CN218877973U - Reagent bottle storage device - Google Patents

Abstract

The utility model provides a reagent bottle storage device, which comprises a bottom plate, a door handle, a reagent bin, a bin door, a transmission assembly and a turnover assembly; the transmission assembly is assembled on the bottom plate, the door handle is connected to one end of the transmission assembly, the overturning assembly is assembled at the other end of the transmission assembly, and the bin door is fixed on the overturning assembly and is right opposite to the opening of the reagent bin; when the door handle moves, the driving component drives the overturning component to move in the same direction, the moving distance of the overturning component is greater than that of the door handle, and the overturning component drives the bin door to rotate; when the door handle moves to the first position, the door covers the opening of the reagent bin, and when the door handle moves to the second position, the door is completely opened. When the door handle is pulled outwards or inwards for a short distance, the transmission component drives the bin door to move for a large distance in the same direction, and the turnover component drives the bin door to rotate, so that the bin door can be opened and closed remotely. The whole structure is simple, the assembly time is short, and the cost is low.

Description

Reagent bottle storage device

Technical Field

The utility model belongs to the field of medical equipment, especially, relate to a reagent bottle storage device.

Background

In medical treatment and scientific research field, reagent bottle storage device can save the reagent bottle that is equipped with reagent, and some storage device are provided with the structure that can realize remote switch door to conveniently access reagent bottle reduces reagent and receives the probability of polluting at the access in-process simultaneously. However, some storage devices have simple structures but cannot realize remote door opening and closing, and some storage devices have complex structures, long production and assembly time consumption and high cost although can realize remote door opening and closing.

SUMMERY OF THE UTILITY MODEL

A technical object of the utility model is to provide a reagent bottle storage device aims at solving the problem that the structure is complicated among the prior art, assembly difficulty, with high costs etc.

In order to solve the technical problem, the utility model discloses a reagent bottle storage device, which comprises a bottom plate, a door handle, a reagent bin, a bin door, a transmission assembly and a turnover assembly; the transmission component is assembled on the bottom plate, the door handle is connected to one end of the transmission component, the turnover component is assembled at the other end of the transmission component, and the bin door is fixed on the turnover component and is right opposite to the opening of the reagent bin; when the door handle moves, the transmission assembly drives the turnover assembly to move in the same direction, the moving distance of the turnover assembly is greater than that of the door handle, and the turnover assembly drives the bin door to rotate; when the door handle moves to the first position, the chamber door covers the opening of the reagent chamber, and when the door handle moves to the second position, the chamber door is completely opened.

Further, the transmission component comprises a movable connecting plate which is slidably assembled on the bottom plate and fixedly assembled with the door handle, a movable gear which is assembled on the movable connecting plate, a fixed rack which is meshed with the movable gear and fixedly assembled on the bottom plate, and a movable rack which is meshed with one side of the movable gear, which is far away from the fixed rack, and is slidably connected with the bottom plate, wherein the overturning component is connected with the movable rack.

Furthermore, the transmission assembly further comprises a first fixing plate fixedly connected to the base plate and an adapter plate slidably assembled to the base plate, the fixing rack is fixedly installed on the first fixing plate, and the moving rack is fixedly installed on the adapter plate.

Further, the bottom plate both sides are provided with guide structure respectively, guide structure include with the bottom plate bottom has the slope structure of predetermineeing the angle, connect in the first guide structure of slope structure one end and connect in the second guide structure of the slope structure other end, first guide structure and second guide structure with the bottom plate bottom has different height distance, the upset subassembly include with guide structure sliding connection's location structure.

Further, the guide structure includes a guide groove, the guide groove includes a first guide groove, a second guide groove and an inclined groove connected between the first guide groove and the second guide groove, distances between the first guide groove and the bottom plate and between the second guide groove and the bottom plate are different, and the positioning structure includes a guide wheel slidably connected in the guide groove.

Furthermore, the turnover assembly further comprises a fixed block fixedly connected with the movable rack, a turnover block rotatably connected with the fixed block and fixedly connected with the bin gate, and a connecting plate, wherein one end of the connecting plate is fixedly connected with the turnover block, and the other end of the connecting plate is fixedly connected with the positioning structure.

Further, the upset subassembly still including install in the fixed block with torsion spring in the pivot between the upset piece, the both ends of torsion spring connect respectively in the upset piece, the torsion spring is used for control location structure pastes tightly guide structure.

Furthermore, the turnover assembly further comprises a limiting block fixedly installed on the connecting plate, a groove is formed in the limiting block, and the top side of the guide structure is embedded in the groove.

Further, the reagent bottle storage device further comprises a reagent bottle placing seat and a drainage device, wherein the reagent bottle placing seat and the drainage device are fixedly connected with the bin gate, and the drainage device comprises a drainage groove arranged in the reagent bin, a drainage pipe externally connected with the drainage groove and a waterproof material arranged at the bottom of the reagent bottle placing seat.

Furthermore, the reagent bottle storage device further comprises an air duct device, wherein the air duct device comprises an air duct arranged below the bottom plate, two fans positioned at the air outlet and the air inlet of the air duct, a radiator fixedly arranged at the bottom of the reagent bin and positioned between the two fans, a cover plate covering part of the air duct, and an air hood positioned at the air outlet of the air duct.

Compared with the prior art, the utility model, well a reagent bottle storage device, beneficial effect lies in:

according to the scheme, the door handle is assembled with the bin door through the transmission assembly and the overturning assembly; when the door handle is pulled outwards or inwards for a short distance, the door handle is connected with the transmission assembly, so that when the door handle moves, the transmission assembly is also driven to move in the same direction, and the bin door is connected with the transmission assembly through the overturning assembly, so that when the transmission assembly moves, the transmission assembly drives the bin door to move in the same direction for a large distance, and the overturning assembly also drives the bin door to rotate; can realize remote switch reagent bottle storage device's bin gate through this scheme, this device overall structure is simple, and the assembly is few with time, and is with low costs.

Drawings

In order to illustrate the embodiments of the present invention or the technical solutions in the prior art more clearly, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

Fig. 1 is a schematic view of the whole structure of a reagent bottle storage device according to the present invention at a first viewing angle;

fig. 2 is a schematic view of the overall structure of a reagent bottle storage device at a second viewing angle according to the present invention;

fig. 3 is a schematic view of a first part of the reagent bottle storage device according to the present invention;

fig. 4 is a schematic view of a second part of the reagent bottle storage device according to the present invention;

fig. 5 is a schematic structural diagram of the reagent container including a heat sink according to the present invention;

fig. 6 is a schematic structural view of the air duct device without a heat sink according to the present invention.

In the drawings, each reference numeral denotes: 1. a base plate; 11. a guide structure; 111. a first guide structure; 112. a tilt structure; 113. a second guide structure; 2. a door handle; 3. a reagent bin; 31. a bin gate; 4. a transmission assembly; 41. a movable connecting plate; 42. a movable gear; 43. fixing a rack; 44. moving the rack; 45. a first fixing plate; 46. an adapter plate; 5. a turnover assembly; 51. a positioning structure; 511. a guide wheel; 52. a fixed block; 53. a turning block; 54. a connecting plate; 55. a second fixing plate; 56. a torsion spring; 57. a limiting block; 6. a reagent bottle placing seat; 7. a drainage device; 71. a water discharge tank; 72. a drain pipe; 73. a water-resistant material; 8. an air duct device; 81. an air duct; 82. a fan; 83. a heat sink; 84. a cover plate; 85. the wind cover.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are exemplary and intended to be used for explaining the present invention, and should not be construed as limiting the present invention, and all other embodiments obtained by those skilled in the art without creative efforts based on the embodiments of the present invention belong to the protection scope of the present invention.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", "axial", "circumferential", "radial", and the like, indicate the orientation or positional relationship based on the orientation or positional relationship shown in the drawings, and are only for convenience of description and simplicity of description, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore, should not be construed as limiting the present invention.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present invention, "a plurality" means two or more unless specifically limited otherwise.

Referring to fig. 1-6, the present invention provides a reagent bottle storage device, which comprises a bottom plate 1, a door handle 2, a reagent chamber 3, a chamber door 31, a transmission assembly 4 and a turnover assembly 5; the transmission component 4 is assembled on the bottom plate 1, the door handle 2 is connected to one end of the transmission component 4, the turnover component 5 is assembled on the other end of the transmission component 4, and the bin door 31 is fixed on the turnover component 5 and is right opposite to the opening of the reagent bin 3; when the door handle 2 moves, the transmission component 4 drives the turnover component 5 to move in the same direction, the moving distance of the turnover component 5 is greater than that of the door handle 2, and the turnover component 5 drives the bin door 31 to rotate; when the door handle 2 moves to the first position, the door 31 covers the opening of the reagent chamber 3, and when the door handle 2 moves to the second position, the door 31 is completely opened.

In the scheme, the door handle 2 is assembled with the bin door 31 through a transmission component 4 and a turnover component 5; when the door handle 2 is pulled outwards or inwards for a short distance, the door handle 2 is connected with the transmission component 4, so that when the door handle 2 moves, the transmission component 4 is also driven to move in the same direction, and the bin door 31 is connected with the transmission component 4 through the overturning component 5, so that when the transmission component 4 moves, the transmission component 4 drives the overturning component 5 to further drive the bin door 31 to move in the same direction for a large distance, and the overturning component 5 also drives the bin door 31 to rotate; by the scheme, the long-distance opening Guan Cangmen can be realized, the whole structure is simple, the assembly time is short, and the cost is low.

Further, referring to fig. 1-3, the transmission assembly 4 includes a movable connecting plate 41 slidably mounted on the base plate 1 and fixedly mounted to the door handle 2, a movable gear 42 mounted on the movable connecting plate 41, a fixed rack 43 engaged with the movable gear 42 and fixedly mounted to the base plate 1, and a movable rack 44 engaged with a side of the movable gear 42 away from the fixed rack 43 and slidably connected to the base plate 1, and the flipping assembly 5 is connected to the movable rack 44.

Specifically, the transmission assembly 4 further includes a first slider and a first slide rail slidably connected to the first slider, the first slider is fixedly mounted on the bottom plate 1, the movable connecting plate 41 is fixedly mounted on the first slide rail, the door handle 2 and the movable gear 42 are respectively fixedly mounted at two ends of the movable connecting plate 41, and the movable connecting plate 41, the fixed rack 43 and the movable rack 44 are arranged in parallel relatively.

When the door handle 2 is pulled to move outwards or inwards, the movable connecting plate 41 fixedly mounted on the first slide rail is pulled, and further the movable gear 42 is driven to move in the same direction, because the movable gear 42 is meshed with the fixed rack 43, the movable gear 42 can rotate and move at the same time, and the movable rack 44 is driven to move in the same direction; because the moving rack 44 is connected to the turnover component 5, the moving rack 44 also drives the turnover component 5 to move in the same direction, thereby opening or closing the door 31. Because the movable gear 42 rotates while moving, the moving speed of the movable gear 42 driving the movable rack 44 is greater than the speed of the movable connecting plate 41, and the moving distance of the door 31 is much greater than the moving distance of the door handle 2, thereby realizing the remote opening and closing of the door 31.

In other embodiments, the transmission assembly 4 may further include a first sliding chute fixedly mounted on the bottom plate 1 and a first pulley slidably assembled with the first sliding chute, and the movable connecting plate 41 is fixedly connected with the first pulley. In some embodiments, the transmission assembly 4 may further include a first guide hole fixedly installed on the base plate 1 and a first guide rod inserted into the first guide hole, and the movable connection plate 41 is fixedly installed on the first guide rod.

Further, referring to fig. 1-3, the transmission assembly 4 further includes a first fixing plate 45 fixedly connected to the base plate 1 and an adapter plate 46 slidably assembled to the base plate 1, the fixing rack 43 is fixedly mounted on the first fixing plate 45, and the moving rack 44 is fixedly mounted on the adapter plate 46.

Specifically, the first fixing plate 45 is of a step-shaped structure, wherein one surface of the first fixing plate is fixedly connected with the bottom plate 1, and the other surface of the first fixing plate is stably connected with the fixing rack 43; the transmission assembly 4 further comprises a second slider and a second slide rail slidably connected to the second slider, and the adapter plate 46 is fixedly mounted on the second slider. It should be understood that the structure of the first fixing plate 45 is not limited, for example, the first fixing plate 45 may be a rectangular parallelepiped shape or an L shape, etc.

In other embodiments, the transmission assembly 4 may further include a second sliding chute fixedly mounted on the bottom plate 1 and a second pulley slidably assembled with the second sliding chute, and the movable connecting plate 41 is fixedly connected with the second pulley. In some embodiments, the transmission assembly 4 may further include a second guide hole fixedly installed on the base plate 1 and a second guide rod inserted into the second guide hole, and the movable connection plate 41 is fixedly installed on the second guide rod.

Further, referring to fig. 1-3, two sides of the bottom plate 1 are respectively provided with a guide structure 11, the guide structure 11 includes an inclined structure 112 having a preset angle with the bottom of the bottom plate 1, a first guide structure 111 connected to one end of the inclined structure 112, and a second guide structure 113 connected to the other end of the inclined structure 112, the first guide structure 111 and the second guide structure 113 have different height distances with the bottom of the bottom plate 1, and the turnover assembly 5 includes a positioning structure 51 slidably connected with the guide structure 11.

Specifically, two sides of the bottom plate 1 are respectively provided with a guide structure 11, the guide structures 11 sequentially include a first guide structure 111, an inclined structure 112 and a second guide structure 113, wherein the first guide structure 111 is close to the bin gate 31, the first guide structure 111 and the second guide structure 113 are respectively parallel to the bottom of the bottom plate 1, the height from the first guide structure 111 to the bottom of the bottom plate 1 is smaller than the height from the second guide structure 113 to the bottom of the bottom plate 1, and an angle between the inclined structure 112 and the first guide structure 111 is an obtuse angle; when the door handle 2 is located at the first position, the positioning structure 51 of the flip assembly 5 is located at an end of the first guiding structure 111 away from the second guiding structure 113, and when the door handle 2 is pulled to move to the second position, the positioning structure 51 of the flip assembly 5 moves along the first guiding structure 111, then moves to the inclined structure 112, and then moves to the second guiding structure 113, so as to change a moving track of the positioning structure 51, and when the door handle 2 moves to the second position, the positioning structure 51 is located at an end of the second guiding structure 113 away from the first guiding structure 111, and at this time, the door 31 is completely opened.

Further, referring to fig. 1-3, the guiding structure 11 includes a guiding groove, the guiding groove includes a first guiding groove, a second guiding groove and an inclined groove connected between the first guiding groove and the second guiding groove, the distances between the first guiding groove and the bottom of the bottom plate 1 and the distances between the second guiding groove and the bottom of the bottom plate are different, and the positioning structure 51 includes a guiding wheel 511 slidably connected in the guiding groove.

Specifically, the first guide structure 111 corresponds to a first guide groove, the inclined structure 112 corresponds to an inclined groove, and the second guide structure 113 corresponds to a second guide groove; guide grooves are respectively arranged on two sides of the bottom plate 1 in parallel, the guide grooves are completely hollow grooves, the guide wheels 511 completely penetrate through the guide grooves and are in sliding connection with the guide grooves, and the height from the first guide grooves to the bottom of the bottom plate 1 is smaller than the height from the second guide grooves to the bottom of the bottom plate 1; when the door handle 2 is located at the first position, the guide wheel 511 of the turnover component 5 is located at one end of the first guide groove far away from the second guide groove, and when the door handle 2 is pulled to move to the second position, the guide wheel 511 of the turnover component 5 moves along the first guide groove first, then moves to the inclined groove, and then moves to the second guide groove, so as to change the moving track of the guide wheel 511 of the turnover component 5, and when the door handle 2 moves to the second position, the guide wheel 511 is located at one end of the second guide groove far away from the first guide groove, and at this time, the bin door 31 is completely opened. In other embodiments, the guiding groove may be a groove, and one side of the guiding wheel 511 may be provided with a protruding structure to be coupled with the groove.

In other embodiments, the guiding structure 11 may also be provided with a rod-shaped structure, and the positioning structure 51 of the flipping unit 5 is provided as a hollow ring-shaped structure that is sleeved outside the rod-shaped structure and slidably connected with the rod-shaped structure, so that the guiding structure 11 can also change the moving track of the positioning structure 51. In some embodiments, the first and second guide structures 111 and 113 may not be parallel to the bottom of the base plate 1.

Further, referring to fig. 1-3, the turning assembly 5 further includes a fixing block 52 fixedly connected to the moving rack 44, a turning block 53 rotatably connected to the fixing block 52 and fixedly connected to the bin gate 31, and a connecting plate 54 having one end fixedly connected to the turning block 53 and the other end fixedly connected to the positioning structure 51.

Specifically, the turning block 53 has a fixing structure and a transmission structure, the fixing structure is fixedly connected with the bin gate 31, the transmission structure is fixedly connected with the connecting plate 54, a circular ring structure is integrally arranged at the joint of the fixing structure and the transmission structure, and the ring structure is rotatably connected with the fixing block 52. Because the angle between the inclined structure 112 and the first guiding structure 111 is an obtuse angle, in the process that the door handle 2 moves from the first position to the second position, the positioning structure 51 is driven to move from the first guiding structure 111 to the inclined structure 112, when the positioning structure 51 moves to the inclined structure 112, the positioning structure 51 is lifted, the positioning structure 51 drives the connecting plate 54 to move towards the inclined structure 112, and then the transmission structure of the turning block 53 is driven to be rotationally connected with the fixed block 52, so that the fixed structure of the turning block 53 drives the bin door 31 to turn outwards; likewise, during the movement of the door handle 2 from the second position to the first position, an inward tilting of the door 31 can be achieved.

Specifically, the angle between the tilt structure 112 and the first guide structure 111 controls the angle at which the door 31 is tilted.

Preferably, referring to fig. 1-3, on the side of the bin gate 31 away from the turning block 53 and the fixing block 52, the turning assembly 5 further includes a second fixing plate 55, and includes a connecting plate 54 and a positioning structure 51, which are symmetrically arranged, one end of the connecting plate 54 is fixedly connected with the second fixing plate 55, and the other end is fixedly connected with the positioning structure 51, because the two sides of the bottom plate 1 are symmetrically provided with the guiding structures 11, on the side of the bin gate 31 away from the turning block 53 and the fixing block 52, the positioning structure 51 is also slidably connected with the guiding structure 11, and the guiding structure 11 also plays a role of controlling the moving track of the positioning structure 51. Because the guide structure 11 and the positioning structure 51 are symmetrically arranged on both sides of the bottom plate 1, the stability of the device can be improved in the process of opening and overturning the bin door 31.

Further, referring to fig. 1-3, the tilting assembly 5 further includes a rotating shaft installed between the fixed block 52 and the tilting block 53, two ends of a torsion spring 56 are respectively connected to the tilting block 53, and the torsion spring 56 is used for controlling the positioning structure 51 to cling to the guiding structure 11.

Because in an actual device, a certain gap exists between the positioning structure 51 and the guide structure 11, the torsion spring 56 can be arranged on the rotating shaft between the fixed block 52 and the turning block 53, and two ends of the torsion spring 56 are respectively connected to the turning block 53, when the positioning structure 51 moves from the first guide structure 111 to the inclined structure 112 or moves from the second guide structure 113 to the inclined structure 112, and the turning block 53 turns, the torsion spring 56 generates an acting force on the turning block 53, and under the acting force, the positioning structure 51 can be always attached to the guide structure 11 in the moving process, so as to limit the vertical shaking of the bin door 31.

Further, referring to fig. 1-3, the flipping unit 5 further includes a limiting block 57 fixedly mounted on the connecting plate 54, the limiting block 57 is provided with a groove, and the top side of the guiding structure 11 is embedded in the groove.

Specifically, the top sides of the guide structures 11 on the two sides are respectively provided with the limiting blocks 57, so that the vibration and the shake of the bin door 31 can be better eliminated in the process of opening, closing and overturning the bin door 31, and the stability of the device is improved.

Further, referring to fig. 4 and 5, the reagent bottle storage device further includes a reagent bottle holder 6 fixedly connected to the door 31, and a drainage device 7, wherein the drainage device 7 includes a drainage groove 71 internally disposed in the reagent chamber 3, a drainage pipe 72 externally connected to the drainage groove 71, and a waterproof material 73 disposed on the reagent bottle holder 6.

Specifically, the drainage groove 71 is provided with a straight structure and is connected with a drainage pipe 72; the waterproof material 73 may be waterproof cotton. After the condensed water is generated in the reagent chamber 3, the condensed water can be discharged through the drainage groove 71 and the drainage pipe 72, so that the condensed water is prevented from flowing to the reagent bottle placing seat 6 along the door of the reagent chamber 3 after being accumulated to a certain degree in the reagent chamber 3 and further flowing into the reagent bottle to pollute the reagent, and the waterproof material 73 of the reagent bottle placing seat 6 can also effectively prevent the reagent bottle placing seat 6 from generating the condensed water. In other embodiments, the drainage groove 71 can be arranged in a Chinese character feng shape, a Chinese character hui shape, and the like; the waterproof material 73 may be replaced with rubber plastic or the like other waterproof material 73.

Further, referring to fig. 1 and fig. 6, the reagent bottle storage device further includes an air duct device 8, where the air duct device 8 includes an air duct 81 disposed below the bottom plate 1, two fans 82 located at air outlets and air inlets of the air duct 81, a heat sink 83 fixedly mounted at the bottom of the reagent chamber 3 and located between the two fans 82, a cover plate 84 covering a portion of the air duct 81, and a fan cover 85 located at an air outlet of the air duct 81.

Specifically, the heat sink 83 only needs to be made of an aluminum material with low cost, and the heat sink 83 made of a heat pipe or a copper material does not need to be added. When the air duct 81 and the air hood work, because the radiator 83 is fixedly arranged in the air duct 81, and the air outlet and the air inlet of the radiator 83 are both provided with the fan 82, the heat can be effectively eliminated by the layout; air duct device 8 runs through in the whole device bottom of reagent bottle storage device, compares with prior art, and air duct device 8 of this scheme simple structure, with low costs.

In the foregoing embodiments, the descriptions of the respective embodiments have respective emphasis, and for parts that are not described in detail in a certain embodiment, reference may be made to the related descriptions of other embodiments.

Above is the description to the technical scheme that the utility model provides, to the technical staff in the field, according to the inventive idea, all have the change part on concrete implementation and application scope, to sum up, this description content should not be understood as the restriction of the utility model.

Claims (10)

1. A reagent bottle storage device is characterized by comprising a bottom plate, a door handle, a reagent bin, a bin door, a transmission assembly and a turnover assembly; the transmission component is assembled on the bottom plate, the door handle is connected to one end of the transmission component, the turning component is assembled on the other end of the transmission component, and the bin door is fixed on the turning component and is right opposite to the opening of the reagent bin; when the door handle moves, the transmission assembly drives the turnover assembly to move in the same direction, the moving distance of the turnover assembly is greater than that of the door handle, and the turnover assembly drives the bin door to rotate; when the door handle moves to the first position, the chamber door covers the opening of the reagent chamber, and when the door handle moves to the second position, the chamber door is completely opened.

2. The reagent bottle storage device as claimed in claim 1, wherein the transmission assembly comprises a movable connecting plate slidably mounted on the bottom plate and fixedly mounted on the door handle, a movable gear mounted on the movable connecting plate, a fixed rack engaged with the movable gear and fixedly mounted on the bottom plate, and a movable rack engaged with a side of the movable gear facing away from the fixed rack and slidably connected to the bottom plate, and the turnover assembly is connected to the movable rack.

3. The reagent bottle storage device of claim 2, wherein the transmission assembly further comprises a first fixing plate fixedly connected to the bottom plate and an adapter plate slidably assembled to the bottom plate, the fixing rack is fixedly mounted on the first fixing plate, and the moving rack is fixedly mounted on the adapter plate.

4. The reagent bottle storage device of claim 2, wherein two sides of the bottom plate are respectively provided with a guide structure, the guide structures comprise an inclined structure having a preset angle with the bottom of the bottom plate, a first guide structure connected to one end of the inclined structure and a second guide structure connected to the other end of the inclined structure, the first guide structure and the second guide structure have different height distances with the bottom of the bottom plate, and the turnover assembly comprises a positioning structure slidably connected with the guide structures.

5. The reagent bottle storage device of claim 4, wherein the guide structure comprises a guide slot, the guide slot comprises a first guide slot, a second guide slot and an inclined slot connected between the first guide slot and the second guide slot, the first guide slot and the second guide slot have different distances from the bottom of the bottom plate, and the positioning structure comprises a guide wheel slidably connected in the guide slot.

6. The reagent bottle storage device of claim 4, wherein the turnover assembly further comprises a fixed block fixedly connected with the movable rack, a turnover block rotatably connected with the fixed block and fixedly connected with the bin gate, and a connecting plate having one end fixedly connected with the turnover block and the other end fixedly connected with the positioning structure.

7. The reagent bottle storage device of claim 6, wherein the turning assembly further comprises a torsion spring mounted on the rotating shaft between the fixed block and the turning block, two ends of the torsion spring are respectively connected to the turning block, and the torsion spring is used for controlling the positioning structure to be attached to the guide structure.

8. The reagent bottle storage device of claim 7, wherein the turning assembly further comprises a limiting block fixedly mounted on the connecting plate, the limiting block is provided with a groove, and the top side of the guiding structure is embedded in the groove.

9. The reagent bottle storage device according to any one of claims 1 to 8, further comprising a reagent bottle holder fixedly connected to the door, and a drainage device, wherein the drainage device comprises a drainage channel arranged in the reagent chamber, a drainage pipe externally connected to the drainage channel, and a waterproof material arranged at the bottom of the reagent bottle holder.

10. The reagent bottle storage device of claim 1, further comprising an air duct device, wherein the air duct device comprises an air duct disposed under the bottom plate, two fans located at the air outlet and the air inlet of the air duct, a heat sink fixedly mounted at the bottom of the reagent chamber and located between the two fans, a cover plate covering a portion of the air duct, and an air hood located at the air outlet of the air duct.

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