CN112693732A

CN112693732A - Biological medicine test tube is injectd and is stored tote box

Info

Publication number: CN112693732A
Application number: CN202011528204.4A
Authority: CN
Inventors: 华志程
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-12-22
Filing date: 2020-12-22
Publication date: 2021-04-23

Abstract

The invention provides a bio-medicine test tube limited storage carrying box, which comprises: the test tube storage device comprises a main body and a placing plate, wherein a closing door is embedded and arranged at the front end of the main body for closing and opening to seal and open the interior of the main body, and the placing plate is embedded and arranged in the main body for placing and keeping the test tube on the surface for storage; and the limiting structures are arranged on the top end surface of the placing plate in a ring-shaped manner in a jogged mode. Can press through the application of force to the test tube when putting into it with the test tube through the limited structure that the device set up, let the lift axle in the limited structure can protrude more comprehensive parcel on the surface around the test tube, restraint and carry out the centre gripping to the test tube when the lift axle goes up and down simultaneously and fix and prevent that the test tube leads to the separation because rocking when carrying the main part.

Description

Biological medicine test tube is injectd and is stored tote box

Technical Field

The invention relates to the technical field of biological medicines, in particular to the technical field of a biological medicine test tube limited storage carrying box.

Background

The pharmaceutical industry and the biomedical engineering industry are two major pillars of the modern pharmaceutical industry. The biomedical industry is composed of both the biotechnology industry and the pharmaceutical industry. The definition and delineation of the biotechnology industry from country to country and from organization to organization is quite variable and often varies from person to person. And wherein biological medicine is the important instrument in the process of experiment at the in-process test tube that carries out the experiment, and current test tube all prescribes a limit to it through the mode that cup joints in placing it in the storage case through simple, and makes like this very easily when needs carry the bin break away from out the limit structure because of rocking leading to its test tube, leads to its test tube to receive the damage.

Disclosure of Invention

Problem (A)

In summary, a bio-medical test tube storage and transportation box is provided for solving the problem that the test tube is easy to be separated from the limit structure and damaged due to shaking in the transportation process of the conventional bio-medical test tube storage and transportation box.

(II) technical scheme

There is provided a bio-medical tube storage tote comprising: the test tube storage device comprises a main body and a placing plate, wherein a closing door is embedded and arranged at the front end of the main body for closing and opening to seal and open the interior of the main body, and the placing plate is embedded and arranged in the main body for placing and keeping the test tubes on the surface for storage;

and the limiting structures are arranged and embedded on the top end surface of the placing plate in a circular manner.

Further, the placing plate comprises;

the placing groove is a plurality of cylindrical grooves on the top end surface of the placing plate;

the rotary disc is a disc embedded at the bottom end inside the groove of the placing groove, and a limiting structure is connected around the surface of the top end of the rotary disc.

Further, the limiting structure comprises;

the offset shaft is a cylindrical round shaft which is hollow around the limiting structure;

the beam-collecting shaft is a hollow round shaft which is embedded in the middle of the offset shaft and has a smaller diameter;

the lifting shaft is a hollow round shaft which is embedded in the hollow part of the bundling shaft and has a smaller diameter;

the supporting disc is arranged on a round shaft which is embedded in the hollow diameter of the lifting shaft, and the bottom end of the supporting disc is elastically connected with the bottom end of the lifting shaft through a spring.

Further, the offset shaft comprises;

the buffer shaft is a round shaft which is embedded and arranged at one side of the hollow part in the middle of the offset shaft, and the diameter of the buffer shaft is embedded with the maximum gap width between the offset shaft and the bunching shaft;

the offset ring groove is a groove with a circular ring-shaped bottom surface in the middle of the offset shaft.

Furthermore, the beam-closing shaft comprises a beam-closing shaft;

the abutting block is a circular-ring-shaped convex block which is convexly arranged in the middle of the bundling shaft and extends towards the center near the top end part, and the bottom end part of the abutting block obliquely extends in an arc shape;

and the offset shaft is a circular shaft-shaped bulge at the middle part of the bottom end of the bundling shaft, and the circular shaft bulge of the offset shaft is embedded with the circular groove of the offset ring groove in width.

Furthermore, the lifting shaft comprises a lifting shaft body;

the extension block is a plurality of rectangular blocks which are connected and spliced to form a round shaft of the lifting shaft, and the surface of one side of the extension block is provided with a thread groove mark which is embedded with the surface around the support disc and inclines leftwards and downwards;

the extension layer is an elastic silica gel connection layer formed by connecting extension blocks in a triangular overlapping manner;

the pushing shaft is a rolling shaft which is embedded and arranged at the position, close to the bottom end, of the other side surface of the extension block.

(III) advantageous effects

(1) Can press through the application of force to the test tube when putting into it with the test tube through the limited structure that the device set up, let the lift axle in the limited structure can protrude more comprehensive parcel on the surface around the test tube, restraint and carry out the centre gripping to the test tube when the lift axle goes up and down simultaneously and fix and prevent that the test tube leads to the separation because rocking when carrying the main part.

(2) The device is provided with the offset shaft, can let the lift axle of the fixed test tube in the limit structure and the axle of restrainting through the offset shaft when the main part takes place to rock to one side because rock the strength that produces and carry out the skew, thereby can let it take place to encircle when lift axle and restraint axial one side and carry out the skew and remove thereby reduce the inertia force that the main part rocked and is produced through the offset shaft, prevent that the test tube from being thrown away.

Drawings

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic view of the overall structure of the placement board of the present invention;

FIG. 3 is a schematic view of a partial side view of a defined structure according to the present invention in full cross-section;

FIG. 4 is an enlarged view of the structure at A in FIG. 3 according to the present invention;

FIG. 5 is a partial side view of the beam-receiving shaft of the present invention;

FIG. 6 is a schematic view of a partial side view of an offset axis of the present invention in cross-section;

in fig. 1 to 6, the corresponding relationship between the part names or lines and the reference numbers is:

the door closing device comprises a main body 1, a closing door 101, a placing plate 2, a placing groove 201, a rotating disc 202, a limiting structure 3, an offset shaft 301, a buffering shaft 3011, an offset ring groove 3012, a bundling shaft 302, a resisting block 3021, an offset shaft 3022, a lifting shaft 303, an extending block 3031, an extending layer 3032, a resisting shaft 3033 and a resisting disc 304.

Detailed Description

Please refer to fig. 1 to 6:

a biomedical tube-containment storage tote comprising: the test tube storage device comprises a main body 1 and a placing plate 2, wherein a closing door 101 is embedded at the front end of the main body 1 for closing and opening to seal and open the interior of the main body 1, and the placing plate 2 is embedded in the main body 1 for placing and keeping test tubes on the surface for storage;

and the limiting structures 3 are arranged and embedded on the top end surface of the placing plate 2 in a circular manner.

Wherein, the placing plate 2 comprises;

the placing groove 201 is formed by a plurality of cylindrical grooves on the top end surface of the placing plate 2;

and a rotating disc 202, wherein the rotating disc 202 is a disc which is embedded in the bottom end of the groove inside the placing groove 201, and the limiting structure 3 is connected around the top end surface of the rotating disc 202. When placing the test tube on placing board 2, the test tube can be placed into among the standing groove 201 and place fixedly in the limited structure 3 on the carousel 202, and it can carry out the swivelling movement to limited structure 3 through the rotation of carousel 202 simultaneously, comes to deposit and take the test tube more conveniently.

Wherein the limiting structure 3 comprises;

an offset shaft 301, wherein the offset shaft 301 is a cylindrical round shaft which is hollow around the limiting structure 3;

a binding shaft 302, the binding shaft 302 being a hollow circular shaft having a smaller diameter and fitted in a hollow portion in the middle of the offset shaft 301;

a lifting shaft 303, wherein the lifting shaft 303 is a hollow round shaft which is embedded in the hollow part of the bundling shaft 302 and has a smaller diameter; the bottom of test tube can support and support on keeping to the dish 304 at lift shaft 303 middle part when the test tube is put into and is injectd structure 3, press to let to keep to dish 304 and can go up and down along lift shaft 303 through carrying out the application of force to the test tube, and through keeping to the groove mark of dish 304 surrounding surface and extension 3031 side surface looks mutual gomphosis around the lift shaft 303, make to keep to dish 304 and can let lift shaft 303 take place to rotate and rise upwards along the groove mark simultaneously when going up and down, make lift shaft 303 can bulge to the top surface of bundling shaft 302 and carry out more comprehensive cover parcel to the surface around the test tube.

The disc 304 is a circular shaft fitted in the hollow diameter of the shaft 303, and the bottom of the disc 304 is elastically connected to the bottom of the shaft 303 through a spring.

Wherein, the offset shaft 301 comprises;

a buffer shaft 3011, the buffer shaft 3011 being a circular shaft fitted to one side of the hollow portion in the middle of the offset shaft 301, and the diameter of the buffer shaft 3011 being fitted to the maximum gap width between the offset shaft 301 and the converging shaft 302;

the offset ring slot 3012 and the offset ring slot 3012 are circular grooves formed on the bottom surface of the middle portion of the offset shaft 301.

Wherein, the beam-closing shaft 302 comprises;

the resisting block 3021, the resisting block 3021 is an annular convex block which is convexly arranged in the middle of the bundling shaft 302 near the top end portion and extends toward the center, and the bottom end portion of the resisting block 3021 is obliquely extended in an arc shape; when the lifting shaft 303 is lifted along the beam-collecting shaft 302, the abutting shaft 3033 on one side of the peripheral extension block 3031 abuts against the abutting block 3021 around the top end of the beam-collecting shaft 302, the abutting shaft 3033 is better lifted along the abutting block 3021 by the inclined extension of the arc of the bottom end of the abutting block 3021, and simultaneously, the extending blocks 3031 are forced to contract each other so as to pass through the beam-collecting shaft 302 because the abutting shaft 3033 is lifted along the abutting block 3021.

The offset shaft 3022, the offset shaft 3022 is a circular shaft-shaped protrusion at the middle of the bottom end of the tightening shaft 302, and the circular shaft protrusion of the offset shaft 3022 is embedded with the circular groove of the offset ring slot 3012. When the main conveying body 1 is shaken due to collision, the force generated by shaking can cause the beam-receiving shaft 302 to shift to one side in the offset shaft 301, and when the beam-receiving shaft 302 shifts in the offset shaft 301, the beam-receiving shaft 302 can press the buffer shaft 3011 in the offset shaft 301 to move around along the offset shaft 301, so that the beam-receiving shaft 302 can also move around along the offset shaft 301 to reduce the inertia force generated by shaking.

Wherein, the lifting shaft 303 comprises;

the extension block 3031 is a plurality of rectangular blocks which are connected and spliced with each other around the lifting shaft 303 to form a round shaft of the lifting shaft 303, and the surface of one side of the extension block 3031 is provided with a thread groove mark which is embedded with the surface around the disc support 304 and inclines leftwards and downwards;

the extension layer 3032 is an elastic silica gel connection layer formed by connecting extension blocks 3031 in a triangular overlapping manner; and the contraction between extension blocks 3031 is drawn close by overlapping through the extension layer 3032 connected between the extension blocks 3031, and the extension layers 3032 can be attached and clamped to the covered test tube when the extension blocks 3031 are drawn close, so that the test tube can be further limited and fixed, and the test tube cannot be easily separated from the limiting structure 3.

The abutting shaft 3033, the abutting shaft 3033 is a roller which is embedded and arranged at the position, close to the bottom end, of the other side surface of the extension block 3031.

(IV) working principle

The invention provides a bio-medicine test tube limiting storage carrying box, firstly, test tubes to be stored and carried are placed on a placing plate 2 in a main body 1 to be limited to a certain degree, then a sealing door 101 of the test tube limiting storage carrying box is closed to seal the inside of the test tube, then the main body 1 is carried by carrying, when the test tubes are placed on the placing plate 2, the test tubes are placed in a limiting structure 3 on a rotary disc 202 in a placing groove 201 to be placed and fixed, meanwhile, the limiting structure 3 can be rotationally moved by the rotation of the rotary disc 202 to be more convenient for storing and taking the test tubes, when the test tubes are placed in the limiting structure 3, the bottom ends of the test tubes are abutted against an abutting disc 304 in the middle of a lifting shaft 303, the abutting disc 304 is lifted along the lifting shaft 303 by applying force and pressing the test tubes, groove marks which are mutually embedded with the peripheral surface of the abutting disc 304 and the peripheral surface of an extension block 3031 on the lifting shaft 303 are mutually, when the tray 304 is lifted, the lifting shaft 303 is rotated and lifted upwards along the groove mark, so that the lifting shaft 303 protrudes out of the top end surface of the bundling shaft 302 to cover and wrap the peripheral surface of the test tube more completely, when the lifting shaft 303 is lifted along the bundling shaft 302, the abutting shaft 3033 on one side of the peripheral extension block 3031 abuts against the abutting block 3021 near the top end of the bundling shaft 302, the abutting shaft 3033 is better lifted along the abutting block 3021 by the inclined extension of the arc at the bottom end of the abutting block 3021, and simultaneously, as the abutting shaft 3033 is lifted along the abutting block 3021, the extension blocks 3031 are forced to be mutually close together to enable the extension blocks to pass through the bundling shaft 302, and the contraction close among the extension blocks 3031 is contracted and closed by the overlapping of the extension layers 3032 connected among the extension blocks, when the extension blocks 3031 are contracted and closed, the covered test tube is attached and clamped, the test tubes can be further limited and fixed, so that the test tubes cannot be easily separated from the limiting structure 3, finally, when the carrying main body 1 is collided and shakes, the force generated by shaking can cause the bundling shaft 302 to deflect towards one side in the offset shaft 301, and when the bundling shaft 302 deflects in the offset shaft 301, the buffering shaft 3011 in the offset shaft 301 can be extruded to move around along the periphery of the offset shaft 301, so that the bundling shaft 302 can also move around along the offset shaft 301 to reduce the inertia force generated by shaking, the test tubes clamped in the middle of the lifting shaft 303 cannot be easily separated due to shaking, meanwhile, the deflection of the bundling shaft 302 is embedded in the offset ring groove 3012 through the offset shaft 3022 at the bottom end to move around, and the bundling shaft 302 is more stable when moving in an offset manner.

Claims

1. A biomedical tube-containment storage tote comprising: the test tube storage device comprises a main body (1) and a placing plate (2), wherein a closing door (101) is embedded and arranged at the front end of the main body (1) to close and open so as to seal and open the inside of the main body (1), and the placing plate (2) is embedded and arranged inside the main body (1) to place and keep test tubes on the surface for storage;

the limiting structures (3) are arranged and embedded on the top end surface of the placing plate (2) in a circular manner.

2. A biomedical test tube containment and storage tote of claim 1, wherein: the placing plate (2) comprises;

the placing groove (201), the placing groove (201) is a plurality of cylindrical grooves on the top end surface of the placing plate (2);

the rotary disc (202) is a disc which is embedded and arranged at the bottom end inside the groove of the placing groove (201), and a limiting structure (3) is connected around the top end surface of the rotary disc (202).

3. A biomedical test tube containment and storage tote of claim 1, wherein: the limiting structure (3) comprises;

the offset shaft (301), the offset shaft (301) is a cylindrical round shaft which is hollow around the limiting structure (3);

a binding shaft (302), wherein the binding shaft (302) is a hollow round shaft which is embedded in the hollow part in the middle of the offset shaft (301) and has a smaller diameter;

a lifting shaft (303), wherein the lifting shaft (303) is a hollow round shaft which is embedded in the hollow part of the bundling shaft (302) and has a smaller diameter;

the disc support (304) is a round shaft which is embedded in the lifting shaft (303) and the hollow diameter of the round shaft is embedded, and the bottom end of the disc support (304) is elastically connected with the bottom end of the lifting shaft (303) through a spring.

4. A bio-medical tube containment storage tote as claimed in claim 3, characterized in that said offset axis (301) comprises;

the buffer shaft (3011), the said buffer shaft (3011) is the round shaft that the jogged setting is on one side of hollow portion in the middle part of the offset shaft (301), and the diameter of the buffer shaft (3011) wants the jogged with the maximum gap width between the offset shaft (301) and the axle of binding (302);

the offset ring groove (3012) is a groove with a circular ring shape on the surface of the bottom end of the middle part of the offset shaft (301).

5. A biomedical test tube containment and storage tote as in claim 3, wherein: the beam-collecting shaft (302) comprises;

the resisting block (3021), the resisting block (3021) is a circular ring-shaped convex block which is convexly arranged in the middle of the bundling shaft (302) and extends towards the center near the top end part, and the bottom end part of the resisting block (3021) obliquely extends in an arc shape;

the shifting shaft (3022), the shifting shaft (3022) is a round shaft-shaped bulge at the middle part of the bottom end of the bundling shaft (302), and the round shaft bulge of the shifting shaft (3022) is embedded with the width of the round ring groove of the shifting ring groove (3012).

6. A biomedical test tube containment and storage tote as in claim 3, wherein: the lifting shaft (303) comprises;

the extension block (3031) is a plurality of rectangular blocks which are connected and spliced to form a round shaft of the lifting shaft (303) around the lifting shaft (303), and one side surface of the extension block (3031) is provided with a thread groove mark which is embedded with the peripheral surface of the abutting disc (304) and inclines leftwards and downwards;

the extension layer (3032) is an elastic silica gel connection layer formed by connecting extension blocks (3031) in a triangular overlapping manner;

the abutting shaft (3033) is a rolling shaft which is embedded and arranged at the position, close to the bottom end, of the other side surface of the extension block (3031).