CN217879236U - Result collection assembly and sample detection device - Google Patents

Abstract

The application discloses a result acquisition assembly and a sample detection device, wherein the result acquisition assembly comprises a bearing mechanism, an acquisition mechanism and an adjusting mechanism; the bearing mechanism is used for bearing the reagent card of the sample application sample; the collecting mechanism and the bearing mechanism are correspondingly arranged; the adjusting mechanism is connected with the bearing mechanism and is used for adjusting the angle between the bearing mechanism and the gravity direction to be a first preset angle or a second preset angle; at a first preset angle, the acquisition mechanism is used for acquiring the result of the reagent card to obtain a detection result; and at a second preset angle, the reagent card is separated from the bearing mechanism. The utility model provides a result acquisition subassembly can carry out the result to the reagent card and gather and unload the reagent card from bearing mechanism through the angle of adjustment bearing mechanism, can realize the automatic uninstallation of reagent card, need not additionally to set up the uninstallation subassembly, and the simple structure of result acquisition subassembly is favorable to reducing the volume of result acquisition subassembly.

Description

Result collection assembly and sample detection device

Technical Field

The application relates to the technical field of respiratory infectious diseases, in particular to a result acquisition assembly and a sample detection device.

Background

The existing sample detection devices are used for antigen-antibody detection of samples, wherein the antigen-antibody detection methods include a variety of detection techniques, such as precipitation reaction, enzyme-linked immunoassay, radioimmunoassay, fluorescence immunoassay, luminescence immunoassay, and the like.

When the existing sample detection device detects a sample to be detected, the result acquisition assembly needs to set an independent unloading assembly after the result acquisition assembly acquires the result of the reagent card, and the reagent card is acquired by unloading in a pushing mode, so that the structure is complex, and the volume of the sample detection device is large.

SUMMERY OF THE UTILITY MODEL

The application provides a result acquisition assembly and a sample detection device to solve the problem that the existing result acquisition assembly cannot automatically unload a reagent card.

The application provides a result acquisition assembly, which comprises a bearing mechanism, an acquisition mechanism and an adjusting mechanism; the bearing mechanism is used for bearing the reagent card with the sample; the acquisition mechanism and the bearing mechanism are correspondingly arranged; the adjusting mechanism is connected with the bearing mechanism and is used for adjusting the angle between the bearing mechanism and the gravity direction to be a first preset angle or a second preset angle; at the first preset angle, the acquisition mechanism is used for acquiring the result of the reagent card to obtain a detection result; and at the second preset angle, the reagent card is separated from the bearing mechanism.

The adjusting mechanism comprises a rotating motor and a driving circuit, the driving circuit is connected with the rotating motor and used for controlling the rotating motor to rotate, and the rotating motor drives the bearing mechanism to rotate to the first preset angle or the second preset angle.

Wherein the first preset angle is between 60 and 90 degrees; the second preset angle is between 0 and 45 degrees.

The collecting mechanism comprises an image collecting part and a light source, the image collecting part and the light source are arranged corresponding to the bearing mechanism, the image collecting part is used for collecting images of the reagent card on the bearing mechanism, and the light source is used for supplementing light for the image collecting part.

The collecting mechanism further comprises a shell, the bearing mechanism, the image collecting piece and the light source are arranged in the shell, and the shell is used for shielding light.

The application also provides a sample detection device, which comprises a sample introduction assembly, a detection processing assembly and the result acquisition assembly; the sample feeding assembly is used for receiving a sample bearing piece, and at least a sample is stored in the sample bearing piece; the detection processing component is used for moving the sample carrier to a sample adding position so as to add the sample to the reagent card; the result acquisition assembly is used for acquiring the result of the reagent card added with the sample.

Wherein, the sample detection device further comprises a storage component, and the storage component is used for storing the reagent card added with the sample so as to enable the sample to react with the reagent of the reagent card.

The storage assembly comprises a reagent card storage mechanism and a positioning mechanism, the reagent card storage mechanism is provided with a plurality of layers of storage cavities, the storage cavities are used for storing the reagent cards added with the samples, and the reagent cards of the storage cavities are arranged in a sheet shape; the positioning mechanism is arranged on one side of the reagent card storage mechanism and used for moving the positions of the storage cavities on each layer.

Wherein, the storage component further comprises a temperature control mechanism which is arranged on the reagent card storage mechanism and used for keeping the storage cavity at a constant storage temperature.

The result acquisition assembly further comprises a conveying mechanism, the conveying mechanism and the acquisition mechanism are correspondingly arranged, the conveying mechanism is used for conveying the acquisition mechanism along the extending direction of the bearing mechanism so as to move the acquisition mechanism into the reagent card storage mechanism, and the acquisition mechanism acquires the result of the reagent card after reaction.

The application provides a result acquisition assembly and a sample detection device, wherein the result acquisition assembly comprises a bearing mechanism, an acquisition mechanism and an adjusting mechanism; the bearing mechanism is used for bearing the reagent card with the sample; the collecting mechanism and the bearing mechanism are correspondingly arranged; the adjusting mechanism is connected with the bearing mechanism and is used for adjusting the angle between the bearing mechanism and the gravity direction to be a first preset angle or a second preset angle; at a first preset angle, the acquisition mechanism is used for acquiring the result of the reagent card to obtain a detection result; and at a second preset angle, the reagent card is separated from the bearing mechanism. The utility model provides a result acquisition subassembly can carry out the result to the reagent card and gather and unload the reagent card from bearing mechanism through the angle of adjustment bearing mechanism, can realize the automatic uninstallation of reagent card, need not additionally to set up the uninstallation subassembly, and the simple structure of result acquisition subassembly is favorable to reducing the volume of result acquisition subassembly.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present application, the drawings required to be used in the description of the embodiments are briefly introduced below, and it is obvious that the drawings in the description below are only some embodiments of the present application, and it is obvious for those skilled in the art to obtain other drawings without creative efforts. Wherein:

FIG. 1 is a schematic structural diagram of an embodiment of a result acquisition assembly provided herein;

FIG. 2 is a schematic view of the carriage mechanism of FIG. 1 at a first predetermined angle;

FIG. 3 is a schematic view of the carriage mechanism of FIG. 1 at a second predetermined angle;

FIG. 4 is a block diagram of one embodiment of a sample testing device provided herein;

fig. 5 is a schematic structural diagram of the memory module of fig. 4.

Detailed Description

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are only a part of the embodiments of the present application, and not all of the embodiments. All other embodiments, which can be obtained by a person skilled in the art without making any inventive step based on the embodiments in the present application, are within the scope of protection of the present application.

It should be noted that if directional indications (such as upper, lower, left, right, front, rear, 8230; \8230;) are referred to in the embodiments of the present application, the directional indications are only used for explaining the relative positional relationship between the components in a specific posture (as shown in the attached drawings), the motion situation, etc., and if the specific posture is changed, the directional indications are correspondingly changed.

In addition, if there is a description relating to "first", "second", etc. in the embodiments of the present application, the description of "first", "second", etc. is for descriptive purposes only and is not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one of the feature. In addition, technical solutions between various embodiments may be combined with each other, but must be realized by a person skilled in the art, and when the technical solutions are contradictory or cannot be realized, such a combination should not be considered to exist, and is not within the protection scope of the present application.

The application first provides a result collection assembly, which is applied to a sample detection device and is used for collecting results of a reagent card sent into the sample detection device. Specifically, the sample detection device is used for detecting antigens of respiratory infectious diseases, wherein the respiratory infectious diseases refer to infectious diseases caused by invasion of pathogens from respiratory tract infections such as nasal cavities, throats, tracheas and bronchi of human bodies. By measuring the corresponding antigen, the degree of reaction between the antigen and the corresponding reagent is known, so that whether the measured person has the corresponding antigen or not is obtained. It should be understood that the sample testing device is only used for the determination of the type of antigen and does not involve the diagnosis and treatment of the corresponding disease, not the use for diagnostic purposes.

Referring to fig. 1-3, fig. 1 is a schematic structural view of an embodiment of a result collecting assembly provided in the present application, fig. 2 is a schematic structural view of a carrying mechanism in fig. 1 at a first preset angle, and fig. 3 is a schematic structural view of the carrying mechanism in fig. 1 at a second preset angle. As shown in fig. 1-3, the result acquisition assembly 400 of the present embodiment includes a carrier mechanism 410, an acquisition mechanism 420, and an adjustment mechanism 430.

The carrying mechanism 410 is used for carrying the reagent card 411 with the sample. Specifically, the reagent card 411 includes a sample hole for dropping a sample. In the process of detecting a sample by the sample detection apparatus, the sample detection apparatus needs to add the sample into the sample adding hole of the reagent card 411 so that the sample reacts with the solution in the reagent card 411, and the reagent card 411 displays a corresponding detection result according to the degree of reaction between the sample and the reagent. The result collecting assembly 400 is used for collecting the detection result of the reagent card 411 to which the sample has been added.

The collecting mechanism 420 is arranged corresponding to the bearing mechanism 410; for example, the collection mechanism 420 may be disposed above or in front of the carrier mechanism 410. In alternative embodiments, the carrier mechanism 410 may be provided with a plurality of collecting positions, so that the collecting mechanism 420 can simultaneously collect results of a plurality of sample-added reagent cards 411, thereby improving the collecting efficiency of the result collecting assembly 400.

The adjusting mechanism 430 is connected to the supporting mechanism 410, and is configured to adjust an angle between the supporting mechanism 410 and the gravity direction to be a first preset angle or a second preset angle; at a first preset angle, the collecting mechanism 420 is used for collecting the result of the reagent card 411 to obtain a detection result; at a second predetermined angle, the reagent card 411 is disengaged from the carrying mechanism 410.

Specifically, the carrier mechanism 410 includes a carrier plate 412 for placing the reagent cards 411, the carrier plate 412 has a plurality of reagent card channels, and the reagent cards 411 to which the samples have been added are moved into the reagent card channels; when the angle between the bearing mechanism 410 and the gravity direction is a first preset angle, the bearing plate 412 is relatively horizontal, the reagent card 411 is in the reagent card channel, and the collecting mechanism 420 collects the result of the reagent card 411 and obtains the detection result; after collection is completed, the angle between the bearing mechanism 410 and the gravity direction is a second preset angle, the bearing plate 412 is inclined, the reagent card 411 slides down from the reagent card channel under the action of gravity, and the reagent card 411 is separated from the bearing mechanism 410, so that automatic unloading of the reagent card 411 is realized, card pushing unloading through other mechanisms or manual card taking unloading are not needed, and convenience and efficiency of unloading of the reagent card 411 are provided.

In this embodiment, the collecting mechanism 420 of the result collecting assembly 400 is disposed corresponding to the carrying mechanism 410; the adjusting mechanism 430 is connected to the supporting mechanism 410, and is configured to adjust an angle between the supporting mechanism 410 and the gravity direction to be a first preset angle or a second preset angle; at a first preset angle, the collecting mechanism 420 is used for collecting the result of the reagent card 411 to obtain a detection result; at a second predetermined angle, the reagent card 411 is disengaged from the carrier mechanism 410. The result collecting assembly 400 of the embodiment can collect the result of the reagent card 411 and automatically unload the reagent card 411 by adjusting the angle of the bearing mechanism 410, and the unloading assembly does not need to be additionally arranged, so that the structure of the result collecting assembly 400 is simple, and the volume of the result collecting assembly 400 is favorably reduced. Moreover, the carrying mechanism 410 is provided with a plurality of collecting positions, so that the result collection can be simultaneously carried out on a plurality of reagent cards 411, and the collection efficiency of the result collection assembly 400 is improved.

Alternatively, the adjusting mechanism 430 includes a rotating motor 431 and a driving circuit, the bearing mechanism 410 includes a rotating shaft 413, the bearing plate 412 is disposed on the rotating shaft 413 and fixed to the rotating shaft 413, and the rotating motor 431 is connected to the rotating shaft 413 to drive the rotating shaft 413 to rotate. The connection between the rotating motor 431 and the rotating shaft 413 includes, but is not limited to, a transmission belt.

The result collecting assembly 400 further comprises a detecting mechanism for detecting whether the carrying mechanism 410 has the reagent card 411 placed thereon. The drive circuit is connected to the rotating motor 431, and the drive circuit is configured to control the rotating motor 431 to rotate. When the detection mechanism detects that the reagent card 411 is placed on the bearing mechanism 410, the driving circuit sends a first driving signal to the rotating motor 431, and the rotating motor 431 drives the bearing mechanism 410 to rotate to a first preset angle; after the collection mechanism 420 finishes collecting the result, the driving circuit sends a second driving signal to the rotating motor 431, and the rotating motor 431 drives the carrying mechanism 410 to rotate to a second preset angle, so that the collected reagent card 411 is separated from the carrying plate 412.

In this embodiment, a driving circuit is connected to the rotating motor 431, the driving circuit is used for controlling the rotating motor 431 to rotate, and the rotating motor 431 drives the bearing mechanism 410 to rotate to the first preset angle or the second preset angle. By the method of the embodiment, the collection position and the unloading position of the reagent card 411 can be combined, and the result collection assembly 400 unloads the reagent card 411 after collecting the result of the reagent card 411, so that the efficiency of the result collection assembly 400 is improved.

In some possible embodiments, the first preset angle is set at any angle between 60 ° and 90 °, optionally, the first preset angle between the carrying mechanism 410 with respect to the gravity direction may be 60 °, 65 °, 70 °, 75 °, 80 °, 85 ° or 90 °; the second preset angle is any angle between 0 ° and 45 °, and optionally the second preset angle between the support means 410 and the direction of gravity may be 0 °, 5 °, 10 °, 15 °, 20 °, 25 °, 30 °, 35 °, 40 ° or 45 °.

When the angle between the supporting mechanism 410 and the gravity direction is a first predetermined angle, the supporting force provided by the carrier plate 412 for the reagent card 411 and the friction force between the reagent card 411 and the carrier plate 412 can overcome the gravity of the reagent card 411, so that the reagent card 411 is held in the carrier plate 412, and the collection mechanism 420 collects the result of the reagent card on the carrier plate 412. When the angle between the supporting mechanism 410 and the gravity direction is a second predetermined angle, the gravity of the reagent card 411 overcomes the friction force between the reagent card 411 and the supporting plate 412, and the reagent card 411 slides relative to the supporting plate 412 and is separated from the supporting plate 412. The angles of the first and second preset angles may be calculated by the gravity of the reagent card 411, the friction coefficient of the carrier plate 412, and other factors.

Optionally, the capturing mechanism 420 comprises an image capturing member 421 and a light source 422. The image capturing member 421 is used for capturing the image information of the reagent card 411, and the result capturing component 400 obtains the detection result according to the image information of the reagent card 411.

The image acquisition part 421 and the light source 422 are both arranged corresponding to the carrying mechanism 410, the image acquisition part 421 is used for acquiring images of the reagent card 411 on the carrying mechanism 410, and the image acquisition part 421 includes but is not limited to a camera; the light source 422 is used for supplementing light to the image capturing element 421, and the light source 422 may be disposed on the capturing position of the supporting mechanism 410.

In one embodiment, the image capturing part 421 obtains the image information of the reagent card 411 on the carrier plate 412, and outputs the image information of the reagent card 411 as the detection result; in another embodiment, the image capturing member 421 obtains the image information of the reagent card 411 on the carrier plate 412, and the capturing mechanism 420 obtains the result information of the reagent card 411 on the carrier plate 412 according to the image information, and uses the result information as the detection data, where the result information may include the result information of normal or abnormal detection.

In this embodiment, the collecting mechanism 420 includes an image collecting member 421 and a light source 422, the image collecting member 421 and the light source 422 are both disposed corresponding to the carrying mechanism 410, the image collecting member 421 is configured to collect an image of the reagent card 411 on the carrying mechanism 410, and the light source 422 is configured to supplement light to the image collecting member 421. The collecting mechanism 420 of this embodiment collects images of the reagent card 411 to obtain a detection result, and the method is simple and easy to implement.

Optionally, the collecting mechanism 420 further comprises a housing 423, the carrying mechanism 410, the image collector 421 and the light source 422 are disposed in the housing 423, and the housing 423 is used for blocking light.

Specifically, the housing 423 may be an outer shell of the shading result collecting assembly 400, a shading chamber is formed in the housing 423, the bearing mechanism 410, the image collecting piece 421 and the light source 422 are located in the shading chamber, the image collecting process of the collecting mechanism 420 is performed in the shading chamber, so as to ensure that the light of the image collecting process is good, and the light of the light source 422 does not affect other components of the sample detecting device.

Referring to fig. 4, fig. 4 is a block diagram of an embodiment of a sample detection device provided in the present application. As shown in fig. 4, the present application also proposes a sample detection device 10, where the sample detection device 10 includes: a sample introduction assembly 100, a detection processing assembly 200 and a result acquisition assembly 400 as described in any of the above embodiments.

The sample feeding assembly 100 is used for receiving a sample tube and a reagent card 411, and a sample of a person to be measured is stored in the sample tube. The sample testing device 10 performs sample testing by matching the sample of the sample tube with the reagent card 411.

The detection processing assembly 200 moves the sample tube and the reagent card 411 to the loading position to add the sample of the sample tube to the reagent card 411. After the detection processing assembly 200 adds the sample of the sample tube to the reagent card 411, the reagent card 411 to which the sample is added is moved to the collecting position, and the result collecting assembly 400 collects the result of the reagent card 411 to which the sample is added, so as to obtain the detection result of the sample.

Optionally, the sample testing device 10 further comprises a storage component 300, the storage component 300 is disposed at one side of the result collecting component 400, and is used for storing a reagent card added with a sample, so that the sample reacts with a reagent of the reagent card 411.

Before the result collecting component 400 collects the result of the reacted reagent card 411, the sample detecting device 10 may also move the reagent card 411 to which the sample has been added to the storage component 300 to store for a preset time, so that the sample completely reacts with the reagent of the reagent card 411, and the detection accuracy of the sample detecting device 10 is improved.

Optionally, the sample testing device 10 further comprises a transport assembly for moving the reagent card 411 from the test processing assembly 200 to the storage assembly 300, and for moving the reagent card 411 from the storage assembly 300 to the result acquisition assembly 400.

Referring to fig. 5, fig. 5 is a schematic structural diagram of the memory device in fig. 4. As shown in fig. 5, the storage assembly 300 includes a reagent card storage mechanism 310 and a positioning mechanism 320, the reagent card storage mechanism 310 being configured to store a reagent card 411 for a predetermined time.

The reagent card storage mechanism 310 is provided with a plurality of storage cavities in the height direction, each storage cavity is provided with a plurality of storage positions 311, each storage position 311 is used for storing a reagent card 411 which is added with a sample, the reagent card 411 of each storage position 311 is arranged in a sheet shape, and the size of each storage position 311 is slightly larger than that of the reagent card 411; the positioning mechanism 320 is disposed on one side of the reagent card storage mechanism 310 for moving the position of the multi-layered storage chamber. Specifically, the positioning mechanism 320 is connected with each layer of storage cavity, and moves the storage cavity up and down through structures such as a motor and a moving track, so as to move each layer of storage cavity to a preset position.

As the sample-loaded reagent card 411 is moved to the storage assembly 300, the positioning mechanism 320 moves the empty single-layer storage chamber to the bottom-most layer, so that the transport assembly moves the sample-loaded reagent card 411 to the corresponding storage location 311 of the reagent card storage mechanism 310; the positioning mechanism 320 moves up and down the storage cavity of the reagent card 411 stored with the added sample, and the reagent card 411 with the added sample is stored in the storage position 311 for a preset time so as to enable the sample to react with the reagent of the reagent card 411; the positioning mechanism 320 moves the storage cavity storing the reacted reagent card 411 to the bottom layer, so that the transport component moves the reacted reagent card 411 from the storage position 311 to the collection position for result collection.

In this embodiment, the storage assembly 300 includes a reagent card storage mechanism 310 and a positioning mechanism 320, the reagent card storage mechanism 310 is provided with a plurality of storage chambers for storing the reagent cards 411 to which the samples are added, the reagent cards 411 of each storage chamber are arranged in a sheet shape, and the positioning mechanism 320 is provided at one side of the reagent card storage mechanism 310 for moving the positions of the plurality of storage chambers. The reagent card storage mechanism 310 is configured as a multi-layer storage chamber mechanism, the reagent cards 411 of each layer of storage chamber are arranged in a sheet shape, the storage capacity of the storage assembly 300 is large, and the detection throughput of the sample detection device 10 is improved.

Optionally, the storage assembly 300 further comprises a temperature control mechanism (not shown) disposed in the reagent card storage mechanism 310 for maintaining a constant storage temperature in the storage chamber. The temperature control mechanism can provide a stable incubation temperature for the reagent card 411 stored in the storage assembly 300, so that the reagent card 411 can react rapidly at the incubation temperature, the storage time of the storage assembly 300 can be reduced, and the detection speed of the sample detection device 10 can be improved.

Optionally, the result collecting assembly 400 further includes a conveying mechanism (not shown), the conveying mechanism is disposed corresponding to the collecting mechanism 420, the conveying mechanism is configured to convey the collecting mechanism 420 along the extending direction of the carrying mechanism 410 so as to move the collecting mechanism 420 into the reagent card storing mechanism 310, and the collecting mechanism 420 collects the result of the reacted reagent card 411.

Specifically, the conveying mechanism may include a conveying track disposed between the result collecting assembly 400 and the reagent card storing mechanism 310, the conveying mechanism is connected to a driving circuit, the driving circuit controls the conveying mechanism to convey the collecting mechanism 420, the collecting mechanism 420 moves into the reagent card storing mechanism 310 along the extending direction of the carrying mechanism 410, and the driving circuit controls the collecting mechanism 420 to directly collect the result of the reacted reagent card 411 in the reagent card storing mechanism 310; after the collection is completed, the transport assembly moves the reagent card 411 onto the carrier plate 412, and the carrier plate 412 rotates to a second predetermined angle to unload the reagent card 411.

Optionally, when the sample feeding assembly 100 receives the sample tube and the reagent card 411, the sample feeding assembly 100 synchronously obtains the personal information of the person to be measured; after the result acquisition component 400 acquires the result of the reagent card 411, the detection result is uploaded to the server, and the server binds the detection result with the personal information of the person to be detected, so that the user can query the personal information of the person to be detected through the server to obtain the detection data.

By providing the result collecting assembly 400, the result collecting assembly 400 can automatically collect the result of the reagent card 411 and unload the reagent card 411, so that the sample detecting device 10 can automatically detect the sample of the sample tube, and the unloading assembly is not required to be additionally arranged to unload the reagent card, thereby being beneficial to reducing the volume and the manufacturing cost of the sample detecting device 10.

The above description is only an embodiment of the present application, and is not intended to limit the scope of the present application, and all equivalent structures or equivalent processes performed by the present application and the contents of the attached drawings, which are directly or indirectly applied to other related technical fields, are also included in the scope of the present application.

Claims (10)

1. A result acquisition assembly for sample testing, comprising:

the bearing mechanism is used for bearing the reagent card with the sample;

the collecting mechanism is arranged corresponding to the bearing mechanism;

the adjusting mechanism is connected with the bearing mechanism and is used for adjusting the angle between the bearing mechanism and the gravity direction to be a first preset angle or a second preset angle;

the acquisition mechanism is used for acquiring results of the reagent card at the first preset angle to obtain a detection result; and at the second preset angle, the reagent card is separated from the bearing mechanism.

2. The result collection assembly of claim 1, wherein the adjustment mechanism comprises a rotating motor and a driving circuit, the driving circuit is connected to the rotating motor, the driving circuit is configured to control the rotating motor to rotate, and the rotating motor drives the bearing mechanism to rotate to the first preset angle or the second preset angle.

3. The result acquisition assembly of claim 2, wherein the first preset angle is between 60 ° -90 °; the second preset angle is between 0 and 45 degrees.

4. The result acquisition assembly of claim 1, wherein the acquisition mechanism comprises an image acquisition element and a light source, the image acquisition element and the light source are both arranged corresponding to the carrier mechanism, the image acquisition element is configured to acquire an image of a reagent card on the carrier mechanism, and the light source is configured to supplement light to the image acquisition element.

5. The result acquisition assembly of claim 4, wherein the acquisition mechanism further comprises a housing, the carrier mechanism, the image acquisition element, and the light source being disposed within the housing, the housing being configured to block light.

6. A sample testing device, comprising:

the sample introduction assembly is used for receiving a sample tube and a reagent card, and the sample tube at least stores a sample;

a detection processing component for moving the sample tube and the reagent card to a sample addition position to add a sample of the sample tube to the reagent card;

the result acquisition assembly of any one of claims 1-5, configured to perform result acquisition on a reagent card to which the sample has been applied.

7. The sample testing device of claim 6, further comprising a storage component for storing a reagent card to which said sample has been applied, such that said sample reacts with a reagent of said reagent card.

8. The sample testing device of claim 7, wherein the storage assembly comprises a reagent card storage mechanism and a positioning mechanism, the reagent card storage mechanism is provided with a plurality of layers of storage chambers for storing the reagent cards added with the samples, and the reagent cards of each storage chamber are arranged in a sheet shape; the positioning mechanism is arranged on one side of the reagent card storage mechanism and used for moving the positions of the storage cavities on each layer.

9. The sample testing device of claim 8, wherein the storage assembly further comprises a temperature control mechanism disposed in the reagent card storage mechanism for maintaining a constant storage temperature in the storage chamber.

10. The sample testing device of claim 8, wherein the result collecting assembly further comprises a conveying mechanism, the conveying mechanism is disposed corresponding to the collecting mechanism, the conveying mechanism is configured to convey the collecting mechanism along an extending direction of the carrying mechanism to move the collecting mechanism into the reagent card storage mechanism, and the collecting mechanism collects the result of the reacted reagent card.

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