CN218766957U - Trim card for molecular diagnostic device - Google Patents

Abstract

The application provides a balance card for molecular diagnosis equipment, and relates to the technical field of molecular detection. The balancing card for the molecular diagnostic equipment comprises a body and a reference membrane, wherein the body is provided with a detection cavity, and the detection cavity is used for being installed on a detection seat of the molecular diagnostic equipment; a reference membrane is disposed within the detection chamber, the reference membrane having a composition that includes a fluorescence indicator to excite fluorescence upon illumination by a light generator of the molecular diagnostic device. The multipurpose of balance card has been realized to this application and has been used, when carrying out centrifugal treatment to the detection card, the balance card can carry out the balance, reduces the noise that the detection card distributes the uneven production among the centrifugal treatment process, and fluorescence indicator can realize the detection to the light path of molecular diagnosis equipment in addition, reduces the influence of trouble to detection card testing result.

Description

Trim card for molecular diagnostic device

The application is a divisional application of the Chinese utility model patent application with the application number of 202220402035.8, entitled "molecular diagnosis device and detection card delivery seat for molecular diagnosis device" applied on 25.02/2022.

Technical Field

The application relates to the technical field of molecular detection, in particular to a balancing card for molecular diagnosis equipment.

Background

For the molecular diagnostic device, it utilizes molecular diagnostic techniques. The molecular diagnosis technology is a diagnosis technology for clinical detection by using nucleic acid or protein as a biomarker, and provides information and decision basis for prediction, diagnosis, prevention, treatment and prognosis of diseases.

When the molecular diagnostic equipment detects the detection card, the light path for detecting the detection card is complex, the light path fails under some special conditions, and when a user cannot quickly know that the failure occurs, the detection result is inaccurate.

SUMMERY OF THE UTILITY MODEL

One aspect of the present application provides a trim card for a molecular diagnostic apparatus, comprising:

the body is provided with a detection cavity, and the detection cavity is used for being installed on a detection seat of the molecular diagnosis equipment; and

a reference membrane disposed within the detection chamber, a composition of the reference membrane including a fluorescence indicator to excite fluorescence upon illumination by a light generator of the molecular diagnostic device.

In another aspect, the present application also provides a trim card for a molecular diagnostic apparatus, comprising:

the body is provided with a detection cavity, and the detection cavity is used for being installed on a detection seat of the molecular diagnosis equipment; and

and the fluorescent indicator is arranged in the detection cavity and is used for exciting fluorescence under the irradiation of a light generator of the molecular diagnostic equipment.

The multipurpose of balance card has been realized in this application and has been used, when carrying out centrifugal treatment to the detection card, the balance card can carry out the balance, reduces the uneven noise that produces of detection card distribution in the centrifugal treatment process, and fluorescence indicator can realize the detection to the light path of molecular diagnostic equipment in addition, reduces the influence of trouble to detecting card testing result.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present application, the drawings needed to be used in the embodiments will be briefly described below. It is obvious that the drawings in the following description are only some embodiments of the application, and that for a person skilled in the art, other drawings can be derived from them without inventive effort.

FIG. 1 is a schematic perspective view of a molecular diagnostic apparatus according to an embodiment of the present application;

FIG. 2 is an exploded view of the molecular diagnostic apparatus of FIG. 1;

FIG. 3 is a schematic perspective view of the frame of FIG. 1;

FIG. 4 is an exploded view of the drive assembly of FIG. 3;

FIG. 5 is a view showing the connection relationship between the frame body and the lead screw assembly in FIG. 3;

FIGS. 6 and 7 are perspective views of the circuit mounting board of FIG. 3 from different perspectives, respectively;

FIG. 8 is a schematic view of a portion of the frame of FIG. 3;

FIG. 9 is a schematic structural view of a second limit switch of FIG. 8;

FIG. 10 is an exploded view of the pressing plate of FIG. 2 of the present application;

fig. 11 and 12 are schematic structural views of the first housing in fig. 10 from different viewing angles, respectively;

FIG. 13 is a schematic view of the compression member of FIG. 10 of the present application;

fig. 14 and 15 are schematic views of the first heating member of fig. 10 from different perspectives, respectively;

FIG. 16 is a schematic view of the first circuit board of FIG. 10;

FIG. 17 is a schematic view of the locking member of FIG. 10;

FIG. 18 is a cross-sectional view of the locking member of FIG. 17 taken along line XVII-XVII;

fig. 19 and 20 are schematic structural views of the second housing in fig. 10 from different viewing angles, respectively;

FIG. 21 is a schematic perspective view of the pressing plate in FIG. 10;

fig. 22 is a schematic structural view of the first slide rail in fig. 21;

fig. 23 is a schematic view of a connection structure of the frame 10 and the pressing plate;

FIG. 24 is a schematic structural view of the shipping assembly of FIG. 2;

FIG. 25 is a schematic view of the carriage of FIG. 24;

FIG. 26 is a schematic illustration of the structure of the pallet of FIG. 24;

FIGS. 27 and 28 are schematic views of the slide holder of FIG. 26 from different perspectives;

FIG. 29 is a schematic view of the third driving member 64 and the retainer of FIG. 26;

FIG. 30 is a schematic view of the connection between the third driving member 64 and the clamping and pressing members in FIG. 2;

FIGS. 31 and 32 are schematic views of the connection structure of the pressing plate and the carrying assembly in FIG. 2;

FIG. 33 is an exploded view of the test socket of the test card of FIG. 2;

FIG. 34 is an exploded view of the support base of FIG. 33;

FIGS. 35 and 36 are schematic structural views of the support seat body in FIG. 34 from different viewing angles, respectively;

FIG. 37 is a schematic view of the construction of the photodetecting member in FIG. 34;

FIG. 38 is a cross-sectional view of the test socket of FIG. 37 taken along line XXXVII-XXXVII;

FIG. 39 is a schematic structural view of the sample addition chamber assembly of FIG. 34;

FIG. 40 is a cross-sectional view of the sample addition chamber assembly of FIG. 39 taken along line XXXIX-XXXIX;

FIG. 41 is a schematic diagram of the light generator of FIG. 33;

FIG. 42 is a cross-sectional view of the first light generator of FIG. 41;

fig. 43 is an exploded view of the light receiving module of fig. 33;

fig. 44 is a structural diagram of the light receiving element of fig. 33;

FIG. 45 is a schematic structural view of the neutron-path component of FIG. 43;

FIG. 46 is a cross-sectional view of the neutron optical path assembly of FIG. 45;

FIG. 47 is a schematic view of the first gasket of FIG. 43;

FIG. 48 is a schematic view of the second gasket of FIG. 43;

FIG. 49 is a schematic view showing the structure of the second grip sheet of FIG. 43;

FIG. 50 is a schematic diagram of a test card according to an embodiment of the present application;

FIG. 51 is a cross-sectional view of the test card of FIG. 50 taken along line L-L;

FIG. 52 is a perspective view of the test card of FIG. 50;

fig. 53 is a schematic view illustrating a usage process of the test card of fig. 50.

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. It should be apparent that the described embodiments are only some of the embodiments of the present application, and not all of the embodiments. All other embodiments obtained by a person of ordinary skill in the art based on the embodiments in the present application without making any creative effort belong to the protection scope of the present application.

Reference herein to "an embodiment" means that a particular feature, structure, or characteristic described in connection with the embodiment can be included in at least one embodiment of the application. The appearances of the phrase in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments mutually exclusive of other embodiments. It is explicitly and implicitly understood by one skilled in the art that the embodiments described herein can be combined with other embodiments.

The embodiment of the application provides a trim card for molecular diagnosis equipment, which comprises:

the body is provided with a detection cavity, and the detection cavity is used for being installed on a detection seat of the molecular diagnosis equipment; and

a reference membrane disposed within the detection chamber, a composition of the reference membrane including a fluorescence indicator to excite fluorescence upon illumination by a light generator of the molecular diagnostic device.

In one embodiment, the body is provided with an installation part to be installed on the sample adding cavity installation seat of the molecular diagnosis device, and the installation part and the detection cavity are positioned on the same side of the body.

In an embodiment, the body is provided with a clamping portion to be clamped with a clamping holder of the molecular diagnostic device, the clamping portion and the mounting portion are located on the same side of the body, and the clamping portion is located between the mounting portion and the detection cavity.

In one embodiment, the body is provided with a limiting part at two side edges of a straight line where the mounting part and the detection cavity are located and at one side close to the detection cavity, and the limiting part and the detection cavity are located at the same side of the body.

In one embodiment, the body is provided with a waste liquid cavity at one side far away from the mounting part and at a position back to the limiting part.

In an embodiment, the balance card further comprises an isolation layer, the isolation layer is covered on one side of the body far away from the installation part, the isolation layer is covered on the opening of the waste liquid cavity, and the isolation layer is covered on the opening of the detection cavity.

In an embodiment, the body is provided with an insertion part, the insertion part and the mounting part are located on the same side of the body, and the insertion part is located between the mounting part and the detection cavity.

In an embodiment, the body is provided with a butt groove to be matched with the sample adding cavity mounting seat, the butt groove and the mounting part are positioned on the same side of the body, and the butt groove is positioned between the mounting part and the detection cavity.

In an embodiment, the leveling card further comprises a cover body, the body is provided with a sample adding cavity at a position back to the installation part, the cover body covers the opening of the sample adding cavity, and the cover body is located on one side of the body far away from the installation part.

The embodiment of the application provides a trim card for molecular diagnosis equipment, which comprises:

the body is provided with a detection cavity, and the detection cavity is used for being installed on a detection seat of the molecular diagnosis equipment; and

and the fluorescent indicator is arranged in the detection cavity and is used for exciting fluorescence under the irradiation of a light generator of the molecular diagnostic equipment.

Next, a molecular diagnostic apparatus using molecular diagnostic techniques will be described. The molecular diagnosis technology refers to a diagnosis technology for clinical detection by using nucleic acid or protein as a biomarker, and provides information and decision basis for prediction, diagnosis, prevention, treatment and outcome of diseases. Particularly in the face of various sudden infectious diseases, the most cost-effective measure is rapid and accurate molecular diagnosis.

Monolithic structure-molecular diagnostic device 100

Referring to fig. 1 and 2, fig. 1 is a schematic perspective view of a molecular diagnostic apparatus 100 according to an embodiment of the present disclosure, and fig. 2 is an exploded view of the molecular diagnostic apparatus 100 in fig. 1. The molecular diagnostic apparatus 100 may include a housing 10, a test card delivery block 20 mounted on the housing 10, a test card test block 30 mounted on the housing 10, and a control circuit board 40 mounted on the housing 10. The test card transport base 20 can be used for placing test cards. The test card transport block 20 is slidable on the frame 10 relative to the frame 10 so that the test card transport block 20 can carry a test card and onto the test card detection block 30. The test card socket 30 is used for generating exciting light to test the test card and form a test signal. The control circuit board 40 can be used to control the sliding of the test card feeding base 20 on the frame 10, and control the test card feeding base 30 to test the test card, and receive and process the test signal to form the diagnosis data.

It is understood that in some embodiments, the molecular diagnostic apparatus 100 may also include a housing. The housing may accommodate the rack 10, the test card feeding base 20, the test card detecting base 30, the control circuit board 40, etc. to protect the molecular diagnostic apparatus 100. The shell can also reduce the interference of external factors to the detection process of the detection card. In some embodiments, the housing may be provided with a separation door to allow the test card transport base 20 to slide out of the separation door when the separation door is opened, thereby facilitating placement of the test card on the test card transport base 20 and removal of the test card from the test card transport base 20. When the isolating door is closed, the effect of protecting the enclosure and reducing the interference of external factors can be realized.

In addition, in other embodiments, the isolation door may also be automatically opened or closed under the control of the control circuit board 40. For example, the isolating door is pushed by a hinge, a hydraulic oil cylinder, a hydraulic cylinder, a screw rod, a gear and other structures under the driving of a motor and other driving structures.

In addition, in some embodiments, the molecular diagnostic apparatus 100 may further include an output device such as a display, a printer, etc. electrically connectable to the control circuit board 40 to output the diagnostic data of the molecular diagnostic apparatus 100 through the output device. Of course, a memory for storing diagnostic data may also be provided in the molecular diagnostic apparatus 100.

Furthermore, in some embodiments, the molecular diagnostic apparatus 100 may further include an input device such as a display, a keyboard, a code scanning device 14 (shown in fig. 3) and the like electrically connected to the control circuit board 40, so as to input a control command to the molecular diagnostic apparatus 100, for example, the control circuit board 40, through the input device, thereby controlling the test card delivery base 20 and/or the test card detection base 30 by the molecular diagnostic apparatus 100 through the control circuit board 40.

Rack 10

Referring to fig. 3, fig. 3 is a schematic perspective view of the rack 10 in fig. 1. The frame 10 may include a frame body 11 and a first driving device 12 mounted on the frame body 11. The rack body 11 is used for mounting the test card delivery base 20, the test card test base 30, the control circuit board 40 and other structures. The first driving device 12 is electrically connected to the control circuit board 40 to receive control of the control circuit board 40. The first driving device 12 is used for being connected with the detection card conveying seat 20 so as to drive the detection card conveying seat 20 to slide relative to the rack main body 11 under the control of the control circuit board 40, and delivery of the detection card is realized.

It should be noted that the terms "first", "second", etc. are used herein for descriptive purposes only and are not to be construed as indicating or implying relative importance or to implicitly indicate the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of the described features.

The frame body 11 may be a frame structure as a whole. The inside of the frame body 11 can be used for installing the detection card conveying seat 20 and the detection card detection seat 30, and the detection card conveying seat 20 is located above the detection card detection seat 30. Certainly, in some embodiments, the mounting positions of the test card feeding seat 20 and the test card testing seat 30 on the rack main body 11 may be other positions, which are not described herein.

The housing body 11 may include a top plate 111, a leg 112 mounted on the top plate 111 and connected to the bottom of the top plate 111, and a reinforcing plate 113 provided at the middle and/or bottom of the leg 112. Wherein the legs 112 are used to support the top plate 111. The reinforcing plate 113 serves to reinforce the stability of the lower portion of the leg 112. In some embodiments, in the case where the molecular diagnostic apparatus 100 is provided with a housing, the housing may be fixed to an outer surface of the rack main body 11 to enhance the appearance of the molecular diagnostic apparatus 100. In some embodiments, the rack body 11 may be a part of a chassis.

In this document, the orientations of "up", "down", "front", "back", "left", "right", "top", "bottom", "upper", "lower" may be used for description. It will be understood that the terms "central," "longitudinal," "lateral," "length," "width," "thickness," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," "clockwise," "counterclockwise," "axial," "radial," "circumferential," and the like herein, when used in the context of the present application, are intended to refer to the orientation or positional relationship illustrated in the drawings, and are used merely for convenience and to simplify the description and do not indicate or imply that the device or element so referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore should not be considered as limiting the present application.

The top plate 111 may be made of a rigid material such as plastic, metal, etc. The top plate 111 may have a plate-like structure, or may have other shapes, which will not be described in detail. The middle portion of the top plate 111 may be opened with a strip-shaped hole 1111 to give way to the test card feeding base 20.

The strip-shaped hole 1111 can be matched with the detection card conveying seat 20, so that the detection card conveying seat 20 extends into the strip-shaped hole 1111, and the detection card conveying seat 20 can slide in the strip-shaped hole 1111. In some embodiments, the extending direction of the strip-shaped hole 1111 coincides with the sliding direction of the test card feeding base 20 with respect to the rack 10, for example, the rack body 11. In some embodiments, the strip hole 1111 may be omitted in the case that the top plate 111 does not need to be provided with the strip hole 1111 for abdicating the detection card feeding seat 20. Of course, in some embodiments, the top plate 111 may be provided with a strip-shaped hole 1111 for certain functions, such as saving material, reducing weight, etc., or may be provided with other shaped holes or grooves like the strip-shaped hole 1111.

The top plate 111 may be provided with a mounting hole 1112 for mounting the first driving device 12. In some embodiments, the mounting holes 1112 may be located in an extending direction of the bar holes 1111, so as to reasonably plan a mounting space on the rack 10, for example, the rack body 11, to reduce the volume of the molecular diagnostic apparatus 100, so that the molecular diagnostic apparatus 100 is compact. In some embodiments, the mounting hole 1112 may communicate with the strip hole 1111. In some embodiments, mounting hole 1112 may be omitted.

The top plate 111 may be provided with a connection part 1113 so that the top plate 111 is connected and fixed with the leg 112 through the connection part 1113, and the top plate 111 mounts the first driving device 12 through the connection part 1113. In some embodiments, the connection portion 1113 may be a through hole penetrating through the top plate 111, and the connection fixing of the top plate 111 and the leg 112 and/or the first driving device 12 may be achieved by a bolt, a screw, or other screwing structure, a plug structure, a snap structure, or other connection structure, and the connection portion 1113, such as the through hole. In one embodiment, a connection portion 1113, such as a through hole, can be disposed on the opposite sides of the position of the stripe hole 1111 and the mounting hole 1112, so that the top plate 111 can mount the first driving device 12 through the connection portion 1113. In some embodiments, the connection 1113 may also be other structures such as a plug structure, a bearing, a threaded structure, etc. In one embodiment, the connection portion 1113 may be omitted.

The legs 112 may be made of a rigid material such as plastic, metal, etc. The legs 112 may have a strip-like structure, but may have other shapes, which will not be described in detail. The legs 112 may be provided at one side of the top plate 111, for example, the bottom of the top plate 111, to support the top plate 111. The support legs 112 are used for mounting the test card transport base 20, so that the test card transport base 20 and the support legs 112 slide relatively to each other, thereby achieving the purpose of transporting the test card to the test card detection base 30 through the test card transport base 20.

The number of legs 112 may be 1 or more. In some embodiments, the number of legs 112 may also be one of 2, 3, 4, 5, 6, 8230; 8230.

In one embodiment, the number of legs 112 may be 4, respectively being a first leg 1121, a second leg 1122, a third leg 1123, and a fourth leg 1124.

It is understood that the designations of "first leg", "second leg", "third leg", "fourth leg", and "leg" may be interchanged in some embodiments. For example, in one embodiment, the "first leg" in other embodiments is referred to as the "second leg", and correspondingly, the "second leg" in other embodiments is referred to as the "first leg".

In one embodiment, the first leg 1121, the second leg 1122, the third leg 1123, and the fourth leg 1124 may be sequentially connected to the top plate 111 to form a quadrilateral, such as a rectangle. In one embodiment, first leg 1121 and second leg 1122 are located on the same side of slotted aperture 1111. The third leg 1123 and the fourth leg 1124 are on the same side of the slotted hole 1111. In an embodiment, the portions of the first leg 1121 and the fourth leg 1124 respectively connected to the top plate 111 are respectively located at two sides of the strip-shaped hole 1111 in the direction perpendicular to the extending direction. The portions of the second leg 1122 and the third leg 1123 that are connected and fixed to the top plate 111 are located on both sides in the direction perpendicular to the extending direction of the strip-shaped hole 1111. In one embodiment, second leg 1122 and third leg 1123 are disposed on a side of mounting aperture 1112 away from bar aperture 1111.

Each leg 112, such as the first leg 1121, can include a leg body 1125 and a first rail 1126 disposed on the leg body 1125. The top of the leg body 1125 may be fixed to the top plate 111 by a bolt, a screw, a connection structure such as a plug structure, a snap structure, and a connection portion 1113, such as a through hole. Of course, the top of the leg body 1125 may be fixed to the top plate 111 by welding, bonding, or the like.

The first guide rail 1126 is configured to mount the card transport 20 such that the card transport 20 slides on the first guide rail 1126 and slides in the extending direction of the first guide rail 1126.

In an embodiment, the extending direction of the first guiding rail 1126 is perpendicular to the extending direction of the strip-shaped hole 1111. In an embodiment, the extending direction of the first rail 1126 may be a vertical direction. It will be appreciated that where a particular configuration is provided, the first rail 1126 may extend at an acute angle to the vertical.

In an embodiment, the first rail 1126 of the first leg 1121 may be disposed on a side of the leg body 1125 of the first leg 1121 toward the fourth leg 1124. The first rail 1126 of the second leg 1122 is disposed on a side of the leg body 1125 of the second leg 1122 toward the third leg 1123. The first rail 1126 of the third leg 1123 is disposed on a side of the leg body 1125 of the third leg 1123 that faces the second leg 1122. The first rail 1126 of the fourth leg 1124 is disposed on a side of the leg body 1125 of the fourth leg 1124 facing the first leg 1121.

It will be appreciated that in some embodiments, the leg body 1125 and the first rail 1126 may be a unitary structure in one leg 112. In some embodiments, the first rail 1126 may not be provided in at least a portion of the leg 112. In some embodiments, the first guide rail 1126 may also be disposed at other locations in the rack body 11, such as on the top panel 111.

The reinforcing plate 113 may be made of a hard material such as plastic, metal, etc. The reinforcing plate 113 may be connected at one end to a lower portion of one leg 112 and at the other end to a lower portion of the other leg 112 to achieve relative stability between the two legs 112, thereby reinforcing the stability of the legs 112. The connection mode between the reinforcing plate 113 and one of the legs 112 may be screw connection, insertion connection, fastening, welding, bonding, etc., which is not described in detail. It is understood that, in order to achieve the stability of the legs 112, the reinforcing plate 113 is not limited to be connected to the lower portion of one leg 112, and one end of the reinforcing plate 113 may be connected and fixed to other portions such as the top or middle portion of the leg 112.

The number of the reinforcing plates 113 may be 1 or more. In some embodiments, the number of the stiffener plates 113 may also be one of 2, 3, 4, 5, 6, 8230 \ 8230;. In some embodiments, the stiffener plate 113 may also be omitted.

In one embodiment, the number of stiffeners 113 may be 4, which are the first stiffener 1131, the second stiffener 1132, the third stiffener 1133, and the fourth stiffener 1134.

It is understood that the names "first stiffener", "second stiffener", "third stiffener", "fourth stiffener", and "stiffener" may be interchanged in some embodiments. For example, in one embodiment, the "first reinforcing plate" in the other embodiments is referred to as a "second reinforcing plate", and accordingly, the "second reinforcing plate" in the other embodiments is referred to as a "first reinforcing plate".

The first reinforcing plate 1131 has one end connected and fixed to the lower portion of the first leg 1121, such as the leg body 1125, and the other end connected and fixed to the lower portion of the second leg 1122, such as the leg body 1125. The second reinforcing plate 1132 is fixedly connected to a lower portion of the second leg 1122, such as the leg body 1125 at one end and to a lower portion of the third leg 1123, such as the leg body 1125 at the other end. The third reinforcement panel 1133 is fixedly connected at one end to a lower portion of the third leg 1123, such as the leg body 1125, and at the other end to a lower portion of the fourth leg 1124, such as the leg body 1125. The fourth reinforcement panel 1134 is fixedly connected to the lower portion of the first leg 1121, e.g., the leg body 1125, at one end, and to the lower portion of the fourth leg 1124, e.g., the leg body 1125, at the other end.

In one embodiment, the stiffening plate 113, such as the first stiffening plate 1131 and the third stiffening plate 1133, may cooperate with the first drive device 12.

In one embodiment, a stiffener 113, such as the second stiffener 1132, may be coupled to the control circuit board 40.

In one embodiment, the connected stiffener plate 113 and leg 112 may be a unitary structure.

Referring to fig. 3 again, the first driving device 12 may include a driving element 121 installed at the frame body 11, for example, at the installation hole 1112, and a screw rod element 122 installed on the frame body 11 and connected to the driving element 121.

The driving assembly 121 may be indirectly connected to the lead screw assembly 122 through a transmission belt, or may be directly connected to the lead screw assembly 122 to transmit power through the lead screw assembly 122. The lead screw assembly 122 is connected to the inspection card feeding base 20. The screw assembly 122 can push the card-detecting transport base 20 to slide on the frame body 11, such as the first guide rail 1126, under the driving of the driving assembly 121, so as to achieve the effect of transporting the card-detecting transport base 20 for the card-detecting.

Referring to fig. 3 and 4 together, fig. 4 is an exploded view of the driving assembly 121 of fig. 3. The driving assembly 121 may include a mounting bracket 1211 mounted at the frame body 11, for example, at the mounting hole 1112, a first driving member 1212 mounted on the mounting bracket 1211, and a synchronizing assembly 1213 mounted on the mounting bracket 1211. The first driving member 1212 is electrically connected to the control circuit board 40 to move under the control of the control circuit board 40.

The synchronizing assembly 1213 is connected to the first driving member 1212 for transmission under the drive of the first driving member 1212. The synchronization assembly 1213 may be connected to the lead screw assembly 122 indirectly via a belt or directly to the lead screw assembly 122 for transmission by driving the lead screw assembly 122.

The mounting bracket 1211 can include a mounting plate 1214 for mounting the first driving member 1212 at one side and a striker plate 1215 for engaging the mounting plate 1214 at an opposite side of the mounting plate 1214. Wherein the mounting plate 1214 and the crimping plate 1215 are used for mounting the synchronization assembly 1213.

The mounting plate 1214 may be made of a rigid material such as plastic, metal, etc. The mounting plate 1214 may have a plate-like structure, or may have other shapes, which are not described in detail. The mounting plate 1214 may be disposed within the mounting hole 1112. In some embodiments, the mounting plate 1214 may also be positioned outside of the mounting holes 1112. In one embodiment, the mounting plate 1214 may be a unitary structure with the top plate 111. In one embodiment, mounting plate 1214 may be omitted and top plate 111 omits mounting holes 1112 in place of mounting plate 1214.

The pinch plate 1215 may include a pinch plate body 1215a disposed opposite the mounting plate 1214 and a spacer 1215b disposed between the pinch plate body 1215a and the mounting plate 1214. The latch plate body 1215a can be positioned on a side of the mounting plate 1214 that is distal from the first driver 1212. The spacers 1215b are used to control the gap between the pinch plate body 1215a and the mounting plate 1214.

The crimp plate body 1215a may be made of a rigid material such as plastic, metal, etc. The pressing plate body 1215a may have a plate-like structure, or may have other shapes, which will not be described herein. The holding plate body 1215a may be disposed outside the mounting hole 1112 and above the top plate 111.

In some embodiments, the mounting plate 1214 is positioned outside of the mounting holes 1112, such as above or below the top plate 111. The pinch plate body 1215a may be positioned within the mounting aperture 1112. In one embodiment, the mounting plate 1214 may be a unitary structure with the top plate 111. In one embodiment, the pinch plate body 1215a may be omitted and the mounting hole 1112 may be omitted from the top plate 111 in place of the pinch plate body 1215a.

The spacers 1215b are fixedly coupled to the clicker plate body 1215a and the mounting plate 1214, respectively, to form a space in which the synchronization element 1213 may be mounted at the gap between the clicker plate body 1215a and the mounting plate 1214.

In one embodiment, the spacers 1215b can be spacer plates. The spacers 1215b, such as the spacer plates, may be fixed to the mounting plate 1214 and the crimping plate body 1215a by screwing, plugging, snapping, bonding, welding, etc.

In one embodiment, the spacers 1215b can also be bolts, screws, etc.

In one embodiment, the spacer 1215b can be a unitary structure with the pinch plate body 1215a. In one embodiment, the spacers 1215b can also be a unitary structure with the mounting plate 1214. In one embodiment, the spacer 1215b is integral with the mounting plate 1214 and the pinch plate body 1215a.

The body 1215a of the pinch plate is positioned on the side of the top plate 111 away from the legs 112 when the mount 1211 is mounted on the top plate 111. The spacer 1215b is fixedly connected to the top plate 111 at the mounting hole 1112 by screwing, inserting, snapping, welding, bonding, or the like. Meanwhile, when the mounting plate 1214 is located in the mounting hole 1112, the spacer 1215b extends into the mounting hole 1112 and is fixedly connected with the mounting plate 1214 by means of screwing, inserting, snapping, welding, bonding and the like, so that the first driving member 1212 is located at the bottom of the top plate 111, and reasonable spatial arrangement of the molecular diagnostic apparatus 100 is realized. When the mounting plate 1214 and the holding-down plate 1215 are positioned on top of the top plate 111, the spacer 1215b is fixedly connected to the mounting plate 1214 by screwing, plugging, snapping, welding, bonding, etc. The mounting plate 1214 is fixedly connected to the top plate 111 by screwing, inserting, fastening, welding, bonding, or the like. When the mounting plate 1214 is located at the bottom of the top plate 111 and the holding-down plate 1215 is located at the top of the top plate 111, the spacer 1215b can be connected and fixed with the mounting plate 1214 through the mounting hole 1112 by screwing, inserting, snapping, welding, bonding, etc.

A first driver 1212 is mounted to the side of the mounting plate 1214 remote from the pinch plate body 1215a. The first driving element 1212 and the mounting plate 1214 may be fixed by screwing, inserting, fastening, welding, or adhering. In some embodiments, the first driving member 1212 may also be mounted to the mounting plate 1214 on a side thereof adjacent to the cliche plate body 1215a.

The first driving member 1212 may be a motor. The output shaft of the motor may extend through the mounting plate 1214 and into between the mounting plate 1214 and the cliche plate body 1215a. In one embodiment, the output shaft of the motor may also extend through the traffic board body 1215a, or alternatively, may be rotatably coupled to the traffic board body 1215a without extending through the traffic board body 1215a. In an embodiment, the first driving element 1212 may also be another power source capable of driving the synchronizing element 1213 to move, which is not described herein.

The synchronization assembly 1213 may comprise a first gear 1216 mounted on an output shaft of the first drive member 1212 and first and second sets of transmission gears 1217 and 1218, respectively, meshing with the first gear 1216.

Wherein the first gear 1216 rotates when the first drive member 1212 is turned on. The first transmission gear set 1217 and the second transmission gear set 1218 are respectively connected to the mounting frame 1211 in a rotatable manner. The first transmission gear set 1217 and the second transmission gear set 1218 can rotate synchronously when the first gear 1216 rotates, and one of them rotates clockwise and the other rotates counterclockwise.

The rotation axis of the first transmission gear set 1217 is arranged in parallel with the output axis of the first driving member 1212, e.g. an electric motor. The rotating shafts of the first transmission gear set 1217 are rotatably connected to the mounting plate 1214 and the holding plate body 1215a, respectively.

The first transmission gear set 1217 may include a second gear 1217a and a first rotation gear 1217b that are coaxially disposed. Wherein the second gear 1217a may be meshed with the first gear 1216. The first wheel 1217b may be connected to the lead screw assembly 122 via a belt or directly to the lead screw assembly 122 for transmission via the lead screw assembly 122.

The second set 1218 of drive gears has an axis of rotation arranged in parallel with an output shaft of a first drive member 1212, such as a motor. The rotating shaft of the second transmission gear set 1218 is respectively connected with the mounting plate 1214 and the pinch plate body 1215a in a rotating manner.

The second drive gear set 1218 may include a coaxially disposed third gear 1218a and a second pulley 1218b. Wherein the third gear 1218a can be meshed with the first gear 1216. The second wheel 1218b can be connected to the lead screw assembly 122 via a conveyor belt or directly connected to the lead screw assembly 122 for transmission via the lead screw assembly 122.

It is to be understood that the designations of "first gear", "second gear", "third gear", and "gear" may be interchanged in some embodiments. For example, in one embodiment, the "first gear" in the other embodiments is referred to as a "second gear", and correspondingly, the "second gear" in the other embodiments is referred to as a "first gear".

It is to be appreciated that the synchronization component 1213 is not limited to the above-mentioned embodiments and can be other types of synchronization components as well. In addition, when the synchronizing assembly 1213 comprises gears and transmission gear sets, other structures can be included, and the number of the gears and the structure and number of the transmission gear sets can be set according to actual situations.

Referring to fig. 5, fig. 5 is a connection relationship diagram of the rack body 11 and the lead screw assembly 122 in fig. 3. The lead screw assembly 122 may include two lead screws, such as a first lead screw 1221 and a second lead screw 1222. In some embodiments, the number of lead screws can also be one of 1, 3, 4, 5, 6, 8230 \8230;, 8230;.

In some embodiments, in order to achieve stable movement of the inspection card conveyance base 20, the number of lead screws may be at least 2.

Two lead screws, for example, a first lead screw 1221 and a second lead screw 1222 are respectively provided on both sides in a direction perpendicular to the extending direction of the strip hole 1111. The first lead screw 1221 can be connected to a first transmission gear set 1217, such as a first rotary wheel 1217b, via a transmission belt or directly, and rotation of the first lead screw 1221 can be achieved by rotation of the first transmission gear set 1217, such as the first rotary wheel 1217b. The second lead screw 1222 can be connected to a second transmission gear set 1218, such as a second rotating wheel 1218b, via a belt or directly, and rotation of the second lead screw 1222 can be achieved via rotation of the second transmission gear set 1218, such as the second rotating wheel 1218b.

Each lead screw, e.g., the second lead screw 1222, may include a bearing member 1223 mounted at the housing body 11, e.g., the connecting portion 1113, a lead screw body 1224 rotationally coupled to the bearing member 1223 and rotationally coupled to the housing body 11, e.g., the stiffener plate 113, and a third runner 1225 mounted at an end of the lead screw body 1224.

Wherein, the bearing member 1223 is sleeved outside the screw main body 1224 to be rotatably connected with the screw main body 1224. The lead screw body 1224 may be a rod-like structure with an external thread provided on a surface. The lead screw body 1224 may extend in a direction that is coincident with the direction of extension of the first rail 1126, although in some embodiments the lead screw body 1224 may not extend in the same direction as the first rail 1126. The lead screw body 1224 may be threadably connected to the test card transport base 20. The third reel 1225 and the second reel 1218b are located on the same side of the housing body 11, e.g., the top plate 111, e.g., the third reel 1225 and the second reel 1218b are located on top of the top plate 111.

In one embodiment, the axis of rotation of the third reel 1225 is parallel to the axis of rotation of the second reel 1218b. In one embodiment, the bearing member 1223 can be omitted and the screw body 1224 can be disposed in the connecting portion 1113, such as a through hole, and directly rotatably coupled to the top plate 111.

It will be appreciated that the designations of "first wheel", "second wheel", "third wheel", and "wheel" may be interchanged in some embodiments. For example, in one embodiment, the "first wheel" in other embodiments is referred to as the "second wheel", and correspondingly, the "second wheel" in other embodiments is referred to as the "first wheel".

In one embodiment, in the first lead screw 1221, the lead screw body 1224 is rotationally coupled to the stiffening plate 113, such as the first stiffening plate 1131. In the second spindle 1222, a spindle body 1224 is rotatably connected to the reinforcement plate 113, for example, a third reinforcement plate 1133. The third rotating wheel 1225 of the first lead screw 1221 may be connected to the first rotating wheel 1217b of the first transmission gear set 1217 by a transmission belt. The third rotating wheel 1225 of the second lead screw 1222 can be connected to the second rotating wheel 1218b of the second transmission gear set 1218 by a transmission belt.

It will be appreciated that the lead screw assembly 122 and the first guide rail 1126 are provided to enable sliding movement of the test card transport base 20 on the frame 10 and thus shipping of the test card. Therefore, in the case where the number of screws in the screw assembly 122 is sufficient to allow the test card transport base 20 to stably and normally slide on the rack 10, the first guide rail 1126 may not be provided on the molecular diagnostic apparatus 100.

Referring to fig. 3 again, the frame 10, for example, the frame body 11, is provided with a circuit mounting board 13 at an outer side thereof for mounting the control circuit board 40. The circuit mounting board 13 is disposed on the same side of the top plate 111 as the leg 112. The circuit mounting board 13 is disposed on the same side of the second leg 1122 and the third leg 1123.

Referring to fig. 3, fig. 6 and fig. 7 together, fig. 6 and fig. 7 are perspective views of the circuit mounting board 13 in fig. 3 from different perspectives, respectively. The circuit mounting board 13 may be made of a hard material such as plastic, metal, or the like. The circuit mounting board 13 may include a mounting board body 131. The mounting plate body 131 is generally plate-like in configuration and may be located on the same side of the second and third legs 1122, 1123. In some embodiments, the mounting plate body 131 may also be secured directly to the second and third legs 1122, 1123. The side of the mounting plate body 131 remote from the legs 112 is used for mounting the control circuit board 40. The mounting board body 131 may be formed with a through hole 1311 so that the circuit trace can be electrically connected to the control circuit board 40 through the through hole 1311 from the inside of the rack body 11. In one embodiment, the mounting plate main body 131 may also be fixedly connected to the reinforcing plate 113, such as the second reinforcing plate 1132. The side of the mounting plate body 131 away from the leg 112 is provided with a connecting post 1312 for mounting the control circuit board 40, and the control circuit board 40 is prevented from directly contacting the mounting plate body 131. The connecting post 1312 may be screwed, inserted, welded, etc. to mount the control circuit board 40. The mounting plate main body 131 can isolate the control circuit board 40 from the rack main body 11, and prevent the control circuit board 40 from being interfered by factors such as the temperature inside the rack main body 11. Of course, in some embodiments, the mounting plate body 131 may be omitted and the connection posts 1312 may be provided directly on the rack 10, for example, the rack body 11, without the need for the isolation control circuit board 40. In one embodiment, the mounting plate body 131 may be an integral structure with the housing body 11.

The mounting plate body 131 may be provided with a first shroud 132 near an edge of the leg 112, for example, the third leg 1123, and the first shroud 132 may be bent from the edge of the mounting plate body 131 toward the third leg 1123 to shield a gap between the mounting plate body 131 and the third leg 1123, thereby serving as a partition at the third leg 1123. In one embodiment, the first shroud 132 may be secured to the third leg 1123 by a threaded, snap, plug, welded, bonded, or the like connection. In some embodiments, the first shroud 132 may be omitted.

The mounting plate body 131 may be provided with a second collar 133 near an edge of the top plate 111, and the second collar 133 may be bent from the edge of the mounting plate body 131 toward the third leg 1123 side. The second shroud 133 may be fixedly attached to the top panel 111. In one embodiment, the second enclosure 133 can be fixed to the top plate 111 by screwing, clipping, inserting, welding, bonding, or the like. In some embodiments, the second shroud 133 may be provided with an opening 1331 in order to give way for components mounted on the top plate 111. In some embodiments, the second shroud 133 may be omitted.

The mounting plate body 131 may be provided with a third enclosing plate 134 near the edge of the leg 112, for example, the second leg 1122, and the third enclosing plate 134 may be bent from the edge of the mounting plate body 131 to the side of the second leg 1122, so as to shield the gap between the mounting plate body 131 and the second leg 1122, thereby playing a role of isolation at the second leg 1122. In one embodiment, the third surrounding plate 134 can be fixed to the second leg 1122 by screwing, clipping, inserting, welding, bonding, etc. In some embodiments, the third shroud 134 may be omitted.

It is understood that the designations of "first enclosure", "second enclosure", "third enclosure", and "enclosure" may be interchanged in some embodiments. For example, in one embodiment, the "first enclosure" in other embodiments is referred to as the "second enclosure", and correspondingly, the "second enclosure" in other embodiments is referred to as the "first enclosure".

Referring to fig. 3 again, the rack 10, such as the rack body 11, is provided with a code scanning device 14 electrically connected to the control circuit board 40. The code scanning device 14 can be used to scan images of information identifiers on the test card, such as two-dimensional codes, bar codes, etc., and transmit the images to the control circuit board 40. The control circuit board 40 identifies the image and obtains the relevant information of the detection card. The code scanning device 14 may be disposed on a path along which the test card conveyance base 20 slides with respect to the housing 10, so that when a test card is placed on the test card conveyance base 20, the information mark on the test card is image-scanned by the code scanning device 14.

In an embodiment, the code scanning device 14 may be disposed on the path of the card feeding base 20 sliding in the bar hole 1111. For example, the code scanning device 14 may be disposed on the stiffener 113, such as the fourth stiffener 1134. The stripe hole 1111 extends to a side away from the installation hole 1112, that is, the stripe hole 1111 extends to a side of the fourth stiffener 1134. In one embodiment, the strip-shaped hole 1111 extends to the side away from the mounting hole 1112 and can extend above the fourth reinforcing plate 1134.

In one embodiment, the code scanning device 14 is disposed on the stiffener 113, such as a fourth stiffener 1134. The card feeding base 20 slides in the extending direction of the bar hole 1111 and slides above the code scanning device 14. At this time, when the test card is placed on the test card delivery seat 20, the code scanning device 14 will immediately perform image scanning on the information identifier on the test card.

It is understood that the code scanning device 14 may be disposed at other locations of the housing 10, such as inside the housing 10. In addition, in some embodiments, when the molecular diagnostic apparatus 100 is provided with a housing, the isolation door in the above embodiments is disposed at the housing at the fourth reinforcing plate 1134 and is disposed opposite to the code scanning device 14, so that when the test card transport seat 20 slides to the isolation door relative to the rack 10, the test card is placed on the test card transport seat 20, and the code scanning device 14 automatically performs image scanning on the information identifier on the test card. In one embodiment, the code scanning device 14 may also be disposed on the housing.

Referring to fig. 5 again, the frame 10, such as the top plate 111, is provided with a first limit switch 15 electrically connected to the control circuit board 40. The first limit switch 15 is located below the top plate 111. The first limit switch 15 is located on the sliding stroke of the detection card conveying seat 20 relative to the rack 10, so that the first limit switch 15 is triggered when the detection card conveying seat 20 slides, the first limit switch 15 generates a control signal and transmits the control signal to the control circuit board 40, the control circuit board 40 controls the operation of the detection card conveying seat 20 according to the control signal, and the detection card conveying seat 20 stops operating, so that the detection card conveying seat 20 stays at a preset position, and the limitation on the detection card conveying seat 20 is realized.

In an embodiment, the first limit switch 15 is used to limit the position of the test card feeding base 20 when sliding along the extending direction of the strip-shaped hole 1111.

In one embodiment, the first limit switch 15 is located on the top plate 111 near the strip-shaped hole 1111. The first limit switch 15 may be specifically located at an end of the strip-shaped hole 1111 far from the mounting hole 1112. Of course, the first limit switch 15 may be disposed at other positions of the housing 10, and the first limit switch 15 may be disposed on the housing in the case where the molecular diagnostic apparatus 100 is provided with the housing.

In some embodiments, the first limit switch 15 may be an optocoupler limit switch, which may in particular be a slot optocoupler. The middle of spacing luminescent part and spacing light receiving part sets up the recess in the channel-shaped opto-coupler, when the position that detects card transport seat 20 was arranged in the recess, detect the card and carry seat 20 and block the light transmission between spacing luminescent part and the spacing light receiving part, the channel-shaped opto-coupler then produces control signal and transmits to control circuit board 40 to detect card transport seat 20 and stop the operation under control circuit board 40's control, and then make and detect card transport seat 20 and stop in preset position department.

Referring to fig. 8, fig. 8 is a schematic partial structure diagram of the rack 10 in fig. 3. The rack 10, for example, the rack body 11, may be provided with a second limit switch 16 electrically connected to the control circuit board 40 to limit the position of the test card feeding base 20. The second limit switch 16 may be located on the stroke of the transport block 20 sliding on the first guide rail 1126 to limit the position of the transport block 20 when sliding on the first guide rail 1126.

The second limit switch 16 is triggered when the card-conveying base 20 slides on the first guide rail 1126, generates a control signal and transmits the control signal to the control circuit board 40, so that the control circuit board 40 controls the operation of the card-conveying base 20 according to the control signal, and stops the operation of the card-conveying base 20, so that the card-conveying base 20 stays at a predetermined position, and the limit of the card-conveying base 20 is realized.

Referring to fig. 8 and 9 together, fig. 9 is a schematic structural diagram of the second limit switch 16 in fig. 8. The second limit switch 16 may include a mounting housing 161 mounted on the leg 112, e.g., the third leg 1123, and a first sub limit switch 162 and a second sub limit switch 163 disposed on the mounting housing 161. Wherein the first sub-limit switch 162 and the second sub-limit switch 163 are both located on the stroke of the transport block 20 sliding on the first guide rail 1126, such that the transport block 20 slides on the stroke between the first sub-limit switch 162 and the second sub-limit switch 163. The first sub limit switch 162 and the second sub limit switch 163 are electrically connected to the control circuit board 40.

It is understood that the names "first limit switch", "second limit switch", "sub-limit switch", "first sub-limit switch", "second sub-limit switch", and "limit switch" may be interchanged in some embodiments. For example, in one embodiment, the "first limit switch" in the other embodiments is referred to as a "second limit switch", and accordingly, the "second limit switch" in the other embodiments is referred to as a "first limit switch".

The mounting case 161 is made of a hard material such as plastic, metal, etc. The mounting case 161 is integrally formed in a case shape. The mounting housing 161 may be mounted on the rack body 11, for example, the third leg 1123. The mounting housing 161 may be fixed to the rack body 11, such as the third leg 1123, by screwing, clipping, inserting, welding, or bonding.

The mounting housing 161 may be located on a side of the third leg 1123 adjacent the circuit mounting board 13. Of course, the mounting housing 161 can be mounted at other positions of the rack 10, which will not be described in detail.

The first sub limit switch 162 and the second sub limit switch 163 may be disposed on the same side of the mounting case 161. The first sub limit switch 162 and the second sub limit switch 163 may be embodied as a side of the mounting case 161 away from the circuit mounting board 13.

The first sub-limit switch 162 may be triggered to generate a signal and transmit the signal to the control circuit board 40 when the detection card feeding base 20 slides to the detection card detection base 30 side, so that the control circuit board 40 controls the operation of the detection card feeding base 20 according to the control signal, and stops the operation of the detection card feeding base 20, so that the detection card feeding base 20 stays at a predetermined position, thereby realizing position limitation when the detection card feeding base 20 slides to the detection card detection base 30 side.

The second sub-limit switch 163 may be triggered to generate a signal and transmit the signal to the control circuit board 40 when the detection card feeding base 20 slides to a side away from the detection card feeding base 30 (i.e., slides to a side of the top plate 111), so that the control circuit board 40 controls the operation of the detection card feeding base 20 according to the control signal, and stops the operation of the detection card feeding base 20, so that the detection card feeding base 20 stays at a predetermined position, thereby realizing position limitation when the detection card feeding base 20 slides to the side of the top plate 111, and reducing mutual damage caused by the contact between the detection card feeding base 20 and the top plate 111.

In an embodiment, the first sub-limit switch 162 and the second sub-limit switch 163 may be both optical coupling limit switches, when the portion of the card feeding base 20 is disposed in the groove, the card feeding base 20 blocks the light transmission between the limiting light emitting portion and the limiting light receiving portion, and the groove optical coupling further generates a control signal and transmits the control signal to the control circuit board 40, so that the first driving device 12, such as the driving assembly 121, stops operating under the control of the control circuit board 40, and the card feeding base 20 stays at the predetermined position.

It is understood that the first sub-limit switch 162 and the second sub-limit switch 163 may also be limit members such as a travel switch and a proximity switch. The first sub limit switch 162 and the second sub limit switch 163 may also be sensors having a limit function.

In one embodiment, the mounting case 161 may be omitted, and the first sub limit switch 162 and the second sub limit switch 163 may be directly provided at other positions of the rack 10. Of course, in the case where the molecular diagnostic apparatus 100 is provided with a cabinet, the mounting case 161 may be provided on the cabinet. Even, the mounting case 161 may be omitted, and the first sub limit switch 162 and the second sub limit switch 163 may be directly provided on the cabinet.

Test card transport base 20

Referring to fig. 2, the inspection card transport 20 may include an abutting plate 50 and a carrying assembly 60 mounted on the frame 10, such as a first rail 1126. Wherein the consignment assembly 60 is used to place the test cards. The pressing plate 50 is connected to the first driving device 12 to slide on the first guide rail 1126 under the action of the first driving device 12, so as to drive the carrying assembly 60 to slide on the first guide rail 1126, and the carrying assembly 60 can carry the detection card and carry the detection card to the detection card detection seat 30.

Pressing disc 50

Referring to fig. 10, fig. 10 is an exploded view of the pressing plate 50 of fig. 2 according to the present application. The pressing plate 50 may include a first housing 51 mounted on the frame 10, e.g., a lead screw body 1224, an electromagnetic member 52 disposed on a side of the first housing 51 facing the detection card detection seat 30, a pressing member 53 for fixing the detection card on the carrying assembly 60, a heating assembly 54 disposed on the first housing 51, a first circuit board 55 mounted on the first housing 51 and electrically connected to the electromagnetic member 52 and the heating assembly 54, respectively, a locking member 56 mounted on the first housing 51 and used for fixing the pressing member 53, a second housing 57 covering a side of the first housing 51 away from the electromagnetic member 52, and a first slide rail assembly 58 disposed on the first housing 51 and mounted on the frame 10, e.g., a first guide rail 1126. Wherein, the first shell 51 and the second shell 57 are buckled to form a pressing disc main body. The first circuit board 55 may be electrically connected to the control circuit board 40. The electromagnetic member 52 can generate a magnetic force under the control of the control circuit board 40 to attach the pressing member 53 to the first housing 51. The electromagnetic member 52 can eliminate the magnetic force under the control of the control circuit board 40 to avoid the attraction of the pressing member 53. The heating assembly 54 may heat the card under the control of the control circuit board 40. The first slide rail assembly 58 is slidable on the frame 10, such as the first guide rail 1126. The first housing 51 is connected to the frame 10, for example, the screw body 1224, to slide in the extending direction of the first rail 1126 under rotation of the screw body 1224.

Referring to fig. 11 and 12, fig. 11 and 12 are schematic structural diagrams of the first housing 51 in fig. 10 from different viewing angles, respectively. The first housing 51 may be made of a hard material such as plastic, metal, etc. The first housing 51 may have a plate-like structure, but may have other shapes, which are not described herein. The first housing 51 may include a housing main body 511. A receiving groove 512 is provided in a middle portion of the housing main body 511 toward the second housing 57 side for receiving the first circuit board 55 and the locking member 56. The cross section of the receiving groove 512 may be circular, or may have other shapes.

The housing main body 511 may be provided with a catching hole 513 around the receiving groove 512 for mounting the heating assembly 54. The clamping holes 513 may be circumferentially and evenly distributed around the receiving groove 512. The number of the catching holes 513 may be 1 or more. In some embodiments, the number of the snap holes 513 may also be one of 2, 3, 4, 5, 6 \8230;. In one embodiment, the number of the locking holes 513 may be 6. In one embodiment. The shape of the engaging hole 513 is a segment of a ring structure.

The housing body 511 is provided with a cutout 514 to give way to the shipping assembly 60. A notch 514 extends inwardly from an edge of the housing body 511 adjacent to the fourth reinforcing plate 1134. The slit 514 may be opposite to the bar hole 1111, and the extending direction of the slit 514 may be the same as the extending direction of the bar hole 1111, so that the hauling component 60 may slide in the bar hole 1111 and the slit 514 at the same time. In one embodiment, the gap 514 is located between two adjacent snap holes 513.

The housing body 511 is bent at the edge of the opening 514 in the receiving groove 512 to form a side wall 5111 adjacent to the second housing 57, so as to isolate the opening 514 from the receiving groove 512. In one embodiment, the surface of the side wall 5111 adjacent to the second housing 57 is flush with the surface of the housing body 511 adjacent to the second housing 57. In one embodiment, the side wall 5111 can be used to support the second housing 57.

The housing body 511 is provided with insertion holes such as a first insertion hole 5112 and a second insertion hole 5113 penetrating the housing body 511 in the receiving groove 512 so that the locking member 56 is installed at the insertion holes. In an embodiment, the insertion holes such as the first insertion hole 5112 and the second insertion hole 5113 may be omitted.

The housing body 511 is provided with a limiting column 5114 in the accommodating groove 512 to limit the mounting position of the first circuit board 55. For example, the limiting column 5114 is disposed around the opening 514 to cooperate with the housing main body 511 to form a space for installing the first circuit board 55, so as to limit the installation position of the first circuit board 55. In one embodiment, the position-limiting post 5114 is provided with a communication hole 5114a, so that the circuit trace passes through the communication hole 5114a from the side of the housing body 511 close to the electromagnetic element 52 and extends into the receiving groove 512 to be electrically connected to the first circuit board 55.

In one embodiment, the retention posts 5114 may also be used to abut the second housing 57 to support the second housing 57. In one embodiment, the restraint posts 5114 can also be omitted. In one embodiment, the communication hole 5114a may be directly provided at other positions of the housing main body 511 than the stopper column 5114.

The housing body 511 is provided with a connection post 5115 inside the receiving groove 512 for mounting the first circuit board 55, so as to prevent the first circuit board 55 from directly contacting the housing body 511. In one embodiment, the connecting post 5115 can be used to connect and fix the first circuit board 55 by screwing, inserting, clipping, bonding, welding, or the like. In one embodiment, the connecting column 5115 can be omitted, and the first circuit board 55 is directly fixed in the receiving groove 512.

The edge of the housing body 511 at the side of the clamping hole 513 far away from the second housing 57 is bent into the clamping hole 513 to form a convex edge 5116, so that the heating assembly 54 can be clamped and mounted, and the heating assembly 54 is prevented from slipping off from the side of the housing body 511 close to the electromagnetic piece 52. A communication port 5117 is provided between the clamping hole 513 and the accommodating groove 512, so that the circuit wire connected to the heating assembly 54 passes through the communication port 5117 and is electrically connected to the first circuit board 55.

The housing body 511 is provided with a first screw portion 515 at a portion close to the lead screw assembly 122, for example, the first lead screw 1221. The housing body 511 is provided with a second screw portion 516 at a position close to the screw rod assembly 122, for example, the second screw rod 1222. The screw connection portions, such as the first screw connection portion 515 and the second screw connection portion 516, may include a connection lug 5151 extending from the housing body 511 and a screw member 5152 mounted on the connection lug 5151. The threaded member 5152 can be disposed on the lead screw assembly 122, such as the lead screw body 1224. The screw member 5152 is internally provided with an internal thread which is engaged with the external thread of the screw body 1224 to cause the housing body 511 to move in the extending direction of the screw assembly 122 such as the screw body 1224 upon rotation of the screw assembly 122 such as the screw body 1224.

The case body 511 is provided with positioning holes 517 for positioning the positions of the detection cards.

The middle of the side surface of the housing main body 511 away from the second housing 57 is provided with a relief groove 518 for accommodating the electromagnetic member 52, the pressing member 53 and the heating element 54. In an embodiment, the section of the avoiding groove 518 is circular, but may be other shapes, which is not described herein. The receding groove 518 and the accommodating groove 512 are arranged back to back relative to the housing main body 511, so that the receding groove 518 is communicated with the notch 514, the insertion holes such as the first insertion hole 5112 and the second insertion hole 5113 are located in the receding groove 518, the communication hole 5114a on the limiting column 5114 is located in the receding groove 518, and the clamping hole 513 is located around the receding groove 518. In one embodiment, the yielding slots 518 may be omitted.

In one embodiment, the housing body 511 has a plurality of receiving slots uniformly distributed on the inner circumference of the relief slot 518 for receiving the electromagnetic element 52. The number of the containing grooves can be a plurality of, and the specific number can be one of 2, 3, 4, 5, 6, 8230 \\ 8230;, and the like. In an embodiment, the number of the receiving grooves may be 2, for example, the first receiving groove 5118 and the second receiving groove 5119.

Referring to fig. 10 again, the electromagnetic element 52 can be energized to generate a magnetic force, so as to attract and fix the pressing element 53. The electromagnet member 52 may include a first electromagnet 521 and a second electromagnet 522 electrically connected to the first circuit board 55, respectively. The first electromagnet 521 may be installed in the first receiving groove 5118. The second electromagnet 522 may be installed in the second receiving groove 5119. Specifically, the first electromagnet 521 and the second electromagnet 522 may be fixed on the housing body 511 by a screw connection, a snap connection, an insertion connection, a welding connection, an adhesion connection, or the like. In one embodiment, the circuit traces electrically connected to the first and second electromagnets 521 and 522 are electrically connected to the first circuit board 55 through the communication holes 5114 a. In one embodiment, electromagnet 52 may be omitted.

Referring to fig. 13, fig. 13 is a schematic structural view of the pressing member 53 of fig. 10 according to the present application. The number of the pressing pieces 53 may be 1 or more. In an embodiment, the number of the pressing members 53 may be 2, and is the first pressing member 531 and the second pressing member 532, respectively. A gap 533 is provided between the two hold-down members 53. Gap 533 is disposed opposite strip hole 1111 to give way to the consignment assembly 60 so that the consignment assembly 60 can move in both gap 533 and strip hole 1111 at the same time.

Each pressing member 53 may be made of a hard material such as metal, and may be made of a metal such as iron, which is attracted by an electromagnet under a magnetic force. Of course, in some embodiments, each of the pressing members 53 may be made of a rigid material such as plastic, metal, etc. to engage the locking member 56.

Each pressing member 53 may be a plate-shaped structure, and may be a circular portion or an annular portion, or may have other shapes, which is not described in detail. The compression member 53, such as the first compression member 531, can include a compression member body 5311. The pressing piece body 5311 may be provided with a yielding portion 5312 to give way to the detection card to increase a contact area of the pressing piece body 5311 and the detection card, thereby limiting the detection card. In one embodiment, the relief portion 5312 may be a through hole or a notch.

The pressing piece body 5311 of the first pressing piece 531 is provided with a sub-relief portion 5313 toward the edge of the second pressing piece 532. The pressing piece body 5311 of the second pressing piece 532 is provided with a sub relief portion 5313 toward the edge of the first pressing piece 531. The sub-abdicating portion 5313 of the first compressing member 531 and the sub-abdicating portion 5313 of the second compressing member 532 are oppositely disposed and can constitute an abdicating portion for abdicating the test card to increase the contact area between the compressing member body 5311 and the test card, thereby limiting the test card. In one embodiment, the sub-receding portion 5313 may be a notch.

In an embodiment, the positioning portions in the above embodiment may be uniformly distributed circumferentially so as to reasonably fix and limit the detection card. It is understood that the number of the concession portions may be identical to the number of the card holes 513 or the number of the test cards.

The compression member body 5311 is provided with a first trim portion 5314 to detachably connect with the consignment assembly 60.

In an embodiment, the first pressing member 531 and the second pressing member 532 may be of an integral structure, and the gap 533 is provided only at a position opposite to the strip hole 1111. Gap 533 extends inwardly from an edge of compression member 53. In one embodiment, gap 533 may be omitted and compression member 53 may be included as part of the shipping assembly 60.

When the electromagnetic member 52 is attracted to the pressing member 53, one electromagnet, for example, the first electromagnet 521, of the electromagnetic member 52 may attract the surface of the first pressing member 531, for example, the pressing member main body 5311, and the other electromagnet, for example, the second electromagnet 522, may attract the surface of the second pressing member 532, for example, the pressing member main body 5311.

In one embodiment, the pressing member 53 can also be locked and fixed with the locking member 56. For example, the body 5311 can be clamped between two adjacent retainers by the clamping member 56. Of course, corresponding connecting structures such as connecting posts, lugs, etc. can also be provided on the body 5311 to be clamped and fixed by the locking member 56.

Referring again to fig. 10, the heating element 54 may include a first heating element 541 mounted on a side of the first housing 51, e.g., the housing body 511, adjacent to the second housing 57 and a second heating element 542 mounted on a side of the first housing 51, e.g., the housing body 511, remote from the second housing 57. The first and second heating members 541 and 542 cooperate to heat-treat the detection card when in abutment with the detection card or in a suitable scene or position.

It is to be understood that the designations of "first heating element", "second heating element", and "heating element" may be interchanged in some embodiments. For example, in one embodiment, "the first heating member" in the other embodiments is referred to as "the second heating member", and accordingly, "the second heating member" in the other embodiments is referred to as "the first heating member".

Referring to fig. 14 and 15, fig. 14 and 15 are respectively schematic structural diagrams of the first heating elements 541 in fig. 10 from different viewing angles. The first heating member 541 may include a heating body 5411. The heating body 5411 may be made of a heat conductive hard material such as metal to facilitate heating of the test card. A heat generating device such as a heating resistor may be provided inside the heating body 5411.

The heating body 5411 can be disposed in the first housing 51, such as the clipping hole 513, and clipped with the first housing 51, such as the housing body 511, so as to achieve the installation of the heating body 5411 on the first housing 51.

The surface of the heating body 5411 facing the side of the second housing 57 is provided with a groove 5412 to fit with the second housing 57. The edge of the heating main body 5411 facing the side of the second housing 57 is provided with a clamping edge 5413, so that the heating main body 5411 is placed in the clamping hole 513 from the side of the first housing 51 close to the second housing 57 and is exposed at the side of the first housing 51 far from the second housing 57, and meanwhile, the clamping edge 5413 is in matched clamping connection with the convex edge 5116, and the sliding of the heating main body 5411 from the side of the first housing 51 close to the electromagnetic piece 52 is avoided.

In some embodiments, when the heating body 5411 is located in the clamping hole 513, the circuit trace electrically connected to the heat generating device inside the heating body 5411 can pass through the communication opening 5117 to be electrically connected to the first circuit board 55, so as to control the heat generating device inside the heating body 5411.

It is appreciated that in an embodiment, the heating body 5411 may be a unitary structure with the first housing 51, such as the housing body 511.

Referring to fig. 10, the second heating member 542 may be a ring-shaped structure as a whole. The second heating member 542 may be made of a heat conductive hard material such as metal, and a heat generating device such as a heating resistor may be provided therein. The second heating member 542 is installed in the escape groove 518 of the housing body 511. The second heating member 542 may be fixed to the receding groove 518 by a screw, an insert, a snap, or the like. The second heating element 542 is provided with a gap 5421 to give way to the cutout 514 and the consignment assembly 60.

In some embodiments, when the second heating member 542 is located in the avoiding groove 518, the circuit traces electrically connected to the heat generating devices inside the second heating member 542 may be electrically connected to the first circuit board 55 through the communication holes 5114a to control the heat generating devices inside the second heating member 542.

Referring to fig. 16, fig. 16 is a schematic structural diagram of the first circuit board 55 in fig. 10. The first circuit board 55 may be an annular structure as a whole. The first circuit board 55 is provided with electronic components such as a resistor, a capacitor, and an inductor. The first circuit board 55 is mounted in the receiving groove 512 of the housing body 511. The first circuit board 55 can be restrained by the restraint posts 5114 to avoid shaking. The first circuit board 55 can be fixed on the connection post 5115 by means of screw connection, insertion connection, or snap connection. The first circuit board 55 is provided with a notch 551 to allow access to the side wall 5111, the notch 514 and the shipping unit 60. The first circuit board 55 can be electrically connected to the heat generating device and the electromagnetic element 52 in the heating assembly 54, respectively, so as to control the heat generating device and the electromagnetic element 52 in the heating assembly 54, respectively. In an embodiment, the first circuit board 55 may be omitted without sharing the working pressure for the control circuit board 40, and the heat generating device and the electromagnetic device 52 in the heating assembly 54 may be directly electrically connected to the control circuit board 40.

Referring to fig. 17 and 18, fig. 17 is a schematic view of the locking member 56 of fig. 10, and fig. 18 is a cross-sectional view of the locking member 56 of fig. 17 taken along line XVII-XVII. The locker 56 may include a locking case 561 fixed to the case body 511, a link assembly 562 disposed inside the locking case 561, and a locking claw 563 disposed outside the locking case 561 and connected to the link assembly 562.

Specifically, the locking housing 561 is hollow, and the locking walls 5611 are provided on opposite sides of the opening, and the locking walls 5611 are protruded toward the locking housing 561. The lock housing 561 is provided with a relief hole 5612 at a portion adjacent to the card wall 5611. The lock housing 561 has a latch 5613 provided in the escape hole 5612. The latch 5613 is elastically deformable. The latch 5613 is protruded toward the locking housing 561. When the lock member 56 is mounted on the housing main body 511, an end of the lock housing 561 remote from the catch wall 5611 protrudes from a side of the first housing 51, for example, the housing main body 511 remote from the second housing 57, into the first insertion hole 5112 or the second insertion hole 5113. The latch 5613 is elastically deformed by the first housing 51, such as the housing body 511, so that the latch 5613 passes through the insertion hole, and the housing body 511 is latched to the relief hole 5612, the latch wall 5611 is located on a side of the housing body 511 away from the second housing 57 and abuts against a bottom surface of the relief groove 518, the latch 5613 is located on a side of the housing body 511 close to the second housing 57 and abuts against a bottom surface of the receiving groove 512, and the latch mounting of the locking housing 561 and the first housing 51, such as the housing body 511, is realized under the action of the latch wall 5611 and the latch 5613. It is understood that the locking housing 561 may also be fixed to the housing body 511 by screwing, plugging, snapping, adhering, welding, etc., which will not be described in detail.

The link assembly 562 may include a link body 5621 installed inside the locking housing 561, a link member 5622 slidably coupled with the link body 5621, an elastic member 5623 installed on the link body 5621 and the link member 5622 and forcing the link member 5622 to slide outward of the locking housing 561 relative to the link body 5621, and a link member 5624 provided on the link body 5621 to lock or unlock the link member 5622.

The linkage body 5621 is hollow and cylindrical, and is disposed in the locking housing 561 and extends from a bottom surface of the locking housing 561 to a position of the latch 5613. In one embodiment, the linkage body 5621 may be integrally formed with the lock housing 561. In one embodiment, the linkage body 5621 may be omitted.

The connecting members 5622 are disposed in the linkage body 5621, and may be disposed in a column shape, an outer diameter of one portion of the connecting members 5622 is larger than that of the other portion of the connecting members 5622, and one end of the connecting member 5622 having a larger outer diameter is connected and fixed to the locking claw 563. In one embodiment, the outer diameter of the connecting member 5622 is uniform.

The elastic member 5623 is fitted over the connecting member 5622 at a portion having a smaller outer diameter. In one embodiment, the resilient member 5623 may be a spring, which is disposed around the connecting member 5622, and has one end abutting against the linkage body 5621 or the locking housing 561 and the other end abutting against the connecting member 5622. It is understood that the resilient member 5623 can be made of other resilient materials, which will not be described in detail.

A link 5624 is fixed inside the link body 5621 to lock or unlock the link 5624. The linkage 5624 may be an electromagnet, for example, the electromagnet is electrically connected to the control circuit board 40, so as to adsorb and fix the connecting element 5622 at a certain position under the control of the control circuit board 40, so that the connecting element 5622 cannot move, so as to lock the connecting element 5622, and when the connecting element 5622 is unlocked, the linkage 5624 is also under the control of the control circuit board 40, so as to unlock the connecting element 5622 at a certain position. In one embodiment, the linkage 5624 may be other structures such as an electromagnet. Of course, the linkage 5624 may also be a mechanical structure such as a wheel, ratchet, etc. that locks or unlocks the linkage 5622.

In an embodiment, the linkage 5624 may be configured to:

when the link member 5624 is locked to the link member 5622, the link member 5622 is moved again into the lock case 561 to slide relative to the link body 5621, whereby the link member 5624 is triggered, and the state where the link member 5624 is locked to the link member 5622 is broken.

When the link 5624 is not locked to the link 5622, the link 5622 moves into the locking housing 561 to slide relative to the link body 5621, and the link 5624 is triggered, so that the link 5624 is locked to the link 5622.

When the locking member 56 is used, when the locking claw 563 is aligned with the pressing member 53, the locking claw 563 can move to one side of the pressing member 53 under the driving of the first housing 51, so that the locking claw 563 is abutted to the pressing member 53, the locking claw 563 is abutted to the abutting force moving into the locking housing 561, and then moves into the locking housing 561, and meanwhile, the locking claw 563 is pressed by the pressing force of the locking housing 561 to the locking claw 563, so that the locking claw 563 is closed to clamp the pressing member 53, for example, a position between two adjacent displacement portions or a structure such as a connecting column or a connecting lug, and the like, thereby realizing the clamping and locking of the pressing member 53. Meanwhile, the locking claw 563 is abutted by the movement into the locking housing 561 to trigger the link 562, and the link 562 keeps the locking claw 563 in a locked state. When the locking claw 563 is kept in the locked state, the locking claw 563 is again abutted to the force moving into the locking housing 561, the locking claw 563 moves into the locking housing 561 again, the linkage assembly 562 is triggered again, the linkage assembly 562 breaks the locked state kept by the locking claw 563 to achieve unlocking, and under the action of the linkage assembly 562, the locking claw 563 moves to one side far away from the locking housing 561, so that the locking claw 563 is opened, the pressing piece 53 cannot be clamped and locked, and the pressing piece 53 is put down.

In one embodiment, the locking member 56 may also be a door lock switch. In one embodiment, retaining member 56 may also be omitted in the presence of solenoid 52.

Referring to fig. 19 and 20, fig. 19 and 20 are respectively schematic structural diagrams of the second housing 57 in fig. 10 from different viewing angles. The second housing 57 may include a cover body 571 that may be engaged with the first housing 51, such as the housing body 511. The cover body 571 can be connected and fixed with the first housing 51, such as the housing body 511, by means of screw connection, insertion, snap, welding, adhesion, and the like, which will not be described herein.

The cover body 571 may be made of a hard material such as plastic, metal, etc. The cover body 571 has a through hole 572. The through hole 572 may be disposed opposite to the receiving groove 512 to give way to the first circuit board 55, so that the first circuit board 55 is exposed. In an embodiment, the through hole 572 may be omitted, and the cover body 571 completely covers the first housing 51, for example, the housing body 511. In one embodiment, the size of the through hole 572 can be adjusted such that the through hole 572 corresponds to the position of the notch 514 in the housing main body 511 to give way to the shipping component 60, and the cover main body 571 covers the first circuit board 55.

The cover body 571 is provided with a cutout 573. The slits 573 extend inward from the edge of the cover body 571 to communicate with the through-holes 572. A cutout 573 is provided in the cover body 571 opposite the cutout 514 such that when the cover body 571 is fastened to the housing body 511, the cutout 573 communicates with the cutout 514 to give way for the shipping assembly 60 so that the shipping assembly 60 can slide within the cutout 573.

A fixing post 574 is disposed on one side of the cover body 571 facing the first housing 51. The fixing post 574 protrudes from the surface of the cover body 571. The fixing posts 574 are located at positions of the cover body 571 opposite to the recesses 5412 of the heating element 54, so that the springs are sleeved on the fixing posts 574, one end of each spring abuts against the cover body 571, and the other end abuts against the heating element 54 at the position of the recess 5412. It will be understood that the heating assembly 54 is movable relative to the first housing 51 and toward the side of the second housing 57 when the first housing 51 is forced away from the side of the second housing 57 by the spring, and the spring is compressed. In one embodiment, the securing posts 574 may be omitted. In an embodiment, the spring may be replaced by other elastic members, which are not described in detail.

The cover body 571 is provided with a hanging lug 575 at a side away from the first housing 51 to connect with the consignment assembly 60. The hanging ring 575 is fixed on the cover body 571 by means of screw connection, insertion, snap, welding, bonding, etc. In one embodiment, the number of tabs 575 can be two, such as a first tab 5751 and a second tab 5752. The first hanging lug 5751 and the second hanging lug 5752 are symmetrically arranged. It will be appreciated that the number and location of the tabs 575 can be set as desired when the tabs 575 are to function in conjunction with the consignment assembly 60.

The cover body 571 is further provided with a positioning hole 576, and the positioning hole 576 is located on the cover body 571 at a position opposite to the positioning hole 517, so that when the cover body 571 is fastened with the housing body 511, the positioning hole 576 is communicated with the positioning hole 517 to position the detection card.

Referring to fig. 10 and 21, fig. 21 is a schematic perspective view of the pressing plate 50 in fig. 10. The first slide rail assembly 58 is disposed on the first housing 51 to enable sliding connection of the first housing 51 to the frame 10, such as the first rail 1126. The first slide rail assembly 58 may include a plurality of slide rails. The particular number of slides may be the same as the number of first rails 1126, and in some embodiments, the number of slides may also be less than the number of first rails 1126.

In one embodiment, the number of the slide rails may be 4, which are the first slide rail 581, the second slide rail 582, the third slide rail 583 and the fourth slide rail 584.

Referring to fig. 21 and 22, fig. 22 is a schematic structural diagram of the first slide rail 581 in fig. 21. Each slide rail, such as the first slide rail 581, may include a first slide rail mount 5811 disposed on the first housing 51, such as the housing body 511, and a first slide rail piece 5812 mounted to the first slide rail mount 5811. Wherein the first sliding rail member 5812 is mountable on the first guide rail 1126 for relative sliding movement of the first sliding rail member 5812 and the first guide rail 1126.

The first slide mount 5811 can be made of a rigid material such as plastic, metal, etc. The first slide rail mount 5811 can be secured to a side of the first housing 51, such as the housing body 511, by a threaded connection, a plug connection, a snap connection, a weld connection, an adhesive connection, or the like. The first slide rail mounting member 5811 is bent toward the cover body 571 at a side away from the detection card detection seat 30 to form a bent portion 5814. The bent portion 5814 may abut against the second case 57 on a side away from the first case 51. In an embodiment, the bent portion 5814 and the second housing 57 can be sequentially passed through by a bolt, a screw, or other screwing structures and connected and fixed with the first housing 51, but other manners, such as inserting, snapping, welding, and adhering, can also be adopted to achieve the connection and fixing relationship between the bent portion 5814, the second housing 57, and the first housing 51.

In an embodiment, a limit plate 5813 may be disposed on a slide rail, such as the first slide rail 581, to cooperate with the second limit switch 16, for example, when the pressing plate 50 slides along the frame 10, such as the first guide rail 1126, the limit plate 5813 may slide along the stroke of the pressing plate 50, and when the limit plate 5813 slides to a predetermined position, the limit plate 5813 may be disposed in a groove of the second limit switch 16, such as a groove-shaped optical coupler, to block light transmission between the limit light-emitting portion and the limit light-receiving portion, so that the groove-shaped optical coupler is triggered to generate a control signal and transmit the control signal to the control circuit board 40, and under the control of the control circuit board 40, the operation of the first driving device 12, such as the driving assembly 121, is stopped, so as to stop the movement of the pressing plate 50. It is understood that the limiting plate 5813 may be disposed on other slide rails of the first slide rail assembly 58, and may also be disposed on other portions of the pressing plate 50.

Referring to fig. 23, fig. 23 is a schematic view of a connection structure of the frame 10 and the pressing plate 50. Wherein the pressing plate 50 is mounted on the frame 10. The first slide rail piece 5812 of the first slide rail 581 is mounted on the first guide rail 1126 on the third leg 1123. Accordingly, the first slide member 5812 of the second slide 582 is mounted on the first rail 1126 on the fourth leg 1124. The first slide rail member 5812 of the third slide rail 583 is mounted to the first guide rail 1126 on the first leg 1121. The first slide rail member 5812 of the second slide rail 582 is mounted on the first rail 1126 on the second leg 1122. The first threaded portion 515 is threaded with a first lead screw 1221, such as a lead screw body 1224. The second screw portion 516 is screwed with a second lead screw 1222 such as a lead screw body 1224. When the driving assembly 121 moves, the first lead screw 1221 and the second lead screw 1222 are driven to move synchronously, and then the first lead screw 1221 and the second lead screw 1222 both rotate relative to the pressing plate 50, so that the first slide rail assembly 58 of the pressing plate 50, for example, the first slide rail piece 5812, can slide on the first guide rail 1126, and the position movement of the pressing plate 50, specifically, the position movement of the pressing plate 50 in the vertical direction, is realized.

Consignment assembly 60

Referring to fig. 24, fig. 24 is a schematic view of the shipping assembly 60 of fig. 2. The transfer assembly 60 may include a carriage 61 disposed above the pressing platen 50 and mounted on the frame 10, e.g., the first rail 1126, and a transfer 62 mounted on the carriage 61. Wherein the carriage 61 is slidable on the frame 10, e.g. on the first guide rail 1126. The sliding frame 61 is connected to the pressing plate 50 to slide on the frame 10 together with the pressing plate 50 in some scenarios. The shipper 62 may be used to place test cards. The carrier 62 is slidable relative to the carriage 61. The sliding direction of the carrying member 62 with respect to the sliding frame 61 is different from the sliding direction of the sliding frame 61 with respect to the frame 10.

It will be appreciated that when the carriage assembly 60 is extended, the carriage 62 slides on the carriage 61 to slide to a first position outside the frame 10, completing the extension, and the detection card is placed when the carriage assembly 60 is in the extended position. Then, when the carrier assembly 60 is retracted, the carrier 62 slides on the carriage 61 to slide to a second position within the frame 10, completing the retraction, and is slidable between a third position and a fourth position on the first rail 1126 when the carrier assembly 60 is in the retracted state. In some embodiments, the shipping assembly 60 may be extended when in the third position. In some embodiments, the shipping assembly 60 may be extended at a position between the third position and the fourth position.

Referring to fig. 25, fig. 25 is a schematic view of the sliding frame 61 in fig. 24. The carriage 61 may include a fixed frame 611, a second slide rail assembly 612 mounted on the fixed frame 611 and slidably connected to the frame 10, for example, the first rail 1126, a second rail 613 mounted on the fixed frame 611 and used for mounting the carrying member 62, and a second driving device 614 for driving the carrying member 62 to slide on the second rail 613.

It is understood that the names "first driving device", "second driving device", and "driving device" may be interchanged in some embodiments. For example, in one embodiment, "first driving means" in other embodiments is referred to as "second driving means", and accordingly, "second driving means" in other embodiments is referred to as "first driving means".

The holder 611 may be made of a hard material such as plastic, metal, etc. The whole fixing frame 611 may have a frame structure, and may also have other shapes, which are not described in detail. The fixing frame 611 may include a first connecting plate 6111, a second connecting plate 6112 connected to the first connecting plate 6111, a third connecting plate 6113 connected to the second connecting plate 6112 and disposed opposite to the first connecting plate 6111, and a fourth connecting plate 6114 connected to the third connecting plate 6113 and the first connecting plate 6111 and disposed opposite to the second connecting plate 6112.

In an embodiment, the first connecting plate 6111, the second connecting plate 6112, the third connecting plate 6113, and the fourth connecting plate 6114 may be enclosed to form a rectangle. Both the extending direction of the second connecting plate 6112 and the extending direction of the fourth connecting plate 6114 may be the same as the extending direction of the strip-shaped hole 1111, or may be different.

The second sliding rail assembly 612 is disposed on the fixed frame 611 for realizing the sliding connection between the fixed frame 611 and the rack 10 when the second sliding rail assembly 612 is slidably connected with the rack 10, for example, the first guiding rail 1126. The second slide rail assembly 612 may include a plurality of slide rails, and the number of the slide rails may be the same as the number of the first guide rails 1126.

In an embodiment, the number of the slide rails can be 4, which are respectively the first slide rail 6121, the second slide rail 6122, the third slide rail 6123, and the fourth slide rail 6124.

Each slide rail, such as the first slide rail 6121, may include a second slide rail mount 6125 disposed on the mount 611 and a second slide rail member 6126 mounted to the second slide rail mount 6125. Wherein the second slide rail member 6126 can be mounted on the first guide rail 1126 to enable relative sliding of the second slide rail member 6126 with respect to the frame 10, e.g., the first guide rail 1126.

The second slide rail mount 6125 can be made of a rigid material such as plastic, metal, etc. The second slide rail mounting member 6125 may be fixed to the fixing bracket 611 by screwing, inserting, welding, fastening, bonding, or the like. In an embodiment, the second slide rail mounting member 6125 may be omitted, and the second slide rail member 6126 may be directly disposed on the fixing bracket 611.

The second slide rail member 6126 of a slide rail, such as the first slide rail 6121, is slidably connected to the first guide rail 1126 of the second leg 1122 when the second slide rail assembly 612 is slidably connected to the frame 10, such as the first guide rail 1126. A slide rail, such as the second slide rail member 6126 of the second slide rail 6122, is slidably connected to the first guide rail 1126 of the third leg 1123. A second slide rail member 6126 of a slide rail, such as a third slide rail 6123, is slidably connected to the first guide rail 1126 of the fourth leg 1124. A second slide rail member 6126 of a slide rail, such as a fourth slide rail 6124, is slidably coupled to the first guide rail 1126 of the first leg 1121.

In an embodiment, the first sliding rail 6121 and the fourth sliding rail 6124 are disposed on a side of the fourth connecting plate 6114 away from the second connecting plate 6112. The second slide rail 6122 and the third slide rail 6123 are disposed on a side of the second connecting plate 6112 away from the fourth connecting plate 6114. Of course, the mounting positions of the first slide rail 6121, the second slide rail 6122, the third slide rail 6123 and the fourth slide rail 6124 on the fixing frame 611 can be adjusted according to actual situations.

Second rail 613 is mounted on mount 611 for mounting tote 62 such that tote 62 slides on second rail 613. The extending direction of the second rail 613 may coincide with the extending direction of the bar hole 1111, so that the carrier 62 slides on the second rail 613 while also sliding in the bar hole 1111. The second guide rail 613 may include a first sub-guide rail 6131 disposed on the fixing bracket 611, e.g., the second coupling plate 6112, and a second sub-guide rail 6132 disposed on the fixing bracket 611, e.g., the fourth coupling plate 6114. The extending direction of the first sub guide rail 6131 may coincide with the extending direction of the second sub guide rail 6132. The first sub-rail 6131 and the second sub-rail 6132 can be fixed on the fixing frame 611 by screwing, fastening, welding, bonding, inserting and the like. In an embodiment, the extending direction of the first sub-guide rail 6131 is a horizontal direction. In an embodiment, when the carrying element 62 slides on the first sub-guide rail 6131 without affecting the sliding of the carrying element 62 in the strip-shaped hole 1111, the extending direction of the first sub-guide rail 6131 may be different from the extending direction of the second sub-guide rail 6132.

It is understood that the designations "first rail," "second rail," and "rail" may be interchanged in some embodiments. For example, in one embodiment, the "first rail" in the other embodiments is referred to as a "second rail", and accordingly, the "second rail" in the other embodiments is referred to as a "first rail".

The second driving device 614 may include a second driving member 6141 disposed on the fixing frame 611 and a lead screw 6142 connected to the second driving member 6141. The second driving member 6141 can be mounted on the fixing frame 611, for example, the first connecting plate 6111, and is used for driving the screw shaft 6142 to rotate. The second driving member 6141 may be electrically connected with the control circuit board 40 to move under the control of the control circuit board 40. The lead screw 6142 is rotatably connected to the fixing frame 611, such as the first connecting plate 6111 and the fourth connecting plate 6114. The extending direction of the lead screw 6142 may coincide with the extending direction of the second guide rail 613. The outer surface of the lead screw 6142 is provided with an external thread. The lead screw 6142 is screwed with the delivery part 62 through an external thread, so that when the lead screw 6142 rotates, the lead screw 6142 and the delivery part 62 rotate relatively, and the delivery part 62 slides on the second guide rail 613 under the matching of the lead screw 6142 and the second guide rail 613.

The second driving member 6141 is installed on one side of the first connecting plate 6111 away from the third connecting plate 6113, and can be specifically fixed by screws, bolts, buckles, insertion, welding, bonding, or other connection methods. In an embodiment, the second driving member 6141 can be a motor. The output shaft of the motor can penetrate the first connection plate 6111 and be connected with the lead screw 6142. Of course, the second drive member 6141 could be other types of power sources.

It is understood that the second rail 613 can be omitted when the number of the lead screws 6142 is large enough to maintain and support the stability of the carrying member 62.

In some embodiments, to position the detection card in the tote 62, the stationary rack 611, such as the first connection plate 6111, is provided with a positioning light generator 615. The light generator 615 is located on a side of the first connection plate 6111 away from the third connection plate 6113. The positioning light generator 615 is disposed opposite to the positioning holes, such as positioning holes 576 and 517, on the pressing plate 50, so that the light generated by the positioning light generator 615 passes through the positioning holes, such as positioning holes 576 and 517, on the pressing plate 50, and then cooperates with the positioning light receiver 716 (shown in fig. 33) to position the detection card on the carrier 62.

In one embodiment, to limit the movement of the tote 62, a light sensor 616 can be disposed on the side of the fixed frame 611, e.g., the second connecting plate 6112, adjacent to the fourth connecting plate 6114. The optical sensor 616 is electrically connected to the control circuit board 40 to operate under the control of the control circuit board 40. The light sensor 616 may include a light emitting unit for emitting light and a light receiving unit for receiving light. When the carrying member 62 slides along the second guide rail 613 toward the first connection plate 6111 and reaches a predetermined position, light emitted from the light receiving unit can be received and reflected to the light receiving unit, the light sensor 616 is triggered to generate a control signal and transmit the control signal to the control circuit board 40, and the control circuit board 40 controls the carrying member 62 so that the carrying member 62 is maintained at the predetermined position. In one embodiment, the light sensor 616 is located on a side of the second connection plate 6112 near the first connection plate 6111. In one embodiment, the optical sensor 616 may also be limited by the first limit switch 15, the travel switch, the proximity switch, and the like in the above-described embodiments.

In some embodiments, to achieve that the pressing plate 50 slides together with the sliding frame 61, a traction member 617 may be provided on the fixing frame 611. In order to achieve a stable sliding of the pressing plate 50 and the sliding frame 61, the number of the pulling members 617 may be plural. For example, the number of the pulling members 617 can be 2, respectively a first pulling member 6171 and a second pulling member 6172. The two traction members 617 may be symmetrically disposed on both sides of the fixed frame 611.

In an embodiment, the first pulling member 6171 is disposed on a side of the second connecting plate 6112 away from the fourth connecting plate 6114. The second pulling member 6172 is disposed on a side of the fourth connecting plate 6114 away from the second connecting plate 6112.

Each of the pulling members 617, for example, the second pulling member 6172, may include a hanging member 6172a disposed on the connecting plate, for example, the fourth connecting plate 6114, and an elastic member 6172b having one end connected to the hanging member 6172a and the other end connected to the pressing plate 50, for example, the hanging lug 575. Wherein the tight fit between the fixing bracket 611 and the pressing plate 50 is increased by the elastic member 6172b.

In one embodiment, the suspension 6172a may be a pillar structure. A hanging part 6172a of the first pulling member 6171 is arranged at a side of the second connecting plate 6112 far away from the fourth connecting plate 6114. A hanging part 6172a of the first pulling piece 6171 can be positioned between the second sliding rail 6122 and the third sliding rail 6123. A hanging part 6172a of the second pulling member 6172 is arranged at a side of the fourth connecting plate 6114 far away from the second connecting plate 6112. A hanger 6172a of the second pulling member 6172 may be located between the first sliding rail 6121 and the fourth sliding rail 6124.

In one embodiment, the elastic member 6172b may be a tension spring. One end of the elastic member 6172b of the first pulling member 6171, such as a tension spring, can be connected and fixed with the hanging member 6172a of the first pulling member 6171. The other end of the elastic member 6172b of the first pulling member 6171, such as a tension spring, can be connected and fixed with the pressing plate 50, such as the first hanging lug 5751. One end of the elastic member 6172b, such as a tension spring, of the second pulling member 6172 may be connected and fixed to the hanging member 6172a of the second pulling member 6172. The other end of the elastic member 6172b of the second pulling member 6172, such as a tension spring, can be connected and fixed with the pressing plate 50, such as the second hanging lug 5752.

It is understood that in some embodiments, the hanging member 6172a of each traction member 617 can be omitted, and the corresponding matching elastic member 6172b can be directly connected and fixed with the corresponding connecting plate in the fixing frame 611. In some embodiments, the traction members 617 may be omitted where the carriage assembly 60, by its own weight, may be implemented to move with the abutment plate 50. In some embodiments, the pulling member 617 may be omitted and the shipping assembly 60 may be threadably coupled to the lead screw assembly 122, such as the first lead screw 1221 and the second lead screw 1222.

Referring to fig. 26, fig. 26 is a schematic view of the structure of the shipping unit 62 of fig. 24. The carrying unit 62 may include a sliding seat 63 mounted on the second rail 613 and threadedly engaged with the second driving device 614, such as the lead screw 6142, a third driving member 64 mounted on the sliding seat 63, and a card holder 65 mounted on the third driving member 64 and driven by the third driving member 64 to rotate. The sliding seat 63 slides on the second guide rail 613 to drive the third driving member 64 and the card holder 65 to move together, and can move to a position outside the rack 10 to place a detection card on the card holder 65, the sliding seat 63 can also drive the third driving member 64 and the card holder 65 to move to a position inside the rack 10, and the third driving member 64 can drive the detection card on the card holder 65 to perform a centrifugal motion to complete the centrifugal processing of the detection card.

Referring to fig. 27 and 28, fig. 27 and 28 are schematic structural views of the sliding seat 63 in fig. 26 from different viewing angles, respectively. The sliding seat 63 may include a sliding seat body 631 for mounting the third driving member 64, a third slide rail assembly 632 disposed on the sliding seat body 631 and slidably connected to the second guide rail 613, e.g., the first sub-guide rail 6131, and a fourth slide rail assembly 633 disposed on the sliding seat body 631 and slidably connected to the second guide rail 613, e.g., the second sub-guide rail 6132. Wherein, the fourth slide rail assembly 633 can be screwed with the second driving device 614, such as the lead screw 6142. So as to drive the sliding seat main body 631 to slide on the second guide rail 613 under the driving of the second driving device 614.

The sliding seat body 631 may be made of a hard material such as plastic, metal, etc. The sliding seat body 631 may include a bottom plate 6311 and side plates 6312 enclosed around the bottom plate 6311. The middle of the bottom plate 6311 may be provided with a yielding hole 6311a for yielding the third driving member 64. The side plate 6312 may extend from an edge of the bottom plate 6311 to a side away from the pressing plate 50. The side plates 6312 may include a first side plate 6312a provided with the third slide rail assembly 632, a second side plate 6312b connected to the first side plate 6312a and located on a side of the bottom plate 6311 close to the first connecting plate 6111, and a third side plate 6312c connected to the second side plate 6312b and symmetrically provided with the first side plate 6312 a.

The third slide rail assembly 632 is fixed on one side of the first side plate 6312a close to the second connecting plate 6112, and may be specifically fixed by means of screwing, inserting, fastening, welding, bonding, or the like. The third slide rail assembly 632 is slidably connected to the second rail 613, for example, the first sub-rail 6131, so as to achieve the sliding connection between the sliding seat body 631 and the sliding frame 61. The third slide rail assembly 632 may include a third slide rail mount 6321, e.g., the first side plate 6312a, disposed on the slide mount body 631 and a third slide rail 6322 mounted on the third slide rail mount 6321. The third sliding rail member 6322 can be mounted on the second guiding rail 613, for example, the first sub-guiding rail 6131, so as to realize the relative sliding between the third sliding rail member 6322 and the second guiding rail 613, for example, the first sub-guiding rail 6131.

The third slide rail mount 6321 may be made of a rigid material such as plastic, metal, etc. The third slide rail mount 6321 may be secured to the side panel 6312, such as the first side panel 6312a, by screwing, plugging, snapping, welding, bonding, or the like. In an embodiment, the third slide rail mount 6321 may be omitted and the third slide rail member 6322 may be disposed directly on the side panel 6312, e.g., the first side panel 6312 a.

The fourth sliding rail assembly 633 is fixed on one side of the third side plate 6312c close to the fourth connecting plate 6114, and may be fixed specifically by screwing, inserting, fastening, welding, adhering, or the like. The fourth slide rail assembly 633 is slidably connected to the second rail 613, for example, the second sub-rail 6132, so as to achieve the sliding connection between the sliding seat main body 631 and the sliding frame 61. The fourth slide rail assembly 633 may include a fourth slide rail mount 6331 disposed on the slide mount body 631, e.g., the third side plate 6312c, a fourth slide rail member 6332 mounted to the fourth slide rail mount 6331, and a screw 6333 mounted to the fourth slide rail mount 6331. The fourth sliding rail member 6332 can be mounted on the second guiding rail 613, for example, the second sub-guiding rail 6132, so as to realize the relative sliding between the fourth sliding rail member 6332 and the second guiding rail 613, for example, the second sub-guiding rail 6132. The screw 6333 can be sleeved on the lead screw 6142, and an internal thread matching with the external thread of the lead screw 6142 is disposed inside the screw 6333, so that the sliding seat 63 moves in the extending direction of the lead screw 6142 under the driving of the second driving member 6141.

It is understood that the names of the "first slide rail", "second slide rail", "third slide rail", "fourth slide rail", and "slide rail" may be interchanged in some embodiments. For example, in one embodiment, "the first slide rail" in other embodiments is referred to as "the second slide rail", and correspondingly, "the second slide rail" in other embodiments is referred to as "the first slide rail".

For the names of the first slide rail assembly, the second slide rail assembly, the third slide rail assembly, the fourth slide rail assembly, the slide rail assembly and the like, the names can be mutually converted in some embodiments. For example, in one embodiment, the "first slide rail assembly" in other embodiments is referred to as a "second slide rail assembly", and correspondingly, the "second slide rail assembly" in other embodiments is referred to as a "first slide rail assembly".

The designations of "first slide rail mount", "second slide rail mount", "third slide rail mount", "fourth slide rail mount" and "slide rail mount" may be interchanged in some embodiments. For example, in one embodiment, the "first slide rail mount" in other embodiments is referred to as a "second slide rail mount", and correspondingly, the "second slide rail mount" in other embodiments is referred to as a "first slide rail mount".

The names "first slide member", "second slide member", "third slide member", "fourth slide member", and "slide member" may be interchanged in some embodiments. For example, in one embodiment, the "first slide member" in the other embodiments is referred to as a "second slide member", and correspondingly, the "second slide member" in the other embodiments is referred to as a "first slide member".

The fourth slide rail mount 6331 may be made of a rigid material such as plastic, metal, etc. The fourth slide rail mount 6331 may be secured to the side panel 6312, such as the third side panel 6312c, by screwing, plugging, snapping, welding, bonding, etc. In an embodiment, the fourth slide rail mount 6331 may be omitted and the fourth slide rail member 6332 may be disposed directly on the side panel 6312, e.g., the third side panel 6312c.

The threaded connection 6333 may be disposed between a side panel 6312, such as the third side panel 6312c, and the fourth slide rail mount 6331.

In one embodiment, the slide block 63 is restrained in order to achieve this. The sliding base 63 is provided with a first stopper 634. The first limiting member 634 may be disposed on a portion of the second side plate 6312b corresponding to the optical sensor 616, so that when the sliding seat 63 slides along the second guide rail 613 toward the first connecting plate 6111, the sliding seat 63 may receive light emitted by the light receiving unit when reaching a predetermined position, the first limiting member 634 reflects the light to the light receiving unit, the optical sensor 616 generates a control signal and transmits the control signal to the control circuit board 40, and the control circuit board 40 controls the second driving member 6141. So that the slide holder 63 is located at a predetermined position. It is understood that the first position-limiting element 634 may also be disposed at other positions where it can cooperate with the optical sensor 616, such as the third driving element 64.

In addition, in order to limit the sliding seat 63. The sliding base 63 is provided with a second limit member (not shown) which is matched with the first limit switch 15. When the sliding seat 63 moves to a side away from the first connecting plate 6111 and reaches a predetermined position, the second limiting member may be disposed in a groove of the first limiting switch 15, such as a slot optical coupler, to block light transmission between the limiting light emitting portion and the limiting light receiving portion, so that the first limiting switch 15, such as the slot optical coupler, is triggered to generate a control signal and transmit the control signal to the control circuit board 40, and under the control of the control circuit board 40, the operation of the second driving member 6141 is stopped, thereby stopping the movement of the sliding seat 63. It will be appreciated that the second limit stop may also be provided at other locations where it can cooperate with the first limit switch 15, such as the third drive member 64.

It is understood that, the names of the "first limiting member", "the second limiting member", and the "limiting member" may be interchanged in some embodiments. For example, in one embodiment, the "first limiting member" in other embodiments is referred to as a "second limiting member", and correspondingly, the "second limiting member" in other embodiments is referred to as a "first limiting member".

Referring again to fig. 26 and 27, the third driving member 64 is mounted on the sliding seat 63, such as the bottom plate 6311. A side plate 6312 surrounds the third drive member 64. The third driving member 64 may be fixedly connected to the sliding seat 63 by screwing, inserting, fastening, welding, bonding, or the like. Part of the structure of the third driving member 64, such as the output shaft, can pass through the relief hole 6311a and be connected and fixed with the card holder 65. In one embodiment, the third drive member 64 may be an electric motor. The output shaft of the motor may pass through the escape hole 6311a and be connected to the catch 65.

It is understood that the designations "first driver", "second driver", "third driver", and "driver" may be interchanged in some embodiments. For example, in one embodiment, the "first driver" in the other embodiments is referred to as the "second driver", and correspondingly, the "second driver" in the other embodiments is referred to as the "first driver".

The card holder 65 is disposed below the sliding seat 63 and is connected and fixed with the third driving member 64.

Referring to fig. 29 and fig. 30, fig. 29 is a schematic structural view illustrating a connection between the third driving member 64 and the retainer 65 in fig. 26, and fig. 30 is a schematic structural view illustrating a connection between the third driving member 64, the retainer 65 and the pressing member 53 in fig. 2. The card holder 65 may include a card holder body 651. The card holder body 651 may be made of a hard material such as plastic, metal, etc. The retainer body 651 is a rotary body, and the axis of the rotary body is coaxial with the output shaft of the third driving member 64. In one embodiment, the card holder body 651 is a circular disk-shaped structure.

The card holder body 651 is provided with a rib 652 on a side close to the third driving member 64. The rib 652 is formed to be diverged around a portion where the card holder main body 651 is connected to the third driving member 64. The ribs 652 are circumferentially and evenly distributed around the portion where the card holder body 651 and the third driving member 64 are connected.

The adjacent two ribs 652 and the card holder body 651 enclose to form a concave part 653 for placing the detection card. The number of recesses 653 may correspond to the number of heating elements 54. Of course, the number of recesses 653 can be less than the number of heating elements 54. In one embodiment, the number of the recesses 653 can be 6, but the specific number of the recesses 653 can be adjusted according to the actual situation.

The card holder body 651 has a second catching portion 654 provided in the recess 653 to catch the test card. The second locking portion 654 is located at a position of the card holder body 651 near the edge. In one embodiment, the second fastening portion 654 is a groove or a protrusion. The card holder body 651 has a receiving hole 655 in the recess 653 to give way to the test card. In one embodiment, the recess 653 is a groove, which can have a depth equal to the thickness of the test card, such that when the test card is placed in the recess 653, the surface of the test card is flush with the surface of the rib 652 that is away from the holder body 651.

In one embodiment, the body 651 is coupled to the pressing member 53. The rib 652 may be provided with a third fastening portion 6521, so that the third fastening portion 6521 is fastened with the pressing member 53. In an embodiment, the third locking portion 6521 is a convex pillar, so that the convex pillar is disposed in the first locking portion 5314 of the pressing member 53, such as a connecting hole, and is locked with the pressing member 53. In an embodiment, the first fastening portion 5314 may be disposed on the rib 652 and the third fastening portion 6521 may be disposed on the pressing piece 53. In an embodiment, the snap-fit relationship between the third clamping portion 6521 and the pressing member 53 can be replaced by other structures, such as a groove and a boss, a plug-in structure, a snap-in structure, etc. In one embodiment, in order to further enhance the fit relationship between the card holder main body 651 and the pressing member 53, a magnetic force connecting member such as a permanent magnet or an electromagnet may be disposed inside the card holder main body 651 and/or the rib 652 so as to attract the pressing member 53 by using the magnetic force, and the fit relationship between the third fastening portion 6521 and the pressing member 53 is enhanced so that the pressing member 53 can abut against the surface of the detection card to prevent the detection card from being unstably mounted.

In one embodiment, to achieve the positioning of the probe card. The rib 652 may have a positioning hole 6522. When the card holder main body 651 is rotated to a predetermined position, the positioning hole 6522 is opposite to the positioning holes 517 and 576 so as to confirm that the detection card on the card holder main body 651 is at the predetermined position when the light generated by the light generator 615 passes through the positioning holes 517, 576 and 6522, and to confirm that the detection card on the card holder main body 651 is not at the predetermined position when the light generated by the light generator 615 passes through the positioning holes 517 and 576 and does not pass through the positioning hole 6522 when the card holder main body 651 is not rotated to the predetermined position.

In one embodiment, the card holder body 651 is provided with a first positioning member 656 (shown in fig. 31) on a side away from the third driving member 64, so as to position the test card when the test card is carried to the test card receptacle 30, so that the test card is placed at a predetermined position for test of the test card. In an embodiment, the first positioning element 656 is a positioning block, which extends to a side away from the card holder body 651, and a cross-sectional area perpendicular to the extending direction gradually changes and gradually decreases. In one embodiment, the positioning block may be conical.

It is to be understood that the carrier 62 may be located at the fourth position when the card holder body 651 carries the test card to the test card test seat 30.

It is to be understood that the names "first position", "second position", "third position", "fourth position", and "position" may be interchanged in some embodiments. For example, in one embodiment, the "first position" in other embodiments is referred to as the "second position", and accordingly, the "second position" in other embodiments is referred to as the "first position".

Please refer to fig. 31 and fig. 32, which are schematic views of the connection structure of the pressing disc 50 and the carrying assembly 60 in fig. 2. When the pressing plate 50 is connected with the carrying assembly 60, the elements of the carrying assembly 60 except the clamping holder 65 are assembled together, and then the sliding frame 61 of the carrying assembly 60 is placed above the pressing plate 50. The first slide rail 6121 in the carriage 61 is arranged opposite the fourth slide rail 584 of the abutment plate 50 to be mounted together on the first guide rail 1126 of the second leg 1122 of the frame 10. A second slide rail 6122 in the carriage 61 is arranged opposite the first slide rail 581 of the push plate 50 to be mounted together on the first guide rail 1126 of the third leg 1123 of the stand 10. A third slide rail 6123 in the carriage 61 is arranged opposite the second slide rail 582 of the abutment plate 50 to be mounted together on the first guide rail 1126 of the fourth leg 1124 of the frame 10. A fourth slide rail 6124 in the carriage 61 is arranged opposite the third slide rail 583 of the abutment plate 50 so as to be mounted together on the first guide rail 1126 of the first leg 1121 of the frame 10.

It will be appreciated that the holding down disk 50 and the shipping assembly 60 may also be mounted on different first rails 1126. It is of course also possible for part of the first rail 1126 to be mounted only on the abutment plate 50 or the consignment assembly 60.

Next, the card holder 65 of the carrying member 62 in the carrying assembly 60 is placed on the side of the pressing plate 50 away from the sliding frame 61, so that the pressing member 53 is located between the first housing 51 and the card holder 65. The output shaft of the third driving member 64 of the carrying member 62 of the carrying assembly 60 passes through the notch of the pressing plate 50 and is fixedly connected with the card holder 65.

The first hanging lug 5751 of the pressing plate 50 is opposite to and connected with the first pulling member 6171 of the carrying assembly 60. The second hanger 5752 of the pressing plate 50 is opposite to and connected to the second pulling member 6172 of the carrying assembly 60. Specifically, one end of the elastic member 6172b of the first pulling member 6171 is connected to the suspension member 6172a of the first pulling member 6171, and the other end of the elastic member 6172b of the first pulling member 6171 is connected to the first hanging lug 5751 of the pressing plate 50. One end of the elastic member 6172b of the second traction member 6172 is connected to the suspension member 6172a of the second traction member 6172, and the other end of the elastic member 6172b of the second traction member 6172 is connected to the first hanging lug 5751 of the pressing plate 50.

Test card test seat 30

Referring to fig. 33, fig. 33 is an exploded view of the test socket 30 of fig. 2. The detection seat 30 may include a support frame 70 fixed to the rack 10, a support seat 80 installed on the support frame 70, and a detection assembly 90 installed on the support frame 70 and the support seat 80. The supporting base 80 is located below the pressing plate 50 so as to support the test card conveyed by the test card conveying base 20, such as the carrying assembly 60. The detection assembly 90 is electrically connected to the control circuit board 40. When the detection assembly 90 places the detection card on the supporting base 80, a series of detection processes are performed on the detection card by using the excitation light to generate a detection signal, and the detection signal is transmitted to the control circuit board 40.

Support frame 70

Referring to fig. 33, the supporting frame 70 is a frame structure, and can be located at the bottom of the frame 10. The supporting frame 70 may include a base 71 disposed at the bottom of the rack 10 and fixedly connected to the rack 10, and a fixing seat 72 mounted at the top of the base 71.

The base 71 may include a base body 711. The base body 711 may be made of a hard material such as plastic, metal, etc. The whole base main body 711 may have a plate-shaped structure, and may have other structures, which are not described herein. The base 71 may be fixed to the frame 10, such as the legs 112, by plugging, screwing, welding, bonding, snapping, etc. In one embodiment, the base 71 may be secured to the ends of the legs 112.

A fixing groove 712 may be formed at a middle portion of the top of the base main body 711 for receiving and fixing the fixing seat 72. In one embodiment, the fixing groove 712 may be omitted, and the fixing seat 72 may be directly fixed on the base 71.

The base body 711 has a plurality of isolation grooves 713 circumferentially distributed around the fixing groove 712 to cooperate with the sensing member 90. A fixing portion 714 is formed between two adjacent isolation grooves 713 to cooperate with the sensing member 90. The provision of the plurality of isolation grooves 713 may reduce a contact area of the sensing member 90 with the base body 711. In an embodiment, isolation trench 713 may be omitted.

A supporting portion 715 for supporting the supporting base 80 is provided at the top of the base main body 711. The support portion 715 may be fixedly connected to the base main body 711 by means of insertion, screwing, welding, bonding, or fastening. In one embodiment, the supporting portion 715 may be a rod-shaped structure, but the supporting portion 715 may have other structures. In an embodiment, the support portion 715 may be omitted in case there is another structure to support the support base 80.

The top of the base main body 711 is provided with a positioning light receiver 716 opposite to the positioning light generator 615 so as to receive light emitted by the positioning light generator 615, thereby positioning the detection card. The positioning light receiver 716 can be electrically connected to the control circuit board 40, so that after the positioning light receiver 716 receives the light, a signal is generated and transmitted to the control circuit board 40, so that the molecular diagnostic apparatus 100 can confirm that the detection card reaches the predetermined position. In some embodiments, the mounting location of the positioning light generator 615 and the mounting location of the positioning light receiver 716 may be interchanged.

The fixing seat 72 may include a mounting seat 721 disposed in the fixing groove 712. The mounting seat 721 may be made of a rigid material such as plastic, metal, etc. The mounting seat 721 is fixed to the base main body 711 by means of insertion, screwing, welding, adhesion, fastening, or the like. Mounting seat 721 may be used to mount sensing assembly 90.

The top of the mounting seat 721 may be provided with a first fastening plate 722 and a second fastening plate 723 which are vertically arranged. Both the first fastening plate 722 and the second fastening plate 723 can be made of hard materials such as plastics, metals and the like. The first fastening plate 722 and the second fastening plate 723 are disposed in a staggered and parallel manner to cooperate with the detecting assembly 90. The first chucking plate 722 is provided with a fixing hole 7221 to be engaged with the sensing assembly 90. The second chucking plate 723 is provided with a fixing hole 7231 to be engaged with the sensing assembly 90. The extending direction of the fixing hole 7221 is parallel to and does not coincide with the extending direction of the fixing hole 7231 to achieve compact mounting of the detection assembly 90. It is understood that in an embodiment, the mounting seat 721 may be omitted, and the first fastening plate 722 and the second fastening plate 723 may be directly mounted on the base body 711.

The first and second fastening plates 722, 723 are provided with a support plate 724 for supporting the support base 80. The support plate 724 is disposed opposite the mount 721.

In one embodiment, at least a portion of the structure of the support frame 70, such as the base 71, may also be a part of the frame 10. That is, the support bracket 70 may be a part of the frame 10.

Supporting seat 80

Referring to fig. 34, fig. 34 is an exploded view of the support seat 80 of fig. 33. The supporting base 80 can include a supporting base main body 81 mounted on the base 71 such as the supporting portion 715 and the supporting plate 724, a detection chamber assembly 82 mounted on the supporting base main body 81, a sample adding chamber assembly 83 mounted on the supporting base main body 81 and supporting the detection card in cooperation with the detection chamber assembly 82, and a second circuit board 84 disposed on the supporting base main body 81. Wherein the detection chamber assembly 82 may be mounted on the support base 80 in a position opposite to the heating assembly 54, e.g., the first heating member 541, to cooperate with the heating assembly 54, e.g., the first heating member 541. The loading chamber assembly 83 can be mounted on the support base 80 opposite the heating assembly 54, such as the second heating member 542, to cooperate with the heating assembly 54, such as the second heating member 542. The detection chamber component 82 and the sample addition chamber component 83 cooperate together to support and heat the detection card. The detection chamber assembly 82 may also be used to perform excitation light detection on the detection card. The detection cavity component 82 and the sample adding cavity component 83 are electrically connected with the second circuit board 84 together, so that heating control of the detection cavity component 82 and the sample adding cavity component 83 is realized.

Referring to fig. 35 and 36, fig. 35 and 36 are respectively schematic structural views of the supporting seat body 81 in fig. 34 from different viewing angles. The support seat main body 81 may be made of a hard material such as plastic, metal, etc. The supporting seat body 81 may have a plate-like structure as a whole. The top of the supporting seat body 81 can be opened with a placing groove 811 to give way to the card holder 65. The supporting seat body 81 is provided with a fastening hole 812 in the placing groove 811 for matching with the sample addition cavity component 83. The supporting seat body 81 is further provided with a second positioning member 813 in the placing groove 811 to cooperate with the first positioning member 656 to position the detection card. In an embodiment, the second positioning element 813 may be a positioning groove formed in the placing groove 811 of the supporting seat body 81, for positioning the position of the detection card when the first positioning element 656, such as a positioning block, is placed in the second positioning element 813, such as a positioning groove. In one embodiment, the shape of the second positioning member 813, such as a positioning block, may match the shape of the first positioning member 656, such as a positioning slot. It can be understood that the positioning and matching relationship between the supporting seat main body 81 and the card holder 65 is not limited to the matching relationship between the second positioning element 813 and the first positioning element 656, and may also be a matching relationship between a magnet and a magnet, a magnetic force between an electromagnet and an electromagnet, or the like, or may be other matching relationships, which is not described in detail.

It is understood that the names of the "first positioning element", "second positioning element", and "positioning element" may be interchanged in some embodiments. For example, in one embodiment, the "first positioning member" in the other embodiments is referred to as a "second positioning member", and correspondingly, the "second positioning member" in the other embodiments is referred to as a "first positioning member".

The support base main body 81 is provided with a positioning hole 814 in the placement groove 811. The positioning hole 814 can be disposed opposite to the positioning hole 517, the positioning hole 576 and the positioning hole 6522, so that the light generated by the positioning light generator 615 passes through the positioning hole 814, the positioning hole 517, the positioning hole 576 and the positioning hole 6522 and is received by the positioning light receiver 716, thereby positioning the detection card.

The support base body 81 has a plurality of extension grooves 815 uniformly distributed around the circumference of the placement groove 811. The extending grooves 815 are communicated with the placing grooves 811, so that the support base body 81 forms an assembly table 816 between two adjacent extending grooves 815, the detection card can be placed on the assembly table 816, and the extending grooves 815 give way to the detection card, so that the assembly table 816 supports and clamps the detection card.

The support base main body 81 is provided with a receiving hole 817 at the position of the mount 816 so that the detection chamber assembly 82 is mounted in the receiving hole 817.

The supporting seat body 81 is provided with a recessed portion 818 at a position close to one side of the supporting frame 70 and opposite to the mounting table 816 so as to mount the detection chamber assembly 82. Receiving holes 817 are located within the depressions 818. A mounting table 819 is disposed between two adjacent recesses 818 for securing the detection chamber assembly 82.

Referring to fig. 34, the detection chamber assembly 82 is mounted in the support body 81, such as the receiving hole 817 and the recess 818. The detection chamber assembly 82 may include at least one light detecting member 821, the specific number of light detecting members 821 may be one of 1, 2, 3, 4, 5, 6, 8230, 8230for mounting the detection chamber assembly 82 within the recess 818.

Referring to fig. 37, fig. 37 is a schematic structural diagram of the light detecting element 821 in fig. 34. The light detecting member 821 may be disposed in correspondence with a first heating member 541 so that they cooperate to heat a detection card. The light detecting member 821 may include a detecting seat 822 disposed in the supporting seat body 81 such as the accommodating hole 817 and the recess 818, and a first clamping piece 823 for fixing the detecting seat 822 on the supporting seat body 81.

Referring to fig. 37 and 38, fig. 38 is a cross-sectional view of the detection block 822 taken along line XXXVII-XXXVII in fig. 37. The test socket 822 may include a test socket body 8221 disposed in the support socket body 81, such as the recess 818. The test seat body 8221 can be made of a hard material such as plastic, metal, etc. An extension portion 8222 is provided to extend from the detection seat main body 8221 toward the receiving hole 817 such that the extension portion 8222 protrudes into the receiving hole 817. The extending portion 8222 is flush with the surface of the mounting table 816 at the side of the support seat main body 81 where the mounting table 816 is provided, so as to improve the appearance performance of the support seat 80.

The extension portion 8222 is provided with a detection groove 8223 so that a part of the structure of the detection card is placed in the detection groove 8223 at the side of the support base body 81 where the mount 816 is provided.

In one embodiment, the extension 8222 is provided with an isolation slot 8224 at a side of the detection slot 8223 close to the sample addition cavity assembly 83, so that a part of the structure of the detection card is placed in the isolation slot 8224 at a side of the support base body 81 where the mounting stage 816 is provided.

The detection slot 8223 extends from the extension portion 8222 to the detection seat main body 8221 side.

The test seat body 8221 is provided with an excitation fiber channel 8225 in an extending direction of the test slot 8223 for mounting the excitation fiber 8226. The excitation fiber channel 8225 communicates with the detection cell 8223 such that the excitation fiber 8226 emits light, e.g., excitation light, toward the detection cell 8223. In one embodiment, the direction of extension of the excitation fiber channel 8225 may coincide with the direction of extension of the detection slot 8223. In one embodiment, the excitation fiber channel 8225 may extend at an angle with respect to the detection slot 8223, and the angle may range from 0 to 75 °. In one embodiment, excitation fiber channel 8225 is angled from test slot 8223 to the sample loading chamber assembly 83 side.

In one embodiment, the excitation fiber channel 8225 is inclined from the detection groove 8223 to the sample loading cavity assembly 83, the extension direction of the excitation fiber channel 8225 and the extension direction of the detection groove 8223 form an included angle, and the degree of the included angle may be one of 0, 15 °, 30 °, 45 °, 60 ° and 75 °.

The excitation fiber 8226 may include an excitation fiber body 8226a and an excitation fiber joint 8226b disposed at an end of the excitation fiber body 8226 a. Wherein the excitation fiber optic connector 8226b is disposed within the excitation fiber optic channel 8225. The connection of the excitation fiber body 8226a and the excitation fiber stub 8226b forms a fixed position for mating with the first clamping tab 823.

In one embodiment, the excitation fiber 8226, such as the excitation fiber body 8226a, has a diameter of about 2.5mm. Specifically, it may be 2.5mm.

The detection seat main body 8221 is provided with a receiving optical fiber channel 8227 communicating with the detection groove 8223 at a position forming an angle with the extending direction of the detection groove 8223. Receiving optical fiber 8228 is used to receive excitation light from excitation optical fiber 8226 and fluorescence light formed by the excitation light illuminating the test card.

In one embodiment, the receiving fiber channel 8227 may extend at an angle of 0-75 ° with respect to the direction of extension of the sensing slot 8223. In one embodiment, excitation fiber channel 8225 is angled away from sample loading chamber assembly 83 from detection slot 8223.

In one embodiment, the receiving optical fiber channel 8227 is inclined from the detection groove 8223 to a side away from the sample application cavity assembly 83, the extending direction of the receiving optical fiber channel 8227 and the extending direction of the detection groove 8223 form an included angle, and the included angle may be one of 0, 15 °, 30 °, 45 °, 60 ° and 75 °.

In an embodiment, the excitation fiber channel 8225 is inclined from the detection groove 8223 to the sample loading cavity component 83 side, the extending direction of the excitation fiber channel 8225 and the extending direction of the detection groove 8223 form an included angle, and the degree of the included angle may be 45 °. Receiving optical fiber channel 8227 inclines from detection groove 8223 to the side far away from sample adding cavity component 83, the extending direction of receiving optical fiber channel 8227 and the extending direction of detection groove 8223 form an included angle, and the degree of the included angle can be 75 degrees. That is, the extension direction of the receiving fiber channel 8227 may form an angle with the extension direction of the excitation fiber channel 8225, and the degree of the angle may be 120 °. The signal-to-noise ratio of the photo detector 821 can reach over 80 dB.

In one embodiment, the excitation fiber channel 8225 may extend in a direction that coincides with the direction of extension of the detection slot 8223. Receiving fiber channel 8227 is inclined from detection groove 8223 to the side far away from sample addition cavity component 83, the extending direction of receiving fiber channel 8227 and the extending direction of detection groove 8223 form an included angle, and the degree of the included angle can be 60 degrees. That is, the extension direction of the receiving fiber channel 8227 may form an angle with the extension direction of the excitation fiber channel 8225, and the degree of the angle may be 60 °. The signal-to-noise ratio of the light detecting element 821 can reach over 60 dB.

The test socket body 8221 is provided with a heating member receiving groove 8229a at a side where the excitation optical fiber passage 8225 is provided, for receiving a heating member such as a heating resistor. The test socket body 8221 can realize the heating of the test card through a heating device. The heat generating devices in the heating member receiving recess 8229a may be electrically connected to the second circuit board 84 to perform heating under the control of the second circuit board 84.

The detection seat body 8221 is provided with a heating member accommodating groove 8229b at a side close to the sample addition chamber component 83 for accommodating a heating member such as a heating resistor. The test socket body 8221 can realize the heating of the test card through a heating device. The heat generating devices in the heating member receiving recess 8229b may be electrically connected to the second circuit board 84 to perform heating under the control of the second circuit board 84.

In one embodiment, the detecting seat body 8221 can be an integral structure with the supporting seat body 81.

Referring to fig. 37, the first clamping piece 823 can be made of hard material such as plastic and metal. The first clamping piece 823 may include a clamping body 8231. The clamping body 8231 can be in a strip plate-shaped structure, and of course, other structures can be adopted, which are not described in detail. The middle portion of the chucking body 8231 may abut against the side of the test socket 822, such as the test socket main body 8221, where the excitation fiber channel 8225 is provided. Fixing portions 8232 are arranged at two ends of the clamping body 8231, so that the clamping body is respectively fixedly installed on the detection seat 822, such as installation tables 819 at two sides of the detection seat main body 8221, and the clamping body can be fixedly connected in a plugging manner, a buckling manner, a welding manner, an adhesion manner and the like. A plurality of chucking holes 8233 are arranged at an edge of the middle portion of the chucking body 8231 to give way to the excitation optical fiber 8226. The chucking body 8231 forms chucking teeth 8234 between adjacent two chucking holes 8233. The clamping body 8231 abuts against the detection seat 822, for example, one side of the detection seat main body 8221 where the excitation optical fiber channel 8225 is arranged, so that the excitation optical fiber connector 8226b is clamped in the excitation optical fiber channel 8225 by two adjacent clamping teeth 8234, and the excitation optical fiber body 8226a is located between the two adjacent clamping teeth 8234. Fixation of the light detecting element 821 is achieved.

In one embodiment, in order to give way to the heating member receiving recess 8229a, the chucking body 8231 is provided with a through hole 8235 at a position opposite to the heating member receiving recess 8229a, so that the heat generating device protrudes from the through hole 8235 into the heating member receiving recess 8229 a.

Referring to fig. 39 and 40, fig. 39 is a schematic structural view of the sample addition cavity assembly 83 in fig. 34. FIG. 40 is a cross-sectional view of the sample addition chamber assembly 83 of FIG. 39 taken along line XXXIX-XXXIX. The loading chamber assembly 83 can include a support plate 831 fixed to the support plate 724, a support assembly 832 mounted to the support plate 831, and a loading chamber mount 833 mounted to the support assembly 832. The sample adding cavity mounting seat 833 is used for fixing the detection card and heating the detection card. Sample application chamber mount 833 cooperates with a heating element 54, such as second heating element 542, to heat the test card.

The blade 831 can be made of a rigid material such as plastic, metal, etc. The whole body can be in a plate-shaped structure, and certainly can be in other structures, which are not described in detail. The supporting plate 831 can be fixed on the supporting plate 724 in a screwing, inserting, bonding, welding mode and the like. In one embodiment, the supporting plate 831 can be fixed to the supporting seat body 81 by screwing, inserting, bonding, welding, or the like. In one embodiment, the retainer 831 can be omitted and the support member 832 can be directly fixedly coupled to the support plate 724. In an embodiment, in the case that the supporting plate 724 is omitted, the supporting plate 831 may be directly fixed to the first and second fastening plates 722 and 723. In one embodiment, when the supporting plate 724 is omitted, the supporting plate 831 may be fixed to the supporting portion 715.

Support member 832 may include a socket post 8321 disposed on a side of blade 831 remote from support plate 724 and a spring 8322 disposed over socket post 8321. One end of the spring 8322 abuts against the supporting plate 831, and the other end abuts against the sample addition cavity mounting seat 833 so as to adjust the distance between the sample addition cavity mounting seat 833 and the supporting plate 831. In one embodiment, the socket post 8321 may be omitted. In one embodiment, the spring 8322 may be replaced by an elastic member made of other materials. In one embodiment, the socket post 8321 may be a portion of the support 831. In one embodiment, a socket 8321 can be disposed on the sample addition chamber mount 833. In one embodiment, the spring 8322 may be replaced by other elastic members such as plastic, torsion spring, metal strip with elastic deformation, etc.

Sample application cavity mount 833 is used to place the test card. Sample addition chamber mount 833 can include a mount body 8331. The mount body 8331 may be made of a hard heat conductive material such as plastic or metal.

The mount body 8331 is adapted to be disposed in the support seat main body 81, such as the clamping hole 812, to slide in the clamping hole 812. A sample application cavity placement groove 8332 is formed in one side of the mounting seat body 8331 away from the supporting plate 831, and is used for mounting the detection card. The side of the mounting seat body 8331 facing the support component 832 is provided with a socket groove 8333 for abutting against the mounting seat body 8331 when the spring 8322 is placed in the socket groove 8333. In one embodiment, socket slot 8333 may be omitted.

The edge of the mounting seat body 8331 facing the supporting component 832 is provided with a clamping edge 8334, so that the mounting seat body 8331 extends into the clamping hole 812 from the supporting seat main body 81 facing the supporting component 832, and the mounting seat body 8331 is prevented from slipping off the supporting seat main body 81 at the side of the supporting seat main body 81 far away from the supporting component 832.

The mounting seat body 8331 is provided with a heating element accommodating groove 8335 so as to accommodate heating elements such as a heating resistor and the like, so that the mounting seat body 8331 can heat the detection card. The heat generating device may be electrically connected to the second circuit board 84 to perform heating under the control of the second circuit board 84. In one embodiment, the heating element receiving recess 8335 is located between the socket recess 8333 and the sample loading chamber receiving recess 8332.

In order to better heat the detection card, the detection flow is prevented from being influenced by the heated water vapor condensation, and the detection precision is improved. The mounting seat body 8331 is provided with an abutting portion 8336 at an edge of one side of the sample addition chamber housing groove 8332 so as to abut against the detection card. In one embodiment, the abutment 8336 may also be used to position the test card.

Referring to fig. 34, the second circuit board 84 can be electrically connected to the heat generating device in the detection chamber assembly 82 and the heat generating device in the sample application chamber assembly 83 respectively, so as to control the heat generating devices to heat.

The second circuit board 84 can be a ring structure and can be sleeved around the sample adding cavity component 83. The second circuit board 84 can be directly fixed on a side of the supporting seat body 81 close to the supporting frame 70, such as the supporting plate 724, for example, by welding, plugging, snapping, adhering, screwing, etc. In one embodiment, the second circuit board 84 may also be directly fixed to the supporting frame 70, such as the supporting plate 724. In one embodiment, the second circuit board 84 may also be directly fixed on the supporting frame 70, such as the supporting portion 715. In one embodiment, the second circuit board 84 can also be directly fixed to the sample addition chamber component 83, such as the support plate 831.

It is understood that the designations of "first circuit board", "second circuit board", and "circuit board" may be interchanged in some embodiments. For example, in one embodiment, the "first circuit board" in the other embodiments is referred to as a "second circuit board", and accordingly, the "second circuit board" in the other embodiments is referred to as a "first circuit board".

In one embodiment, the second circuit board 84 can be omitted without sharing the working pressure for the control circuit board 40, and the heat generating device in the detection chamber assembly 82 and the heat generating device in the sample adding chamber assembly 83 can be directly electrically connected to the control circuit board 40.

Detection assembly 90

Please refer to fig. 33. The detection assembly 90 may include a light generator 91 mounted on the support frame 70, such as the base body 711, a light receiving assembly 92 mounted on the support frame 70, such as the base body 711, and a detection chamber assembly 82 mounted on the support seat 80, such as the support seat body 81 (i.e., the detection chamber assembly 82 of the support seat 80 described above, and the detection chamber assembly 82 may be a common component of the support seat 80 and the detection assembly 90). The light generator 91 and the light receiving assembly 92 are electrically connected to the control circuit board 40. The light generator 91 is used to generate excitation light, and may generate excitation light under the control of the control circuit board 40. The excitation light may be transmitted to the detection chamber assembly 82 to excite the detection card and generate fluorescence, which may be received by the light receiving assembly 92, and the light receiving assembly 92 may generate a detection signal under the control of the control circuit board 40. The detection signal is transmitted to the control circuit board 40 and the control circuit board 40 processes and generates diagnostic data.

Referring to fig. 33 and 41 together, fig. 41 is a schematic structural diagram of the light generator 91 in fig. 33. The number of the light generators 91 may be 1 or more. The number of the light generators 91 may be specifically one of 2, 3, 4, 5, 6, 82308230; 8230). In an embodiment, the number of light generators 91 may be 2, in particular a first light generator 911 and a second light generator 912.

The first light generator 911 and the second light generator 912 may be fixed on the fixing base 72, such as the mounting base 721, and may be fixed on the fixing base 72, such as the mounting base 721, by means of plugging, welding, screwing, bonding, snapping, and the like. The excitation light output end of the first light generator 911 can pass through the fixing hole 7221 to be fixed on the first clamping plate 722. The excitation light output end of the second light generator 912 may pass through the fixing hole 7231 to be fixed on the second clamping plate 723.

Referring to FIG. 42, FIG. 42 is a cross-sectional view of the first light generator 911 shown in FIG. 41. The light generator 91, such as the first light generator 911, may include a main housing 913 provided with a receiving cavity 9130, the light source 914 installed in the receiving cavity 9130, a first lens module 915 installed in the receiving cavity 9130, a functional membrane set 916 installed in the receiving cavity 9130, and an excitation fiber 917 extending into the receiving cavity 9130. The light source 914 is electrically connected to the control circuit board 40 through a circuit trace, and is used for generating an excitation light under the control of the control circuit board 40. The excitation light can be coupled into the excitation fiber 917 after passing through the first lens module 915 and the functional membrane module 916 in sequence.

The main housing 913 may include a front housing 9131 provided with a first sub-receiving cavity 9131a and a rear housing 9132 fastened to the front housing 9131 and provided with a second sub-receiving cavity 9132a. The first sub-receiving cavity 9131a and the second sub-receiving cavity 9132a constitute a receiving cavity 9130.

The front housing 9131 may include a front housing body 9133 that is snap-fitted to the rear housing 9132 and a front housing cover plate 9134 that covers the side of the front housing body 9133 away from the rear housing 9132.

The front housing body 9133 may be made of a rigid material such as plastic, metal, or the like. The front housing body 9133 provides first sub-receiving cavities 9131a. The front housing body 9133 is provided with first receiving holes 9131b communicating with the first sub-receiving cavities 9131a at a side away from the rear housing body 9132 to give way to the light sources 914.

The front housing cover plate 9134 may be made of a rigid material such as plastic, metal, or the like. The front housing cover plate 9134 can be snap-fit to the front housing body 9133, for example, by welding, snapping, plugging, screwing, etc. The front housing cover plate 9134 may have disposed thereon circuit traces electrically connected to the light sources 914 and a first electrical interface 9141 electrically connected to the circuit traces. The first electrical interface 9141 may be disposed at a side of the front housing cover plate 9134 that is fastened to the front housing cover plate 9134. The first electrical interface 9141 may be electrically connected with the control circuit board 40.

The rear housing 9132 may include a rear housing body 9135 that is snap-fit with the front housing 9131, e.g., the front housing body 9133, and a rear housing cover 9136 that covers the rear housing body 9135 on a side away from the front housing 9131, e.g., the front housing body 9133.

The rear housing body 9135 can be made of a rigid material such as plastic, metal, or the like. The rear case body 9135 is provided with a second sub-receiving chamber 9132a. The rear housing body 9135 may be fixedly attached to the front housing 9131, such as the front housing body 9133, by means of a bayonet, snap, screw, weld, adhesive, or the like.

The rear housing cover 9136 can be made of a rigid material such as plastic, metal, and the like. The rear case cover plate 9136 is provided with a second receiving hole 9136a communicating with the second sub-receiving cavity 9132a for mounting the excitation fibers 917.

The light source 914 may be an LED lamp. In particular to a blue LED lamp with the peak wavelength of 470 nm. Of course, other types of light sources are also possible. The light source 914 may be electrically connected to circuit traces on the front housing cover plate 9134 to make electrical connection with the control circuit board 40. The light source 914 is disposed at a side of the front case cover plate 9134 adjacent to the front case body 9133. The light source 914 is disposed opposite to the first receiving hole 9131 b. In one embodiment, the light source 914 can extend into the first receiving hole 9131b, but can also extend from the first receiving hole 9131b into the first sub-receiving cavity 9131a.

The first lens module 915 is mounted in the first sub-receiving cavity 9131a. The optical axis of the light source can be the same as that of the light source 914, so that the excitation light emitted from the light source 914 can pass through the optical axis, and the beam of the excitation light can be narrowed and the focal length of the excitation light can be reduced, thereby better coupling the excitation light into the excitation fiber 917. The first lens module 915 may include a first lens 9151, a second lens 9152 having the same optical axis as the first lens 9151, and a first fixing ring 9153 for fixing the first lens 9151 and the second lens 9152. The optical axis of the first lens 9151 is the same as the optical axis of the light source 914. The optical axis of the first lens 9151 or the optical axis of the second lens 9152 can be referred to as the optical axis of the first lens module 915.

In an embodiment, the lenses, e.g., the first lens 9151 and the second lens 9152, are both positive lenses, having a positive focal length. The lenses, such as the first lens 9151 and the second lens 9152, may be specifically plano-convex lenses. The plano-convex lens is a positive lens and mainly has the functions of beam expanding, imaging, beam collimation, focusing collimation, beam collimation point light source and the like in an optical system. One of the plane-convex lens incidence surface and the plane-convex lens exit surface is a convex surface, and the other plane is a plane.

The incident surface of the first lens 9151 is a plane, and the exit surface is a convex surface. The incident surface of the second lens 9152 is convex, and the exit surface is planar. The incident surface of the first lens 9151 is disposed opposite to the light source 914. An incident surface of the second lens 9152 is disposed opposite to an exit surface of the first lens 9151. The exit surface of the second lens 9152 is disposed opposite the functional membrane group 916.

The first fixing ring 9153 can be sleeved around the first lens 9151 and the second lens 9152 to fix the first lens 9151 and the second lens 9152. When the first lens module 915 is disposed in the first sub-receiving cavity 9131a, one side of the first locking ring 9153 facing the light source 914 abuts against the front housing 9131, e.g., the front housing body 9133, and one side of the first locking ring 9153 away from the light source 914 abuts against the rear housing 9132, e.g., the rear housing body 9135, so as to fix the first lens module 915 by the front housing 9131 and the rear housing 9132.

It is understood that, in some embodiments, the first lens module 915 may further include other types of lenses, such as a convex lens, a concave lens, and the like, which are not described in detail. The arrangement of the first lens 9151 and the second lens 9152 in the first lens module 915 is not limited to the above arrangement, and may be other arrangements, for example, the first lens 9151 and the second lens 9152 may be directly fixed on the front case 9131, for example, the front case main body 9133, by means of bonding, inserting, snapping, screwing, or the like.

The functional membrane group 916 is used for filtering stray light of the excitation light, adjusting the excitation light and the like. The functional film set 916 may include an optical filter 9161, a light uniformizing sheet 9162 and a second fastening ring 9163 disposed in the second sub-receiving cavity 9132a.

The optical filter 9161 is configured to receive the excitation light transmitted through the first lens module 915, for example, the second lens 9152, so as to filter stray light in the excitation light. The filter 9161 is also called a fluorescent filter. The fluorescence filter is a key optical element applied to life science instruments and biomedicine, and mainly has the functions of selecting and separating excitation light of substances and characteristic waveband spectrums of emitted fluorescence in fluorescence inspection analysis systems of biology, medicine and the like, and then observing the spectrums by a fluorescence microscope. In one embodiment, the filters 9161 may be excitation filters. The Excitation Filter is also called a fluorescence Excitation Filter (Excitation Filter ), and refers to a Filter through which only light with a wavelength for Exciting fluorescence passes in a fluorescence microscope or a fluorescence imaging system, and it is a matter of course that laser (i.e., laser emitted by the light source 914) is directly used as Excitation light.

The filter 9161 is in contact with the rear case 9132, for example, the rear case main body 9135, on the side away from the first lens module 915. One side of the optical filter 9161 close to the first lens module 915, for example, the second lens 9152, abuts against the second fixing ring 9163, so that the optical filter 9161 is fixed to the rear housing 9132. Of course, the optical filter 9161 may be fixed to the rear case 9132, e.g., the rear case body 9135, in other manners, such as by adhesion, insertion, snap, screw, etc.

In one embodiment, the filters 9161 may be excitation filters. The filter 9161 may specifically be an excitation filter of EX450-475 (excitation wavelength 450-475 nm).

The light uniformizing sheet 9162 is used for receiving the excitation light after passing through the optical filter 9161. The dodging sheet 9162, also known as a dodging mirror, diffuser or homogenizer, is used to convert the excitation light into a uniform spot of arbitrary shape.

The light uniformizer 9162 is for receiving the excitation light transmitted through the filter 9161. One side of the dodging sheet 9162 close to the optical filter 9161 is abutted to the optical filter 9161, and one side of the dodging sheet 9162 far away from the optical filter 9161 is abutted to the rear housing 9132 such as a rear housing cover plate 9136, so that the dodging sheet 9162 is fixed. Of course, the light homogenizing sheet 9162 can be fixed on the rear housing 9132 by other methods, such as adhesion, insertion, snap, screw connection, etc.

One end of the excitation fiber 917 can extend into the rear housing 9132, e.g., the second receiving hole 9136a, so that excitation light transmitted through the light uniformizing sheet 9162 is coupled into the excitation fiber 917. Of course, the excitation fibers 917 may also extend into the rear housing 9132, e.g., the second sub-receiving cavity 9132a.

The other end of the excitation fiber 917 can be coupled to at least one excitation fiber 8226, so that the plurality of light detecting elements 821 can detect with the same excitation light, and detection errors caused by different excitation lights can be reduced. In an embodiment, the number of the photo detectors 821 is 6, and the excitation fibers 917 of the first light generator 911 may be coupled to the excitation fibers 8226 of three photo detectors 821. The excitation fibers 917 of the second light generator 912 may be coupled to the excitation fibers 8226 of the three light detectors 821.

In one embodiment, the excitation fiber 917 is about 2.5mm in diameter. Specifically, it may be 2.5mm.

Referring to fig. 43, fig. 43 is an exploded view of the light receiving element 92 in fig. 33. The light receiving assembly 92 may include a light receiving element 921 electrically connected to the control circuit board 40, a light path assembly 922 for light path connection with the detection chamber assembly 82, a first gasket 923 disposed on the light receiving element 921 and for fixing the light path assembly 922, a second gasket 924 disposed on the first gasket 923 and for fixing the light path assembly 922, and a clamping assembly 925 disposed on the second gasket 924 and for fixing the light path assembly 922. Wherein the fluorescent light is transmitted to the light receiving element 921 through the light path member 922. The light receiving element 921 generates a detection signal and transmits the detection signal to the control circuit board 40.

Referring to fig. 44, fig. 44 is a structural diagram of the light receiving element 921 in fig. 33. The light receiving element 921 may include a fixing plate 9211 that is in a ring shape and is arranged with a circuit trace, a second electrical interface 9212 that is disposed on the fixing plate 9211 and is electrically connected with the circuit trace, and a light sensor 9213 that is circumferentially uniformly distributed on the fixing plate 9211 and is electrically connected with the circuit trace. Among them, the light receiving element 921 may be used to receive fluorescence. The light receiving element 921 is electrically connected to the control circuit board 40 through the second electrical interface 9212 to transmit the detection signal generated by the fluorescence trigger to the control circuit board 40.

The fixing plate 9211 may be installed at the fixing portion 714 and the isolation groove 713 on the support bracket 70, for example, the base body 711. The fixing plate 9211 may be disposed spaced apart from the base body 711 at the isolation groove 713. Of course, the fixing plate 9211 may also extend into the isolation groove 713 to form a snap-fit structure with the base body 711. The fixing plate 9211 may be fixed to the base main body 711 at the fixing portion 714 by screwing, fastening, inserting, bonding, welding, or the like. The fixing plate 9211 may surround the fixing groove 712. In one embodiment, the size of the fixing plate 9211 may be similar to, or even the same as, the size of the supporting seat 80, such as the supporting seat body 81, so that the receiving fiber channel 8227 of the supporting seat 80, such as the detection cavity assembly 82, is located above the optical sensor 9213, even directly above the optical sensor 9213, and the difficulty in disposing the receiving fiber 8228 is reduced.

In one embodiment, the light sensor 9213 is a photodiode.

Referring to fig. 43, the optical path component 922 may include at least one sub-optical path component 9221. In an embodiment, the number of the sub optical path assemblies 9221 may correspond to the number of the photosensors 9213 in the light receiving part 921 such that the sub optical path assemblies 9221 correspond to the photosensors 9213 one to one.

Referring to fig. 45 and 46, fig. 45 is a schematic structural diagram of the sub-optical path assembly 9221 in fig. 43. Fig. 46 is a cross-sectional view of the neutron optical path assembly of fig. 45. The sub optical path member 9221 may include a second lens module 9222 transmitting fluorescence to the photosensor 9213 and a receiving fiber 9223 transmitting fluorescence to the second lens module 9222.

The second lens module 9222 may include a third lens 9224 mounted in the first gasket 923, a third snap ring 9225 for fixing the third lens 9224 in the first gasket 923, a fourth snap ring 9226 mounted in the second gasket 924, and a fourth lens 9227 fixed in the second gasket 924 by the fourth snap ring 9226.

It is to be understood that the designations of "first lens", "second lens", "third lens", "fourth lens", and "lens" may be interchanged in some embodiments. For example, in one embodiment, the "first lens" in the other embodiments is referred to as a "second lens", and accordingly, the "second lens" in the other embodiments is referred to as a "first lens".

In one embodiment, the lenses, e.g., the third lens 9224 and the fourth lens 9227, are both positive lenses, having a positive focal length. The lenses such as the third lens 9224 and the fourth lens 9227 may be specifically plano-convex lenses. The plano-convex lens is a positive lens and mainly has the functions of beam expanding, imaging, beam collimation, focusing collimation, beam collimation point light source and the like in an optical system. One of the plane-convex lens incidence surface and the plane-convex lens exit surface is a convex surface, and the other plane is a plane.

The incident surface of the third lens 9224 is a convex surface, and the exit surface is a plane surface. The incident surface of the fourth lens 9227 is a plane, and the exit surface is a convex surface. The incident surface of the third lens 9224 is disposed opposite to the exit surface of the fourth lens 9227. The exit surface of the third lens 9224 is disposed opposite to the photosensor 9213. The incident surface of the fourth lens 9227 is disposed opposite to the receiving optical fiber 9223.

In one embodiment, an Emission Filter (Emission Filter, barrier Filter, emitter) may be further disposed between the third lens 9224 and the fourth lens 9227. The emission filter is a filter for selecting and transmitting fluorescence emitted by the detected substance, except for autofluorescence of the detected substance, light in other ranges is cut off, the wavelength of the emitted light is usually longer than that of the excitation light, and a narrow band filter, a band pass filter or a long wave pass filter can be selected as the emission filter.

In an embodiment, the emission filter may specifically be an excitation filter of EM522-645 (emission wavelength 522-645 nm).

The third snap ring 9225 is provided on the incident surface side of the third lens 9224 to press the third lens 9224 against the first gasket 923, thereby fixing the third lens 9224.

The fourth fixing ring 9226 is disposed on the exit surface side of the fourth lens 9227, so as to press the fourth lens 9227 against the second gasket 924, thereby fixing the fourth lens 9227.

It is understood that the designations "first clamping ring", "second clamping ring", "third clamping ring", "fourth clamping ring" and "clamping ring" may be interchanged in some embodiments. For example, in one embodiment, the "first clamping ring" in other embodiments is referred to as the "second clamping ring", and correspondingly, the "second clamping ring" in other embodiments is referred to as the "first clamping ring".

It is understood that in some embodiments, the second lens module 9222 may further include other types of lenses such as convex lenses, concave lenses, and other functional membranes such as light homogenizing sheets, optical filters, and the like, which are not described in detail. The third lens 9224 and the fourth lens 9227 may be disposed in other manners, such as by adhering, inserting, fastening, and screwing the third lens 9224 to the first gasket 923. For example, the fourth lens 9227 may be directly secured to the second gasket 924 by adhesive, snap, screw, etc.

In one embodiment, the second lens module 9222 provides an emission filter between the third lens 9224 and the fourth lens 9227. The emission filter is a filter for selecting and transmitting fluorescence emitted from the substance to be detected, and light in other ranges is cut off in addition to autofluorescence of the substance to be detected, and the wavelength of the emitted light is usually longer than that of the excitation light, and a band filter, a band pass filter, a long wave pass filter, or the like can be selected as the emission filter.

In one embodiment, the emission filter may be disposed between the first gasket 923 and the second gasket 924 to achieve a fixed connection to the emission filter.

The receiving fiber 9223 can include a receiving fiber body 9223a and a receiving fiber stub 9223b disposed at an end of the receiving fiber body 9223 a. Wherein the receiving fiber connector 9223b is disposed within the first gasket 923 and/or the second gasket 924 to transmit fluorescence to the second lens module 9222, e.g., the fourth lens 9227. The receiving fiber body 9223a forms a fixed position at the connection with the receiving fiber stub 9223b to mate with the clamping assembly 925. In one embodiment, the diameter of the receiving fiber 9223, such as the receiving fiber body 9223a, is about 2.5mm. Specifically, it may be 2.5mm.

One end of the receiving optical fiber 9223 may be connected to one receiving optical fiber 8228 so that the fluorescence is transmitted to the light sensor 9213 through the receiving optical fiber 8228 and the receiving optical fiber 9223.

Referring to fig. 47, fig. 47 is a schematic structural view of the first gasket 923 shown in fig. 43. The first gasket 923 may be made of a hard material such as metal, plastic, etc. The first gasket 923 may have a ring structure, and may have a shape corresponding to the fixing plate 9211, so that the first gasket 923 and the fixing plate 9211 are stacked.

The first gasket 923 can be fixed with the fixing plate 9211 by means of screwing, welding, buckling, bonding, and the like.

The first gasket 923 is provided with a relief notch 9231 to relieve the light receiving element 921, for example, the second electrical interface 9212. When the first gasket 923 is stacked on the fixing plate 9211, the second electrical interface 9212 may be disposed in the recess 9231.

The first gasket 923 circumferentially and evenly distributes a plurality of first filling holes 9232 for installing second lens modules 9222 such as third lenses 9224 and third snap rings 9225. The third lens 9224 may abut against the first gasket 923 on the side facing the photosensor 9213. One side of the third lens 9224, which is far away from the optical sensor 9213, can be abutted against the third snap ring 9225 to realize the fixed connection of the third snap ring 9225 and the first gasket 923 to the third lens 9224.

The first filling hole 9232 may be disposed opposite to the light sensor 9213 so that the light sensor 9213 may receive fluorescence. In one embodiment, the light sensor 9213 may extend into the first fill hole 9232. The emission surface of the third lens 9224 may abut against the first gasket 923. The third fastening ring 9225 can be fixedly connected with the first gasket 923 to realize the connection fixation of the third lens 9224.

Referring to fig. 48, fig. 48 is a structural schematic view of the second gasket 924 in fig. 43. The second gasket 924 can be made of a rigid material such as metal, plastic, etc. The second gasket 924 may be an annular structure, and may specifically conform to the shape of the first gasket 923, such that the first gasket 923 and the second gasket 924 are stacked. The second gasket 924 is provided with an abdicating notch 9241 opposite to the abdicating notch 9231 so as to abdicate the second electrical interface 9212. When the second gasket 924, the first gasket 923 and the fixing plate 9211 are stacked, the second electrical interface 9212 may be disposed in the escape notch 9231 and the escape notch 9241.

The first washer 923 can be fixed with the second washer 924 by screwing, welding, buckling, bonding, etc. In one embodiment, the first gasket 923 can be a unitary structure with the second gasket 924.

A plurality of second filling holes 9242 are circumferentially and uniformly distributed on the second gasket 924 for mounting a second lens module 9222 such as a fourth lens 9227 and a fourth retainer ring 9226. The second filling hole 9242 may be disposed opposite to the first filling hole 9232 so that the light sensor 9213 may receive fluorescence. The fourth lens 9227 may abut against the fourth engaging ring 9226 on the side facing the optical sensor 9213. The side of the fourth lens 9227 away from the optical sensor 9213 can abut against the second gasket 924 to realize the fixed connection of the fourth clamping ring 9226 and the second gasket 924 to the fourth lens 9227. The receiving fiber tabs 9223b of the receiving fibers 9223 can extend from the second gasket 924 away into the second fill hole 9242.

It is to be appreciated that the first gasket 923 and the second gasket 924 can form an assembly housing, and the first filling hole 9232 and the second filling hole 9242 communicate to form a filling hole.

Referring to fig. 43, a clamping member 925 is disposed on a side of the second washer 924 away from the first washer 923 for fixedly receiving the optical fiber 9223. The clamping assembly 925 may include a plurality of circumferentially spaced second clamping tabs 9251. Referring to fig. 49, fig. 49 is a schematic structural view of the second clamping sheet 9251 in fig. 43. The second clamping piece 9251 may be made of a hard material such as plastic, metal, etc. The second grip piece 9251 may include a grip body 9252. The chucking body 9252 may have a strip-shaped sheet structure so as to be disposed on the second gasket 924. The chucking body 9252 is arranged with a plurality of chucking holes 9253 in the extending direction thereof. A gripping hole 9253 extends inwardly from the edge. Between two adjacent clamping holes 9253 is a clamping tooth 9254. The receiving optical fiber connector 9223b can be caught by the latch 9254 in the second filling hole 9242 by attaching the catching body 9252 to the side of the second washer 924 away from the first washer 923 such that the receiving optical fiber body 9223a is located between two adjacent latches 9254. A secure connection between the receiving fiber 9223 and the second washer 924 is achieved.

It is to be understood that the names of "first fastening sheet", "second fastening sheet", and "fastening sheet" may be interchanged in some embodiments. For example, in one embodiment, "first fastening sheet" in other embodiments is referred to as "second fastening sheet", and correspondingly, "second fastening sheet" in other embodiments is referred to as "first fastening sheet".

The clamp body 9252 is provided with a fixing portion 9255 for fixing the clamp body 9252 to the second washer 924. In an embodiment, the fixing portion 9255 may be a through hole, so that the fixing portion 9255 can be inserted through a screw bolt or the like, and then inserted through the second washer 924 and the first washer 923, and then screwed and fixed with the light receiving element 921, such as the fixing plate 9211.

It is understood that the clamping body 9252 can be fixed to the second washer 924 by other means, such as inserting, snapping, etc., which will not be described in detail.

In one embodiment, all of the second clamping tabs 9251 of the clamping assembly 925 are of unitary construction.

Control circuit board 40

Referring again to fig. 1 and 2, the control circuit board 40 may include a first sub-control circuit board 41 fixed to the rack 10, such as the circuit mounting board 13, and a second sub-control circuit board 42 disposed on the top of the rack 10, such as the top plate 111. The first sub-control circuit board 41 is electrically connected to the second sub-control circuit board 42.

The first sub-control circuit board 41 may be mounted on the connection post 1312 of the circuit mounting board 13 in the rack 10 to prevent the first sub-control circuit board 41 from being directly attached to the mounting board body 131. Of course, in an embodiment, when the connecting post 1312 is omitted, the first sub-control circuit board 41 can be directly fixed on the mounting board main body 131.

The first sub-control circuit board 41 may be electrically connected to the frame 10, for example, the first driving member 1212, so as to control the sliding position of the card feeding base 20 relative to the frame 10.

The first sub-control circuit board 41 can be electrically connected to the pressing plate 50, such as the first circuit board 55, so as to control the electromagnetic element 52 to perform magnetic force absorption on the pressing element 53, so as to control the heating element 54 to heat the detection card.

The first sub-control circuit board 41 can be electrically connected to the carriage assembly 60, such as the second driving member 6141, to control the third driving member 64 and the card holder 65 to slide together relative to the sliding frame 61.

The first sub-control circuit board 41 can be electrically connected to the carrying assembly 60, such as the third driving member 64, so as to control the third driving member 64 to drive the card holder 65 to centrifuge the test card.

The first sub-control circuit board 41 can be electrically connected to the detection chamber component 82, such as a heat generating device, so as to control the detection seat 822 to heat the detection card.

The first sub-control circuit board 41 can be electrically connected to the sample application cavity component 83, such as a heating device, so as to control the sample application cavity mounting seat 833 to heat the detection card.

The first sub-control circuit board 41 can be electrically connected to the detection assembly 90, such as the light source 914, so as to control the light source 914 to emit the excitation light.

The first sub-control circuit board 41 may be electrically connected to the detecting member 90, for example, the photo sensor 9213, so as to control the photo sensor 9213 to receive fluorescence.

The first sub-control circuit board 41 can be electrically connected to the frame 10, such as the first limit switch 15, and the detection card transport base 20, such as the optical sensor 616, so as to control the position of the third driving member 64 in the carrying member 62, which drives the card holder 65 to slide.

The first sub-control circuit board 41 may be electrically connected to the frame 10, for example, the first sub-limit switch 162 and the second sub-limit switch 163, so as to control the sliding position of the carrying assembly 60.

The first sub-pcb 41 may be electrically connected to the carrier 62, e.g., the positioning light generator 615, and the support bracket 70, e.g., the positioning light receiver 716, so as to control the position of the test card.

The second sub-pcb 42 may be mounted above the housing 10, e.g. the top plate 111. In an embodiment, when the molecular diagnostic apparatus 100 is provided with a chassis, the second sub-control circuit board 42 may be provided at a position of the chassis opposite to the top plate 111.

The second sub control circuit board 42 may be electrically connected to an output device such as a display, a printer, etc., to output the diagnosis data of the molecular diagnosis device 100 through the output device.

The second sub-control circuit board 42 may be electrically connected to an input device such as a display, a keyboard, a code scanner 14, etc. to input a control command to the molecular diagnostic apparatus 100, for example, the control circuit board 40, via the input device, so as to control the molecular diagnostic apparatus 100 to the test card delivery seat 20 and/or the test card test seat 30 via the control circuit board 40.

In one embodiment, one of the second sub-control circuit board 42 and the first sub-control circuit board 41 may be omitted and integrated on one sub-control circuit board.

Test card 93

Next, a test card will be described, which can be used in the molecular diagnostic device 100 of the above embodiment to complete the test of the sample loaded on the test card, and further process the test card to form diagnostic data.

Referring to fig. 50, fig. 50 is a schematic structural diagram of a detection card according to an embodiment of the present application. Test card 93 is also referred to as a molecular diagnostic centrifugation test card or test card. The detection card 93 may include a body 94 provided with a sample addition cavity, a flow channel, a waste liquid cavity, an isolation cavity and a detection cavity, an isolation layer 95 covering one side of the body 94, and a cover 96 covering the sample addition cavity of the body 94.

Referring to fig. 50, 51 and 52 together, fig. 51 is a cross-sectional view of the detection card 93 taken along line L-L in fig. 50, and fig. 52 is a schematic perspective view of the detection card 93 in fig. 50. The body 94 is made of a rigid material such as plastic or the like. The main body 94 may be made of ABS (Acrylonitrile Butadiene Styrene), PDMS (Polydimethylsiloxane), PC (Polycarbonate), PMMA (Polymethyl methacrylate), PS (General purpose polystyrene), PP (Polypropylene), COC (copolymers of cyclic Olefin), COP (cyclic Olefin Polymer), etc. and may be formed by injection molding, numerical control machine processing, or 3D printing.

The body 94 may be a plate-like structure as a whole. The shape of the fan is roughly a sector, and the fan can be in a sector ring shape, a fan blade shape or a pie shape. For example, the body 94 may be formed as a fan shape having two straight sides and one curved side connected end to end. For example, the body 94 may be formed as a fan-ring shape having a straight edge and an outer circular arc edge, a straight edge, and an inner circular arc edge connected end to end in sequence. Of course, the body 94 may have other shapes, which will not be described in detail.

In one embodiment, the included angle between the two straight lines of the fan-shaped structure of the body 94 may be 40-60 °, the diameter of the inner arc edge may be 10-100 mm, and the diameter of the outer arc edge may be 100-200 mm. By adopting the detection cards 93 with the size structure, at least 6 detection cards can be arranged in the detection plane of the molecular diagnosis equipment 100 to form a circular surface, so that at least 6 detection cards 93 can simultaneously detect, the overall detection efficiency is improved, and the detection requirements on a larger scale can be met.

The body 94 is near the center of the outer arc or the inner arc and has a mounting portion 941 protruding to a side far away from the isolation layer 95. The main body 94 is provided with a sample addition cavity 9411 at a position opposite to the mounting portion 941 and close to one side of the isolation layer 95, and is used for adding a sample to the sample addition cavity 9411. The sample application chamber 9411 is mainly used for pretreating a sample (liquid sample), and the pretreatment may include one or more of chemical treatment, thermal treatment, enzymatic treatment, physical separation, and the like. In some embodiments, the volume of sample addition chamber 9411 is generally 200-2000. Mu.L. The sample loading cavity 9411 can be preloaded with a dry reagent, air-dried/dried in situ, or added as a lyophilized reagent into the sample loading cavity 9411.

The body 94 is provided with a fourth engaging portion 942 at a position away from the isolation layer 95 and close to the outer circular arc edge, so as to cooperate with the carrying component 60, such as the second engaging portion 654. In an embodiment, the fourth fastener 942 may be a protrusion. It can be understood that the positions of the second fastening portion 654 and the fourth fastening portion 942 can be interchanged, and the second fastening portion 654 and the fourth fastening portion 942 can also be fastened and engaged in other manners.

It is to be understood that the names of the "first fastening portion", "second fastening portion", "third fastening portion", "fourth fastening portion", and "fastening portion" may be mutually converted in some embodiments. For example, in one embodiment, "the first trim portion" in the other embodiments is referred to as "the second trim portion", and accordingly, "the second trim portion" in the other embodiments is referred to as "the first trim portion".

The body 94 is provided with a first limiting portion 943 at the edge of one straight line edge close to the outer arc edge and bent towards the side far away from the isolation layer 95, and a second limiting portion 944 at the other straight line edge close to the outer arc edge and protruded towards the side far away from the isolation layer 95. The first position-limiting portion 943 of the body 94 cooperates with the second position-limiting portion 944 to fix the detection card 93, so that the centrifugal processing of the detection card 93 can be smoothly performed, and the body 94 is provided with a waste liquid cavity 9441 at a position close to one side of the isolation layer 95 and opposite to the second position-limiting portion 944. The body 94 is provided with a plurality of plug-in portions along the extending direction of the outer circular arc edge at one side far away from the isolation layer 95 and between the first limiting portion 943 and the second limiting portion 944. Each plug section set may include a first plug section 945 and a second plug section 946. The line between the first inserting part 945 and the second inserting part 946 can pass through the circle center of the outer arc edge. The first mating portion 945 is disposed between the mounting portion 941 and the second mating portion 946. First plug portion 945 and second plug portion 946 are configured to mate with test card test socket 30, such as isolation slot 8224 and test slot 8223.

The body 94 is recessed with an isolation cavity 9451 on a side near the isolation layer 95 and opposite the first plug 945. The isolation cavity 9451 is provided with a fusible isolator. The separator may be switched between a molten state and an unmelted state (typically solid). The separator can be controlled to be in an unmelted state when not being tested by the test card 93, and can prevent the sample from entering the test cavity 9461 (shown in FIG. 52) through the flow channel. In some embodiments, the separator may be a paraffin wax, a microcrystalline wax, a synthetic wax, or a natural wax.

The main body 94 is recessed with a detection cavity 9461 at a side close to the isolation layer 95 and opposite to the second mating member 946. Reagents are disposed in the detection chamber 9461. The isolation chamber 9451 communicates with the detection chamber 9461 on a side adjacent to the isolation layer 95. The insulation within the isolation chamber 9451 may also serve to seal off reagents to prevent reverse entry of reagents into the isolation chamber 9451. The reagents are maintained within the detection chamber 9461. While the separator can be controlled to be in a molten state during the test, the sample can enter the detection chamber 9461 through the loading chamber 9411 to react with the reagent in the detection chamber 9461 to complete the test.

The detection chamber 9461 may be lined with reagents and meltable separators. In some embodiments, the separator may be a paraffin wax, a microcrystalline wax, a synthetic wax, or a natural wax. The insulator is characterized in that the insulator is solid at normal temperature and low temperature, changes into liquid after being heated to specific temperature, and has no inhibition effect on nucleic acid amplification reaction. In some embodiments, the reagents may be dry reagents including one or more of primers and DNA (deoxyribonucleic acid) binding dyes, enzymes, magnesium sulfate, potassium chloride, dNTPs (nucleotide triphosphates) used in the amplification reaction. The dry reagent is loaded into the detection chamber 9461 in a liquid state and formed by a drying process, which includes air drying, oven drying, and freeze drying, at a temperature less than the melting temperature of the separator. In the process of detection and heating, the reagent and the separator are both in liquid state, and because the specific gravity of the separator is smaller than that of the reagent, the separator can be displaced out of the detection cavity 9461 under the action of a centrifugal field, so that the reaction and detection are not affected.

In some embodiments, the insulator is loaded into the detection chamber 9461 in a molten state and formed by natural solidification or freeze-down. When the reagent is not tested, the separator can be controlled to be in an unmelted state, and the reagent can be stored in a sealed and separated mode through the separator. When the test needs to be performed, the separator can be controlled to be in a melting state, for example, the detection card 93 is heated, so that the separator is heated and melted, at this time, the separator can be moved out of the detection cavity 9461 and flow to the separation cavity 9451 under the action of centrifugal force, the sample can enter the detection cavity 9461, and then the separator is solidified again, so as to plug the mouth of the detection cavity 9461, and further form mutual isolation seal for the detection cavities 9461, so that the reaction or the test can be performed between the detection cavities 9461 independently.

The main body 94 is provided with a flow channel 947 on a side close to the isolation layer 95 to communicate the sample-adding chamber 9411 with the isolation chamber 9451.

The body 94 is provided with an abutting groove 948 at a position opposite to the flow passage 947 on a side away from the isolation layer 95 so as to be engaged with the abutting portion 8336. For example, the abutting portion 8336 may be disposed in the abutting groove 948 to heat the portion of the flow channel 947, so as to prevent water vapor from condensing in the flow channel 947, thereby reducing the influence on the subsequent detection process and improving the detection accuracy. In some embodiments, the abutment groove 948 may be omitted.

The isolation layer 95 may have a film-like structure, but may have other structures. The isolation layer 95 may be made of a material such as a compression adhesive, an ultraviolet light curable adhesive, or an optical double-sided adhesive, or may be made of a material similar to the body 94. The isolation layer 95 can be attached to the body 94, and can be specifically fixed in a sealing manner by, for example, ultrasonic welding, laser welding, adhesive sealing, or the like, so as to isolate the flow channel 947, the waste liquid chamber 9441, the isolation chamber 9451, and the detection chamber 9461.

The lid body 96 covers the opening of the sample addition chamber 9411. To seal off the sample application chamber 9411. When a sample needs to be added, the cover 96 can be opened, the sample can be added to the sample addition chamber 9411, and then the cover 96 can be closed. The cover 96 is water-resistant and air-permeable, i.e., can discharge the water vapor generated in the heating process, reduce the air pressure in the test card 93, thereby ensuring good air-permeable effect, and can prevent the escape of pollutants such as aerosol, biomolecules and the like generated in the amplification reaction, thereby avoiding the pollution of detection to personnel and environment.

When the detection card 93 is rotated centrifugally, the sample liquid passes through the sample addition chamber 9411 and the flow channel 947. At this time, the separator is in a solid state, whereby the detection chamber 9461 can be sealed, and the sample liquid cannot flow to the detection chamber 9461. After the sample liquid is heated, the separator is melted by heat and flows toward the detection cavity 9461, so that the flow channel 947 and the detection cavity 9461 can communicate with each other, and the sample liquid can flow into the detection cavity 9461. Because the specific gravity of the separator is less than that of the reagent, the separator can be displaced onto the reagent under the action of the centrifugal field, so that the reaction and detection are not affected, and the detection cavity 9461 can be sealed at the same time.

Some embodiments of the present application further provide a method for detecting based on the above-mentioned detection card 93. This method can be used in the molecular diagnostic apparatus 100 in the above-described embodiment. Referring to fig. 53, fig. 53 is a schematic diagram illustrating a using process of the detection card in fig. 50. The specific steps can be as follows:

step S5301: the sample application chamber receives a sample.

After the sample is added to the sample adding cavity 9411, the sample needs to be heated and pretreated, and the heating mode can be a metal heating block, a heating airflow, an electromagnetic wave (infrared radiation, laser, microwave) or the like. The heating region of the test card can be the region near the sample application chamber. The heating process is carried out by raising the temperature to a specified temperature, such as 90 ℃. And after reaching the specified temperature, preserving heat for 3-10min according to the specified requirement to realize pretreatment. After the pretreatment is completed, the temperature of the sample liquid is lowered to a prescribed temperature, for example, 60 ℃.

Step S5302: the detection card is rotated by centrifugal force to cause the sample to flow through the flow channel to the detection chamber.

And carrying out centrifugal processing on the rotation control of the detection card. For example, the direction of rotation may be controlled to be clockwise, the rotation speed greater than 1000rpm, and the rotation time about 10-15s. Through rotation, the sample liquid can flow to the detection cavity from the sample adding cavity through the flow channel, so that the filling of the sample in the detection cavity can be realized conveniently. And excess sample fluid will enter the waste chamber.

Step S5303: the heating melts the separator to cause the sample to flow into the detection chamber and mix with the reagent in the detection chamber.

It is necessary to heat the region near the detection chamber to a temperature higher than the melting point of the separator, thereby melting the separator and mixing the sample with the reagent in the detection chamber.

Step S5304: the centrifuge is rotated to displace the separator with the sample in the detection chamber and seal the inlet end of the detection chamber.

The rotation of the detection card is controlled again. Wherein, the motor can rotate along the clockwise direction, the rotating speed is more than 1000rpm, and the rotating time is 10-15s. At this moment, because the rotation of detection card for the sample gets into and detects the intracavity, and the aqueous solution that just separates and detect the intracavity takes place the replacement, and the separator shifts to the entry end that detects the chamber, thereby accomplishes the sealed in each detection chamber. And then changing the control parameters of the motor to enable the detection card to rotate clockwise and anticlockwise alternately. For example, the card may be controlled to rotate clockwise at a speed of 3000rpm for a period of 1s, and then rotate counterclockwise at a speed of 3000rpm for a period of 1s, alternately rotating 10 to 15 times. The sample and the reagent in the detection cavity can be mixed completely, dissolved and mixed by the clockwise and anticlockwise alternate rotation mode.

Meanwhile, the isolating body flows to the inlet end of the detection cavity under the action of centrifugal force after being heated and melted so as to seal the inlet end of the detection cavity.

Step S5305: and detecting the mixed mixture.

In this step, an amplification reaction and detection are required. If real-time detection is used, detection and amplification reactions are performed simultaneously, and if endpoint detection is used, detection is performed after amplification is complete. Wherein, the amplification reaction can be realized by the following modes: heating the detection cavity, and controlling the temperature within the range of 60-75 ℃. After reaching the specified temperature, the amplification reaction is finished by heat preservation for 30-60min according to the specified requirements.

The following describes a process of performing a sample test using the molecular diagnostic apparatus 100 and the test card 93, and the specific process is as follows:

the control circuit board 40 performs basic information setting such as the number, type, heating temperature, number of rotation revolutions, operation parameters, etc. of the samples detected by the detection card 93 through an input device. After the basic information is set, the detection of the detection card 93 may be further started through an input device.

A test card 93 loaded with a sample.

Under the control of the control circuit board 40, the first driving element 1212 respectively controls the first lead screw 1221 and the second lead screw 1222 to rotate through the synchronizing assembly 1213, so that the pressing plate 50 drives the carrying assembly 60 to slide on the first guide rail 1126 toward the top plate 111. When the limit plate 5813 triggers the second limit switch 16, for example, the second sub-limit switch 163, the pressing plate 50 reaches a predetermined position. The first driving member 1212 stops operating when the control circuit board 40 receives the signal that the second sub-limit switch 163 is triggered.

Under the control of the control circuit board 40, the second driving member 6141 slides the carrying member 62 along the second guiding rail 613 to the side away from the first connecting plate 6111 through the lead screw 6142. When the carrying member 62, for example, the second limit member, triggers the first limit switch 15, the carrying member 62 reaches a predetermined position. The second driving member 6141 stops operating after the control circuit board 40 receives the signal that the first limit switch 15 is triggered.

The test card 93 loaded with the sample is placed at the recess 653 of the carrier 62, e.g., the card holder 65. The detection card 93, for example, a mounting portion 941 is placed in the accommodation hole 655. The detection card 93, for example, the fourth engaging portion 942 engages with the second engaging portion 654 of the card holder 65, and the placement of one detection card 93 is completed.

The control circuit board 40 performs image scanning on the information identifier on the card holder 65 through the code scanning device 14, and determines whether the detected card 93 is a detection card predetermined by the user, and if not, performs an early warning prompt. If so, the next step is carried out.

Under the control of the control circuit board 40, the third driving member 64 starts to rotate, which drives the card holder 65 to rotate, so that the recess 653 where the next test card 93 can be placed reaches a predetermined position, and then the placement of the next test card 93 is operated.

After the detection cards 93 are placed in the recesses 653 of the holder 65, the detection cards 93 are circumferentially and uniformly distributed on the holder 65. If the number of test cards 93 is not sufficient to be circumferentially disposed on the card support 65, a leveling card may be placed in the recess 653 of the card support 65 so that the leveling card is circumferentially disposed on the card support 65 along with the test cards 93. This completes the placement of the test card 93.

Under the control of the control circuit board 40, the second driving member 6141 slides the carriage 62 along the second guide rail 613 to the side close to the first connecting plate 6111 through the lead screw 6142. When a shipping member 62, such as the first stop 634, triggers the light sensor 616, the shipping member 62 reaches a predetermined position. The second driving member 6141 stops operating after the control circuit board 40 receives the signal triggered by the optical sensor 616.

The carriage 61, for example, the positioning light generator 615 emits light under the control of the control circuit board 40, and the light is transmitted to the card support 65 through the positioning holes 576 and 517.

If the light passes through the positioning hole 6522 of the card holder 65 again, the light is directly transmitted to the positioning light receiver 716 through the supporting base 80 such as the positioning hole 814. The control circuit board 40 will confirm that the detection card is at the predetermined position.

If the light cannot pass through the positioning hole 6522 of the card holder 65. The positioning light receiver 716 cannot receive light from the positioning light generator 615. The control circuit board 40 controls the third driving member 64, so that the third driving member 64 drives the card holder 65 to rotate, the positioning holes 6522 and the positioning holes 576 on the card holder 65 are disposed opposite to each other, and the light passes through the positioning holes 576, 517 and 6522, and is received by the positioning light receiver 716. And then the next step is carried out.

Under the control of the control circuit board 40, the first driving element 1212 respectively controls the first lead screw 1221 and the second lead screw 1222 to rotate through the synchronizing assembly 1213, so that the pressing plate 50 drives the carrying assembly 60 to slide on the first guide rail 1126 to the side away from the top plate 111. When the carrier 62, such as the retainer 65, comes into contact with the support 80, such as the support body 81. The first positioning member 656 on the side of the card holder 65 facing the support seat main body 81 extends into the second positioning member 813, and due to the special structure of the first positioning member 656, the first positioning member 656 is easily arranged in the second positioning member 813, so that the detection card 93 is positioned.

When the retainer 65 abuts against the support 80, for example, the support body 81. The test card 93 will be positioned on the support base 80. The detection card 93 is placed in the sample chamber placement groove 8332 of the sample chamber holder 833, for example, in the mounting portion 941. The test card 93, e.g., first socket 945, will be placed in the light detector 821, e.g., isolation slot 8224. The test card 93, such as the second mating member 946, will be placed in the light detector 821, such as the test slot 8223. The detection card 93, for example, the first stopper 943 is placed in the support base body 81, for example, the extension groove 815, and abuts against the mounting block 816. The detection card 93, e.g., the second stopper portion 944, is to be placed in the support base main body 81, e.g., the extension groove 815, and is to abut against the mounting block 816. At this point, the placement of the detection card 93 on the support base 80 is completed.

When the limiting plate 5813 triggers the second limit switch 16, for example, the first sub-limit switch 162, the pressing plate 50 reaches a predetermined position. The first driving member 1212 stops operating when the control circuit board 40 receives a signal that the first sub-limit switch 162 is triggered. At this time, the pressing plate 50, for example, the heating element 54, abuts against the portion of the detection card 93 where the isolation cavity 9451 and the detection cavity 9461 are provided, and the pressing piece 53, for example, the escape portion 5312 and the sub-escape portion 5313, escapes from the lid 96 of the detection card 93 to clamp the lid 96. At the same time, since the locking member 56 is pressed, the fixing of the pressing member 53 is released.

Under the control of the control circuit board 40, the sample adding cavity component 83, for example, the heating element in the sample adding cavity mounting seat 833 and the heating element in the second heating element 542, heats the detection card 93, for example, the sample adding cavity 9411. The heating pretreatment of the sample is realized.

In the case where the electromagnetic member 52 is present, it is necessary to cancel the electromagnetic force under the control of the control circuit board 40 so that the pressing member 53 is placed above the card holder 65. Specifically, the pressing member 53, for example, the first fastening portion 5314 is sleeved on the third fastening portion 6521 of the card holder 65, so that the pressing member 53 and the card holder 65 are fixed, and in addition, acting forces generated by an electromagnet, a permanent magnet and the like in the card holder 65 are matched, so that the card holder 65 and the pressing member 53 are abutted more tightly. In the case where the pressing member 53 is not provided, the pressing member 53 is fixed only by the electromagnetic member 52.

Under the control of the control circuit board 40, the first driving element 1212 respectively controls the first lead screw 1221 and the second lead screw 1222 to rotate through the synchronizing assembly 1213, so that the pressing plate 50 drives the carrying assembly 60 to slide on the first guide rail 1126 to the side close to the top plate 111. When the limit plate 5813 triggers the second limit switch 16, for example, the second sub-limit switch 163, the pressing plate 50 reaches a predetermined position. The first driving unit 1212 stops operating when the control circuit board 40 receives a signal that the second sub-limit switch 163 is triggered.

Under the control of the control circuit board 40, the third driving member 64 starts to rotate, so as to drive the card holder 65 to rotate, thereby realizing the first centrifugal processing of the detection card. After completion, the detection card is repositioned by the cooperation of the positioning light generator 615 and the positioning light receiver 716.

The detection card 93 is again conveyed to the support 80, for example, the support main body 81, under the control of the control circuit board 40.

Under the control of the control circuit board 40, the heat generating devices in the first heating members 541 are controlled and heated, and the heat generating devices in the photodetecting member 821 are controlled and heated. The secondary heating of the detection card 93 is realized.

The test card 93 is then centrifuged again.

Finally, the detecting card 93 is transported to the supporting base 80, for example, the supporting base main body 81.

Under the control of the control circuit board 40, the light generator 91 emits excitation light to excite the mixture in the detection cavity 9461 of the detection card 93 in the detection slot 8223. The light sensor 9213 in the light receiving unit 92 receives the fluorescence. The detection signals are received and processed by the control circuit board 40 to form diagnostic data.

While the foregoing is directed to the preferred embodiment of the present application, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the application.

Claims (10)

1. A trim card for a molecular diagnostic apparatus, comprising:

the body is provided with a detection cavity, and the detection cavity is used for being installed on a detection seat of the molecular diagnosis equipment; and

a reference membrane disposed within the detection chamber, a composition of the reference membrane including a fluorescence indicator to excite fluorescence under illumination by a light generator of the molecular diagnostic device.

2. The trim card for molecular diagnostic equipment according to claim 1, wherein the body is provided with a mounting portion to be mounted on a sample application chamber mounting seat of the molecular diagnostic equipment, the mounting portion being located on the same side of the body as the detection chamber.

3. The trim card for a molecular diagnostic apparatus according to claim 2, wherein the body is provided with a clamping portion to be clamped with a clamping holder of the molecular diagnostic apparatus, the clamping portion and the mounting portion are located on the same side of the body, and the clamping portion is located between the mounting portion and the detection chamber.

4. The trim card for molecular diagnostic equipment according to claim 2, wherein the body is provided with a limiting portion at two side edges of a straight line where the mounting portion and the detection cavity are located and at one side close to the detection cavity, and the limiting portion and the detection cavity are located at the same side of the body.

5. The trim card for a molecular diagnostic apparatus according to claim 4, wherein the body is provided with a waste liquid chamber at a side away from the mounting portion and at a position set back from one of the stopper portions.

6. The balancing card for molecular diagnostic equipment of claim 5, further comprising an isolation layer, wherein the isolation layer covers one side of the body away from the mounting portion, the isolation layer covers the opening of the waste liquid cavity, and the isolation layer covers the opening of the detection cavity.

7. The trim card for a molecular diagnostic apparatus according to claim 2, wherein the body is provided with a plug portion, the plug portion and the mounting portion are located on the same side of the body, and the plug portion is located between the mounting portion and the detection chamber.

8. The trim card for molecular diagnostic equipment according to claim 2, wherein the body is provided with an abutting groove for engaging with the sample application chamber mounting seat, the abutting groove and the mounting portion are located on the same side of the body, and the abutting groove is located between the mounting portion and the detection chamber.

9. The trim card for molecular diagnostic equipment according to claim 2, further comprising a cover, wherein the body is provided with a sample application cavity at a position opposite to the mounting portion, the cover covers the opening of the sample application cavity, and the cover is located at a side of the body away from the mounting portion.

10. A trim card for a molecular diagnostic apparatus, comprising:

the body is provided with a detection cavity, and the detection cavity is used for being installed on a detection seat of the molecular diagnosis equipment; and

and the fluorescent indicator is arranged in the detection cavity and is used for exciting fluorescence under the irradiation of a light generator of the molecular diagnostic equipment.

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