CN113138285A

CN113138285A - Conveying device on detection analyzer

Info

Publication number: CN113138285A
Application number: CN202010592884.XA
Authority: CN
Inventors: 方炜; 唐林勇; 商涛; 王中平
Original assignee: Leadway HK Ltd
Current assignee: Leadway HK Ltd
Priority date: 2020-01-16
Filing date: 2020-06-25
Publication date: 2021-07-20
Also published as: CN213482254U; CN213482252U; CN213482251U; CN113138286A; CN213875703U; CN213302233U; CN213482253U; CN113203871A

Abstract

The invention relates to a conveying device on a detection analyzer, which comprises a movable bearing plate and an object stage which is positioned on the bearing plate and can be separated from the bearing plate; the object stage and the bearing plate each include an upper surface and a lower surface, the lower surface of the object stage and the upper surface of the bearing plate facing each other; the upper surface of the objective table is provided with a structure for fixing the detection element, the objective table and the bearing plate are respectively provided with magnetic blocks, and the magnetic blocks are arranged in a magnetic attraction mode. When the object stage is placed in a preset area on the bearing plate, the magnetic block enables the object stage to automatically move to a designated position on the bearing plate, and the attraction of the magnetic block enables the object stage to be automatically positioned relative to the bearing plate, so that the technical effect of blind placement is achieved. The invention can be applied to detection analyzers for specific protein, cholesterol, heme, urine routine, dry biochemistry and the like. The invention has the advantages of simple operation, time and labor saving, high working efficiency and the like. Meanwhile, the invention has simple structure and low cost and is suitable for wide popularization.

Description

Conveying device on detection analyzer

Technical Field

The invention belongs to the field of medical detection, relates to an accessory on a biological sample analyzer, and particularly relates to a conveying device on a detection analyzer.

Background

Urine analyzers are instruments for measuring chemical components in urine and have important roles in the field of medical diagnosis. A typical urine analyzer requires that a test strip or a test card (collectively referred to as "biological sample detection reagent" or simply "detection reagent") immersed in urine be placed on a carrier and transported to a detection site for detection. When two kinds of test devices, i.e. a test strip and a test card, can be used in the same instrument, there are generally three kinds of implementation schemes.

The first solution is to put the test strips or cards on their respective carriers, and then place the carriers on a common carrier. Like the solution disclosed in the urine analyzer of us.pat. No.7118713b2, when an operator replaces a test strip or a test card with a test card or a test strip, the operator needs to replace the carriage at the same time, and a dead angle for cleaning is formed due to the placement position of the carriage on the stage.

The second solution is to provide a test card placement location on the carrier, and perform dimension processing on the test strip carrier, so that the test strip carrier can also be placed in the test card placement location, such as the solution disclosed in the urine analyzer of us.pat. No. 6239445b1. This solution, while using a smaller test card carrier than the first solution, still requires repeated replacement of the carrier during use.

The third scheme is to make a carrier into a double-sided design, wherein the carrier usually needs a larger volume, one side is provided with a test strip placing position, and the other side is provided with a test card placing position. When replacing the test strip or the test card with the test card or the test strip, an operator needs to clean and dry the used surface of the carrier, and then connect the used surface with the instrument, and the unused surface is used for placing the test card or the test strip.

Similar product is that the microscope carrier tow sides is put the detection material, and this type can be inconvenient relatively in the operation, when changing a material and detect, need take off the objective carrier, must put into on the reverse side again after the cleanness, and the space that just occupies also can be great.

Therefore, the microscope carrier design in the prior art enables the urine analyzer to have the problems of large instrument volume, multiple operation steps, large cleaning difficulty, inconvenience in use and the like.

In addition, when the detection reagent is placed on the stage and then detected by the detection instrument, the detection reagent needs to be accurately positioned in the detection instrument, so that the detection region on the detection reagent (the region where the biological sample is added and the detection reagent is detected) is accurately aligned with the optical detection unit on the detection instrument, and the detection result is output after the detection region is processed by spectroscopic analysis or the like. If the detection reagent is not accurately positioned in the detection instrument, the active light source emitted by the optical detection component on the detection instrument cannot accurately irradiate the detection area on the detection reagent, so that the detection result is inaccurate or even wrong. Although some prior art can fix a position accurately, the location process is loaded down with trivial details, wastes time and energy, and work efficiency is low. Therefore, there is a need for a transport device on a test analyzer or a test meter including the transport device that is accurate at a predetermined level and easy and fast to operate.

Disclosure of Invention

The invention provides a conveying device on a detection analyzer, which comprises a movable bearing plate and an object stage which is positioned on the bearing plate and can be separated from the bearing plate; the object stage and the bearing plate each include an upper surface and a lower surface, the lower surface of the object stage and the upper surface of the bearing plate facing each other; the upper surface of the objective table is provided with a structure for fixing a detection element, magnetic blocks are respectively arranged on the objective table and the bearing plate, and the magnetic blocks are arranged in a magnetic attraction manner; when the object stage is placed in a preset area on the bearing plate, the magnetic block enables the object stage to automatically move to a specified position on the bearing plate.

Furthermore, the conveying device comprises two pairs of magnetic blocks which are spaced at a proper distance from each other, the two magnetic blocks on the object stage are opposite in polarity in the same direction, the two magnetic blocks on the bearing plate are opposite in polarity in the same direction, and the magnetic blocks on the object stage and the corresponding magnetic blocks on the bearing plate are arranged in an opposite attraction manner.

Furthermore, a concave area is arranged on the upper surface of the bearing plate in an area close to the magnetic blocks on the bearing plate; when the orthographic projection of the magnetic block on the object stage on the bearing plate is positioned in the depressed area, the magnetic blocks on the object stage and the bearing plate are attracted, so that the object stage is automatically positioned relative to the bearing plate.

Furthermore, at least part of the magnetic block on the object stage protrudes out of the lower surface of the object stage, the bearing plate is provided with counter bores with the contour shape and the size matched with those of the magnetic block on the object stage on the upper surface of the bearing plate, at least part of the magnetic block mounted on the object stage falls into the counter bores on the bearing plate, and the magnetic block abuts against the hole walls of the counter bores, so that automatic positioning is realized.

Furthermore, a cone chamfer angle guide hole with larger size is arranged at the uppermost opening of the counter bore, the depth of the chamfer angle is 0.3-2.0 mm, and the included angle between the chamfer angle and the vertical axis of the counter bore is 30-60 degrees.

Furthermore, a section of slope channel communicated with the counter bore is arranged on the upper surface of the bearing plate, and the slope channel gradually descends from a position far away from the counter bore to a position close to the counter bore.

Furthermore, the upper surface of the bearing plate and the lower surface of the object stage are respectively provided with a positioning structure which is matched with each other.

Furthermore, the positioning structure comprises protrusions respectively arranged on the upper surface of the bearing plate and the lower surface of the object stage, and the protrusions are abutted against each other by the suction force of the magnetic block, so that automatic positioning is realized.

Further, location structure is including setting up protruding and the recess of mutually supporting of surface under loading board upper surface and the objective table respectively, and the protruding falls into the recess, and the suction of magnetic path makes the lateral wall of protruding and recess support each other and lean on to realize automatic positioning.

Furthermore, the outer contour of the orthographic projection of the protrusion and the groove on the bearing plate and the objective table on the upper surface of the bearing plate or the lower surface of the objective table is wedge-shaped, the protrusion slides in the groove along the lengthwise direction of the bearing plate, and the side walls of the protrusion and the groove are mutually abutted.

Furthermore, the cross section of the projection and the groove on the bearing plate and the object stage is wedge-shaped or inverted trapezoid with wide top and narrow bottom, the projection slides into the groove in the direction approximately vertical to the upper surface of the bearing plate, and the side walls of the projection and the groove abut against each other.

Furthermore, a liquid discharge channel is arranged on the upper surface of the bearing plate in the area close to the magnetic block on the bearing plate.

Furthermore, the upper surface of the bearing plate is provided with a liquid discharge hole communicated with the depressed area, and the liquid discharge hole penetrates through the lower surface of the bearing plate.

Furthermore, a liquid drainage channel communicated with the counter bore is arranged on the upper surface of the bearing plate and comprises a liquid drainage hole penetrating through the lower surface of the bearing plate.

Further, a water absorbing material is arranged in the liquid drainage channel, and the water absorbing material is selected from the following components: absorbent filter paper, sponge, nitrocellulose membrane and glass fiber membrane.

Has the advantages that:

according to the conveying device on the detection analyzer, the magnets which are arranged in opposite attraction and the positioning structure are adopted, so that the object stage filled with the detection reagent is only required to be placed at the preset approximate position of the bearing plate (accurate positioning is not required) during operation, the object stage can automatically reach the accurate position on the bearing plate under the driving of the magnetic force and the accurate guidance of the positioning structure, the automatic accurate positioning is realized, and the technical effect of blind placement is achieved. Therefore, the invention has the advantages of simple operation, time and labor saving, high working efficiency and the like. Meanwhile, the invention has simple structure and low cost and is suitable for wide popularization.

Drawings

Fig. 1 is a schematic structural view of a stage for a detection analyzer according to the present invention.

Fig. 2 is a plan view of a stage for a detection analyzer according to the present invention.

Fig. 3 is a schematic view showing a detection plate placed on a stage for a detection analyzer according to the present invention.

Fig. 4 is a sectional view a-a of fig. 3.

Fig. 5 is a schematic view of the back of the detection plate.

Fig. 6 is a schematic diagram of a test strip placed on a stage for a detection analyzer according to the present invention.

Fig. 7 is a sectional view a-a of fig. 6.

Fig. 8 is a schematic view of a detection unit of the detection analyzer.

Fig. 9 is a schematic view of a detection board placed on a detection unit of the detection analyzer.

FIG. 10 is a schematic diagram of a test strip placed on a detection unit of a detection analyzer.

Figure 11 is an exploded view of the stage and carrier plate in combination.

Fig. 12 is a schematic view of a detection unit of a detection analyzer including another stage.

Fig. 13 is a schematic view of a detection plate configured with the stage of fig. 12.

FIG. 14 is a schematic view of a detection unit of the detection analyzer including another stage.

FIG. 15 is a perspective view of the carrier plate according to the first embodiment of the present invention, showing the upper surface structure of the carrier plate.

FIG. 16 is similar to FIG. 15 but shows the magnetic blocks in a precisely positioned position.

FIG. 17 is a top view of the carrier plate and the stage after they are combined.

Fig. 18 is a cross-sectional view taken along line a-a of fig. 17.

Fig. 18A is an enlarged partial schematic view of fig. 18 at position a.

Fig. 18B is an enlarged partial schematic view of fig. 18 at position B.

Fig. 19 is a perspective view of the stage in the second embodiment of the present invention, showing the lower surface structure of the stage.

Fig. 19A is an enlarged partial schematic view of fig. 19 at position a.

Fig. 19B is an enlarged partial schematic view of fig. 19 at position B.

FIG. 20 is a perspective view of the carrier plate according to the second embodiment of the present invention, showing the upper surface structure of the carrier plate (including the magnetic blocks).

Fig. 20A is an enlarged partial schematic view of fig. 20 at position a.

Fig. 20B is a partially enlarged schematic view of fig. 20 at position B.

Figure 21 is a side partial cross-sectional view of the carrier plate of figures 19 and 20 in combination with the stage to a precisely positioned position on the carrier plate.

Fig. 21A is an enlarged partial schematic view of fig. 21 at position a.

FIG. 22 is a schematic diagram of a first arrangement of the polarities of the magnetic blocks on the stage and the carrier plate.

FIG. 23 is a schematic diagram of a second arrangement of the polarities of the magnetic blocks on the stage and the carrier plate.

FIG. 24 is a perspective view of the carrier plate according to the third embodiment of the present invention, showing the upper surface structure (without magnetic blocks) of the carrier plate.

Fig. 24A is an enlarged partial cross-sectional view taken along line a-a of fig. 24.

FIG. 25 is a perspective view of the carrier plate according to the fourth embodiment of the present invention, showing the upper surface structure of the carrier plate (without magnetic blocks).

Fig. 26 is a side sectional view of the object table of the fourth embodiment of the present invention placed in the initial position of the loading plate.

Fig. 26A is an enlarged partial schematic view of fig. 26 at position a.

FIG. 27 is similar to FIG. 26 but shows a precisely located position on the carrier plate.

Fig. 27A is an enlarged partial schematic view of fig. 27 at position a.

FIG. 28 is a perspective view of the carrier plate according to the fifth embodiment of the present invention, showing the upper surface structure of the carrier plate (without magnetic blocks).

Fig. 28A is an enlarged partial schematic view of fig. 28 at position a.

Fig. 28B is an enlarged partial schematic view of fig. 28 at position B.

FIG. 29 is similar to FIG. 28 but contains a magnetic block.

Fig. 30 is a top plan view of fig. 29.

FIG. 31 is a perspective view of a supporting board according to a sixth embodiment of the present invention, showing the upper surface structure of the supporting board (without magnetic blocks).

Fig. 32 is a perspective view of the stage according to the sixth embodiment of the present invention, showing the lower surface structure (including magnetic blocks) of the stage.

Fig. 33 is a top view (partially in section) of the initial position of fig. 31 and 32 in combination.

Figure 34 is similar to figure 33 but shows the stage reaching a precisely positioned position on the carrier plate.

Fig. 35 is a side sectional view of fig. 34.

FIG. 36 is a perspective view of a carrier plate according to a seventh embodiment of the present invention, showing the upper surface structure of the carrier plate (without magnetic blocks).

Fig. 37 is a perspective view of the stage in the seventh embodiment of the present invention, showing the lower surface structure of the stage (without magnetic blocks).

Fig. 38 is a top view of fig. 37 in combination with fig. 38.

Figure 39 is a cross-sectional view taken along line a-a of figure 38 showing the initial position of the stage in combination with the carrier plate.

Figure 40 is similar to figure 39 but shows the precise positioning of the stage in combination with the carrier plate.

Reference numerals

Object stage

100, 100 ', 100 ", magnetic block 101, 101 ', 401 ', groove 110, boss 111, object stage concave hole 111 ', convex strip 112, first slot 120, opening 121, convex block 122, second slot 130, slot convex pin 134 ', opening 131, convex block 132, protrusion 133, object stage lower surface 151, object stage upper surface 152, detection plate 200, 200 ', bottom plate 210, cover plate 220, concave hole 211, detection plate protrusion 211 ', depression 230, test strip 300, 300 ', substrate 301, detection test strip 302, test strip hole 301 ', detection unit 10, bearing plate 400, bearing plate upper surface 410, bearing plate lower surface 411,

depression area

412, 413,

vertical wall

416, 153, counter bore 414, 414 ', slope channel 415, protrusion 154, groove 417, cone chamfer guiding hole 418, drainage channel 419, 419 ', drainage port 420, first

magnetic hole

102, 402, second magnetic hole 102 ', 402 ', the gantry type PCB detection device comprises a gantry type bracket 500, a motor 600, a gear 700, a hexagonal head 900 and a detection photoelectric PCB 800.

Detailed Description

In the following detailed description, reference is made to the accompanying drawings that form a part hereof, and in which is shown by way of illustration specific embodiments in which the invention may be practiced. It is not excluded that the invention can also be implemented in other embodiments and that the structure of the invention can be varied without departing from the scope of use of the invention.

As shown in fig. 1 to 14, the objective table for a biological sample analyzer of the present invention can place both a detection plate and a detection test strip (the detection test strip is simply called a test strip; for convenience, the detection plate and the detection test strip are collectively called a detection element) on the same plane. The operator selects the detection plate or the test strip respectively according to the needs of the test items, and places the detection plate or the test strip on the objective table, completes information detection and analysis on the detection plate and the test strip, avoids frequently taking out or overturning the objective table from the biological sample analyzer, thereby effectively avoiding operation errors caused by complex operation of operators while improving the detection efficiency. Therefore, the detection plate limiting structure is arranged on the same surface, such as the front surface, of the object stage for bearing the test strip. This pick-up plate limit structure makes the pick-up plate be injectd in the suitable position of objective table to make the objective table get into biological sample analysis appearance after, the testing result on the pick-up plate just in time is located the light source detection zone.

In some embodiments, the detection plate limiting structure is a boss matched with the detection plate, or a concave hole matched with the detection plate, or a groove for accommodating the detection plate, or a combination of the boss and the groove, or a combination of the concave hole and the groove.

In the embodiment shown in fig. 1 to 10, the stage 100 is provided with a boss 111. This boss 111 is as pick-up plate limit structure, and when placing pick-up plate 200 on the objective table, the boss is used for spacing pick-up plate 200 as limit structure and pick-up plate cooperation, plays the detection position of locating the pick-up plate at the objective table. Meanwhile, when the test strip is positioned on the objective table, the boss 111 also limits the position of the test strip on the objective table, so that the detection results of the detection plate and the test strip are just positioned in a proper light source detection area of the biological sample analyzer, and the detection results of the detection plate and the test strip are accurately read by the biological sample analyzer. The raised platform also serves as a support structure for cooperating with the test strip to support the test strip 300 such that the test strip on the stage is in a substantially uniform plane.

In a further optimized design scheme, the height of the boss on the objective table is designed to ensure that the detection height of the test strip on the boss is the same as the detection height of the test strip in the detection plate on the boss. Therefore, no matter the detection plate or the test strip is positioned on the lug boss for detection, the detection plate or the test strip can be positioned in a proper light source detection area of the biological sample analyzer, and the detection results of the detection plate and the test strip are accurately read.

The sensing plate 200, in the embodiment shown in fig. 5, includes a base plate 210 and a cover plate 220. The test strip for detection is attached to the base plate 210, and the cover plate 220 covers the base plate 210 and the test strip, thereby forming the detection plate 200. The bottom plate 210 of the detection plate is provided with a concave hole 211 corresponding to the boss 111 on the back surface, and the concave hole is a limiting structure on the detection plate. In an optimized design, the concave holes 211 on the detection plate are equal in size and position and correspond to the bosses 11 on the object stage. After the detection plate 200 is positioned on the stage 100, the concave hole 211 is engaged with the boss 111 on the stage.

The number of the bosses 111 is not limited, as long as the bosses can be matched with the concave holes of the detection plate, so that the detection plate can be placed at the correct detection position of the objective table. The number of the bosses 111 may be one or more. Specifically, the number of the bosses 111 is 1 to 5; in one specific embodiment, there are 3 bosses 111. The number of detection plate recesses 211 may be the same as or different from the number of bosses 111 on the stage. The number of the concave holes 211 is the same as that of the bosses 111, for example, when the number of the bosses 111 is three, the number of the concave holes 211 is also three. The number of the concave holes 211 is different from the number of the convex blocks 111, for example, when the number of the convex blocks 111 is three, the number of the concave holes 211 is four, wherein three concave holes correspond to the convex blocks, and the rest one concave hole can be used for other purposes or is idle when being matched with the objective table.

The bosses on the object stage can be uniformly distributed and arranged. In another preferred embodiment, the uneven arrangement of the bosses 111 is used to identify and define the orientation of the inspection board 200 on the stage 100, so as to ensure that the orientation of the inspection board 200 on the stage 100 is not wrong. The inaccurate or undetectable detection result caused by the reversal of the direction of the detection board 200 or the deviation of the detection board from the light source detection area of the biological sample analyzer is avoided. In the case where the bosses 111 are not uniformly arranged on the stage 100, specific ways include, but are not limited to: the bosses 111 are not arranged on the same straight line; alternatively, the pitches between the bosses 111 are different. For example, when there are two bosses 111, the central connecting line of the two bosses is not parallel to the horizontal central axis or the vertical central axis of the detection plate; for another example, when the number of the convex strips 111 is three or more, the distance between two adjacent convex strips 111 is different; or three or more bosses 111 are not provided in a straight line.

The arrangement of the concave holes 211 on the back surface of the detection plate base plate 210 is the same as the arrangement of the bosses 111 on the object stage 100. For example, when the bosses 111 are arranged in a straight line and have different pitches, the concave holes 211 are arranged in a straight line and have different pitches, and the pitches of the concave holes 211 are the same as the pitches of the bosses 111 in a one-to-one correspondence. When the projection 111 is located on the center line of the stage 100, the recess hole 211 is arranged on the center line of the base plate 210.

The recesses 211 may or may not penetrate the entire base plate 210 on the back of the base plate 210. When the boss on the objective table is assembled with the concave hole on the detection plate in a matching manner, the boss cannot influence the detection of the test paper strip in the detection plate.

In the embodiment shown in fig. 1-10, the area of the stage 100 in which the detector plate is stored is provided with a recess 110, the recess 110 of the stage being adapted to receive and retain the detector plate, and in some embodiments, a boss 111 is provided within the recess 110. The lug boss and the groove are combined to limit the detection plate. In addition, since the groove forms a large urine containing space, urine overflowing from the test strip 300 or the detection plate 200 can be contained. On the one hand, collect the urine in the recess and can not flow out the objective table and cause the pollution to the environment, on the other hand, because the recess bottom has certain distance with test paper strip or pick-up plate put on the boss, collect and can't contact test paper strip or pick-up plate in the urine that overflows of recess bottom to avoid different urine samples to pollute test paper strip or pick-up plate that are detecting. In a further optimized design, two side walls of the groove 110 are provided with raised strips 112 protruding from the side walls; the ribs 112 are positioned adjacent the ends of the grooves 110; the distance between the ribs 112 of the two side walls is equal to the width of the detection plate 200. The convex strips 112 on the two side walls are contacted and clamped with the side walls of the detection plate 200, so that the detection plate 200 is better fixed in the groove 110. One or more ribs 112 are provided on both sidewalls near both ends of the groove 110. The protrusions 112 respectively arranged on the two sidewalls of the groove 110 are symmetrical.

To facilitate access of the detector plate 200 to the stage 100, particularly from the recess, a depression 230, such as a symmetrically designed depression 230, is provided in the detector plate intermediate the two side walls of the base plate 210 and cover plate 220. When the detection plate is taken out from the groove, the space formed by the concave part can facilitate the fingers of an operator or the gripping clips of the mechanical arm to extend into the concave part to grip the detection plate.

In the embodiment shown in fig. 12-13, the position limiting structure of the detection plate on the stage is a concave hole 111', and the arrangement mode refer to the arrangement and the arrangement of the boss 111. Correspondingly, be equipped with on the back of pick-up plate 200 ' bottom plate with objective table shrinkage pool 111 ' complex pick-up plate arch 211 ', this pick-up plate arch 211 ' quantity and mode of arrangement all with objective table shrinkage pool 111 ' one-to-one, when pick-up plate 200 ' was located objective table 100 ', pick-up plate arch 211 ' one-to-one on the pick-up plate 200 ' inserted in the objective table shrinkage pool 111 ' on the objective table 100 ', made pick-up plate 200 ' by injecing on objective table 100 '.

The cross section of the boss or the concave hole of the limiting structure can be different in shape. For example, when there are 3 bosses, two of the bosses may be square and the third boss may be circular. Correspondingly, the concave holes on the detection plate matched with the detection plate are also respectively square and round.

The test strip 300 of the embodiment shown in fig. 8 includes a substrate 301 to which a test strip 302 is attached. The test paper may be urine joint test paper, lateral flow test paper, or the like.

The object stage is provided with a test strip positioning structure. For example, the positioning structure for positioning the test strip on the object stage is a slot or a convex pin. When the positioning structure is a convex nail, the convex nail is matched with the positioning structure, and the test strip is provided with a test strip hole. The test strip is clamped and positioned by the slot, or the test strip hole is matched with the convex pin on the objective table to position the test strip.

In the embodiment shown in fig. 1-10, the test strip positioning structure on the object stage 100 is a slot, and there are two slots, i.e. a first slot 120 and a second slot 130, corresponding to two ends of the test strip. The first slot 120 and the second slot 130 are respectively disposed at two ends of the groove 110, and position and support the test strip 300. In some embodiments, the first slot 120 is located at an end of the object stage 100 to facilitate insertion of the test strip 300 into the object stage 100 from the end of the object stage 100. When a liquid sample is added to the entire elongated test strip 300, the weight of the liquid will cause the middle of the test strip to sag, and when the sag prone middle is supported by the raised platform, it is ensured that the entire test strip is in nearly the same plane at the test site. Therefore, to ensure better support for the test strip 300, the center of the boss 111 is aligned with the center of the first slot 120 and the center of the second slot 130. That is, when the test strip 300 is located on the object stage 100, the two ends of the test strip 300 are respectively located in the first slot 120 and the second slot 130, and the boss 111 is located right below the test strip 300. The detection board 200 is placed in the area of the groove 110, the two ends of the test strip are placed in the clamping

grooves

120 and 130, and the thickness of the detection board 200 is larger than that of the test strip 300, so that in an optimal design, the depth of the groove 110 is larger than that of the first clamping groove 120 and the second clamping groove 130, and therefore after the test strip and the detection board are placed on the objective table, the detection result areas on the test strip and the detection board can be located at the same height and in a proper light source area. In a more specific embodiment, in order to ensure that the test strips are located at the same horizontal height, the height of the boss 111 in the groove 110 is the same as the height of the first slot 120 and the second slot 130 higher than the groove 110; or, the depth of the groove 110 is the same as that of the clamping

grooves

120 and 130, so that the test strip 300 is conveniently manufactured and integrally formed, meanwhile, the first clamping groove 120 and the second clamping groove 130 are both provided with the protruding blocks 122 and 132, and the heights of the protruding blocks 122 and 132 are the same as that of the bosses 111 in the groove, so that the test strip 300 in the clamping grooves and the groove is ensured to be in a horizontal state. The widths of the first clamping groove 120 and the second clamping groove 130 are the same as the width of the test strip 300, so that the clamping grooves can better clamp and position the test strip. Alternatively, two ends of the first card slot 120 are provided with openings 121; the width of the opening 121 is the same as the width of the test strip 300. That is, the side wall of the test strip 300 is engaged with the opening 121 of the first card slot, so that the first card slot 120 is fixed to one end of the test strip 300. Meanwhile, one end of the second card slot 130 is opened 131; symmetrical protrusions 133 are arranged at the opening 131. And, two side walls of the end of the second slot 130 are provided with symmetrical protrusions 133. The distance between the protrusions 133 and the sidewall protrusions 133 at the second slot opening 131 is the same as the width of the test strip 300. The other end of the test strip is fixed in the second slot 130 by the contact of the protrusion 133 at the opening and the protrusion 133 on the side wall with the side wall of the test strip 300.

In the embodiment of fig. 12-13, the strip alignment structure on the same surface of the object holder 100 'as the cavity is a male pin 314', and the male pin 314 'is aligned with the object holder cavity 111'. Meanwhile, a test strip hole 301 'is formed in the test strip 300'. When the test strip 300 ' is positioned on the object stage 100 ', the test strip hole 301 ' is sleeved on the convex pin 314 ', so that the test strip 300 ' is positioned. Of course, the test strip positioning structure may also further include a first slot 120 and a second slot 130, the protruding pins 314 ' are located in the first slot 120 and the second slot 130, and the test strip 300 ' is positioned by the first slot 120 and the second slot 130 cooperating with the protruding pins 314 '. Of course, the test strip positioning structure may also be the combination of the

slots

120, 130 and the protruding pins 314 ', so that the test strip 300' is fixed more firmly.

In the embodiment of fig. 14, the position-limiting structure on the stage 100 ″ is a boss 111, which corresponds to the position-limiting structure recess 211 of the detecting plate 200. The test strip positioning structure on the object stage 100 "is the convex pin 314 ', and the corresponding positioning structure of the test strip 300 ' is the test strip hole 301 '.

The detection plate and the test strip can be called a detection device, and the detection plate limiting structure and the test strip positioning structure can be called a detection device fixing structure.

A biological sample analyzer for biological sample analysis includes a stage and a detection unit. The object stage 100 is used in a biological sample analyzer, and in particular, the object stage 100 is used to be placed in a detection unit 10 of the biological sample analyzer, bring a detection plate 200 or a test strip 300 into the detection unit 10, and realize a detection analysis function of the biological sample analyzer by reading and analyzing information of the detection plate 200 or the test strip 300 by the detection unit 10, as shown in fig. 8 to 14.

Specifically, as shown in fig. 1 to 14, the inspection unit 10 includes a stage, a stage conveyance stage, a movement mechanism, and an optical inspection mechanism. More specifically, the inspection unit 10 includes an

object stage

100 or 100' or 100 ″, a carrying platform including a carrying plate 400, a motion mechanism including a motor 600 and a gear 700, and an optical inspection mechanism including a light source (e.g., a hexagon head 900) and an inspection photo PCB 800. The hexagonal head is an optical path detection channel, 6 LED lamps are distributed in a circle around the hexagonal head, a PD receiving channel is arranged in the middle of the hexagonal head, and the hexagonal head is assembled with a detection photoelectric PCB and then installed on the gantry support. The motor 600 is connected with the gear 700, the gear 700 is in gear engagement with the bearing plate 400, meanwhile, the gear 700, the hexagonal head 900 and the detection photoelectric PCB 800 are connected to the gantry bracket 500, the motor 600 drives the gear 700 to rotate, the gear 700 drives the bearing plate 400 to linearly reciprocate on the gantry bracket 500 through gear engagement, and finally, the objective table 100 on the bearing plate 400 is driven to linearly enter and exit in the gantry bracket 500; therefore, the object stage 100 enters the gantry support 500, and the information on the detection plate 200 or the test strip 300 on the object stage 100 is read by the cooperation of the hexagonal head 900 and the detection photoelectric PCB 800; and, the object stage 100 is separated from the gantry 500, the detection plate 200 or the test strip 300 on the object stage 100 can be replaced, and the object stage 100 can be taken down for cleaning.

The object stage 100 is placed on the loading board 400, and as shown in the examples of fig. 8 to 11, the object stage 100 is detachably fixed on the loading board 400. In one embodiment, as shown in fig. 11, the supporting board 400 is detachably assembled with the object stage 100 by the magnetic attraction of the magnet. Specifically, two ends of the back of the object stage are provided with magnetic holes, namely a first magnetic hole 102 and a second magnetic hole 102'; magnetic holes, namely a first magnetic hole 401 and a second magnetic hole 402', are arranged at two ends of the bearing plate. The magnetic block 101 is inserted into the first magnetic hole 102, and the magnetic block 101 'is inserted into the second magnetic hole 102', and similarly, a magnetic block (not shown) is also inserted into the magnetic hole 402. In addition, the two magnetic blocks 101 and 101 'in the first magnetic hole 102 and the second magnetic hole 102' on the object stage have opposite magnetism facing the carrier plate, for example, the side of the magnetic block 101 in the first magnetic hole 102 facing the carrier plate is an S pole, and the side of the magnetic block 101 'in the second magnetic hole 102' facing the carrier plate is an N pole. And the magnetism of a magnetic block is pressed into the magnetic holes 402 of the bearing plate 400 and attracted with the magnetic surfaces of the magnetic blocks on the back surface of the objective table, namely, the magnetic block is pressed into the first magnetic hole 401 of the bearing plate corresponding to the first magnetic hole 102 of the objective table, one surface of the magnetic block facing the objective table is an N pole, the magnetic block is pressed into the second magnetic hole 402 'of the bearing plate corresponding to the second magnetic hole 102' of the objective table, and the magnetic block on one surface of the magnetic block facing the objective table is an S pole. According to the principle that like poles repel and opposite poles attract, the object stage can only be placed 102 to 402 on the bearing plate, and 102 'to 402' is placed, so that the magnetic blocks in the magnetic holes are mutually attracted. If 102 is mistakenly assigned to 402 ', 102' is mistakenly assigned to 402, the magnetic blocks in the magnetic holes repel each other, and the stage cannot be placed on the carrier plate. This ensures that the object stage cannot be incorrectly placed in the direction of the carrier plate.

The following description is made of the operation of the detection unit 10 of the embodiment of fig. 8-10 of the present invention.

The detection plate 200 of the present embodiment is exemplified by an HCG detection plate, and a test strip for detecting HCG is placed in the detection plate. The test strip 300 in this embodiment is a urine joint test strip for routine urine tests, such as a urine 11 joint test strip, a urine 12 joint test strip, and the like.

When an operator needs to detect the HCG in the urine sample, the objective table 100 is driven by the carrier plate 400 to move out of the gantry 500 under the control of the motor 600, the detection plate 200 is arranged in the groove 110 of the objective table, so that the concave hole 211 of the detection plate 200 and the boss 111 in the groove are correspondingly clamped one by one, and the urine sample is added into the sample adding hole of the detection plate. Then, after the loading board 400 is driven to drive the stage 100 to move under the gantry bracket 500, the hexagonal head 900 and the inspection photoelectric PCB 800 read and analyze the inspection information on the inspection board 200. After the detection is finished, the motor 600 drives the bearing plate 400 to drive the object stage 100 to move away from the gantry bracket 500, and the detection plate 200 is taken down. If the urine test paper is used for urine routine test, the object stage 100 is driven by the carrier plate 400 to move out of the gantry 500, and the test strip 300 is placed in the first slot 120 and the second slot 130 of the object stage, so that the test strip 300 is clamped in the first slot 120 and the second slot 130, and the middle of the test strip 300 is supported on the boss 111. Then, after the loading board 400 is driven to drive the object stage 100 to move under the gantry 500, the hexagonal head 900 and the test photoelectric PCB 800 read and analyze the test information on the test strip 300. After the detection is finished, the motor 600 drives the carrying plate 400 to drive the object stage 100 to move away from the gantry 500, and the test strip 300 is taken down. The objective table can be used for testing a test strip of a urine union and can also be used for testing an HCG plate. During the conversion process of the urine-associated test paper and the detection plate, the object stage does not need to be moved.

When all the detections are completed, the motor 600 drives the object stage 100 to move to the lower part of the gantry 500 for storage. When the object stage 100 needs to be cleaned, the bearing plate 400 and the object stage 100 move out of the gantry support 500 through the motor 600, the object stage 100 is taken down from the bearing plate 400 to be cleaned, and after cleaning is completed, the magnetic blocks 101 of the object stage and the magnetic blocks 401 of the bearing plate are correspondingly and fixedly connected together through magnetic attraction. The loading plate 400 and the loading platform 100 are moved into the gantry 500 by the motor 600.

Referring to fig. 1 to 40, the present invention further provides a transport device for an analyzer, which includes a movable carrier 400 and a stage 100. The carrier plate 400 is driven by a motor 600, a gear 700, etc., to reciprocate. The object stage 100 is placed on the loading plate 400 and can be separated from the loading plate 400. The side of the carrier 400 facing the stage 100 is an upper surface 410, and the opposite side is a lower surface 411. The side of the stage 100 facing the carrier 400 is a lower surface 151, and the opposite side is an upper surface 152 (fig. 19). The object stage 100 and the carrier plate 400 are respectively provided with

magnetic blocks

101 and 401 which are attracted magnetically. When the object stage 100 is placed in a predetermined area of the loading plate 400, the attraction force of the

magnetic blocks

101 and 401 automatically moves the object stage 100 to a designated position on the loading plate 400, thereby automatically positioning the object stage 100 with respect to the loading plate 400.

Referring now to FIGS. 15-18B, a first embodiment of the present invention is shown. The upper surface 410 of the carrier plate 400 is provided with recessed areas 412, 413 (shown in fig. 18A, 18B) in the areas close to the magnetic blocks 401, 401 'on the carrier plate, preferably at positions directly above where the two magnetic blocks 401, 401' are placed on the carrier plate, respectively. The contour of the recessed

regions

412, 413 is rectangular, square, circular or oval (only rectangular is shown in fig. 15 and 16, and other shapes are omitted), and the area of the recessed regions is larger than the outer contour of the magnetic block 101 in the object stage 100. Therefore, when the object stage 100 is placed on the carrier board 400, only the magnetic blocks 101 and 101 'in the object stage 100 need to be placed in the recessed

areas

412 and 413 of the upper surface 410 of the carrier board 400 (i.e. the pre-set areas), and the magnetic blocks 101 and 101' in the object stage 100 still have movable spaces in the recessed

areas

412 and 413 of the upper surface 410 of the carrier board 400, and do not need to be placed at the precise positioning positions. Since the outline of the recessed

areas

412, 413 is rectangular, square, circular or elliptical, and the area is larger than the outline of the magnetic blocks 101, 101 'in the object stage 100, the magnetic blocks 101, 101' on the object stage can be easily placed in the recessed

areas

412, 413 respectively, so that the operation is very convenient.

For more precise positioning, the transmission device of the detection analyzer of the present invention comprises two pairs of magnetic blocks 101, 101' (which are respectively arranged along the longitudinal direction of the object stage 100 and the loading plate 400, and for simplicity, only one pair of magnetic blocks will be described in detail below, and the other pair of magnetic blocks can be analogized). The two magnetic blocks 101 and 101' on the object stage 100 have opposite polarities in the same direction (for example, a vertical downward direction); the polarities of the two magnetic blocks 401 and 401' on the carrier plate 400 in the same direction (e.g., a vertical downward direction) are also opposite; therefore, the magnetic blocks on the object stage 100 and the corresponding magnetic blocks on the carrier plate 400 are arranged in opposite attraction (the arrangement is as follows).

Fig. 22 and 23 show two arrangements of the magnetic properties of the magnetic blocks on the object stage and carrier plate (this arrangement is applicable to all embodiments).

Referring now to FIGS. 19-21A, a second embodiment of the present invention is shown. The present embodiment differs from the first embodiment in that: the upper surface 410 of the carrier plate 400 and the lower surface 151 of the object stage 100 are respectively provided with a positioning structure which are matched with each other. In this embodiment, the alignment structure includes

vertical walls

416, 153 disposed on the upper surface 410 of the carrier plate and the lower surface 151 of the stage, respectively. When the stage 100 is placed in a predetermined area of the carrier plate, the

vertical walls

416 and 153 are abutted against each other by the attraction of the magnet 101, thereby achieving automatic positioning. Referring to fig. 21A, the axes of the magnetic blocks on the carrier plate 400 and the object stage 100 are not coincident, but are offset by a distance F between 0.5 mm and 3.0 mm, so that the

magnetic blocks

101 and 401 attract each other to urge the

vertical walls

416 and 153 to continuously abut against each other. So designed, it can be ensured that the object stage 100 is more precisely positioned on the loading plate 400.

Please refer to fig. 24 and 24A, which illustrate a third embodiment of the present invention. The present embodiment differs from the first embodiment in that: the recessed

areas

412 and 413 on the upper surface 410 of the carrier plate are replaced by two counter bores and 414' with the outline size corresponding to the outline size of the magnetic block 101 protruding from the lower surface 151 of the stage (as shown in fig. 24). In other words, the upper surface 410 of the carrier plate is provided with counter bores 414, 414 ' directly above the two magnetic blocks 401, 401 ' thereof, which are adapted to the shapes of the two magnetic blocks 101, 101 ' fixed on the stage (fig. 24A only illustrates the positional relationship of one pair of magnetic blocks 101 ', 401 ', and the positional relationship of the other pair of

magnetic blocks

101, 401 can be referred to). That is, the magnetic block 101 '(shown in phantom in FIG. 24A) on the stage at least partially protrudes above the lower surface 151 of the stage and can at least partially enter the counterbore 414', but the magnetic block 101 'on the stage is constrained from wobbling in the counterbore 414' in a direction parallel to the upper surface 410 of the stage as much as possible. The magnetic block 101 'on the object stage is a cylinder, the contour of the counter bore 414' on the bearing plate is also a cylinder, and the diameter of the counter bore 414 'is 0.1-1.0 mm larger than that of the magnetic block 101'. In order to guide the magnetic block 101 ' to enter the counter bore 414 ' more easily in a direction perpendicular to the upper surface 410 of the loading plate, in an aspect of the present embodiment, a conical chamfered guide hole 418 with a larger size is provided at the uppermost opening of the counter bore 414 '. In a preferred embodiment, the depth L of the chamfer is 0.3-2.0 mm, and the included angle a between the chamfer and the vertical axis of the counterbore is 30-60 degrees (preferably 40 degrees). It should be noted that in other aspects of this embodiment, the conical chamfered guide holes 418 may not be included at the uppermost openings of the counterbores 414, 414'.

Referring now to FIGS. 25-27A, a fourth embodiment of the present invention is shown. The present embodiment differs from the third embodiment in that: the upper surface 410 of the carrier plate is provided with a section of ramp channel 415 communicated with the counterbore 414, and the ramp channel 415 gradually descends from a position far away from the counterbore 414 to a position close to the counterbore 414 (the other side of the ramp channel 415' is similar in structure and is not described again). When the object table 100 is placed at a predetermined position on the carrier plate 400 (shown in fig. 26A), under the attraction of the magnetic blocks, the magnetic blocks on the object table 100 slide into the counter bores 414, 414 ' along the ramp channels 415, 415 ' substantially in the longitudinal direction of the carrier plate 400, respectively, and abut against the side walls of the counter bores 414, 414 ', thereby achieving precise positioning (shown in fig. 27A).

Referring to fig. 28-30, a fifth embodiment of the present invention is shown. This embodiment combines the structures of the first and third embodiments, i.e., a design that includes both a recessed region 412 and a counterbore 414, with the counterbore 414 being located within the recessed region 412. When the object table 100 is placed at a predetermined position on the loading board 400 (the magnetic block 101 is placed in the recessed area 412), the magnetic block on the object table 100 automatically slides into the counter bore 414 to abut against the side wall of the counter bore 414 under the attraction of the magnetic block, so as to achieve precise positioning (as shown in fig. 29 and 30).

Referring to fig. 28A and 28B, taking the fifth embodiment as an example, the upper surface 410 of the carrier plate is provided with drainage channels 419, 419 ' communicating with the counter bores 414, 414 ' respectively in the areas close to the magnetic blocks 401, 401 ' on the carrier plate, so as to drain the liquid (e.g. urine) leaked therein in time. Further, the drain 419 may further include drain holes 420. In one design, the drain holes 420 have a lower floor than the drain channels 419, but do not extend through to the lower surface 411 of the carrier plate. In another design, the drain holes 420 extend through to the lower surface 411 of the carrier plate. Alternatively, a water absorbent material may be placed at the bottom of the counter bores 414, 414' to absorb liquid that leaks there. Water-absorbing materials may also be placed in the drainage channels 419 and/or the drainage holes 420 to absorb liquid that leaks into them. These water-absorbing materials are selected from: absorbent filter paper, sponge, nitrocellulose membrane and glass fiber membrane.

Please refer to fig. 15, fig. 16, fig. 18A and fig. 20B. The design of the drain channel 419 and the drain hole 420 is applicable not only to the fifth embodiment but also to other embodiments. For example, in the first, second, sixth, and seventh embodiments, the upper surface 410 of the carrier plate is provided with drain holes 420 communicating with the recessed area, and the drain holes 420 may or may not penetrate through to the lower surface 411 of the carrier plate. In the third and fourth embodiments, the upper surface 410 of the carrier plate is provided with a drain channel 419 communicating with the counter bores 414, 414', and the drain channel 419 includes a drain hole 420, and the drain hole 420 may or may not penetrate through to the lower surface 411 of the carrier plate.

Referring now to FIGS. 31-35, a sixth embodiment of the present invention is shown. The present embodiment differs from the previous embodiments in that: the positioning structure is different. In this embodiment, the positioning structure comprises a protrusion 154 and a groove 417 which are respectively disposed on the upper surface 410 of the carrier plate and the lower surface 151 of the stage and are matched with each other, the protrusion 154 falls into the groove 417, and the suction force of the magnetic block makes the sidewalls of the protrusion 154 and the groove 417 abut against each other, thereby realizing automatic positioning. In this embodiment, the orthographic projection of the protrusions 154 and the recesses 417 on the carrier plate 400 and the object table 100 on the upper surface 410 of the carrier plate or the lower surface 151 of the object table has a wedge-shaped outer contour. When the stage 100 is placed at a predetermined position on the loading plate 400 (the protrusion 154 is placed in the groove 417), under the attraction of the magnetic blocks, the protrusion 154 slides in the groove 417 along the longitudinal direction (X direction in fig. 33) of the loading plate 400, and the sidewalls of the protrusion 154 and the groove 417 abut against each other, thereby achieving precise positioning (see fig. 34 and 35). Although the protrusion 154 is shown to be designed on the object stage 100 and the groove 417 is shown to be designed on the carrier plate 400, the protrusion 154 may be designed on the carrier plate 400 and the groove 417 may be designed on the object stage 100.

Please refer to fig. 36-40, which illustrate a seventh embodiment of the present invention. The present embodiment differs from the sixth embodiment in that: the cross-sectional profile of the protrusions 154 'and the recesses 417' of the carrier plate and the object stage is a wedge or an inverted trapezoid with a wide top and a narrow bottom. When the object table 100 is placed at a predetermined position on the loading plate 400, the protrusion 154 'slides into the groove 417' in a direction substantially perpendicular to the upper surface 410 of the loading plate under the attraction of the magnetic blocks, so as to guide the object table 100 to automatically reach a precise positioning position on the loading plate 400. Although the protrusion 154 'is shown to be designed on the object stage 100 and the groove 417' is shown to be designed on the carrier plate 400, the protrusion 154 'may be designed on the carrier plate 400 and the groove 417' may be designed on the object stage 100.

The above description is only a specific embodiment of the present invention and does not therefore limit the scope of the invention as claimed. All the equivalent structures or equivalent processes performed by using the contents of the specification and the drawings of the invention, or the direct or indirect application thereof to other related technical fields, are included in the protection scope of the invention.

Claims

1. A conveyer on detection analysis appearance which characterized in that: comprises a movable bearing plate and an object stage which is positioned on the bearing plate and can be separated from the bearing plate; the object stage and the bearing plate each include an upper surface and a lower surface, the lower surface of the object stage and the upper surface of the bearing plate facing each other; the upper surface of the objective table is provided with a structure for fixing a detection element, magnetic blocks are respectively arranged on the objective table and the bearing plate, and the magnetic blocks are arranged in a magnetic attraction manner; when the object stage is placed in a preset area on the bearing plate, the magnetic blocks which are magnetically attracted on the object stage and the bearing plate are close to each other, so that the object stage automatically moves to a specified position on the bearing plate.

2. The transport device on a test analyzer according to claim 1, wherein: the magnetic carrier comprises two pairs of magnetic blocks which are spaced at a proper distance from each other, the two magnetic blocks on the object stage are opposite in polarity in the same direction, the two magnetic blocks on the bearing plate are opposite in polarity in the same direction, and the magnetic blocks on the object stage and the corresponding magnetic blocks on the bearing plate are arranged in an opposite attraction manner.

3. The transport device on a test analyzer according to claim 2, wherein: a concave area is arranged on the upper surface of the bearing plate in an area close to the magnetic blocks on the bearing plate; when the magnetic block on the object stage enters the concave area, the magnetic blocks on the object stage and the bearing plate attract each other, so that the object stage is automatically positioned relative to the bearing plate.

4. The transfer device on a detection analyzer according to claim 1, 2 or 3, wherein: at least part of the magnetic block on the object stage protrudes out of the lower surface of the object stage, the bearing plate is provided with counter bores with the outline shape and the size matched with those of the magnetic block on the object stage on the upper surface of the bearing plate, at least part of the magnetic block mounted on the object stage enters the counter bores on the bearing plate and abuts against the hole walls of the counter bores, and therefore automatic positioning is achieved.

5. The transport device on a test analyzer according to claim 4, wherein: the opening at the uppermost end of the counter bore is provided with a conical chamfer angle guide hole with larger size, the depth of the chamfer angle is 0.3-2.0 mm, and the included angle between the chamfer angle and the vertical axis of the counter bore is between 30 and 60 degrees.

6. The transport device on a test analyzer according to claim 4, wherein: the upper surface of the bearing plate is provided with a section of slope channel communicated with the counter bore, and the slope channel gradually descends from a position far away from the counter bore to a position close to the counter bore.

7. The transfer device on a detection analyzer according to claim 1, 2 or 3, wherein: the upper surface of the bearing plate and the lower surface of the objective table are respectively provided with a positioning structure which is matched with each other.

8. The transport device on a test analyzer as set forth in claim 7, wherein: the positioning structure comprises protrusions respectively arranged on the upper surface of the bearing plate and the lower surface of the object stage, and the protrusions are abutted against each other by the suction force of the magnetic block, so that automatic positioning is realized.

9. The transport device on a test analyzer as set forth in claim 7, wherein: the locating structure comprises a protrusion and a groove which are arranged on the upper surface of the bearing plate and the lower surface of the object stage and matched with each other, the protrusion falls into the groove, the suction force of the magnetic block enables the side walls of the protrusion and the groove to abut against each other, and therefore automatic locating is achieved.

10. The transport device on a test analyzer of claim 9, wherein: the outer contour of the projection and the groove on the upper surface of the bearing plate or the lower surface of the object stage are wedge-shaped, and the projection slides along the longitudinal direction of the bearing plate in the groove and abuts against the side wall of the projection and the groove.

11. The transport device on a test analyzer of claim 9, wherein: the profile of the cross section of the bearing plate or the object stage of the bulge and the groove on the bearing plate and the object stage is in a wedge shape or an inverted trapezoid shape with a wide upper part and a narrow lower part, the bulge slides into the groove in the direction approximately vertical to the upper surface of the bearing plate, and the side walls of the bulge and the groove are mutually abutted.

12. The transfer device on a detection analyzer according to claim 1 or 2, wherein: the upper surface of the bearing plate is provided with a liquid drainage channel in the area close to the magnetic block on the bearing plate.

13. The transport device on a test analyzer according to claim 3, wherein: the upper surface of the bearing plate is provided with a liquid discharge hole communicated with the depressed area, and the liquid discharge hole penetrates through the lower surface of the bearing plate.

14. The transport device on a test analyzer according to claim 4, wherein: the upper surface of the bearing plate is provided with a liquid drainage channel communicated with the counter bore, and the liquid drainage channel comprises a liquid drainage hole penetrating through the lower surface of the bearing plate.

15. The transport device on a test analyzer of claim 14, wherein: the drainage channel is internally provided with water-absorbing materials which are selected from the following materials: absorbent filter paper, sponge, nitrocellulose membrane and glass fiber membrane.