CN218842186U - PCR fluorescent quantitative analyzer and hot cover assembly thereof - Google Patents

Abstract

The utility model discloses a hot cover component, which comprises a moving frame and a cover plate component arranged on the moving frame; the motion frame comprises an upper motion plate and a lower motion plate, a motion sliding block which is matched with a motion track and the motion track in a sliding mode is arranged between the upper motion plate and the lower motion plate, and the upper motion plate and the lower motion plate can move relatively along the direction of the motion track; the lower motion plate is located between the upper motion plate and the bracket bottom plate, and the cover plate assembly is mounted on the lower motion plate and located on the lower side of the lower motion plate facing the bracket bottom plate. The utility model also discloses a PCR fluorescence quantitative analysis appearance. The utility model discloses a PCR fluorescence quantitative analysis appearance and hot lid subassembly thereof can make the apron subassembly can not produce lateral shifting for hot well cover board at the in-process that covers tightly to ensure that the sample tube of placing in hot well cover board can not produce the slope.

Description

PCR fluorescent quantitative analyzer and hot cover assembly thereof

Technical Field

The utility model belongs to the technical field of medical instrument, specific be a PCR fluorescence quantitative analysis appearance and hot lid subassembly thereof.

Background

At present, the existing analyzers mostly adopt a turnover structure to realize the opening and closing of the thermal cover on the reaction base, and the turnover thermal cover is usually connected with the reaction base by a hinge torsion spring. For example, the chinese patent with publication number CN212152337U discloses a full-automatic PCR hot lid, which comprises a PCR cartridge, wherein the PCR cartridge is further hinged with a PCR hot lid; a fixing frame is welded at the hinged position of the PCR hot cover, a rotating motor is fixed on the fixing frame through a nut, a rotating shaft of the rotating motor is connected with a hinged shaft, and a locking rotating shaft is further fixed on the rotating shaft of the rotating motor in a sleeved mode; the fixing support is characterized in that a fixing bottom plate is further mounted at the lower end of the fixing support, a nut of the fixing bottom plate is fixed on the PCR box body, a fixing support is fixed on the nut of the fixing bottom plate, a locking linear screw rod motor is fixed on the nut of the fixing support, and a locking rod of the locking linear screw rod motor upwards penetrates through the fixing support. This be used for full-automatic PCR hot lid adopts rotation motor and linear screw motor to drive PCR hot lid rotation and locking respectively, though can satisfy the automatic upset of PCR hot lid and the technical purpose of locking to a certain extent, but at the in-process of locking on PCR hot lid, PCR hot lid probably still can have certain relative displacement for reaction base, and this relative displacement can lead to the reagent pipe to produce the slope.

Disclosure of Invention

In view of this, an object of the present invention is to provide a PCR fluorescence quantitative analyzer and a thermal cover assembly thereof, which can prevent the cover assembly from moving laterally relative to the thermal well cover plate during the process of covering tightly, so as to prevent the sample tube placed in the thermal well cover plate from tilting.

In order to achieve the above purpose, the utility model provides a following technical scheme:

the utility model firstly provides a hot cover component, which comprises a moving frame and a cover plate component arranged on the moving frame; the motion frame comprises an upper motion plate and a lower motion plate, a motion sliding block which is matched with a motion track and the motion track in a sliding way is arranged between the upper motion plate and the lower motion plate, and the upper motion plate and the lower motion plate can move relatively along the direction of the motion track; the lower motion plate is located between the upper motion plate and the bracket bottom plate, and the cover plate assembly is mounted on the lower motion plate and located on the lower side of the lower motion plate facing the bracket bottom plate.

Furthermore, a cover plate guide shaft perpendicular to the movement track is arranged between the lower movement plate and the cover plate assembly, the lower movement plate can move relative to the cover plate assembly along the cover plate guide shaft, and a spring positioned between the lower movement plate and the cover plate assembly is sleeved on the cover plate guide shaft.

Furthermore, a reset tension spring is arranged between the upper moving plate and the lower moving plate.

Further, at least one side of the lower motion plate is provided with a motion limiting block for limiting the end positions of the two ends of the lower motion plate moving along the first direction.

Further, both sides of the upper motion plate are respectively provided with a hot cover guide shaft.

Furthermore, a hot cover guide roller is arranged on the hot cover guide shaft.

Further, the cover plate assembly includes a cover plate.

Furthermore, the peripheral edge of the cover plate is provided with heat-insulating rubber surrounding the cover plate for one circle.

Further, a cover plate heating film is arranged on the top surface of the cover plate, and a cover plate heat insulation plate is arranged above the cover plate heating film.

Furthermore, the hot lid subassembly still includes and is used for measuring the temperature sensor of apron heating film temperature, be equipped with the excess temperature protection switch on the power supply circuit of apron heating film.

The utility model also provides a PCR fluorescence quantitative analysis appearance, include as above the hot lid subassembly.

The beneficial effects of the utility model reside in that:

the utility model discloses a hot cover subassembly, through setting up the motion frame components of a whole that can function independently into upper movement plate and lower movement plate, and make upper movement plate and lower movement plate can be along the movement track relative movement on the first direction, thus, when apron subassembly downstream and lid back on hot well cover board, continue to drive upper movement plate syncline below and remove this moment, this in-process, apron subassembly and lower movement plate keep the position motionless on the first direction, upper movement plate moves and drives apron subassembly and lower movement plate downstream for lower movement plate on the first direction, with reinforcing apron subassembly and the lid resultant force between the hot well cover board, keep apron subassembly and hot well cover board unchangeable in the position of first direction simultaneously, can not lead to the sample tube skew.

The utility model discloses still have following technological effect:

through set up apron guiding axle and spring between lower motion board and apron subassembly, after the apron subassembly lid was on hot well cover board, lower motion board continued downstream under the effect of last motion board to compression spring utilizes the spring to exert elasticity to the apron, and the apron subassembly compresses tightly on hot well cover board under this elasticity effect.

Drawings

In order to make the purpose, technical scheme and beneficial effect of the utility model clearer, the utility model provides a explain as follows the attached drawing:

FIG. 1 is a schematic diagram of a PCR fluorescent quantitative analyzer;

FIG. 2 is a schematic view of the thermal cover device in an open position;

FIG. 3 is a schematic view of the thermal cover apparatus in a closed state;

FIG. 4 is an exploded view of a thermal cover module;

fig. 5 is a schematic structural view of the heat cover assembly and the heat cover bracket of the present invention;

FIG. 6 is an exploded view of the kinematic frame;

FIG. 7 is a schematic structural view of an upper sports board;

FIG. 8 is a schematic view of the lower motion plate;

fig. 9 is a schematic structural view of the cover plate assembly.

Description of the reference numerals:

10-a housing; 11-top hole; 12-a thermal cover device;

20-a cap assembly; 21-a top cover; 22-raised areas; 23-a top cover guide shaft;

30-a thermal cover assembly; 31-a kinematic mount; 32-a cover plate assembly; 33-upper motion plate; 34-a lower motion plate; 35-a motion track; 36-a moving slide; 37-a return tension spring; 38-upper tension spring connecting rod; 39-lower spring connecting rod; 40-a top cover guide sliding hole; 41-driving a guide sliding hole; 42-a top cover guide chute; 43-a motion limiting block; 44-a spring; 45-cover plate; 46-heat preservation rubber; 47-cover plate heating film; 48-cover plate heat insulation plate; 49-over-temperature protection switch;

50-a thermal cover holder; 51-a rack floor; 52-a guide rail plate; 53-roof rail; 531-a top cover lower track section; 532-upper track section of the top cover; 533-the top cover connects the track segments; 54-thermal lid track; 541-hot cover upper track section; 542-hot capping the lower track section; 543-the heat cover connects the track sections; 55-a top cover guide shaft; 56-top cover guide rollers; 57-hot lid guide shaft; 58-hot lid guide rollers; 59-thermal well cover plate; 61-thermal cover drive track; 62-thermal lid drive slide; 63-a synchronous pulley; 64-a synchronous belt; 65-a drive motor; 66-opto-coupler sensors; 67-hot lid drive guide bar; 68-a limiting groove; 69-motion limit stops.

Detailed Description

The present invention will be further described with reference to the accompanying drawings and specific embodiments so that those skilled in the art can better understand the present invention and can implement the present invention, but the embodiments are not limited to the present invention.

As shown in fig. 1, the PCR quantitative fluorescence analyzer of the present embodiment includes a housing 10, a top hole 11 is disposed on a top surface of the housing, and a thermal cover device 12 is disposed in the housing 10. The hot lid apparatus 12 of the present embodiment as shown in fig. 2-3 includes a hot lid module and a hot lid holder 50. As shown in fig. 4, the hot lid module of the present embodiment includes a top lid assembly 20 and a hot lid assembly 30. The top cover assembly 20 comprises a top cover 21, a protruding area 22 protruding upwards and matching with the top hole 11 is arranged on the top surface of the top cover 21, and a top cover guide shaft 23 is arranged on the bottom surface of the top cover 21. The hot lid assembly 30 of the present embodiment includes a moving frame 31 and a lid assembly 32 mounted on the moving frame 31. As shown in fig. 5, the hot lid support 50 of the present embodiment includes a support bottom plate 51, and rail plates 52 are respectively disposed on both sides of the support bottom plate 51, and a lid rail 53 and a hot lid rail 54 are respectively disposed on the rail plates 52 corresponding to the lid assembly 20 and the hot lid assembly 30. In this embodiment, for convenience of description, a direction parallel to the holder base plate 51 and the rail plate 52 is referred to as a first direction, and a direction perpendicular to the holder base plate 51 is referred to as a second direction. A top cover guide mechanism is arranged between the top cover 21 and the moving frame 31, and enables the top cover 21 and the moving frame 31 to move relatively in the second direction and move synchronously in the first direction.

Specifically, as shown in fig. 5, the number of the top cover rails 53 of the present embodiment is at least one, each of the top cover rails 53 includes a top cover lower rail section 531 and a top cover upper rail section 532 parallel to the first direction, a distance between the top cover lower rail section 531 and the rack bottom plate 51 is smaller than a distance between the top cover upper rail section 532 and the rack bottom plate 51, and a top cover connecting rail section 533 is arranged between the top cover lower rail section 531 and the top cover upper rail section 452 to connect the top cover lower rail section and the top cover upper rail section. The top cover 21 is provided with top cover guide shafts 55 corresponding to the top cover rails 53. When the number of the top cover rails 53 is at least two, the distance between any two top cover guide shafts 55 in the first direction is equal to the distance between two top cover rails 53 corresponding to the two top cover guide shafts 55 in the first direction, and the distance between any two top cover guide shafts 55 in the second direction is equal to the distance between two top cover rails 53 corresponding to the two top cover guide shafts in the second direction. Specifically, the distance between the two top cover rails 53 in the first direction is the distance between the two top cover rails 53 and the same structural position corresponding to the two top cover rails 53 in the first direction, for example, the distance between the joining position where the top cover lower rail section 531 of the two top cover rails 53 is joined with the top cover connecting rail section 533 in the first direction. Similarly, the distance between the two top cover rails 53 in the second direction is the distance between the top cover lower rail segments 531 of the two top cover rails 53 or the distance between the top cover upper rail segments 532 of the two top cover rails 53. As shown in fig. 5, the top cover rail 53 of the present embodiment is provided with two top cover guide shafts 55, and the top cover guide shafts of the present embodiment are provided with top cover guide rollers 56 in order to reduce resistance when the top cover guide shafts 55 move in the top cover rail 53. Of course, in other embodiments, the number of the top cover rails 53 can be set to 1, 3, or more than 3 as required, and will not be described again. In the embodiment, the distances between the top cover lower rail sections 531 of the two top cover rails 53 and the rack bottom plate 51 are equal, and similarly, the distances between the top cover upper rail sections 532 of the two top cover rails 53 and the rack bottom plate 51 are equal; in other embodiments, the distances between the top cover lower rail segments 531 of the two top cover rails 53 and the support bottom plate 51 may not be equal, and similarly, the distances between the top cover upper rail segments 532 of the two top cover rails 53 and the support bottom plate 51 are not equal; regardless of the positional relationship of the top cover rails 53, the top cover 21 is required to be always kept at a predetermined angular position with respect to the holder base plate 51 (in the present embodiment, the bottom surface of the top cover 21 is parallel to the holder base plate 51) by correspondingly arranging the top cover guide shafts 55 engaged with the top cover rails 53. The two top cover rails 53 of this embodiment are in communication, i.e., the top cover upper rail section 532 of one of the top cover rails 53 is in communication with the top cover lower rail section 531 of the other top cover rail 53. Of course, in other embodiments, the two roof rails 53 may be disconnected from each other.

As shown in fig. 5, the hot lid track 54 of the present embodiment includes a hot lid upper track section 541 and a hot lid lower track section 542 parallel to the first direction, the distance between the hot lid upper track section 541 and the rack base plate 51 is greater than the distance between the hot lid lower track section 542 and the rack base plate 51, and a hot lid connecting track section 543 is disposed between the hot lid upper track section 541 and the hot lid lower track section 542 for connection. Correspondingly, the moving frame 31 of the present embodiment is provided with a hot lid guide shaft 57 slidably engaged with the hot lid track 54, and when the hot lid guide shaft 57 is located at the hot lid lower track segment 542, the top lid guide shaft 55 is located at the top lid upper track segment 532 of the corresponding hot lid track 54; when the hot lid guide shaft 57 is located in the hot lid upper rail section 541, the lid guide shaft 55 is located in the lid lower rail section 531 of the corresponding hot lid rail 54. That is, when the top cover 21 and the moving frame 31 move synchronously in the first direction, and the top cover 21 covers the top hole 11 upwards under the guiding action of the top cover track 53, the moving frame 31 moves downwards under the guiding action of the hot cover track 54 and makes the cover plate assembly 32 cover the hot well cover plate 59; similarly, when the top cover 21 is guided by the top cover rail 53 to open the top hole 11 downward, the moving frame 31 is guided by the hot cover rail 54 to move upward and move the cover plate assembly 32 away from the hot well cover plate 59. That is, in the present embodiment, the bracket bottom plate 51 is provided with the thermal well cover plate 59, and the thermal well cover plate 59 is provided in the area between the thermal cover lower rail segments 542 on both sides of the bracket bottom plate 51. When the hot lid guide shaft 57 is located in the hot lid down track section 542, the lid assembly 32 covers the hot well lid 59, and when the hot lid guide shaft 57 is located in the hot lid up track section 541, the lid assembly 32 is removed from the area of the hot well lid 59. The top hole 11 of the present embodiment is provided in the area between the top cover upper rail sections 532 of the housing 10 on both sides; when the top cover guide shaft 55 is located in the top cover upper track section 532, the raised area 22 is located in the top hole 11 to cover the top hole 11; when the top cover guide shaft 55 is located in the top cover lower rail section 531, the top cover 21 moves out of the area where the top hole 11 is located to open the top hole 11. In a preferred embodiment of the present embodiment, in order to reduce the resistance of the hot lid guide shaft 57 during its movement along the hot lid track 54, hot lid guide rollers 58 are provided on the hot lid guide shaft 57. In addition, the top cover rail 53 and the hot cover rail 54 of the present embodiment are both provided with a rail groove structure on the rail plate 52, and in some other embodiments, the top cover rail 53 and the hot cover rail 54 may also be implemented in various other existing manners, which will not be described again.

Of course, as shown in fig. 5, the hot lid holder 50 of the present embodiment is provided with a hot lid driving mechanism for driving the moving frame 31 to move in the first direction. The thermal cover driving mechanism of the embodiment comprises two thermal cover driving rails 61 parallel to the first direction, a thermal cover driving slider 62 in sliding fit with the two thermal cover driving rails 61 is arranged on the two thermal cover driving rails 61, and a thermal cover driving guide rod 67 located in the second direction is arranged on the thermal cover driving slider 62. The thermal cover bracket 50 of this embodiment is further provided with a power mechanism for driving the thermal cover driving slider 62 to move along the thermal cover driving rail 61, and the power mechanism can be implemented in various manners, such as a belt transmission mechanism, a chain transmission mechanism, a screw lead screw mechanism, a rack and pinion mechanism, and the like. The power mechanism of the embodiment includes synchronous pulleys 63 respectively located at two ends of the hot cover driving rail 61 and a synchronous belt 64 sleeved on the two synchronous pulleys 63, and the hot cover bracket 50 is provided with a driving motor 65 for driving one of the synchronous pulleys 63 to rotate. In a preferred embodiment of the present invention, the holder base plate 51 or the guide rail plate 52 is provided with an optical coupler sensor 66 for detecting the end positions of the two ends of the thermal cover driving slider 62 moving along the thermal cover driving rail 61, and the optical coupler sensor 66 of the present embodiment is provided on the holder base plate 51.

As shown in fig. 6 to 8, the moving frame 31 of the present embodiment includes an upper moving plate 33 and a lower moving plate 34, and a moving rail 35 parallel to the first direction and a moving slider 36 slidably engaged with the moving rail 35 are provided between the upper moving plate 33 and the lower moving plate 34. Specifically, in the present embodiment, the moving rail 35 is installed on the bottom surface of the upper moving plate 33, and the moving slider 36 is installed on the top surface of the lower moving plate 33; of course, in other embodiments, the moving block 36 may be mounted on the bottom surface of the upper moving plate 33, and the moving rail 35 may be mounted on the top surface of the lower moving plate 33, which will not be described in detail. The lower moving plate 34 of the present embodiment is located between the upper moving plate 33 and the bracket bottom plate 51, and the cover plate assembly 32 is mounted on the lower moving plate 34 and located on the side of the lower moving plate 32 facing the bracket bottom plate 51. A return tension spring 37 is disposed between the upper moving plate 33 and the lower moving plate 34 of the present embodiment, and specifically, an upper tension spring connecting rod 38 and a lower tension spring connecting rod 39 for mounting a tension spring are disposed on the upper moving plate 33 and the lower moving plate 34, respectively. By providing the return tension spring 37, the upper moving plate 33 and the lower moving plate 34 are relatively displaced along the moving rail 35 by an external force, and then returned by the return tension spring 37 after the external force disappears.

As shown in fig. 7, the top cover guiding sliding hole 40 which is slidably engaged with the top cover guiding shaft 23 is provided on the upper moving plate 33 of the present embodiment, that is, the top cover guiding mechanism of the present embodiment includes the top cover guiding shaft 23 which is fixedly installed on the bottom surface of the top cover 21 and the top cover guiding sliding hole 40 which is provided on the upper moving plate 33 and is engaged with the top cover guiding shaft 23. In addition, the upper moving plate 33 of the present embodiment is provided with the driving guiding sliding holes 41 slidably engaged with the thermal cover driving guide rods 67, and the driving guiding sliding holes 41 are located in the second direction, so that under the action of the thermal cover driving guide rods 67, the thermal cover driving sliding blocks 62 can drive the upper moving plate 33 to synchronously move along the first direction, and simultaneously, the upper moving plate 33 can also move relative to the thermal cover driving sliding blocks 62 in the second direction.

As shown in fig. 8, in order not to interfere the movement of the upper moving plate 33 relative to the lower moving plate 34 in the first direction along the moving rail 35, the present embodiment is provided with a top cover guide chute 42 engaged with the top cover guide shaft 23 on the lower moving plate 34, and the length direction of the top cover guide chute 42 is parallel to the first direction. In a preferred embodiment of the present embodiment, at least one side of the lower moving plate 34 is provided with a movement stopper 43 for limiting the positions of both end portions thereof moving in the first direction. In this embodiment, the motion limiting blocks 43 are disposed on both sides of the lower motion plate 34, and correspondingly, the guide rail plate 52 is disposed with a limiting structure engaged with the motion limiting blocks 43, the limiting structure of this embodiment is a limiting groove 68 disposed on the guide rail plate 52, and both side walls of the limiting groove 68 are engaged with the motion limiting blocks 43 to limit the end positions of both ends of the lower motion plate 34 moving along the first direction. In this embodiment, the receding groove for the receding hot cover driving slider 62 provided on the guide rail plate 52 is integrally communicated with the limiting groove 68, but in other embodiments, the receding groove and the limiting groove 68 may be separately provided, which will not be described in detail. For better limit fit with the motion limit stopper 43, the motion limit stopper 69 is further provided on the rail plate 52 in this embodiment, which will not be described in detail.

Further, a cover guiding shaft is disposed between the lower moving plate 34 and the cover assembly 32, the lower moving plate 34 and the cover assembly 32 can move in the second direction along the cover guiding shaft, and the cover guiding shaft is sleeved with a spring 44 disposed between the lower moving plate and the cover assembly. As shown in fig. 9, the cover plate assembly 32 of the present embodiment includes a cover plate 45, a heat insulating rubber 46 surrounding the periphery of the cover plate 45 is disposed around the periphery of the cover plate, a cover plate heating film 47 is disposed on the top surface of the cover plate 45, and a cover plate heat insulating plate 48 is disposed above the cover plate heating film 47. The hot lid assembly of this embodiment further includes a temperature sensor for measuring the temperature of the lid heating film 47, and an over-temperature protection switch 49 is provided on the power supply circuit of the lid heating film 48.

The operation of the thermal cover device 12 of the present embodiment is as follows: in the open state, the top cover guide shaft 55 is located at the end of the top cover lower track section 531, the hot cover guide shaft 57 is located at the end of the hot cover upper track section 541, and the top cover 21 and the top hole 11 are completely staggered at the moment, so that the top hole 11 is completely opened; the cover plate assembly 32 is completely out of alignment with the thermal well cover plate 59 and can be used to place sample tubes into the thermal well cover plate 59 or remove sample tubes from the thermal well cover plate 59 through the top opening 11, as shown in fig. 2. Starting a driving motor 65 to drive a synchronous pulley 63 to rotate, driving a hot cover driving sliding block 62 to move along a hot cover driving rail 61 to the right side shown in fig. 1 by using a synchronous belt 64, driving a moving frame 31 and the hot cover driving sliding block 62 to synchronously move along a first direction under the action of a hot cover driving guide rod 67, and driving a top cover 21 to move along the first direction by the moving frame 31 under the action of a top cover guide shaft 23; when the hot lid guide shaft 57 moves to the hot lid connecting rail segment 543, the hot lid guide shaft 57 moves obliquely downward under the guiding action of the hot lid connecting rail segment 543, and in this process, the lid assembly 32 moves obliquely downward along with the moving frame 31 and covers the hot well lid 59, and at this time, the closing force between the lid 45 and the hot well lid 59 is small; the upper moving plate 33 is continuously driven to move obliquely downward along the hot cover connecting track segment 543, under the limiting action of the movement limiting block 43, the lower moving plate 34 does not move along the first direction with the upper moving plate 33, that is, at this time, relative movement is generated between the upper moving plate 33 and the lower moving plate 34 along the moving track 35 in the first direction, and the return tension spring 37 is lengthened, and under the driving action of the upper moving plate 33, the lower moving plate 34 moves downward along the second direction and compresses the spring 44, so that the cover closing force between the cover plate assembly 32 and the hot well cover plate 59 is enhanced; when the hot lid guide shaft 57 moves to the hot lid down track segment 542, the spring 44 is compressed to the shortest distance and the cover plate 45 closes the hot well cover plate 59. In the process that the moving frame 31 drives the top cover 21 to move along the first direction, when the top cover guide shaft 55 moves to the top cover connecting track section 533, the top cover 21 is located below the top hole 11 at this time, the top cover guide shaft 55 moves obliquely upward along the top cover connecting track section 533, under the action of the top cover guide shaft 23, the top cover 21 moves synchronously along the first direction relative to the moving frame 31 and generates relative movement in the second direction, when the top cover guide shaft 55 moves to the top cover upper track section 532, the top cover 21 reaches the uppermost position, and the protruding area 22 is embedded into the top hole 11 to cover the top hole 11. When the top cover guide shaft 55 moves to the top cover upper track section 532 and the hot cover guide shaft 57 moves to the hot cover lower track section 541, the hot cover apparatus 12 is in a closed state, as shown in fig. 3.

Specifically, the movement process of the thermal cover device 12 from the closed state to the open state is opposite to the movement process of the thermal cover device 12 from the open state to the closed state, and the only difference is that after the thermal cover guide shaft 57 moves into the thermal cover upper track section 541, the upper moving plate 33 and the lower moving plate 34 are automatically reset to the initial state under the pulling force of the reset tension spring 37, which will not be described in detail.

The above-mentioned embodiments are merely preferred embodiments for fully illustrating the present invention, and the scope of the present invention is not limited thereto. Equivalent substitutes or changes made by the technical personnel in the technical field on the basis of the utility model are all within the protection scope of the utility model. The protection scope of the present invention is subject to the claims.

Claims (11)

1. A thermal cover assembly, comprising: the device comprises a moving frame and a cover plate assembly arranged on the moving frame; the motion frame comprises an upper motion plate and a lower motion plate, a motion sliding block which is matched with a motion track and the motion track in a sliding way is arranged between the upper motion plate and the lower motion plate, and the upper motion plate and the lower motion plate can move relatively along the direction of the motion track; the lower motion plate is positioned between the upper motion plate and the bracket bottom plate, and the cover plate assembly is mounted on the lower motion plate and positioned at the lower side of the lower motion plate facing the bracket bottom plate.

2. The hot lid assembly as claimed in claim 1, wherein: a cover plate guide shaft perpendicular to the movement track is arranged between the lower movement plate and the cover plate assembly, the lower movement plate can move relative to the cover plate assembly along the cover plate guide shaft, and a spring positioned between the lower movement plate and the cover plate assembly is sleeved on the cover plate guide shaft.

3. The hot lid assembly as claimed in claim 1, wherein: and a reset tension spring is arranged between the upper moving plate and the lower moving plate.

4. The hot lid assembly as claimed in claim 1, wherein: at least one side of the lower motion plate is provided with a motion limiting block used for limiting the end positions of two ends of the lower motion plate moving along the first direction.

5. The hot lid assembly as claimed in claim 1, wherein: and hot cover guide shafts are respectively arranged on two sides of the upper moving plate.

6. The thermal lid assembly of claim 5, wherein: and the hot cover guide shaft is provided with a hot cover guide roller.

7. The hot lid assembly as claimed in claim 1, wherein: the cover plate assembly includes a cover plate.

8. The thermal lid assembly of claim 7, wherein: the peripheral edge of the cover plate is provided with heat-insulating rubber surrounding the cover plate for one circle.

9. The hot lid assembly as claimed in claim 7, wherein: the top surface of the cover plate is provided with a cover plate heating film, and a cover plate heat insulation plate is arranged above the cover plate heating film.

10. The hot lid assembly as claimed in claim 9, wherein: the hot cap subassembly still includes and is used for measuring the temperature sensor of apron heating film temperature, be equipped with the excess temperature protection switch on the power supply circuit of apron heating film.

11. A PCR fluorescence quantitative analyzer is characterized in that: comprising a hot lid assembly according to any of claims 1-9.

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