CN205374483U - Full -automatic fluorescence immunity quantitative analysis equipment - Google Patents

Abstract

The utility model discloses a full -automatic fluorescence immunity quantitative analysis equipment, including reagent strips module, transfer module, arm module, transport module, fluorescence scanning module and storage module, the utility model provides a pair of full -automatic fluorescence immunity quantitative analysis equipment can realize that full automatic detects, in the testing process, need not the artifical operation of interfering midway, also can accomplish smoothly, and degree of automation is high, the accuracy is high, easy operation is convenient.

Description

A kind of full-automatic fluorescence immunoassay quantitative analytical device

Technical field

This utility model relates to fluorescence immunoassay quantitative analysis detection technique field, particularly relates to a kind of full-automatic fluorescence immunoassay quantitative analytical device.

Background technology

When carrying out fluorescence immunoassay detection by quantitative, the quantitative analysis being correlated with is carried out frequently with diagnostic instruments, itself and traditional manual detection compare, and work efficiency obtains certain raising, but, diagnostic instruments common at present is semi-automatic detecting instrument, in operation, it is still desirable to manual operation, and in the market some so-called fully-automated synthesis instruments, in actual application process, it is desired nonetheless to artificial manual intervention just can complete to use.

Therefore, there are the shortcomings such as the probability of maloperation is bigger in conventional in the market detecting instrument, however it remains inefficiency.

Utility model content

The purpose of this utility model is in that to propose a kind of full-automatic fluorescence immunoassay quantitative analytical device, during to solve the fluorescence immunoassay detection by quantitative existed in prior art, adopt semiautomation operation, it is still desirable to artificial interference just can smoothly complete, ineffective technical problem.

For reaching this purpose, this utility model by the following technical solutions:

A kind of full-automatic fluorescence immunoassay quantitative analytical device, including reagent strip module, shift module, mechanical arm module, transport module, fluorescent scanning module and storage module；

Described reagent strip module includes support, and described support is provided with multiple test kit, and described support is connected to for controlling the moving assembly that described support moves；

Described shift module includes reaction tray, and described reaction tray is provided with the storage tank for depositing reagent strip, and described reaction tray is connected to motor, and described reaction tray is provided with the propelling movement assembly for pushing described reagent strip；

Described mechanical arm module includes mechanical arm main body, and described mechanical arm main body is connected to operation track, and described operation track includes X-axis, Y-axis and Z axis, and the end of described mechanical arm main body is connected to suction nozzle pick-up, and described suction nozzle pick-up is connected to plunger displacement pump；

Described transport module includes conveyer belt, and described conveyer belt is arranged over the incubation module being oppositely arranged with described conveyer belt；

Described fluorescent scanning module is located at the end of described conveyer belt, described fluorescent scanning module includes longitudinal motor, described longitudinal motor is provided with the draw-in groove for being moved by described reagent strip to described fluorescent scanning module, and described fluorescent scanning module is connected to data analysis module；

Described storage module includes diluent storage module, suction nozzle storage module and sample module.

Further, described sample module includes the long rails of the parallel distribution of multiple row, and described long rails is provided with the longitudinal sliding block for depositing sample；

The bottom of described long rails is provided with cross track, described cross track is provided with transverse slider, described transverse slider is connected to cross motor by leading screw, described transverse slider is provided with scan module and longitudinal motor, described longitudinal motor is connected to the leading screw with drive block, described drive block can be connected with longitudinal sliding block clamping described in each column respectively, and described scan module is connected with described data analysis module.

Further, described diluent storage module includes multiple rows of transversely arranged diluent holding tank, and described diluent holding tank is connected to longitudinal sliding block, and described longitudinal sliding block is located on long rails, and described longitudinal sliding block is connected to longitudinal motor by leading screw；

The side of described longitudinal sliding block is provided with horizontal slide rail, described horizontal track portion is located at the top of described longitudinal sliding block, described horizontal slide rail and described diluent holding tank are parallel to each other, described horizontal slide rail is provided with transverse slider, described transverse slider is connected to cross motor by leading screw, and described transverse slider is provided with fixing spindle motor, and described fixing spindle motor is connected to telescopic shaft, the telescopic direction of described telescopic shaft is perpendicular to described diluent holding tank, and described telescopic shaft is provided with Kaifeng blade.

Further, described suction nozzle storage module includes base, and described base is provided with the suction nozzle support for depositing disposable tip.

Further, the described support of described reagent strip module includes multiple socket, and described socket is connected with described test kit, and described moving assembly includes long rails, and described is set up on described long rails, and described support is connected to longitudinal motor by leading screw；

The bottom of described long rails is provided with cross track, and described cross track is provided with transverse slider, and described transverse slider is connected to cross motor by leading screw, and described transverse slider is provided with the first push rod for pushing reagent strip.

Further, the bottom of described reaction tray is located at by described motor, and described reaction tray is provided with multiple storage tank；

Described propelling movement assembly includes long rails, and described long rails is provided with longitudinal sliding block, and described longitudinal sliding block is connected to longitudinal motor by screw mandrel, and described longitudinal sliding block is provided with the second push rod for pushing reagent strip.

Further, the X-axis of described operation track includes conveyer belt, and described conveyer belt is connected to sliding support, and described sliding support is connected with Y-axis；

Described Y-axis includes bracing frame, the direction of transfer of the conveyer belt that support frame as described above is provided with slide rail, the glide direction of described slide rail and described X-axis is mutually perpendicular to, and described slide rail is provided with slide block, described slide block is connected to drive motor by conveyer belt, and described slide block is connected with Z axis；

Described Z axis includes elevating lever, and the bottom of described elevating lever is connected with described suction nozzle pick-up, and described elevating lever is provided with tooth, and described slide block is provided with the gear being meshed with described tooth, and described gear is connected to drive motor.

Further, described draw-in groove is located at the bottom of described fluorescent scanning module, and described draw-in groove passes along the bottom of described fluorescent scanning module, and described fluorescent scanning module is provided with reagent strip recovery holes away from the side of described draw-in groove.

Further, described data analysis module is connected to industry control screen, printer and data transmission interface.

Further, also including housing, plate in being provided with support baseboard in described housing and supporting, described housing is provided with function window.

A kind of full-automatic fluorescence immunoassay quantitative analytical device that this utility model provides, during use, it is possible to realize full automatic fluorescence immunoassay quantitative analysis.Concrete, in diluent storage module, suction nozzle storage module and sample module deposit corresponding diluent respectively, disposable tip and blood sample, afterwards, reagent strip module is to delivery of therapeutic agents bar in reaction tray, reaction tray rotates and reagent strip turns to mechanical arm main body place, wherein, the hole of bleeding of the reagent strip in reaction tray is oppositely arranged up and down with suction nozzle pick-up, mechanical arm main body is in X-axis, Y-axis and Z axis complete the three dimensions to suction nozzle pick-up control, its action includes mobile to suction nozzle storage module place connection disposable tip, move again and complete to sample to sample module, move again to diluent storage module place and complete mixing；Then, draw sample after mixing, mobile to reaction tray place, by mixed sample drop on reagent strip；Finally, disposable tip of decorporating, reconnect new disposable tip.

After reagent strip is supplied on conveyer belt, being completed incubation by incubation module in reagent strip course of conveying on the conveyor belt, wherein, incubation module primarily serves the effect of insulation.When completing the end that the reagent strip of incubation is transported to conveyer belt, draw-in groove reagent strip moved to fluorescent scanning module and complete detection, and the information parameter that detection obtains is flowed to data analysis module, thus completing once full-automatic fluorescence immunoassay quantitative analysis.

This full-automatic fluorescence immunoassay quantitative analytical device, it may be achieved full-automatic detection, in detection process, midway operates without artificial interference, it is also possible to smoothly complete, and automaticity is high, accuracy is high, simple to operation.

Accompanying drawing explanation

Fig. 1 is the structural representation of the full-automatic fluorescence immunoassay quantitative analytical device that this utility model embodiment provides；

Fig. 2 is the structural representation of the reagent strip module of the full-automatic fluorescence immunoassay quantitative analytical device that this utility model embodiment provides；

Fig. 3 is the structural representation of the shift module of the full-automatic fluorescence immunoassay quantitative analytical device that this utility model embodiment provides；

Fig. 4 is the structural representation of the mechanical arm module of the full-automatic fluorescence immunoassay quantitative analytical device that this utility model embodiment provides；

Fig. 5 is the structural representation of the transport module of full-automatic fluorescence immunoassay quantitative analytical device that provides of this utility model embodiment and fluorescent scanning module；

Fig. 6 is the structural representation of the diluent storage module of the full-automatic fluorescence immunoassay quantitative analytical device that this utility model embodiment provides；

Fig. 7 is the structural representation of the suction nozzle storage module of the full-automatic fluorescence immunoassay quantitative analytical device that this utility model embodiment provides；

Fig. 8 is the structural representation of the sample module of the full-automatic fluorescence immunoassay quantitative analytical device that this utility model embodiment provides；

Fig. 9 is the structural representation in the front of the housing of the full-automatic fluorescence immunoassay quantitative analytical device that this utility model embodiment provides；

Figure 10 is the structural representation at the back side of the housing of the full-automatic fluorescence immunoassay quantitative analytical device that this utility model embodiment provides.

In figure:

1, reagent strip module；2, shift module；3, mechanical arm module；4, transport module；5, fluorescent scanning module；6, diluent storage module；7, suction nozzle storage module；8, sample module；9, housing；10, cross motor；11, longitudinal motor；101, test kit；102, socket；103 first push rods；201, reaction tray；202, motor；203, storage tank；204, the second push rod；301, plunger displacement pump；302, X-axis；303, Y-axis；304, Z axis；401, conveyer belt；501, recovery holes；601, diluent holding tank；602, fixing spindle motor；603, telescopic shaft；701, base；702, suction nozzle support；801, sample；802, scan module；901, support baseboard；902, plate in supporting；903, industry control screen, 904, printed report outlet；905, reagent strip loads window；906, reagent strip outlet；907, abandoned reagents bar outlet；908, suction nozzle, diluent and sample storage silo；909, suction nozzle recovery bin；910, serial ports；911, parallel port；912, USB interface；913, power interface；914, power supply indicator.

Detailed description of the invention

The technical solution of the utility model is further illustrated below in conjunction with accompanying drawing and by detailed description of the invention.

As Figure 1-10 shows, a kind of full-automatic fluorescence immunoassay quantitative analytical device, including reagent strip module 1, shift module 2, mechanical arm module 3, transport module 4, fluorescent scanning module 5 and storage module；

Reagent strip module 1 includes support, and support is provided with multiple test kit 101, and support is connected to for controlling the moving assembly that support moves；

Shift module 2 includes reaction tray 201, and reaction tray 201 is provided with the storage tank 203 for depositing reagent strip, and reaction tray 201 is connected to motor 202, and reaction tray 201 is provided with the propelling movement assembly for pushing reagent strip；

Mechanical arm module 3 includes mechanical arm main body, and mechanical arm main body is connected to operation track, runs track and includes X-axis 302, Y-axis 303 and Z axis 304, and the end of mechanical arm main body is connected to suction nozzle pick-up, and suction nozzle pick-up is connected to plunger displacement pump 301；

Transport module 4 includes conveyer belt 401, and conveyer belt 401 is arranged over the incubation module being oppositely arranged with conveyer belt 401；

Fluorescent scanning module 5 is located at the end of conveyer belt 401, and fluorescent scanning module 5 includes longitudinal motor 11, and longitudinal motor 11 is provided with the draw-in groove for being moved by reagent strip to fluorescent scanning module 5, and fluorescent scanning module 5 is connected to data analysis module；

Storage module includes diluent storage module 6, suction nozzle storage module 7 and sample module 8.

As shown in Figure 8, sample module 8 includes the long rails of the parallel distribution of multiple row, and long rails is provided with the longitudinal sliding block for depositing sample 801；

The bottom of long rails is provided with cross track, cross track is provided with transverse slider, transverse slider is connected to cross motor 10 by leading screw, transverse slider is provided with scan module 802 and longitudinal motor 11, longitudinal motor 11 is connected to the leading screw with drive block, drive block can be connected with each column longitudinal sliding block clamping respectively, and scan module 802 is connected with data analysis module.

Sample 801 is the blood taking tube with blood, and what blood taking tube was in column is plugged on longitudinal sliding block, after sample module 8 deposits corresponding collection tube, it is necessary to each collection tube is scanned.

Transverse slider is by under the effect of cross motor 10, the position of longitudinal motor 11, drive block and scan module 802 can be controlled, the distance of mobile string longitudinal sliding block every time, drive block and longitudinal sliding block clamping, under the effect of longitudinal motor 11, longitudinal sliding block moves, so that each blood taking tube on longitudinal sliding block is scanned through module 802, makes scan module 802 complete the scanning to information；After having scanned, longitudinal sliding block resets, and cross motor 10 drives transverse slider to move to next longitudinal sliding block place, carries out the scanning of next column collection tube.Wherein, the effect of scan module 802 is the information of the patient on typing blood taking tube.

As shown in Figure 6, diluent storage module 6 includes multiple rows of transversely arranged diluent holding tank 601, and diluent holding tank 601 is connected to longitudinal sliding block, and longitudinal sliding block is located on long rails, and longitudinal sliding block is connected to longitudinal motor 11 by leading screw；

The side of longitudinal sliding block is provided with horizontal slide rail, horizontal track portion is located at the top of longitudinal sliding block, horizontal slide rail is parallel to each other with diluent holding tank 601, horizontal slide rail is provided with transverse slider, transverse slider is connected to cross motor 10 by leading screw, and transverse slider is provided with fixing spindle motor 602, and fixing spindle motor 602 is connected to telescopic shaft 603, the telescopic direction of telescopic shaft 603 is perpendicular to diluent holding tank 601, and telescopic shaft 603 is provided with Kaifeng blade.

Fixing spindle motor 602 can drive telescopic shaft about 603 to stretch, and wherein, the action of telescopic shaft 603 includes opening diluent, diluent being pushed accumulator tank.Wherein, open diluent action, telescopic shaft 603 is lifted up, telescopic shaft 603 rotates, under the effect of cross motor 10, successively the diluent often arranged is broken a seal, after complete diluent in a row is opened, longitudinal motor 11 drives diluent holding tank 601 to move, and telescopic shaft 603 carries out the unlatching of next row.

When diluent is pushed accumulator tank, telescopic shaft 603 stretch downward (is positioned at the middle and lower part of diluent), afterwards, telescopic shaft 603 does not turn, under the drive of cross motor 10, diluent on diluent holding tank 601 is shifted onto in accumulator tank, accumulator tank is arranged on the side of diluent holding tank 601, and afterwards, telescopic shaft 603 resets, driven by longitudinal motor 11, then carry out the propelling movement of next row.

As it is shown in fig. 7, suction nozzle storage module 7 includes base 701, base 701 is provided with the suction nozzle support 702 for depositing disposable tip.

Disposable tip rule on suction nozzle support 702 is arranged, as arranged in arrays, wherein, base 701 is arranged in support on plate 902, base 701 and dismantled and assembled between plate 902 in supporting, it is necessary to when supplementing disposable tip, base 701 is pulled down, disposable tip is placed on suction nozzle support 702, convenient interpolation.Under the effect of mechanical arm main body, suction nozzle pick-up completes the pickup to disposable tip.

As in figure 2 it is shown, the support of reagent strip module 1 includes multiple socket 102, socket 102 is connected with test kit 101, and moving assembly includes long rails, props up and is set up on long rails, and support is connected to longitudinal motor 11 by leading screw；

The bottom of long rails is provided with cross track, and cross track is provided with transverse slider, and transverse slider is connected to cross motor 10 by leading screw, and transverse slider is provided with the first push rod 103 for pushing reagent strip.

Each socket 102 arranges a test kit 101, the reagent strip of same model can be placed in each test kit 101, wherein, the test item that the reagent strip of different model is corresponding different, drive support to move by longitudinal motor 11, regulate and tear mouth alignment transverse slider accordingly open, afterwards, under the effect of cross motor 10, the first push rod 103 is driven to move, reagent strip in test kit 101 is pushed in reaction tray 201 by the first push rod 103, completes the propelling movement to reagent strip.

As it is shown on figure 3, the bottom of reaction tray 201 is located at by motor 202, reaction tray 201 is provided with multiple storage tank 203；

Pushing assembly and include long rails, long rails is provided with longitudinal sliding block, and longitudinal sliding block is connected to longitudinal motor 11 by screw mandrel, and longitudinal sliding block is provided with the second push rod 204 for pushing reagent strip.

Motor 202 can be selected for motor, and the effect of reaction tray 201 is to accept reagent strip, drives reagent strip to rotate the combination with mixed liquor, finally pushes to transport module 4 again.After concrete reagent strip is pushed to reaction tray 201, reaction tray 201 rotates 45 °, by scanning means (not shown), reagent strip is scanned, verify that whether its information is correct, namely whether the model of its reagent strip is consistent with detection needed for blood sample, if correct response dish 201 continues to rotate 135 °, on reagent strip, mixed liquor is added by mechanical arm module 3, react, afterwards, reaction tray 201 drives reagent strip to continue half-twist, under the effect of longitudinal motor 11, the second push rod 204 reagent strip pushes to transport module 4；If incorrect, reaction tray 201 rotates 45 ° under the effect of longitudinal motor 11, the second push rod 204 reagent strip is released reaction tray 201.

As shown in Figure 4, the X-axis 302 running track includes conveyer belt, and conveyer belt is connected to sliding support, and sliding support is connected with Y-axis 303；

Y-axis 303 includes bracing frame, and bracing frame is provided with slide rail, and the direction of transfer of the X-axis 302 of the glide direction of slide rail and conveyer belt is mutually perpendicular to, and slide rail is provided with slide block, and slide block is connected to drive motor by conveyer belt, and slide block Z axis 304 connects；

Z axis 304 includes elevating lever, and the bottom of elevating lever is connected with suction nozzle pick-up, and elevating lever is provided with tooth, and slide block is provided with the gear being meshed with tooth, and gear is connected to drive motor.

Mechanical arm main body can realize the three-dimensional motion of X-axis 302, Y-axis 303 and Z axis 304, its action includes completing assembling disposable tip in suction nozzle storage module 7, complete to draw sample 801 in sample module 8, sample 801 is instilled diluent, draw mixed liquor (plunger displacement pump 301 completes the absorption to mixed liquor and discharge) again, finally, mixed liquor is added drop-wise on reagent strip.

As it is shown in figure 5, draw-in groove is located at the bottom of fluorescent scanning module 5, draw-in groove can pass along the bottom of fluorescent scanning module 5, and fluorescent scanning module 5 is provided with reagent strip recovery holes 501 away from the side of draw-in groove.

Draw-in groove is arranged on the end of conveyer belt 401, by the reagent strip clamping on conveyer belt 401, under the effect of longitudinal motor 11, reagent strip is delivered to the lower section of fluorescent scanning module 5, fluorescent scanning module 5 completes the detection to reagent strip, and after detection completes, longitudinal motor 11 continues to drive reagent strip to move, being finally moved to recovery holes 501 place, reagent strip drops at recovery holes 501 place.

As it is shown in figure 9, data analysis module is connected to industry control screen 903, printer and data transmission interface.

The testing result of fluorescent scanning module 5 is carried out data analysis by data analysis module, it can be undertaken printing, preserve and exporting by analyzing accordingly result, concrete, industry control screen 903 is operated, by printer printed report, wherein industry control screen 903 can also show essential information, such as personal information, testing result etc..Data transmission structure can be serial ports 910, parallel port 911 or USB interface 912 (USB interface includes square USB port and flat-shaped USB interface) etc..Meanwhile, housing 9 arranges corresponding power interface 913 and power supply indicator 914.

As shown in Fig. 1 and Figure 10, this full-automatic fluorescence immunoassay quantitative analytical device also includes housing 9, and plate 902 in being provided with support baseboard 901 in housing 9 and supporting, housing 9 is provided with function window.

Modules is separately positioned in support baseboard 901 and support on plate 902, carries out rational layout.Wherein, arranging corresponding window on housing 9, export 904 including printed report, doctor/patient thus mouth takes out the printed report of detection；Reagent strip loads window 905 for adding reagent strip in test kit 101；Reagent strip outlet 906, exits in reaction tray 201 with the unmatched reagent strip of sample 801, exports 906 taking-ups by reagent strip；Abandoned reagents bar outlet 907, the reagent strip completing detection is fallen by recovery holes 501, abandoned reagents bar export 907 taking-ups, suction nozzle, diluent and sample storage silo 908, can realize supplementing disposable tip, diluent and sample 801 by this storehouse；The storage box of suction nozzle recovery bin 909, disposable tip and diluent drops in suction nozzle recovery bin, carries out unified recycling after using.

Time specifically used, diluent storage module 6, suction nozzle storage module 7 and sample module 8 are respectively configured required configuration diluent, disposable tip and blood sample 801, mechanical arm module 3 completes gripping suction nozzle, draw sample 801 and instill diluent, draw the action of mixed liquor again, reagent strip is delivered to shift module 2 by reagent strip module 1, at shift module 2, mixed liquor is added dropwise on reagent strip, afterwards, by shift module 2, reagent strip pushed to transport module 4, complete incubation at transport module 4, completed detection by fluorescent scanning module 5 afterwards.

Know-why of the present utility model is described above in association with specific embodiment.These describe and are intended merely to explanation principle of the present utility model, and can not be construed to the restriction to this utility model protection domain by any way.Based on explanation herein, those skilled in the art need not pay performing creative labour can associate other detailed description of the invention of the present utility model, and these modes fall within protection domain of the present utility model.

Claims (10)

1. a full-automatic fluorescence immunoassay quantitative analytical device, it is characterized in that, including reagent strip module (1), shift module (2), mechanical arm module (3), transport module (4), fluorescent scanning module (5) and storage module；

Described reagent strip module (1) includes support, and described support is provided with multiple test kit (101), and described support is connected to for controlling the moving assembly that described support moves；

Described shift module (2) includes reaction tray (201), described reaction tray (201) is provided with the storage tank (203) for depositing reagent strip, described reaction tray (201) is connected to motor (202), and described reaction tray (201) is provided with the propelling movement assembly for pushing described reagent strip；

Described mechanical arm module (3) includes mechanical arm main body, described mechanical arm main body is connected to operation track, described operation track includes X-axis (302), Y-axis (303) and Z axis (304), the end of described mechanical arm main body is connected to suction nozzle pick-up, and described suction nozzle pick-up is connected to plunger displacement pump (301)；

Described transport module (4) includes conveyer belt (401), and described conveyer belt (401) is arranged over the incubation module being oppositely arranged with described conveyer belt (401)；

Described fluorescent scanning module (5) is located at the end of described conveyer belt (401), described fluorescent scanning module (5) includes longitudinal motor (11), described longitudinal motor (11) is provided with for described reagent strip moves the draw-in groove to described fluorescent scanning module (5), and described fluorescent scanning module (5) is connected to data analysis module；

Described storage module includes diluent storage module (6), suction nozzle storage module (7) and sample module (8).

2. full-automatic fluorescence immunoassay quantitative analytical device according to claim 1, it is characterised in that described sample module (8) includes the long rails of the parallel distribution of multiple row, and described long rails is provided with the longitudinal sliding block for depositing sample；

The bottom of described long rails is provided with cross track, described cross track is provided with transverse slider, described transverse slider is connected to cross motor (10) by leading screw, described transverse slider is provided with scan module (802) and longitudinal motor (11), described longitudinal motor (11) is connected to the leading screw with drive block, described drive block can be connected with longitudinal sliding block clamping described in each column respectively, and described scan module is connected with described data analysis module.

3. full-automatic fluorescence immunoassay quantitative analytical device according to claim 1, it is characterized in that, described diluent storage module includes multiple rows of transversely arranged diluent holding tank (601), described diluent holding tank (601) is connected to longitudinal sliding block, described longitudinal sliding block is located on long rails, and described longitudinal sliding block is connected to longitudinal motor (11) by leading screw；

The side of described longitudinal sliding block is provided with horizontal slide rail, described horizontal track portion is located at the top of described longitudinal sliding block, described horizontal slide rail and described diluent holding tank are parallel to each other, described horizontal slide rail is provided with transverse slider, described transverse slider is connected to cross motor (10) by leading screw, described transverse slider is provided with fixing spindle motor (602), described fixing spindle motor (602) is connected to telescopic shaft (603), the telescopic direction of described telescopic shaft (603) is perpendicular to described diluent holding tank (601), described telescopic shaft (603) is provided with Kaifeng blade.

4. full-automatic fluorescence immunoassay quantitative analytical device according to claim 1, it is characterized in that, described suction nozzle storage module (7) includes base (701), and described base (701) is provided with the suction nozzle support (702) for depositing disposable tip.

5. full-automatic fluorescence immunoassay quantitative analytical device according to claim 1, it is characterized in that, the described support of described reagent strip module (1) includes multiple socket (102), described socket (102) is connected with described test kit (101), described moving assembly includes long rails, described is set up on described long rails, and described support is connected to longitudinal motor (11) by leading screw；

The bottom of described long rails is provided with cross track, described cross track is provided with transverse slider, described transverse slider is connected to cross motor (10) by leading screw, and described transverse slider is provided with the first push rod (103) for pushing reagent strip.

6. full-automatic fluorescence immunoassay quantitative analytical device according to claim 1, it is characterized in that, the bottom of described reaction tray (201) is located at by described motor (202), and described reaction tray (201) is provided with multiple storage tank (203)；

Described propelling movement assembly includes long rails, and described long rails is provided with longitudinal sliding block, and described longitudinal sliding block is connected to longitudinal motor (11) by screw mandrel, and described longitudinal sliding block is provided with the second push rod (204) for pushing reagent strip.

7. full-automatic fluorescence immunoassay quantitative analytical device according to claim 1, it is characterized in that, the X-axis (302) of described operation track includes conveyer belt, and described conveyer belt is connected to sliding support, and described sliding support is connected with Y-axis (303)；

Described Y-axis (303) includes bracing frame, support frame as described above is provided with slide rail, the direction of transfer of the conveyer belt of the glide direction of described slide rail and described X-axis (302) is mutually perpendicular to, described slide rail is provided with slide block, described slide block is connected to drive motor by conveyer belt, and described slide block is connected with Z axis (304)；

Described Z axis (304) includes elevating lever, and the bottom of described elevating lever is connected with described suction nozzle pick-up, and described elevating lever is provided with tooth, and described slide block is provided with the gear being meshed with described tooth, and described gear is connected to drive motor.

8. full-automatic fluorescence immunoassay quantitative analytical device according to claim 1, it is characterized in that, described draw-in groove is located at the bottom of described fluorescent scanning module (5), described draw-in groove passes along the bottom of described fluorescent scanning module (5), and described fluorescent scanning module (5) is provided with reagent strip recovery holes (501) away from the side of described draw-in groove.

9. full-automatic fluorescence immunoassay quantitative analytical device according to claim 1, it is characterised in that described data analysis module is connected to industry control screen (903), printer and data transmission interface.

10. full-automatic fluorescence immunoassay quantitative analytical device according to claim 1, it is characterized in that, also include housing (9), plate (902) in being provided with support baseboard (901) in described housing (9) and supporting, described housing (9) is provided with function window.