CN113460495A - A strorage device for biological sample - Google Patents

Abstract

The invention discloses a storage device for biological samples, relates to the technical field of biological sample storage, and solves the problems that the existing biological sample storage device has high heat exchange speed of split charging pipes in use, and the split charging pipes are easy to cause the situation of repeated freeze thawing caused by overhigh temperature of the biological samples in the transfer process between cooling devices, thereby influencing the storage effect of the biological samples; a micro electric refrigerator and a cooling fan are arranged in the low-temperature storage base; the device comprises sub-packaging pipes, wherein six groups of sub-packaging pipes are arranged on the sub-packaging pipes, and the six groups of sub-packaging pipes are circumferentially arrayed and clamped to be connected to the top of the low-temperature storage base. The split structure is adopted to realize the split charging of the biological sample, the use is convenient, the split bottle is set to be the heat insulation structure, the preservation effect of the biological sample is effectively improved, the cooling and refrigeration of the biological sample are realized by adopting the internal circulation mode, the cooling speed is high, the refrigeration effect is good, the operation is simple, and the use is convenient.

Description

A strorage device for biological sample

Technical Field

The invention relates to the technical field of biological sample storage, in particular to a storage device for biological samples.

Background

In biological and medical research processes, experimental research is often required to be carried out through biological samples, the biological samples are stored through low temperature in the use process of the biological samples, the biological samples are generally stored through a subpackaging pipe firstly, and then the subpackaging pipe is stored through a low-temperature storage box at low temperature.

Based on the above, the heat exchange speed of the split charging pipes is high when the existing biological sample storage device is used, the split charging pipes are easy to cause the situation of repeated freeze thawing caused by overhigh temperature of the biological sample in the transfer process between cooling devices, the storage effect of the biological sample is influenced, and meanwhile, the temperature change in the storage device is easy to be large in the use process; thus, the existing need is not met, for which we propose a storage device for biological samples.

Disclosure of Invention

The invention aims to provide a storage device for biological samples, which solves the problems that the heat exchange speed of split charging pipes in the prior art is high, repeated freezing and thawing conditions caused by overhigh temperature of the biological samples are easily caused in the process of transferring the split charging pipes among cooling devices, the storage effect of the biological samples is influenced, and the temperature change in the storage device is easily caused in the use process.

In order to achieve the purpose, the invention provides the following technical scheme: a storage device for biological samples, comprising a cryopreservation base;

a micro electric refrigerator and a cooling fan are arranged in the low-temperature storage base;

the device comprises sub-packaging pipes, a low-temperature storage base and a plurality of sub-packaging pipes, wherein the sub-packaging pipes are totally provided with six groups, and the six groups of sub-packaging pipes are circumferentially arrayed and tightly clamped on the top of the low-temperature storage base;

the storage upper cover is in threaded fastening connection with the top of the low-temperature storage base, and the storage upper cover is sleeved outside the six-component mounting pipe;

the switching valves are arranged in pairs, six pairs of switching valves are arranged, the six pairs of switching valves are arranged in the low-temperature storage base in a circumferential array mode and communicated with the coolant in the low-temperature storage base;

and the cooling linkage switch mechanism is arranged inside the switch valve and drives the switch valve to act.

Preferably, the low-temperature storage base further includes:

the split charging installation tables are provided with six groups, and the circumferences of the six groups of split charging installation tables are fixedly connected to the top of the low-temperature storage base;

the mounting clamping grooves are clamping grooves with inclined planes, and are circumferentially arranged on the vertical surface of the subpackaging mounting table in an array manner;

the branch dress pipe still includes:

and the installation clamping blocks are arranged at the bottom of the sub-packaging pipe in a circumferential array manner and are connected with the installation clamping grooves in a clamping manner.

Preferably, the dispensing tube further comprises:

the heat preservation, the heat preservation sets up in the outside of partial shipment pipe, and the heat preservation is inside to be the vacuum structure.

Preferably, the dispensing tube further comprises:

the disposable storage pipe is arranged at the innermost side;

the cooling pipe, the cooling pipe setting is in the outside of depositing the pipe in formula of throwing.

Preferably, the cooling pipe is a double-spiral structure with the tail ends communicated, and a group of air inlets and a group of air outlets are respectively arranged at the bottom of the cooling pipe.

Preferably, the dispensing tube further comprises:

and the elastic valve core is tightly pressed on the air inlet and the air outlet at the bottom of the cooling pipe through a spring.

Preferably, the switching valve further includes:

and the valve core top plate is fixedly connected to the top of the switch valve, and the grid is arranged on the valve core top plate.

Preferably, the cooling gang switch mechanism further includes:

the switch linkage driving shaft is coaxially and fixedly connected to the bottom of the sub-packaging pipe, and the cross section of the switch linkage driving shaft is in a regular hexagon shape;

the switch linkage transmission shaft is connected to the top of the low-temperature storage base in a rotating mode in a circumferential array mode;

the switch linkage jack is arranged at the top of the switch linkage transmission shaft and is of a regular hexagon hole-shaped structure, and when the split charging pipe is installed, the switch linkage driving shaft is connected with the switch linkage jack in an inserting mode.

Preferably, the cooling gang switch mechanism further includes:

the switch driving bevel gear is coaxially and fixedly connected to the bottom of the switch linkage transmission shaft;

the switch driven bevel gears are coaxially and fixedly connected to valve cores of the switch valves, and the two groups of switch driven bevel gears are meshed with the switch driving bevel gears simultaneously to form a bevel gear transmission mechanism.

Compared with the prior art, the invention has the beneficial effects that:

when the split charging device is installed, the split charging pipe is inserted on a split charging installation platform, then the split charging pipe is rotated, the split charging pipe and the low-temperature storage base are quickly installed through the installation clamping block and the installation clamping groove, meanwhile, the switch linkage driving shaft is inserted into the switch linkage jack, the installation split charging pipe drives the switch linkage driving shaft to rotate through the insertion connection of the switch linkage driving shaft and the switch linkage jack, the switch linkage driving shaft drives the valve core of the switch valve to move to open the switch valve through the bevel gear transmission mechanism formed by the engagement of the switch driven bevel gear and the switch driving bevel gear, the top plate of the valve core props against the bottom of the elastic valve core, the elastic valve core slides upwards, and the cooling pipe is communicated with the switch valve.

When the biological sample storage device works, the low-temperature storage base generates cold air through the micro electric refrigerator and the cooling fan, the cold air enters the cooling pipe through the group of switch valves and flows in the cooling pipe, the disposable storage pipe is cooled through the double-spiral track of the cooling pipe and then flows back into the low-temperature storage base from the other group of switch valves, and the biological sample is ensured to be always in a low-temperature state through the circulating flow of the cold air, so that the good storage of the biological sample is ensured.

The split structure is adopted to realize the split charging of the biological sample, the use is convenient, the split bottle is set to be the heat insulation structure, the biological sample is ensured to be in a low-temperature state in the independent conveying process of the split bottle, the preservation effect of the biological sample is effectively improved, meanwhile, the internal circulation mode is adopted to realize the cooling and refrigeration of the biological sample, the cooling speed is high, the refrigeration effect is good, the temperature loss is reduced, the operation is simple, and the use is convenient.

Drawings

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

FIG. 2 is a schematic side view of the mounting shaft of the dispensing tube of the present invention;

FIG. 3 is a schematic axial view of the cryogenic storage base of the present invention;

FIG. 4 is an enlarged view of a portion of FIG. 3;

FIG. 5 is a side view of the dispensing tube of the present invention;

FIG. 6 is a schematic side view of the cooling tube of the present invention;

FIG. 7 is a schematic isometric cross-sectional view of a dispensing tube of the present invention;

FIG. 8 is a schematic side view of the switching valve mounting shaft of the present invention;

FIG. 9 is a schematic side view of the switching valve shaft of the present invention;

FIG. 10 is a schematic cross-sectional view of the resilient valve cartridge of the present invention;

in the figure: 1. a low temperature storage base; 101. a split charging mounting table; 102. installing a clamping groove; 2. storing the upper cover; 3. subpackaging pipes; 301. a heat-insulating layer; 302. a disposable storage tube; 303. a cooling tube; 304. an elastic valve core; 305. mounting a clamping block; 306. a switch linkage drive shaft; 4. a switch linkage transmission shaft; 401. a switch linkage jack; 402. the switch drives the bevel gear; 5. an on-off valve; 501. a switch driven bevel gear; 502. and a valve core top plate.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

Example 1

Referring to fig. 1 to 10, an embodiment of the present invention includes: a storage device for biological samples comprises a low-temperature storage base 1, wherein a micro electric refrigerator and a cooling fan are arranged inside the low-temperature storage base 1, and the storage device has the effects that cold air is generated by the micro electric refrigerator and the cooling fan to cool samples, so that low-temperature storage is guaranteed;

the device comprises sub-packaging pipes 3, wherein six groups of the sub-packaging pipes 3 are arranged, and the six groups of the sub-packaging pipes 3 are circumferentially arrayed, tightly clamped and connected to the top of the low-temperature storage base 1; referring to fig. 6 and 7, the dispensing tube 3 further includes: the heat insulation layer 301 is arranged on the outer side of the sub-packaging pipe 3, the vacuum structure is arranged inside the heat insulation layer 301, heat conduction and heat convection of heat are isolated through the vacuum structure of the heat insulation layer 301, the heat insulation effect is achieved, and temperature rise in the sub-packaging pipe 3 is effectively avoided; a disposable storage tube 302, the disposable storage tube 302 being disposed innermost; a cooling pipe 303, the cooling pipe 303 being disposed outside the disposable storage pipe 302, and functioning as a cooling pipe. The biological sample is stored through the disposable storage tube 302, and the disposable storage tube 302 is cooled through the cooling tube 303, so that the repeated freezing and thawing of the biological sample are effectively avoided; the cooling pipe 303 is of a double-spiral structure with the tail ends communicated, and the bottom of the cooling pipe 303 is provided with a group of air inlets and a group of air outlets respectively, so that cold air enters the cooling pipe 303 through the air inlets, cools the disposable storage pipe 302 through the double-spiral track of the cooling pipe 303 and is discharged through the air outlets; the elastic valve core 304 is tightly pressed on the air inlet and the air outlet at the bottom of the cooling pipe 303 through springs, and the elastic valve core 304 has the effects that the cooling pipe 303 is sealed through the elastic valve core 304 after the sub-packaging pipe 3 is detached, dust and sundries are effectively prevented from entering the sub-packaging pipe 3, and meanwhile, heat is prevented from entering the sub-packaging pipe 3 to influence the storage of a biological sample; the switch valve 5 further includes: the valve core top plate 502 is fixedly connected to the top of the switch valve 5, and the grid is arranged on the valve core top plate 502, so that when the distribution pipe 3 is installed at the top of the low-temperature storage base 1, the valve core top plate 502 abuts against the bottom of the elastic valve core 304 to enable the elastic valve core 304 to slide upwards, and the cooling pipe 303 is communicated with the switch valve 5;

the storage upper cover 2 is connected to the top of the low-temperature storage base 1 in a threaded fastening mode, and the storage upper cover 2 is sleeved outside the six-component containing pipe 3;

the switch valves 5 are arranged in pairs, six pairs of switch valves 5 are arranged on the switch valves 5, the six pairs of switch valves 5 are arranged in the low-temperature storage base 1 in a circumferential array mode, and the switch valves 5 are communicated with the coolant in the low-temperature storage base 1;

the cooling linkage switch mechanism is arranged inside the switch valve 5 and drives the switch valve 5 to act; referring to fig. 9, the cooling gang switch mechanism further includes: the switch linkage driving shaft 306 is coaxially and fixedly connected to the bottom of the subpackaging pipe 3, and the cross section of the switch linkage driving shaft 306 is in a regular hexagon shape; the switch linkage transmission shaft 4 is connected to the top of the low-temperature storage base 1 in a rotating mode in a circumferential array mode; the split charging pipe is characterized in that the split charging pipe 3 is rotatably installed when the split charging pipe 3 is installed and disassembled, and the installation split charging pipe 3 drives the switch linkage transmission shaft 4 to rotate through the inserting connection of the switch linkage driving shaft 306 and the switch linkage jack 401; the switch driving bevel gear 402 is coaxially and fixedly connected to the bottom of the switch linkage transmission shaft 4; the switch driven bevel gears 501 are coaxially and fixedly connected to valve cores of the switch valves 5, the two groups of switch driven bevel gears 501 are meshed with the switch driving bevel gears 402 simultaneously to form a bevel gear transmission mechanism, and the switch linkage transmission shaft 4 is used for driving the valve cores of the switch valves 5 to move through the bevel gear transmission mechanism formed by the meshing of the switch driven bevel gears 501 and the switch driving bevel gears 402 when the switch linkage transmission shaft 4 rotates, so that the switch valves 5 are switched.

Referring to fig. 3 and 4, the cryopreservation base 1 further includes:

the packaging device comprises a packaging mounting table 101, wherein six groups of the packaging mounting table 101 are arranged, and the six groups of the packaging mounting table 101 are circumferentially and fixedly connected to the top of the low-temperature storage base 1;

the mounting clamping grooves 102 are clamping grooves with inclined planes, and the mounting clamping grooves 102 are circumferentially arranged on the vertical surface of the subpackaging mounting table 101 in an array manner;

the dispensing tube 3 further comprises:

the installation fixture blocks 305 are arranged at the bottom of the split charging pipes 3 in a circumferential array mode, the installation fixture blocks 305 are connected with the installation clamping grooves 102 in a clamping mode, the split charging pipes 3 are inserted into the split charging installation platform 101 firstly, then the split charging pipes 3 are rotated, and the split charging pipes 3 and the low-temperature storage base 1 are installed and detached quickly through the installation fixture blocks 305 and the installation clamping grooves 102.

The working principle is as follows: when the split charging device is used, during installation, the split charging pipe 3 is firstly inserted on the split charging installation platform 101, then the split charging pipe 3 is rotated, the fast installation of the split charging pipe 3 and the low-temperature storage base 1 is realized through the installation clamping block 305 and the installation clamping groove 102, meanwhile, the switch linkage driving shaft 306 is inserted into the switch linkage jack 401, the installation split charging pipe 3 drives the switch linkage driving shaft 4 to rotate through the insertion connection of the switch linkage driving shaft 306 and the switch linkage jack 401, the switch linkage driving shaft 4 drives the switch valve 5 to open through the valve core action of the switch valve 5 through the bevel gear transmission mechanism formed by the engagement of the switch driven bevel gear 501 and the switch driving bevel gear 402, the valve core top plate 502 supports against the bottom of the elastic valve core 304, the elastic valve core 304 slides upwards, and the cooling pipe 303 is connected with the switch valve 5; during operation, the low-temperature storage base 1 generates cold air through the micro electric refrigerator and the cooling fan, the cold air enters the cooling pipe 303 through the group of switch valves 5 and flows in the cooling pipe 303, the disposable storage pipe 302 is cooled through the double-spiral track of the cooling pipe 303 and then flows back into the low-temperature storage base 1 from the other group of switch valves 5, and the biological sample is ensured to be always in a low-temperature state through the circulating flow of the cold air, so that the good storage of the biological sample is ensured.

Example 2

Example 2 differs from example 1 in that: the dispensing tube 3 is connected with the low-temperature storage base 1 through threads, so that the dispensing tube is convenient to connect in use, has good sealing performance, and ensures a good low-temperature storage effect.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims (9)

1. A storage device for biological samples, characterized by: comprises a low-temperature storage base (1);

a micro electric refrigerator and a cooling fan are arranged in the low-temperature storage base (1);

the device comprises sub-packaging pipes (3), wherein six groups of the sub-packaging pipes (3) are arranged, and the six groups of the sub-packaging pipes (3) are circumferentially arrayed and tightly clamped on the top of the low-temperature storage base (1);

the storage upper cover (2) is in threaded fastening connection with the top of the low-temperature storage base (1), and the storage upper cover (2) is sleeved outside the six-component containing pipe (3);

the switching valves (5) are arranged in pairs, six pairs of switching valves (5) are arranged, the six pairs of switching valves (5) are arranged in the low-temperature storage base (1) in a circumferential array mode, and the switching valves (5) are communicated with the coolant in the low-temperature storage base (1);

and the cooling linkage switch mechanism is arranged inside the switch valve (5) and drives the switch valve (5) to act.

2. A storage device for biological samples according to claim 1, wherein: the low-temperature storage base (1) further comprises:

the split charging installation tables (101), the split charging installation tables (101) are provided with six groups, and the six groups of the split charging installation tables (101) are circumferentially and fixedly connected to the top of the low-temperature storage base (1);

the mounting clamping grooves (102) are clamping grooves with inclined planes, and the mounting clamping grooves (102) are arranged on the vertical surface of the subpackaging mounting table (101) in a circumferential array manner;

the sub-packaging pipe (3) also comprises:

the installation clamping blocks (305) are arranged at the bottom of the sub-packaging pipe (3) in a circumferential array mode, and the installation clamping blocks (305) are connected with the installation clamping grooves (102) in a clamping mode.

3. A storage device for biological samples according to claim 1, wherein: the branch dress pipe (3) still includes:

the heat preservation layer (301), the heat preservation layer (301) set up in the outside of branch dress pipe (3), and heat preservation layer (301) inside is the vacuum structure.

4. A storage device for biological samples according to claim 1, wherein: the branch dress pipe (3) still includes:

a disposable storage tube (302), the disposable storage tube (302) being disposed innermost;

a cooling pipe (303), wherein the cooling pipe (303) is arranged outside the disposable storage pipe (302).

5. A storage device for biological samples according to claim 4, wherein: the cooling pipe (303) is of a double-spiral structure with the tail ends communicated, and a group of air inlets and a group of air outlets are respectively formed in the bottom of the cooling pipe (303).

6. A storage device for biological samples according to claim 4, wherein: the branch dress pipe (3) still includes:

and the elastic valve core (304) is pressed on the air inlet and the air outlet at the bottom of the cooling pipe (303) through springs.

7. A storage device for biological samples according to claim 1, wherein: the switch valve (5) further comprises:

the valve core top plate (502), the valve core top plate (502) is fixedly connected to the top of the switch valve (5), and a grid is arranged on the valve core top plate (502).

8. A storage device for biological samples according to claim 1, wherein: the cooling linked switch mechanism further comprises:

the switch linkage driving shaft (306), the switch linkage driving shaft (306) is coaxially and fixedly connected to the bottom of the subpackaging pipe (3), and the section of the switch linkage driving shaft (306) is in a regular hexagon shape;

the switch linkage transmission shafts (4), the switch linkage transmission shafts (4) are connected to the top of the low-temperature storage base (1) in a circumferential array manner;

the switch linkage jack (401), the switch linkage jack (401) is arranged at the top of the switch linkage transmission shaft (4), the switch linkage jack (401) is of a regular hexagon hole-shaped structure, and when the sub-installation pipe (3) is installed, the switch linkage driving shaft (306) is connected with the switch linkage jack (401) in an inserting mode.

9. A storage device for biological samples according to claim 8, wherein: the cooling linked switch mechanism further comprises:

the switch driving bevel gear (402), the switch driving bevel gear (402) is coaxially and fixedly connected to the bottom of the switch linkage transmission shaft (4);

the switch driven bevel gears (501) are coaxially and fixedly connected to valve cores of the switch valves (5), and the two groups of switch driven bevel gears (501) are meshed with the switch driving bevel gear (402) simultaneously to form a bevel gear transmission mechanism.

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