CN113441201A - Clinical laboratory's sample storage device - Google Patents

Abstract

The invention discloses a clinical laboratory sample storage device, which comprises a cabinet body and a cabinet door, wherein a storage box is arranged in a working cavity, a storage cavity is arranged in the storage box, a storage rack is arranged in the storage cavity, a rotating motor is arranged on the lower wall of the working cavity, a supporting rotating shaft of the rotating motor extends into the working cavity and then is fixedly connected with the storage box, damping blocks with damping cavities are fixedly connected to the end surfaces of the two sides of the storage rack, friction plates are respectively arranged on the upper inner wall and the lower inner wall of each damping cavity, a supporting connecting plate with the upper end and the lower end respectively jointed with the friction plates is arranged in each damping cavity, a first damping spring is arranged between the end surface of the supporting connecting plate close to one side of the storage rack and the end wall of the damping cavity close to one side of the storage rack, a supporting shaft is fixed on the end surface of the supporting connecting plate far away from one side of the storage rack, the supporting shaft penetrates through the damping cavities and is fixedly connected with the side wall of the storage cavity, and a second damping spring is arranged between the end surface of the damping block far away from one side of the storage rack and the side wall of the storage cavity, the second damping spring sleeve is established on the back shaft, can reach and carry out the effect of stably depositing to the detection appearance mark of depositing.

Description

Clinical laboratory's sample storage device

Technical Field

The invention belongs to the technical field of medical treatment, and particularly relates to a sample storage device for a clinical laboratory.

Background

The current clinical laboratory's sample storage device includes the cabinet body and cabinet door usually, and the internal working chamber that is equipped with of cabinet is equipped with the case of depositing in the working chamber, deposits the chamber and is equipped with a plurality of storage racks, and the inspection sample is placed on storage rack. In order to place the test samples conveniently, the storage box is generally set to be in a rotatable mode, but two problems are brought about, one problem is that the test samples in the storage rack are necessarily vibrated in the rotating process of the storage box, and the other problem is that a little vibration is generated in the process of placing the test samples in the storage rack, so that the stability of storing the test samples is not facilitated.

Disclosure of Invention

Technical problem to be solved

The invention aims to provide a clinical laboratory sample storage device.

(II) technical scheme

In order to solve the technical problems, the invention provides a clinical laboratory sample storage device, which comprises a cabinet body with a working cavity and a cabinet door for closing the working cavity, wherein a storage box is arranged in the working cavity, the storage box is internally provided with a storage cavity with an opening facing one side, the storage cavity is provided with a plurality of storage racks, the storage box is rotatably arranged in the working cavity, a rotating motor is fixedly arranged in the lower wall of the working cavity, a supporting rotating shaft of the rotating motor extends into the working cavity and then is fixedly connected with the storage box, the end surfaces of the two sides of each storage rack are fixedly connected with a damping block with a damping cavity, the upper inner wall and the lower inner wall of each damping cavity are respectively provided with a friction plate, a supporting connecting plate with the upper end and the lower end respectively jointed with the friction plate is arranged in each damping cavity, a first damping spring is arranged between the end surface of the supporting connecting plate close to one side of the storage rack and the end surface of the damping cavity close to one side of the storage rack, and a supporting shaft is fixed on the end surface of the supporting connecting plate far away from one side of the storage rack, the back shaft runs through behind the shock attenuation chamber with deposit chamber lateral wall fixed connection, the snubber block is kept away from storage rack a side terminal surface and is deposited and be equipped with second damping spring between the chamber lateral wall, and second damping spring overlaps and establishes on the back shaft.

Wherein, the axes of the first damping spring and the second damping spring are overlapped.

Wherein, a friction force for resisting relative movement exists between the support connecting plate and the friction plate.

The storage rack is a U-shaped rack with an upward U-shaped opening, and a placing cavity with an upward opening is formed in the storage rack.

The working cavity is located and deposits the chamber opening and be equipped with the outside upset chamber of opening towards one side, and the upside rotates between two walls in the upset intracavity and is equipped with the upset back shaft, cabinet door and upset back shaft fixed connection.

Wherein, the cabinet door is kept away from working chamber one side terminal surface and is equipped with the upset handrail.

Wherein, the work intracavity is equipped with the mobile detection board, the mobile detection board is kept away from and is deposited the fixed flexible pipeline that is equipped with in case side end face top, be equipped with the intercommunication pipeline that runs through the mobile detection board in the flexible pipeline, the internal intercommunication pipeline department that corresponds of cabinet is equipped with the fan chamber with the intercommunication pipeline intercommunication, the fan intracavity rotates and is equipped with the rotation fan, be equipped with the control chamber in the fan chamber upper wall, the fixed control panel that is equipped with of control chamber inner wall, the intercommunication is equipped with the admission line between work chamber lateral wall is kept away from to control chamber lower wall and fan chamber, control chamber lateral wall intercommunication is equipped with the outside air pipe of opening.

The movable detection plate is fixed with a movable shaft far away from one side end face of the storage box, a movable cavity is arranged in one side wall of the working cavity close to the movable detection plate, a movable supporting seat capable of moving is arranged in the movable cavity, a supporting groove is formed in the movable supporting seat, and the movable shaft stretches into the supporting groove.

And a telescopic spring is arranged between the moving shaft and the supporting groove.

The lower end face of the movable supporting seat is fixedly provided with a guide sliding rod, a supporting shaft and a rotary drum fixedly connected with the supporting shaft are rotatably arranged on the lower side between the two walls of the movable cavity, the supporting shaft is connected with a rotary drum motor, and a guide sliding chute matched and connected with the guide sliding rod is fixedly arranged on the outer circular surface of the rotary drum.

(III) advantageous effects

Compared with the prior art, the vibration reduction device has the advantages that the support connecting plate is fixedly connected through the support shaft in the rotating process of the storage box, the vibration reduction block is driven to move through the stable support of the support connecting plate and the friction plate, at the moment, after the primary vibration reduction is carried out through the first damping spring, the surface of the friction plate is rough and is in friction connection with the upper side and the lower side of the support connecting plate, the vibration is further reduced, meanwhile, the vibration input in the moving process of the storage box is reduced through the connection of the second damping spring, and the purpose of stably storing the stored detection sample label is achieved.

Drawings

FIG. 1 is a schematic diagram of a clinical laboratory sample storage device according to an embodiment of the present invention;

FIG. 2 is a schematic sectional view A-A of FIG. 1;

FIG. 3 is an enlarged schematic view at B of FIG. 1;

FIG. 4 is an enlarged schematic view at C of FIG. 2;

FIG. 5 is an enlarged schematic view at D of FIG. 1;

FIG. 6 is an enlarged schematic view at E in FIG. 2;

description of reference numerals: 11 is a cabinet body; 12 is a working cavity; 13 is a storage box; 14 is a storage rack; 15 is a placing cavity; 16 is a storage cavity; 17 is a supporting rotating shaft; 18 is a rotating motor; 19 is a fan cavity; 20 is a rotary fan; 21 is a power rotating shaft; 22 is a fan motor; 23 is a telescopic pipeline; 24 is a communicating pipeline; 25 is a mobile detection plate; 26 is an air inlet pipeline; 27 is a control panel; 28 is a control cavity; 29 is a ventilating duct; 30 is an air outlet channel; 31 is a switching cavity; 32 is a switching threaded shaft; 33 is a switching motor; 34 is a first pull rope; 35 is a turnover cavity; 36 is a turnover supporting shaft; 37 is a cabinet door; 38 is a turning handrail; 40 is a movable closing plate; 41 is a movable closed cavity; 42 is a connecting spring; 43 is a pipeline through cavity; 44 is a telescopic connecting pipeline; 45 is a communication port; 46 is an air inlet pipeline; 51 is a moving axis; 52 is a telescopic spring; 53 is a movable supporting seat; 54 is a supporting groove; 55 is a guide slide bar; 56 is a moving cavity; 57 is a drum motor; 58 is a guide chute; 59 is a rotating drum; 60 is a supporting shaft; 61 is a cooling plate; 63 is a moving sleeve; 64 is a detection plate; 65 is a vibration plate; 67 is a damping spring; 68 is a friction plate; 69 is a damping spring; 70 is a supporting shaft; 71 is a supporting connecting plate; 72 is a damping block; 73 is a damping chamber; 74 is a lifting closed cavity; 75 is a lifting closing plate; 76 is a lifting spring; 77 is a second pull rope; 78 is a detection chamber; and 79 is a humidity detection plate.

Detailed Description

The following detailed description of embodiments of the present invention is provided in connection with the accompanying drawings and examples. The following examples are intended to illustrate the invention but are not intended to limit the scope of the invention.

The structure of the sample storage device for the clinical laboratory in the embodiment of the invention is shown in fig. 1 to 6, and comprises a cabinet body 11 and a cabinet door 37, wherein a working chamber 12 is arranged in the cabinet body 11, a rotatable storage box 13 is arranged in the working chamber 12, a storage chamber 16 with an opening facing one side is arranged in the storage box 13, a plurality of storage racks 14 are arranged and distributed in a matrix from top to bottom in the storage chamber 16, a placing chamber 15 with an upward opening is arranged in all the storage racks 14, all the storage racks are U-shaped racks with an upward U-shaped opening, the clinical laboratory sample is placed in the placing chamber 15, a turnover chamber 35 with an outward opening is arranged at one side of the storage chamber 16, a turnover support shaft 36 is rotatably arranged at the upper side between two walls in the turnover chamber 35, the cabinet door is fixed at the lower side of the outer circular surface of the turnover support shaft 36, a turnover handrail 38 is fixedly connected to the lower side of the end surface of the cabinet door 37 far away from the working chamber 12, when the sample storage device is used, a worker can turn over and open the cabinet door 37 by holding the turnover handrail 38 by hand, then, a test sample such as a petri dish or a research reagent to be stored is placed in the placing chamber 15, and then the cabinet door 37 is turned over again and the working chamber 12 is sealed.

A rotating motor 18 is fixedly arranged in the lower wall of the working cavity 12, the rotating motor 18 is connected with a supporting rotating shaft 17, the upper end surface of the supporting rotating shaft 17 extends into the working cavity 12 and then is fixedly connected with the bottom of the storage box 13, the storage box 13 can be driven to rotate in the working cavity 12 after the rotating motor 18 is started, the end surfaces of the two sides of all the storage racks 14 in the storage box 13 are fixedly connected with shock absorption blocks 72 which are symmetrical relative to the two sides of the storage rack 14, shock absorption cavities 73 are arranged in the shock absorption blocks 72, friction plates 68 are respectively arranged on the upper inner wall and the lower inner wall of each shock absorption cavity 73, a movable supporting connecting plate 71 is arranged in each shock absorption cavity 73, the supporting connecting plate 71 is attached to the upper friction plate 68 and the lower friction plate 68, friction force for blocking relative movement exists between the supporting connecting plate 71 and the friction plates 68, a first shock absorption spring 67 is fixedly connected between the end surface of the supporting connecting plate 71, which is close to the storage rack 14, and the end wall of the shock absorption cavity 73, which is close to the storage rack 14, a supporting shaft 70 is fixedly connected to the end face of one side of the supporting connecting plate 71, which is far away from the storage rack 14, the supporting shaft 70 penetrates through the shock absorption block 72 and then extends outwards to the storage cavity 16 and is fixedly connected with two side walls of the storage cavity 16, the shock absorption block 72 is fixedly connected between the end face of one side of the shock absorption block 72, which is far away from the storage rack 14, and two side walls of the storage cavity 16, a second shock absorption spring 69 is fixedly connected between the end face of one side of the shock absorption block 72 and the two side walls of the storage cavity 16, the axes of the first shock absorption spring 67 and the second shock absorption spring 69 are overlapped, in the rotating process of the storage box 13, the supporting connecting plate 71 is fixedly connected through the supporting shaft 70, the shock absorption block 72 is stably supported and driven to move through the supporting connecting plate 71 and the friction plate 68, at this time, after preliminary shock absorption is performed through the first shock absorption spring 67, the surface of the friction plate 68 is rough and is in friction connection with the upper and lower sides of the supporting connecting plate 71, and simultaneously, the input of the vibration in the moving process of the storage box 13 is reduced through the connection of the second shock absorption spring 69, the medical reagent storage device achieves stable storage of the stored medical reagent.

A movable detection plate 25 is arranged in the working chamber 12 and at one side of the storage box 13, a telescopic pipeline 23 is fixedly arranged at the upper part of the end surface of one side of the movable detection plate 25 far away from the storage box 13, a communication pipeline 24 penetrating through the movable detection plate 25 is arranged in the telescopic pipeline 23, a movable shaft 51 is fixedly arranged at the middle position of the end surface of one side of the movable detection plate 25 far away from the storage box 13, a movable chamber 56 is arranged in the wall of one side of the working chamber 12 close to the movable detection plate 25, a movable supporting seat 53 capable of moving is arranged in the movable chamber 56, a supporting groove 54 with an opening facing the working chamber 12 is arranged in the movable supporting seat 53, the end surface of one side of the movable shaft 51 far away from the movable detection plate 25 extends into the supporting groove 54, a telescopic spring 52 is fixedly connected between the end surface of one side of the movable shaft 51 far away from the movable detection plate 25 and the end surface of one side of the supporting groove 54 far away from the working chamber 12, a guide slide rod 55 is fixedly arranged at the lower end surface of the movable supporting seat 53 and positioned in the movable chamber 56, a supporting shaft 60 is rotatably arranged at the lower side between the two walls of the moving cavity 56, a rotary drum 59 is fixedly connected to the outer circular surface of the supporting shaft 60, a guide sliding chute 58 is fixedly arranged on the outer circular surface of the rotary drum 59, the lower end surface of the guide sliding rod 55 is pointed and extends downwards into the guide sliding chute 58, the guide sliding chute 58 is similar to a spiral groove and can convert the rotary displacement into the linear displacement of the guide sliding rod 55, a rotary drum motor 57 is fixedly arranged in one side wall of the moving cavity 56, which is far away from the working cavity 12, one end of the supporting shaft 60 is in power connection with the rotary drum motor 57, when the rotary drum motor 57 is started, the supporting shaft 60 can be driven to rotate, the rotary drum 59 is driven to rotate through fixed connection, the rotary drum 59 is driven to move by the matching of the guide sliding chute 58 and the guide sliding rod 55, the guide sliding rod 55 moves to drive the moving supporting seat 53 to move to one side of the working cavity 12 through fixed connection, the moving supporting seat 53 moves to the left and pushes the moving shaft 51 to move to one side of the working cavity 12 through the elastic action of the telescopic spring 52, at this time, the movable shaft 51 drives the movable detection plate 25 to move for a certain distance through fixed connection, and at this time, the telescopic pipeline 23 extends for a certain distance, so that the movable detection plate 25 is attached to the storage box 13 finally.

A fan cavity 19 is arranged in the upper wall of the movable cavity 56, one side of the communicating pipeline 24 is communicated with the fan cavity 19, a rotary fan 20 is arranged in the fan cavity 19 in a rotating mode, a rotary rotating shaft 21 is fixedly connected to a rotating center of one side, away from the working cavity 12, of the rotary fan 20, a fan motor 22 is fixedly arranged in one side wall, away from the working cavity 12, of the fan cavity 19, one side end face, away from the working cavity 12, of the rotary rotating shaft 21 is in power connection with the fan motor 22, a control cavity 28 is arranged in the upper wall of the fan cavity 19, a control panel 27 is fixedly arranged on the inner wall of the control cavity 28, an air inlet pipeline 26 is arranged between the lower wall of the control cavity 28 and one side wall, away from the working cavity 12, of the fan cavity 19 in a communicating mode, a ventilating pipeline 29 with an outward opening is arranged on one side wall of the control cavity 28, after a detection sample is placed in the placement cavity 15 and the cabinet door 37 is closed again, the rotary motor 18 can be automatically started to drive the support rotating shaft 17 to rotate and drive the storage box 13 to rotate through fixed connection and gradually rotate to the storage cavity 16 of the storage box 13, and move the detection plate 25 And then stopped, at which time the drum motor 57 is started to finally move the detection plate 25 toward the storage compartment 13 under the elastic force of the extension spring 52 and tightly close the open side of the storage compartment 16, at which time the inside of the storage compartment 16 can be detected by moving the detection plate 25, meanwhile, the control panel 27 is controlled to be started to control the temperature and humidity of the air inside the control cavity 28 and even inside the storage cavity 16, specifically, the outside air is sucked into the temperature control cavity 28 through the ventilation pipeline 29 to control the temperature, at the moment, the fan motor 22 is started and drives the power rotating shaft 21 to rotate, the power rotating shaft 21 drives the rotating fan 20 to rotate through fixed connection, the rotating fan 20 rotates and blows the air inside the fan cavity 19 into the storage cavity 16 through the communication pipeline 24 and keeps the temperature and humidity inside the storage cavity 16, and certainly, the temperature and humidity can be controlled by auxiliary heating sheets or refrigerating sheets.

A movable closing chamber 41 is communicated with and arranged on one side wall of the working chamber 12 far away from the turnover chamber 35, a movable closing plate 40 capable of moving is arranged in the movable closing chamber 41, a connecting spring 42 is fixedly connected between one side end face of the movable closing plate 40 far away from the working chamber 12 and one side end wall of the movable closing chamber 41 far away from the working chamber 12, a detection plate 64 is fixedly arranged in the upper wall of the working chamber 12, vibration plates 65 capable of providing vibration force are symmetrically arranged on two walls of the detection plate 64, a detection chamber 78 is arranged in the detection plate 64, a humidity detection plate 79 is fixedly arranged on the lower wall in the detection chamber 78, a cooling plate 61 is fixedly arranged on the upper wall in the detection chamber 78, an air inlet pipeline 46 is communicated between one side wall of the detection chamber 78 and one side wall of the movable closing chamber 41 far away from the working chamber 12, a communicating port 45 communicated with the inner upper side of the movable closing plate 40 in a penetrating manner is arranged, a telescopic connecting pipeline 44 is fixedly arranged on the upper portion of one side end face of the movable closing plate 40 far away from the working chamber 12, a pipeline through cavity 43 is arranged in the telescopic connecting pipeline 44 in a penetrating and communicating mode, one side of the pipeline through cavity 43 is communicated with a communicating port 45, and the other side of the pipeline through cavity 43 is communicated with an air inlet pipeline 46.

A switching cavity 31 is communicated with one side wall of the detection cavity 78 far away from the air inlet pipeline 46, an air outlet channel 30 with an upward opening is communicated with the upper wall of the switching cavity 31, a switching threaded shaft 32 is rotatably arranged on one side wall of the switching cavity 31 far away from the detection cavity 78, a moving sleeve 63 is arranged in the detection cavity 78, the switching threaded shaft 32 is in threaded connection with the moving sleeve 63, a switching motor 33 is fixedly arranged in one side wall of the switching cavity 31 far away from the detection cavity 78, the end surface of one side of the switching threaded shaft 32 far away from the detection cavity 78 is in power connection with the switching motor 33, a first pull rope 34 is fixedly connected with the end surface of one side of the moving sleeve 63 far away from the air inlet pipeline 46, a lifting closed cavity 74 is communicated with the upper wall and the lower wall of the cabinet body 11 in the air inlet pipeline 46, a lifting closed plate 75 capable of moving up and down is arranged in the lifting closed cavity 74, a lifting spring 76 is fixedly connected between the lower end surface of the lifting closed plate 75 and a second pull rope 77, the second cord 77 is connected to the first cord 34.

When accurate humidity detection is required, the drum motor 57 is started to make the mobile detection plate 25 return to the initial position, that is, away from the opening of the storage chamber 16, at this time, the rotary motor 18 is started to drive the support rotary shaft 17 to rotate ninety degrees, and the opening of the storage chamber 16 is made to face towards one side of the mobile closed chamber 41 and then stopped, at this time, the mobile closed plate 40 moves towards one side close to the working chamber 12 through the elastic force of the connecting spring 42 and stably closes the opening of the storage chamber 16 again, at this time, the switching motor 33 is started and drives the switching threaded shaft 32 to rotate, the switching threaded shaft 32 drives the mobile sleeve 63 to move towards one side away from the air inlet pipeline 46 through threaded connection, at this time, the mobile sleeve 63 moves and reduces the air pressure in the detection chamber 78, at this time, the air in the storage chamber 16 is sucked into the detection chamber 78 through the pipeline through chamber 43 and the communication port 45 communicated through the air inlet pipeline 46, and at the same time, the mobile sleeve 63 moves and the first pull rope 34 and the second pull rope 77 are not tensioned, at this time, the lifting closing plate 75 moves upwards due to the elastic force of the lifting spring 76, and when the moving sleeve 63 moves to a side close to the switching cavity 31, the air in the switching cavity 31 is discharged out of the cabinet through the air outlet channel 30, meanwhile, the lifting closing plate 75 moves upwards to the upper limit position and closes the left side and the right side of the air inlet pipeline 46, the cooling plate 61 is started to reduce the temperature in the detection cavity 78 and cool and solidify the water vapor in the air in the detection cavity 78, the vibration plate 65 is started to drive the detection plate 64 to vibrate, the condensed water on the inner wall of the detection cavity 78 drops to the surface of the humidity detection plate 79, and accurate humidity detection is performed by the humidity detection plate 79, preventing sensitivity of the internal detector from being lowered after long-time humidity and temperature detection is performed by moving the detection plate 25, and thus, the humidity control rate is lowered, thereby causing damage to the internally stored medical reagents and the test specimen such as the study sample.

The above is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, it is possible to make several improvements and modifications without departing from the technical principle of the present invention, and these improvements and modifications should also be considered as the protection scope of the present invention.

Claims (10)

1. A clinical laboratory sample storage device comprises a cabinet body with a working cavity and a cabinet door for closing the working cavity, wherein a storage box is arranged in the working cavity, the storage box is internally provided with a storage cavity with an opening facing one side, the storage cavity is provided with a plurality of storage racks, and the clinical laboratory sample storage device is characterized in that the storage box is rotatably arranged in the working cavity, a rotating motor is fixedly arranged in the lower wall of the working cavity, a supporting rotating shaft of the rotating motor extends into the working cavity and then is fixedly connected with the storage box, the end surfaces of the two sides of all the storage racks are fixedly connected with shock absorption blocks with shock absorption cavities, the upper inner wall and the lower inner wall of each shock absorption cavity are respectively provided with a friction plate, a supporting connection plate with the upper end and the lower end respectively jointed with the friction plate is arranged in the shock absorption cavity, a first shock absorption spring is arranged between the end surface of the supporting connection plate, which is close to one side end surface of the storage rack, and a supporting shaft is fixed on the end surface of the supporting connection plate, which is far away from the storage rack, the back shaft runs through behind the shock attenuation chamber with deposit chamber lateral wall fixed connection, the snubber block is kept away from storage rack a side terminal surface and is deposited and be equipped with second damping spring between the chamber lateral wall, and second damping spring overlaps and establishes on the back shaft.

2. A clinical specimen storage device according to claim 1, wherein the axes of the first and second shock absorbing springs are arranged to coincide.

3. A clinical specimen storage device according to claim 1, wherein there is friction between the support web and the friction plate to resist relative movement.

4. The clinical laboratory sample storage device according to claim 1, wherein said storage rack is a U-shaped rack with an upward U-shaped opening, and a storage chamber with an upward opening is provided in said storage rack.

5. The clinical laboratory sample storage device according to claim 1, wherein the working chamber is provided with an outward-opening turnover chamber at one side of the opening of the storage chamber, a turnover support shaft is rotatably arranged at the upper side between the two walls in the turnover chamber, and the cabinet door is fixedly connected with the turnover support shaft.

6. A clinical laboratory sample storage device according to claim 5, wherein said cabinet door is provided with a flip armrest on the end surface away from said working chamber.

7. The clinical laboratory sample storage device according to claim 1, wherein a movable detection plate is disposed in the working chamber, a telescopic pipe is fixedly disposed above an end face of the movable detection plate, the telescopic pipe, the communicating pipe, the fan chamber, the communicating pipe and the rotating fan chamber are disposed in the cabinet body, the fan chamber is communicated with the communicating pipe, the rotating fan is rotatably disposed in the fan chamber, a control chamber is disposed in an upper wall of the fan chamber, a control panel is fixedly disposed in an inner wall of the control chamber, an air inlet pipe is communicated between a lower wall of the control chamber and a side wall of the fan chamber, the side wall of the control chamber is communicated with an air conduit with the air conduit, and the air conduit is opened outwards.

8. The clinical laboratory sample storage device according to claim 7, wherein a moving shaft is fixed to a side end surface of said moving detection plate away from said storage box, a moving chamber is provided in a side wall of said working chamber adjacent to said moving detection plate, a movable support base is provided in said moving chamber, a support groove is provided in said movable support base, and said moving shaft is inserted into said support groove.

9. The clinical laboratory sample storage device of claim 8, wherein a telescoping spring is disposed between said movable shaft and said support slot.

10. The clinical laboratory sample storage device according to claim 8, wherein a guide slide bar is fixedly arranged on the lower end surface of the movable support base, a support shaft and a rotary drum fixedly connected with the support shaft are rotatably arranged on the lower side between the two walls of the movable chamber, the support shaft is connected with a rotary drum motor, and a guide sliding groove matched with the guide slide bar is fixedly arranged on the outer circumferential surface of the rotary drum.

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