CN112619733B

CN112619733B - Reagent pipe heat preservation strorage device

Info

Publication number: CN112619733B
Application number: CN202011564724.0A
Authority: CN
Inventors: 刘丽娜
Original assignee: Harbin Moheng Biotechnology Co ltd
Current assignee: Harbin Moheng Biotechnology Co ltd
Priority date: 2020-12-25
Filing date: 2020-12-25
Publication date: 2023-10-17
Anticipated expiration: 2040-12-25
Also published as: CN112619733A

Abstract

The invention belongs to the technical field of storage devices, in particular to a reagent tube heat-preserving storage device which comprises a base, a first shell and an adjusting mechanism, wherein the first shell is provided with a first shell; the first shell is fixedly connected to the top of the base; the adjusting mechanism is arranged in the first shell; the adjusting mechanism comprises a test tube rack, a first rod, a V-shaped rod, an arc-shaped plate and a groove; the test tube rack consists of a rectangular plate, a supporting plate and a first sliding block; the support plates are symmetrically and fixedly connected to the bottoms of the rectangular plates; the first sliding block is fixedly connected to the bottom of the supporting plate; the rectangular plate is connected to the inner wall of the first shell in a sliding manner; a first through hole is uniformly formed in the surface of the rectangular plate; the groove is formed in the inner wall of the first through hole; the V-shaped rod is hinged to the inner wall of the groove; the bottom of the V-shaped rod is fixedly connected with a first spring which is in a stretching state; reagent tubes of different diameter sizes can be clamped.

Description

Reagent pipe heat preservation strorage device

Technical Field

The invention belongs to the technical field of storage devices, and particularly relates to a reagent tube heat-preserving storage device.

Background

In cell culture, a reagent tube is required, and the nutrient solution for the cells may be prepared by the reagent tube or the cell culture solution may be temporarily stored by the reagent tube.

In the prior art, the diameter of a hole for placing a reagent tube in a test tube rack is generally not changeable, and under the condition that the hole site is insufficient, the hole site with large diameter cannot adapt to the reagent tube with small diameter, so that the reagent tube cannot be fixed on the test tube rack.

Disclosure of Invention

In order to overcome the defects in the prior art, the problem that the diameter of a hole for placing a reagent tube in a test tube rack cannot be changed generally, and under the condition that the hole site is insufficient, the hole site with a large diameter cannot adapt to the reagent tube with a small diameter, so that the reagent tube cannot be fixed on the test tube rack is solved.

The technical scheme adopted for solving the technical problems is as follows: the invention relates to a reagent tube heat-preserving device, which comprises a base, a first shell and an adjusting mechanism, wherein the first shell is provided with a first heat-preserving cavity; the first shell is fixedly connected to the top of the base; the adjusting mechanism is arranged in the first shell;

the adjusting mechanism comprises a test tube rack, a first rod, a V-shaped rod, an arc-shaped plate and a groove; the test tube rack consists of a rectangular plate, a supporting plate and a first sliding block; the support plates are symmetrically and fixedly connected to the bottoms of the rectangular plates; the first sliding block is fixedly connected to the bottom of the supporting plate; the rectangular plate is connected to the inner wall of the first shell in a sliding manner; a first through hole is uniformly formed in the surface of the rectangular plate; the groove is formed in the inner wall of the first through hole; the V-shaped rod is hinged to the inner wall of the groove; the bottom of the V-shaped rod is fixedly connected with a first spring which is in a stretching state; the arc plate is fixedly connected to one end of the V-shaped rod, and the first rod is fixedly connected to the other end of the V-shaped rod; during operation, upwards pull the rod No. one for the V-arrangement pole produces rotation, and then make the distance between two curved plates increase, keep the position of rod No. one this moment, then put into the reagent pipe in the through-hole No. one, loosen the rod No. one, make the V-arrangement pole produce rotation, and press from both sides the reagent pipe through the curved plate, thereby make the reagent pipe of different diameter sizes can be fixed on the test-tube rack, because the curved plate is the elastic material constitution, it can produce elastic deformation when receiving the extrusion, the broken phenomenon of reagent pipe that also can avoid taking place to lead to because of excessively pressing from both sides tight reagent pipe simultaneously, the V-arrangement pole uses the test tube to set up two as axisymmetry

Further, the side wall of the first shell is symmetrically and fixedly connected with a supporting block; a sliding groove is formed in the top of the supporting block; the side wall of the chute is fixedly connected with a guide post; a second through hole is formed in the side wall of the first sliding block; the guide post and the second through hole are in a sliding fit state; during operation, after the reagent tube is fixed on the test tube rack through the arc plate, the test tube rack is fed into the first shell, the guide pillar is inserted into the second through hole, and the first sliding block slides along the sliding groove, so that the test tube rack can be stably moved into the first shell, the shaking of the test tube rack in the moving process can be avoided, the solution in the reagent tube is prevented from falling into the first shell, the solution pollution of the first shell is avoided, and the waste of the solution can be reduced.

Further, a buffer mechanism is arranged on the inner wall of the chute; the buffer mechanism comprises a second shell, a second spring and a first push plate; the second shell is fixedly connected to the inner wall of the chute and symmetrically arranged about the center of the guide post; the first push plate is fixedly connected to the side wall of the second shell through a second spring; during operation, when the slider gets into the inside of the No. one casing along the spout, the slider at first with push pedal contact to the push pedal of continuous extrusion makes the push pedal extrusion spring No. one, because the spring has buffering absorbing effect, will avoid taking place because the too big phenomenon that leads to the slider of a slider to bump with No. two casings of dynamics, avoided the test-tube rack to produce and rock, thereby avoid the solution in the reagent pipe to fall into the inside of the No. one casing.

Further, a lubrication mechanism is arranged in the sliding groove; the lubricating mechanism comprises an oil bag, a second push plate, a second rod, a cavity and a third through hole; an oil bag is fixedly connected in the second shell; the inner wall of the second shell is connected with a second push plate in a sliding manner; the second rod penetrates through the side wall of the second shell and is connected with the second shell in a sliding manner; one end of the second rod is fixedly connected with the second push plate, and the other end of the second rod is fixedly connected with the first push plate; the cavity is arranged in the guide post and is communicated with the oil bag; the third through holes are uniformly formed in the side wall of the guide post, and are communicated with the cavity; during operation, after the first push plate is extruded by the first slide block, the second push plate is extruded by the first push plate, so that the second push plate is pushed by the second push plate to slide, the oil bag is extruded, lubricating oil in the oil bag flows into the cavity and flows to the outer side wall of the guide pillar along the third through hole, and then the sliding of the first slide block is matched, the lubrication of the guide pillar is realized, and the sliding of the first slide block in the sliding chute is facilitated.

Further, the top of the base is fixedly connected with a third shell; the first shell is communicated with the third shell through a straight pipe; a heating mechanism is arranged in the third shell; the heating mechanism comprises a motor, fan blades and an electric heating wire; the motor is fixedly connected to the inner wall of the third shell; the fan blade is fixedly connected to an output shaft of the motor; a first plate is fixedly connected to the inner wall of the third shell; a first through groove is formed in the surface of the first plate; the electric heating wire is fixedly connected to the side wall of the first through groove; an ultraviolet lamp is fixedly connected to the inner side wall of the top of the third shell; when the ultraviolet lamp works, the motor is started, the fan blades are driven by the motor to rotate, so that gas flows out of the first through groove, heating of the gas is realized, the gas flows from the bottom of the ultraviolet lamp and finally flows into the first shell from the straight pipe, the temperature inside the first shell is regulated, and the heat preservation of the first shell is facilitated; the arrangement of the first plate can avoid overheat of the ultraviolet lamp caused by overlarge temperature of the electric heating wire, and further avoid damage of the ultraviolet lamp.

Further, a second through groove is formed in the side wall of the third shell; the inner wall of the second through groove is fixedly connected with a filter screen; the output shaft of the motor is fixedly connected with a cam; a fourth shell is symmetrically and fixedly connected to the inner wall of the third shell; a third through groove is formed in the top of the fourth shell; the inner wall of the fourth shell is connected with a third push plate in a sliding manner; the side wall of the third push plate is symmetrically hinged with a connecting rod, and the other end of the connecting rod is hinged with a second slide block; the second sliding block is connected to the inner wall of the fourth shell in a sliding way; the side wall of the second sliding block is fixedly connected with a third rod, and the third rod penetrates through the fourth shell; during operation, after the motor drives the flabellum to rotate, also make the cam rotate, and then make the cam intermittent type nature extrude No. three push plates, then No. three push plates extrusion connecting rod for the connecting rod promotes No. two sliders and slides forward, and then drives No. three poles and slide forward, thereby make No. three poles intermittent type nature extrusion filter screen, can make the dust on filter screen surface drop, and then avoided the phenomenon that the dust blockked up the filter screen, thereby make outside air get into No. three inside of casing smoothly, realize the regulation to No. one inside temperature of casing.

The beneficial effects of the invention are as follows:

1. according to the reagent tube heat preservation and storage device, the reagent tubes are clamped through the cooperation of the test tube rack, the first rod, the V-shaped rod, the arc plate, the groove and the first spring, so that the reagent tubes with different diameters can be fixed on the test tube rack.

2. According to the reagent tube heat-preserving and storing device, through the cooperation of the second shell, the second spring and the first push plate, the phenomenon that the first slide block collides with the second shell due to overlarge force is avoided, and further the shaking of the test tube rack is avoided, so that solution in the reagent tube is prevented from falling into the first shell.

Drawings

The invention is further described below with reference to the accompanying drawings.

FIG. 1 is a perspective view of the present invention;

FIG. 2 is a partial cross-sectional view of the present invention;

FIG. 3 is an enlarged view of a portion of FIG. 2 at A;

FIG. 4 is an enlarged view of a portion of FIG. 2 at B;

FIG. 5 is an enlarged view of a portion of FIG. 2 at C;

FIG. 6 is a partial enlarged view at D-D of FIG. 4;

FIG. 7 is an enlarged view of a portion of FIG. 6 at E;

FIG. 8 is an enlarged view of a portion of FIG. 6 at F;

FIG. 9 is a schematic perspective view of a V-shaped rod and arcuate plate of the present invention;

in the figure: 1. a base; 2. a first shell; 31. a test tube rack; 311. a rectangular plate; 3111. a first through hole; 312. a support plate; 313. a first sliding block; 32. a first rod; 33. a V-shaped rod; 34. an arc-shaped plate; 35. a groove; 36. a first spring; 41. a support block; 42. a chute; 43. a guide post; 44. a second through hole; 51. a second housing; 52. a second spring; 53. a first push plate; 61. an oil bag; 62. a second push plate; 63. a second rod; 64. a cavity; 65. a third through hole; 71. a third housing; 72. a straight pipe; 73. an ultraviolet lamp; 81. a motor; 82. a fan blade; 83. heating wires; 84. a first plate; 85. a first through groove; 91. a second through groove; 92. a filter screen; 93. a cam; 94. a fourth housing; 95. a third through groove; 96. a third push plate; 97. a connecting rod; 98. a second slide block; 99. and a third rod.

Description of the embodiments

The invention is further described in connection with the following detailed description in order to make the technical means, the creation characteristics, the achievement of the purpose and the effect of the invention easy to understand.

As shown in fig. 1 to 9, the reagent tube heat-preserving storage device of the present invention comprises a base 1, a first shell 2 and an adjusting mechanism; the first shell 2 is fixedly connected to the top of the base 1; the adjusting mechanism is arranged in the first shell 2;

the adjusting mechanism comprises a test tube rack 31, a first rod 32, a V-shaped rod 33, an arc plate 34 and a groove 35; the test tube rack 31 consists of a rectangular plate 311, a supporting plate 312 and a first sliding block 313; the supporting plate 312 is symmetrically fixedly connected to the bottom of the rectangular plate 311; the first slider 313 is fixedly connected to the bottom of the support plate 312; the rectangular plate 311 is slidably connected to the inner wall of the first shell 2; a first through hole 3111 is uniformly formed on the surface of the rectangular plate 311; the groove 35 is formed in the inner wall of the first through hole 3111; the V-shaped rod 33 is hinged on the inner wall of the groove 35; the bottom of the V-shaped rod 33 is fixedly connected with a first spring 36, and the first spring 36 is in a stretching state; the arc plate 34 is fixedly connected to one end of the V-shaped rod 33, and the first rod 32 is fixedly connected to the other end of the V-shaped rod 33; during operation, the first rod 32 is pulled upwards to enable the V-shaped rod 33 to rotate, the distance between the two arc plates 34 is further increased, the position of the first rod 32 is kept, then the reagent tube is placed in the first through hole 3111, the first rod 32 is loosened to enable the V-shaped rod 33 to rotate, the reagent tube is clamped through the arc plates 34, reagent tubes with different diameters can be fixed on the test tube rack 31, elastic deformation can be generated when the arc plates 34 are made of elastic materials and are extruded, meanwhile, the phenomenon that the reagent tube is broken due to excessive clamping of the reagent tube can be avoided, and the V-shaped rod 33 is symmetrically arranged with the test tube as an axis.

As an embodiment of the present invention, the side wall of the first housing 2 is symmetrically and fixedly connected with a supporting block 41; a sliding groove 42 is formed in the top of the supporting block 41; the side wall of the chute 42 is fixedly connected with a guide post 43; a second through hole 44 is formed in the side wall of the first slider 313; the guide post 43 and the second through hole 44 are in a sliding fit state; during operation, after the reagent tube is fixed on the test tube rack 31 through the arc plate 34, the test tube rack 31 is fed into the first shell 2, the guide pillar 43 is inserted into the second through hole 44, the first sliding block 313 slides along the sliding groove 42, the test tube rack 31 is stably moved into the first shell 2, shaking of the test tube rack 31 in the moving process can be avoided, and solution in the reagent tube is prevented from falling into the first shell 2, so that solution pollution to the first shell 2 is avoided, and waste of the solution can be reduced.

As an embodiment of the present invention, a buffer mechanism is disposed on the inner wall of the chute 42; the buffer mechanism comprises a second shell 51, a second spring 52 and a first push plate 53; the second housing 51 is fixedly connected to the inner wall of the chute 42, and the second housing 51 is symmetrically arranged about the center of the guide post 43; the first push plate 53 is fixedly connected to the side wall of the second shell 51 through a second spring 52; when the test tube rack is in operation, when the first slider 313 enters the first shell 2 along the sliding groove 42, the first slider 313 is in contact with the first push plate 53 at first and continuously extrudes the first push plate 53, so that the first push plate 53 extrudes the first spring 36, the phenomenon that the first slider 313 collides with the second shell 51 due to overlarge strength can be avoided due to the buffer and shock absorption effect of the spring, the shaking of the test tube rack 31 is avoided, and the solution in the reagent tube is prevented from falling into the first shell 2.

As an embodiment of the present invention, a lubrication mechanism is provided inside the chute 42; the lubricating mechanism comprises an oil bag 61, a second push plate 62, a second rod 63, a cavity 64 and a third through hole 65; an oil bag 61 is fixedly connected in the second shell 51; the inner wall of the second shell 51 is slidably connected with a second push plate 62; the second rod 63 penetrates through the side wall of the second housing 51 and is slidably connected with the second housing 51; one end of the second rod 63 is fixedly connected to the second push plate 62, and the other end of the second rod is fixedly connected to the first push plate 53; the cavity 64 is arranged inside the guide post 43, and the cavity 64 is communicated with the oil bag 61; the third through holes 65 are uniformly formed on the side wall of the guide post 43, and the third through holes 65 are communicated with the cavity 64; when the sliding block 313 presses the first push plate 53, the first push plate 53 presses the second rod 63, so that the second rod 63 pushes the second push plate 62 to slide, the oil bag 61 is pressed, lubricating oil in the oil bag 61 flows into the cavity 64 and flows to the outer side wall of the guide post 43 along the third through hole 65, and then the sliding of the sliding block 313 is matched, the guide post 43 is lubricated, and the sliding of the sliding block 313 in the sliding groove 42 is facilitated.

As an embodiment of the present invention, the top of the base 1 is further fixedly connected with a third shell 71; the first shell 2 is communicated with the third shell 71 through a straight pipe 72; a heating mechanism is arranged inside the third shell 71; the heating mechanism comprises a motor 81, fan blades 82 and an electric heating wire 83; the motor 81 is fixedly connected to the inner wall of the third shell 71; the fan blade 82 is fixedly connected to an output shaft of the motor 81; a first plate 84 is fixedly connected to the inner wall of the third shell 71; a first through groove 85 is formed on the surface of the first plate 84; the heating wire 83 is fixedly connected to the side wall of the first through groove 85; an ultraviolet lamp 73 is fixedly connected to the inner side wall of the top of the third shell 71; when the ultraviolet lamp is in operation, the motor 81 is started, the motor 81 drives the fan blades 82 to rotate, so that gas flows out of the first through groove 85, heating of the gas is realized, the gas flows out of the bottom of the ultraviolet lamp 73 and finally flows into the first shell 2 from the straight pipe 72, the temperature inside the first shell 2 is regulated, and the heat preservation of the first shell 2 is facilitated; the first plate 84 is provided to prevent the ultraviolet lamp 73 from being overheated due to the excessive temperature of the heating wire 83, thereby preventing the ultraviolet lamp 73 from being damaged.

As an embodiment of the present invention, the side wall of the third housing 71 is provided with a second through groove 91; the inner wall of the second through groove 91 is fixedly connected with a filter screen 92; the output shaft of the motor 81 is fixedly connected with a cam 93; a fourth shell 94 is symmetrically and fixedly connected to the inner wall of the third shell 71; a third through groove 95 is formed in the top of the fourth shell 94; a third push plate 96 is slidably connected to the inner wall of the fourth housing 94; the side wall of the third push plate 96 is symmetrically hinged with a connecting rod 97, and the other end of the connecting rod 97 is hinged with a second slide block 98; the second slider 98 is slidably connected to the inner wall of the fourth housing 94; a third rod 99 is fixedly connected to the side wall of the second slider 98, and the third rod 99 penetrates through the fourth housing 94; when the motor 81 drives the fan blade 82 to rotate, the cam 93 is also enabled to rotate, the cam 93 is enabled to intermittently extrude the third push plate 96, then the third push plate 96 extrudes the connecting rod 97, the connecting rod 97 pushes the second slide block 98 to slide forwards, and then the third rod 99 is driven to slide forwards, so that the third rod 99 intermittently extrudes the filter screen 92, dust on the surface of the filter screen 92 can fall, the phenomenon that the filter screen 92 is blocked by dust is avoided, and therefore external air smoothly enters the inside of the third shell 71, and the temperature inside the first shell 2 is adjusted.

Working principle: the first rod 32 is pulled upwards to rotate the V-shaped rod 33, the distance between the two arc plates 34 is further increased, the position of the first rod 32 is kept, then the reagent tube is placed in the first through hole 3111, the first rod 32 is loosened to rotate the V-shaped rod 33, the reagent tube is clamped through the arc plates 34, reagent tubes with different diameters can be fixed on the test tube rack 31, and the arc plates 34 are made of elastic materials and can generate elastic deformation when being extruded, and meanwhile, the phenomenon of reagent tube breakage caused by excessive clamping of the reagent tube can be avoided; after the reagent tube is fixed on the test tube rack 31 through the arc plate 34, the test tube rack 31 is sent into the first shell 2, the guide post 43 is inserted into the second through hole 44, and the first sliding block 313 slides along the sliding groove 42, so that the test tube rack 31 stably moves into the first shell 2, the shaking of the test tube rack 31 in the moving process can be avoided, the solution in the reagent tube is prevented from falling into the first shell 2, the pollution of the solution to the first shell 2 is avoided, and the waste of the solution is also reduced; when the first slider 313 enters the first housing 2 along the chute 42, the first slider 313 is in contact with the first push plate 53 at first and continuously extrudes the first push plate 53, so that the first push plate 53 extrudes the first spring 36, and the phenomenon that the first slider 313 collides with the second housing 51 due to overlarge force can be avoided due to the buffer and shock absorption effects of the spring, so that the shaking of the test tube rack 31 is avoided, and the solution in the reagent tube is prevented from falling into the first housing 2; after the first sliding block 313 extrudes the first push plate 53, the first push plate 53 extrudes the second rod 63, so that the second rod 63 pushes the second push plate 62 to slide, further the oil bag 61 is extruded, lubricating oil in the oil bag 61 flows into the cavity 64 and flows to the outer side wall of the guide post 43 along the third through hole 65, and then the sliding of the first sliding block 313 is matched, so that the lubrication of the guide post 43 is realized, and the sliding of the first sliding block 313 in the sliding groove 42 is facilitated; starting the motor 81, and driving the fan blades 82 to rotate by the motor 81, so that gas flows out of the first through groove 85, heating of the gas is realized, the gas flows from the bottom of the ultraviolet lamp 73 and finally flows into the first shell 2 from the straight pipe 72, the temperature inside the first shell 2 is regulated, and the heat preservation of the first shell 2 is realized; the first plate 84 can avoid overheating of the ultraviolet lamp 73 due to overlarge temperature of the heating wire 83, and further avoid damage to the ultraviolet lamp 73; after motor 81 drives flabellum 82 to rotate, also make cam 93 rotate, and then make cam 93 intermittent type nature extrusion No. three push pedal 96, then No. three push pedal 96 extrusion connecting rod 97 for connecting rod 97 promotes No. two slider 98 and slides forward, and then drives No. three pole 99 and slide forward, thereby make No. three pole 99 intermittent type nature extrusion filter screen 92, can make the dust on filter screen 92 surface drop, and then avoided the phenomenon that the dust blockked up filter screen 92, thereby make outside air get into No. three casing 71's inside smoothly, realize the regulation to No. one casing 2 inside temperature.

The front, rear, left, right, up and down are all based on fig. 2 of the drawings in the specification, the face of the device facing the observer is defined as front, the left side of the observer is defined as left, and so on, according to the person viewing angle.

In the description of the present invention, it should be understood that the terms "center," "longitudinal," "lateral," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like indicate orientations or positional relationships based on the orientation or positional relationships shown in the drawings, merely to facilitate describing the present invention and simplify the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and therefore should not be construed as limiting the scope of the present invention.

The foregoing has shown and described the basic principles, principal features and advantages of the invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, and that the above embodiments and descriptions are merely illustrative of the principles of the present invention, and various changes and modifications may be made without departing from the spirit and scope of the invention, which is defined in the appended claims. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims

1. A reagent pipe storage device that keeps warm which characterized in that: comprises a base (1), a first shell (2) and an adjusting mechanism; the first shell (2) is fixedly connected to the top of the base (1); the adjusting mechanism is arranged in the first shell (2);

the adjusting mechanism comprises a test tube rack (31), a first rod (32), a V-shaped rod (33), an arc plate (34) and a groove (35); the test tube rack (31) consists of a rectangular plate (311), a supporting plate (312) and a first sliding block (313); the supporting plate (312) is symmetrically fixedly connected to the bottom of the rectangular plate (311); the first slider (313) is fixedly connected to the bottom of the supporting plate (312); the rectangular plate (311) is connected to the inner wall of the first shell (2) in a sliding manner; the surface of the rectangular plate (311) is uniformly provided with a first through hole (3111); the groove (35) is formed in the inner wall of the first through hole (3111); the V-shaped rod (33) is hinged to the inner wall of the groove (35); the bottom of the V-shaped rod (33) is fixedly connected with a first spring (36), and the first spring (36) is in a stretching state; the arc-shaped plate (34) is fixedly connected to one end of the V-shaped rod (33), the first rod (32) is fixedly connected to the other end of the V-shaped rod (33), and the V-shaped rods (33) are symmetrically arranged by taking the test tube as an axis;

the top of the base (1) is fixedly connected with a third shell (71); the first shell (2) is communicated with the third shell (71) through a straight pipe (72); a heating mechanism is arranged in the third shell (71);

the heating mechanism comprises a motor (81), fan blades (82) and an electric heating wire (83); the motor (81) is fixedly connected to the inner wall of the third shell (71); the fan blades (82) are fixedly connected to an output shaft of the motor (81); a first plate (84) is fixedly connected to the inner wall of the third shell (71); a first through groove (85) is formed in the surface of the first plate (84); the electric heating wire (83) is fixedly connected to the side wall of the first through groove (85); an ultraviolet lamp (73) is fixedly connected to the inner side wall of the top of the third shell (71);

a second through groove (91) is formed in the side wall of the third shell (71); the inner wall of the second through groove (91) is fixedly connected with a filter screen (92); an output shaft of the motor (81) is fixedly connected with a cam (93); a fourth shell (94) is symmetrically and fixedly connected to the inner wall of the third shell (71); a third through groove (95) is formed in the top of the fourth shell (94); the inner wall of the fourth shell (94) is slidably connected with a third push plate (96); a connecting rod (97) is symmetrically hinged to the side wall of the third push plate (96), and a second sliding block (98) is hinged to the other end of the connecting rod (97); the second sliding block (98) is connected to the inner wall of the fourth shell (94) in a sliding manner; the side wall of the second sliding block (98) is fixedly connected with a third rod (99), and the third rod (99) penetrates through the fourth shell (94).

2. A reagent tube thermal storage device according to claim 1, wherein: the side wall of the first shell (2) is symmetrically and fixedly connected with a supporting block (41); a sliding groove (42) is formed in the top of the supporting block (41); the side wall of the chute (42) is fixedly connected with a guide post (43); a second through hole (44) is formed in the side wall of the first slider (313); the guide post (43) and the second through hole (44) are in a sliding fit state.

3. A reagent tube thermal storage device according to claim 2, wherein: the inner wall of the chute (42) is provided with a buffer mechanism; the buffer mechanism comprises a second shell (51), a second spring (52) and a first push plate (53); the second shell (51) is fixedly connected to the inner wall of the chute (42), and the second shell (51) is symmetrically arranged about the center of the guide post (43); the first push plate (53) is fixedly connected to the side wall of the second shell (51) through a second spring (52).

4. A reagent vessel thermal storage apparatus as defined in claim 3, wherein: a lubrication mechanism is arranged in the sliding groove (42); the lubricating mechanism comprises an oil bag (61), a second push plate (62), a second rod (63), a cavity (64) and a third through hole (65); an oil bag (61) is fixedly connected in the second shell (51); the inner wall of the second shell (51) is connected with a second push plate (62) in a sliding manner; the second rod (63) penetrates through the side wall of the second shell (51) and is in sliding connection with the second shell (51); one end of the second rod (63) is fixedly connected with the second push plate (62), and the other end of the second rod is fixedly connected with the first push plate (53); the cavity (64) is arranged in the guide pillar (43), and the cavity (64) is communicated with the oil bag (61); the third through holes (65) are uniformly formed in the side wall of the guide post (43), and the third through holes (65) are communicated with the cavity (64).