow reagent I transmission needle 530 to be below the liquid level of the flow reagent I, and acquiring 0.4-1000uL of the flow reagent I through a transmission pump 900 connected with the flow reagent I;

s11, moving the flow reagent I transfer needle 530 to the flow reagent I adding position 206 in S9 by the rocker arm rotating mechanism and the rocker arm elevating mechanism in the flow reagent I transfer assembly 500, moving the flow reagent I transfer needle 530 into the container 208 of the sample to be tested, and adding the flow reagent I by the transfer pump 900 connected thereto;

s14, the automatic sample injector of the sample to be detected moves the next sample to be detected to a specific mixing and puncturing position in sequence, and S6-S13 are repeated until all the samples to be detected are detected or the provided flow type sample reaction container is used up;

s15, waiting for the time required by the reaction of the sample to be detected and the flow reagent I;

s16, the flow sample reaction container assembly 200 moves the flow sample reaction container to which the sample to be measured and the flow reagent I have been added and which satisfies the required reaction time, to the specific flow reagent II addition position 207;

s17, adding a flow reagent II into the flow sample reaction container added with the sample to be detected and the flow reagent I by the flow reagent II transmission component;

a) adding a flow type reagent II of 100 and 2000uL into a flow type sample reaction container added with a sample to be detected and a flow type reagent I by a flow type reagent II transmission assembly, and uniformly mixing the sample by a flow type sample uniformly mixing assembly; or

b) Adding two or more than two flow reagents II into a flow sample reaction container added with a sample to be detected and a flow reagent I by a flow reagent II transmission assembly, wherein the flow reagents II are respectively 100-2000uL, and uniformly mixing the sample by a flow sample uniformly mixing assembly;

s18, repeating S17 until the flow type reagent II transmission assembly finishes adding the flow type reagent II into all the flow type sample reaction containers which are added with the sample to be detected and the flow type reagent I and meet the required reaction time;

s19, waiting for the time required for the reaction of the sample to be detected, the flow reagent I and the flow reagent II to be added.

By adopting the technical scheme, the utility model automatically mixes the sample to be detected, automatically obtains the sample to be detected from the sample container to be detected, automatically adds the sample to be detected into the sample reaction container to be detected, automatically adds the required multiple flow reagents, and automatically mixes the mixture of the sample to be detected and various antibody reagents, thereby ensuring the quality of the reaction process of the sample and the reagents, completely avoiding any manual intervention, and eliminating the biological risk of exposing operators to high-risk contact and easy infection. An operator only needs to put a sample container to be detected into a sample container rack to be detected, place the sample container rack on an automatic sample injector assembly of the sample to be detected, obtain a prepared sample to be detected according to a set flow, and then perform flow analysis and detection.

The present invention is not limited to the above embodiments, and any modification, deduction, replacement, or improvement made within the principle of the present invention should be included in the protection scope of the present invention.

Claims

1. A sample preparation device for a flow analyzer, comprising:

the automatic sample injector assembly for the samples to be detected is used for automatically moving a sample rack to be detected placed by a user to a specific position, and the transmission assembly for the samples to be detected is used for adding the samples to be detected at the specific position into the flow type sample reaction container assembly;

the flow sample reaction container assembly is used for loading a container for flow sample reaction;

the flow reagent I assembly is used for loading flow reagent I for flow sample reaction, and the flow reagent I transmission assembly is used for adding the flow reagent I into the flow sample reaction container assembly;

the flow reagent II assembly is used for loading flow reagent II for flow sample reaction, and the flow reagent II transmission assembly is used for adding flow reagent II into the flow sample reaction container assembly;

the flow type sample mixing assembly is used for adding a sample to be side in the flow type sample reaction container assembly into the flow type reagent I or the flow type reagent II, or adding the flow type reagent I and the flow type reagent II into the sample to be side and then uniformly mixing.

2. The sample preparation device for a flow analyzer of claim 1, wherein the sample autosampler assembly is configured to receive one or more sample holders to be tested, the sample holders to be tested being moved on the sample autosampler assembly, the sample holders to be tested being configured to receive one or more sample containers to be tested.

3. The sample preparation device of a flow analyzer according to claim 1, wherein the sample transport assembly is provided with a mixing penetration beam, and the mixing penetration beam is provided with a sample container mixing assembly and a penetration assembly.

4. The sample preparation device of a flow analyzer according to claim 3, wherein the sample container mixing assembly to be tested is provided with a turnover shaft and a sample container gripper to be tested, and the sample container gripper to be tested is provided on the turnover shaft.

5. The sample preparation device for a flow analyzer according to claim 3, wherein the puncture assembly is provided with a puncture needle and a puncture needle cleaning device, and the puncture needle cleaning device can clean the puncture needle; the puncture needle is connected with a sample transmission pump to be tested through a pipeline.

6. The sample preparation device for a flow analyzer according to claim 1, wherein the flow sample reaction container assembly is provided with a flow sample reaction container holder mechanism on which the flow sample reaction container structure is provided, and a holder mechanism moving mechanism on which the flow sample reaction container holder mechanism is provided.

7. The sample preparation device for a flow analyzer according to claim 6, wherein the carriage mechanism moving mechanism comprises a rotary driving mechanism and a horizontal driving mechanism, the rotary driving mechanism is disposed on the rotary driving mechanism, and the rotary driving mechanism is disposed on the horizontal driving mechanism.

8. The sample preparation device for a flow analyzer according to claim 6, wherein the flow sample reaction vessel structure is provided with a flow sample reaction vessel rack provided with a plurality of annularly arranged flow sample reaction vessels.

9. The sample preparation device for a flow analyzer according to claim 1, wherein the flow reagent I assembly is provided with a flow reagent I container holder mechanism on which a flow reagent I container is provided, and a moving mechanism on which the flow reagent I container holder mechanism is provided.

10. The sample preparation device for a flow analyzer according to claim 9, wherein the movement mechanism is a rotation mechanism, the flow reagent I container is provided with one or two or more reagent containers arranged in a ring shape, and the flow reagent I in the reagent container is one reagent for reaction of the flow sample or a mixed reagent of two or more reagents for reaction of the flow sample.

11. The sample preparation device of a flow analyzer of claim 1, wherein the flow reagent I-pack is provided with a temperature control mechanism.

12. The sample preparation device for a flow analyzer according to claim 1, wherein the flow reagent I transfer assembly is provided with a flow reagent I transfer needle, a flow reagent I transfer needle movement mechanism, and the flow reagent I transfer needle is connected to the flow reagent I transfer pump through a pipeline.

13. The sample preparation device for a flow analyzer according to claim 12, wherein the movement mechanism of the flow reagent I transfer needle is a rocker arm elevating mechanism and a rocker arm rotating mechanism, the rocker arm rotating mechanism is disposed on the rocker arm elevating mechanism, and the flow reagent I transfer needle is disposed on the rocker arm rotating mechanism.

14. The sample preparation device for a flow analyzer of claim 12, further comprising a washing reservoir for washing the flow reagent I transfer needle.

15. The sample preparation device of a flow analyzer according to claim 1, wherein the flow reagent II assembly is provided with a flow reagent II container connected to a flow reagent II delivery pump via a pipeline;

the flow reagent II in the flow reagent II container is a reagent for reaction of a flow sample different from the flow reagent I or a mixed reagent of two or more reagents for reaction of a flow sample different from the flow reagent I.

16. The sample preparation device for a flow analyzer according to claim 1, wherein the flow type reagent II transport module is provided with a flow type reagent II loading needle, a flow type reagent II loading motion mechanism, and a flow type reagent II loading needle cleaning device, and the flow type reagent II loading needle is provided on the reagent II loading motion mechanism.

17. The sample preparation device of the flow analyzer according to claim 16, wherein the flow sample mixing assembly comprises a mixing rotation driving mechanism, a mixing jacking vertical driving mechanism, a mixing jacking and a mixing end cap, the mixing rotation driving mechanism is disposed on the mixing jacking vertical driving mechanism, the mixing jacking is disposed on the mixing rotation driving mechanism, and the mixing end cap is disposed above the mixing jacking.

18. The sample preparation device of a flow analyzer of claim 17, wherein the mixing stop cap is disposed on the flow reagent II loading movement mechanism, and the mixing stop cap is disposed on the flow reagent II loading needle cleaning device.