阅读说明：本技术 一种合成生物样品存储系统 (Synthetic biological sample storage system ) 是由 吴永豪 于 2021-07-19 设计创作，主要内容包括：本发明公开了一种合成生物样品存储系统,其结构包括防护挡板、支脚、温控器、机体、存放装置,本发明进行使用时,实验人员通过把手将存放槽从保护腔内部拉出,通过防护挡板对存放槽的底部进行阻隔限位,存放槽受到拉力向外移动时,存放槽的底部会不离开保护腔,使得存放槽向外拉出后会呈倾斜状态,便于实验人员存放生物样品,生物样品存放完成后,通过温控器对机体的温度进行控制,有效保持生物样品的活性。(The invention discloses a synthetic biological sample storage system which structurally comprises a protective baffle, support legs, a temperature controller, a machine body and a storage device.)

1. The utility model provides a synthetic biological sample storage system, its structure includes guard shield (1), stabilizer blade (2), temperature controller (3), organism (4), strorage device (5), its characterized in that:

the protective baffle (1) is connected to a plurality of storage devices (5), the storage devices (5) are arranged on the machine body (4) in an equidistant mode, a temperature controller (3) is arranged on one side of the machine body (4), and the temperature controller (3) is communicated with the storage devices (5) through electric wires;

storage device (5) are including protection chamber (51), handle (52), storage tank (53), inside storage tank (53) that is equipped with of protection chamber (51), install handle (52) on storage tank (53), protection chamber (51) bottom is connected with two protective baffle (1), install on organism (4) protection chamber (51).

2. The synthetic biological sample storage system of claim 1, wherein: the protective cavity (51) comprises a frame body (511), a triangular plate (512), a protective buffering piece (513), a groove (514), a top plate (515), a fixed seat (516) and a deformation pulling piece (517), wherein the fixed seat (516) is installed at the middle position of the frame body (511), six triangular plates (512) which are connected with the fixed seat (516) in an inserting mode are arranged on the fixed seat (516), the protective buffering piece (513) is connected to one side, facing the triangular plate (512), of the fixed seat (516), one end, away from the fixed seat (516), of the protective buffering piece (513) is tightly attached to the groove (514), the top plates (515) are connected to two sides of the groove (514), the top plates (515) are matched with the triangular plate (512), the deformation pulling piece (517) is arranged on one side of the frame body (511), a storage groove (53) is arranged inside the frame body (511), and two protective baffles (1) are connected to the bottom of the frame body (511), the frame body (511) is installed on the machine body (4).

3. The synthetic biological sample storage system of claim 2, wherein: protection is slowly said (513) including connecting (C1), sealed air cushion (C2), elastic component (C3), connect (C1) and be equipped with two, connect (C1) for two and connect on two elastic component (C3), connect (C1) and keep away from the one end and the sealed air cushion (C2) fixed connection of elastic component (C3), sealed air cushion (C2) one end meets with recess (514), and the other end meets with fixing base (516).

4. The synthetic biological sample storage system of claim 2, wherein: deformation pulls piece (517) including paster (D1), links up bullet strip (D2), opens and closes piece (D3), deformation and draws piece (D4), butt joint angle (D5), carousel (D6), bull stick (D7), paster (D1) are connected on deformation pulls piece (D4), deformation pulls piece (D4) both sides and is equipped with butt joint angle (D5) identical with it, deformation pulls piece (D4) inside intermediate position and is equipped with linking bullet strip (D2), deformation pulls piece (D4) and keeps away from the one end lock joint of paster (D1) on butt joint angle (D5), butt joint angle (D5) are fixed on carousel (D6), carousel (D6) and bull stick (D7) activity block, bull stick (D7) are inserted and are inlayed on framework (511).

5. The synthetic biological sample storage system of claim 1, wherein: deposit groove (53) transfer piece (534), interface (535), supplementary fastener (536) including depositing chamber (531), placing mouth (532), chuck (533), activity, be equipped with on depositing chamber (531) and place mouth (532), it has chuck (533) to deposit chamber (531) externally mounted, chuck (533) inside is equipped with interface (535), chuck (533) inside is equipped with six activities that meet with it and transfers piece (534), six the activity is transferred piece (534) and is linked to each other through supplementary fastener (536), it establishes inside framework (511) to deposit chamber (531), it installs handle (52) on chamber (531) to deposit.

6. The synthetic biological sample storage system of claim 5, wherein: the movable adjusting piece (534) comprises a movable piece (E1), a contraction sleeve (E2), a contact head (E3), a shell (E4), a clamping seat (E5) and an overlapped elastic piece (E6), the movable piece (E1) is connected to the inside of the shell (E4) in a penetrating mode, one end of the movable piece (E1) is connected with the contraction sleeve (E2), the other end of the movable piece is connected with the overlapped elastic piece (E6), one end, far away from the movable piece (E1), of the overlapped elastic piece (E6) is vertically inserted and embedded into the clamping seat (E5), the clamping seat (E5) is matched with the shell (E4), the top of the shell (E4) is provided with the contact head (E3), the contact head (E3) is connected with the contraction sleeve (E2), the shell (E4) is connected to the inside of the chuck (533), and the clamping seat (E5) is connected with the auxiliary clamping piece (536).

7. The synthetic biological sample storage system of claim 5, wherein: supplementary fastener (536) are including connecting axle (F1), play steel sheet (F2), first enhancement layer (F3), second enhancement layer (F4), play steel sheet (F2) and be equipped with two, two play steel sheet (F2) and connect on connecting axle (F1), two it is equipped with first enhancement layer (F3), second enhancement layer (F4) to play between steel sheet (F2), the one end and the second enhancement layer (F4) butt joint of bullet steel sheet (F2) are kept away from in first enhancement layer (F3), connecting axle (F1) lock joint is on cassette (E5).

8. The synthetic biological sample storage system of claim 7, wherein: the first reinforcing layer (F3) and the second reinforcing layer (F4) are buckled and connected to form a rectangular structure.

Technical Field

The invention relates to the technical field of synthetic biology, in particular to a synthetic biological sample storage system.

Background

With the development of biological technology, cell therapy is rapidly developing and increasingly accepted worldwide, the fundamental aspect of cell therapy is the acquisition and storage of living cells, and in addition, the in vitro culture of cells has also been widely applied to various biological research fields, in the in vitro cell culture work, in order to preserve cells and make them have biological activity for a long time, the storage and recovery of cells become a crucial link, the storage tank is movably adjusted by an angle adjusting piece, and when storing biological samples, the improvement is needed:

when storing a biological sample, an experimenter needs to place the biological sample on a storage tank, because the placing grooves are mostly in a drawer translation shape, when an experimenter stores biological samples, the whole placing groove needs to be pulled out, the biological samples can be stored in the placing grooves, if the experimenter often forcibly pulls the placing grooves to the bottom when pulling the grooves, so that the placing groove and the sliding rails collide with each other due to acting force, the sliding rails on the two sides of the placing groove are damaged after a long time, and when the placing groove is pulled out, the placing groove is easy to separate from the sliding rail and fall off, if the experimenter does not support the placing groove in time, the separated placing groove can directly fall on the ground to generate overlarge collision force, so that the biological sample stored on the placing groove may be broken by the impact force generated by dropping the placing groove, thereby causing damage to the biological sample for the experiment.

Disclosure of Invention

Aiming at the defects in the prior art, the invention is realized by the following technical scheme: the utility model provides a synthetic biological sample storage system, its structure includes guard flap, stabilizer blade, temperature controller, organism, strorage device, guard flap connects on strorage device, strorage device is equipped with a plurality ofly, and a plurality of strorage device equidistance are installed on the organism, organism one side is equipped with the temperature controller, the temperature controller is linked together through the electric wire with strorage device.

As further optimization of the invention, the storage device comprises a protection cavity, a handle and a storage groove, the storage groove is arranged in the protection cavity, the handle is arranged on the storage groove, the bottom of the protection cavity is connected with two protective baffles, and the protection cavity is arranged on the machine body.

The protection cavity comprises a frame body, a triangular plate, a protection buffering piece, a groove, a top plate, a fixed seat and a deformation pulling piece, wherein the fixed seat is installed in the middle of the frame body, six triangular plates are arranged on the fixed seat and are inserted with the fixed seat, the protection buffering piece is connected to one side of the fixed seat, which faces the triangular plate, the end, away from the fixed seat, of the protection buffering piece is tightly attached to the groove, the top plate is connected to both sides of the groove, the top plate is matched with the triangular plate, the deformation pulling piece is arranged on one side of the frame body, a storage groove is formed in the frame body, two protection baffle plates are connected to the bottom of the frame body, and the frame body is installed on a machine body.

The protection buffering piece comprises two joints, a sealing air cushion and an elastic piece, wherein the two joints are connected to the two elastic pieces, one end of each joint, far away from the elastic piece, is fixedly connected with the sealing air cushion, one end of each sealing air cushion is connected with the corresponding groove, and the other end of each sealing air cushion is connected with the corresponding fixing seat.

As a further optimization of the invention, the deformation pulling piece comprises a patch, a connection elastic strip, a tensioning piece, a deformation pulling piece, a butt joint angle, a rotary table and a rotating rod, wherein the patch is connected to the deformation pulling piece, the butt joint angle matched with the deformation pulling piece is arranged on two sides of the deformation pulling piece, the connection elastic strip is arranged in the middle of the inside of the deformation pulling piece, one end of the deformation pulling piece, far away from the patch, is buckled on the butt joint angle, the butt joint angle is fixed on the rotary table, the rotary table is movably clamped with the rotating rod, and the rotating rod is inserted in the frame body.

As the further optimization of the invention, the storage groove comprises a storage cavity, a placement opening, a chuck, movable adjusting pieces, an interface and auxiliary clamping pieces, wherein the placement opening is formed in the storage cavity, the chuck is installed outside the storage cavity, the interface is arranged inside the chuck, six movable adjusting pieces connected with the chuck are arranged inside the chuck, the six movable adjusting pieces are connected through the auxiliary clamping pieces, the storage cavity is formed inside the frame body, and a handle is installed on the storage cavity.

As a further optimization of the invention, the movable adjusting piece comprises a movable piece, a shrinkage sleeve, a contact head, a shell, a clamping seat and a superposed elastic piece, wherein the movable piece is connected inside the shell in a penetrating manner, one end of the movable piece is connected with the shrinkage sleeve, the other end of the movable piece is connected with the superposed elastic piece, one end of the superposed elastic piece, which is far away from the movable piece, is vertically inserted and embedded on the clamping seat, the clamping seat is matched with the shell, the contact head is arranged at the top of the shell, the contact head is connected with the shrinkage sleeve, the shell is connected inside the chuck, and the clamping seat is connected with the auxiliary clamping piece.

As a further optimization of the invention, the auxiliary clamping piece comprises a connecting shaft, two elastic steel plates, a first reinforcing layer and a second reinforcing layer, the two elastic steel plates are connected to the connecting shaft, the first reinforcing layer and the second reinforcing layer are arranged between the two elastic steel plates, one end of the first reinforcing layer, which is far away from the elastic steel plates, is in butt joint with the second reinforcing layer, and the connecting shaft is buckled on the clamping seat.

As a further optimization of the invention, the first reinforcing layer and the second reinforcing layer are buckled and connected to form a rectangular structure.

Advantageous effects

The synthetic biological sample storage system has the following beneficial effects:

1. according to the invention, through the protective baffle, the protective cavity, the handle and the storage groove, an experimenter can pull out the storage groove from the interior of the protective cavity through the handle, the bottom of the storage groove is blocked and limited through the protective baffle, and when the storage groove is pulled to move outwards, the bottom of the storage groove does not leave the protective cavity, so that the storage groove can be in an inclined state after being pulled outwards, and the experimenter can store biological samples conveniently.

2. According to the invention, the storage tank is arranged in the frame body through the frame body, the groove, the top plate and the deformation pulling piece, the deformation pulling piece is connected to the side wall of the storage tank, the angle position of the storage tank is effectively limited, the phenomenon of overturning caused by overlarge stress is prevented, and the movable angle of the storage tank is adjusted through the matching of the groove and the top plate with the frame body.

3. According to the invention, the storage cavity, the placing opening, the chuck, the movable adjusting piece, the interface and the auxiliary clamping piece are arranged in the frame body through the chuck, the chuck rotates, and the movable adjusting piece can be effectively matched to control the movable angle of the chuck, so that the placing opening on the storage cavity can be completely exposed, and an experimenter can conveniently store biological samples.

Drawings

Other features, objects and advantages of the invention will become more apparent upon reading of the detailed description of non-limiting embodiments with reference to the following drawings:

FIG. 1 is a schematic diagram of a synthetic biological sample storage system according to the present invention;

fig. 2 is a schematic view of the internal structure of the storage device of the present invention.

FIG. 3 is a schematic side view of the protection chamber according to the present invention.

Fig. 4 is an enlarged structural diagram of a in fig. 3.

FIG. 5 is a schematic view of the internal structure of the deformation pulling member of the present invention.

FIG. 6 is a side view of the storage tank of the present invention.

Fig. 7 is a schematic sectional structure view of the movable adjusting member of the present invention.

Fig. 8 is a schematic cross-sectional structure view of the auxiliary clip of the present invention.

In the figure: the protective device comprises a protective baffle-1, a supporting leg-2, a temperature controller-3, a machine body-4, a storage device-5, a protective cavity-51, a handle-52, a storage groove-53, a frame-511, a triangular plate-512, a protective buffer-513, a groove-514, a top plate-515, a fixed seat-516, a deformation pulling piece-517, a joint-C1, a sealing air cushion-C2, an elastic piece-C3, a patch-D1, a connecting elastic strip-D2, an opening and closing piece-D3, a deformation pulling piece-D4, a butt joint angle-D5, a rotary disc-D6, a rotary rod-D7, a storage cavity-531, a placing opening-532, a chuck-533, a movable adjusting piece-534, a joint-535, an auxiliary clamping piece-536, a movable piece-E1, a contraction sleeve-E2, a joint-D7, a storage cavity-531, a storage cavity-511, a storage cavity-532, a movable adjusting piece-D-3, a storage cavity-E1, a contraction sleeve-E-2, a storage device, the device comprises a contact head-E3, a shell-E4, a clamping seat-E5, a superposed spring piece-E6, a connecting shaft-F1, a spring steel plate-F2, a first reinforcing layer-F3 and a second reinforcing layer-F4.

Detailed Description

In order to make the technical means, the creation characteristics, the achievement purposes and the effects of the invention easy to understand, the invention is further described with the specific embodiments.

Example one

Referring to fig. 1, the present invention provides a technical solution: the utility model provides a synthetic biological sample storage system, its structure includes guard shield 1, stabilizer blade 2, temperature controller 3, organism 4, strorage device 5, guard shield 1 is connected on strorage device 5, strorage device 5 is equipped with a plurality ofly, and a plurality of strorage device 5 equidistance are installed on organism 4, organism 4 one side is equipped with temperature controller 3, temperature controller 3 is linked together through the electric wire with strorage device 5.

Referring to fig. 2, the storage device 5 includes a protection cavity 51, a handle 52 and a storage slot 53, the storage slot 53 is disposed inside the protection cavity 51, the handle 52 is mounted on the storage slot 53, two protection baffles 1 are connected to the bottom of the protection cavity 51, and the protection cavity 51 is mounted on the machine body 4.

The protective baffle 1 is used for matching with the protective cavity 51, and when the experimenter pulls out the storage groove 53, the bottom of the storage groove 53 is blocked inside the protective cavity 51 through the protective baffle 1, so that the pulled-out storage groove 53 can be in an inclined state.

Referring to fig. 3, the protection cavity 51 includes a frame body 511, a triangular plate 512, a protection buffering member 513, a groove 514, a top plate 515, a fixing seat 516, and a deformation pulling member 517, the fixing seat 516 is installed at the middle position of the frame body 511, six triangular plates 512 inserted into the fixing seat 516 are arranged on the fixing seat 516, the protection buffering member 513 is connected to one side of the fixing seat 516 facing the triangular plate 512, one end of the protection buffering member 513 far away from the fixing seat 516 is tightly attached to the groove 514, the groove 514 is connected to the top plate 515, the top plate 515 is matched with the triangular plates 512, the deformation pulling member 517 is arranged on one side of the frame body 511, a storage groove 53 is arranged inside the frame body 511, the bottom of the frame body 511 is connected to two protection baffles 1, and the frame body 511 is installed on the machine body 4.

The triangular plate 512 is used for matching with the top plate 515, the triangular plate 512 is in a compact state and has triangular stability, and the top plate 515 can be effectively supported, so that the top plate 515 is not easy to deform after being pressed.

Referring to fig. 4, the protection buffer 513 includes two connectors C1, two sealing cushions C2, and two elastic members C3, the connector C1 is connected to the two elastic members C3, one end of the connector C1, which is far away from the elastic member C3, is fixedly connected to the sealing cushion C2, one end of the sealing cushion C2 is connected to the groove 514, and the other end is connected to the fixing base 516.

The sealing cushion C2 is used to match the groove 514, the groove 514 will contract inward when being impacted by external components, and the impact force on the groove 514 is absorbed by the sealing cushion C2, which effectively relieves the impact force on the groove 514.

Referring to fig. 5, the deformation pulling member 517 includes a patch D1, an engaging elastic strip D2, an opening-closing member D3, a deformation pulling member D4, an abutting angle D5, a rotating disc D6, and a rotating rod D7, the patch D1 is connected to the deformation pulling member D4, abutting angles D5 matched with the deformation pulling member D4 are disposed at two sides of the deformation pulling member D4, the engaging elastic strip D2 is disposed at the middle position inside the deformation pulling member D4, one end of the deformation pulling member D4 away from the patch D1 is fastened to the abutting angle D5, the abutting angle D5 is fixed to the rotating disc D6, the rotating disc D6 is movably fastened to the rotating rod D7, and the rotating rod D7 is inserted into the frame 511.

Foretell linking bullet strip D2 is used for cooperating deformation to draw a D4, deformation draws a D4 to connect on the lateral wall of storage tank 53 through paster D1, storage tank 53 is after outwards moving, deformation draws a D4 can draw the system to storage tank 53 along with the outside extension of storage tank 53's activity, it has the spring elasticity effect to link up bullet strip D2, can assist deformation to draw a D4 to draw the system, make deformation draw a D4 can reset fast after the shrink.

Example two

Referring to fig. 1, the present invention provides a technical solution: the utility model provides a synthetic biological sample storage system, its structure includes guard shield 1, stabilizer blade 2, temperature controller 3, organism 4, strorage device 5, guard shield 1 is connected on strorage device 5, strorage device 5 is equipped with a plurality ofly, and a plurality of strorage device 5 equidistance are installed on organism 4, organism 4 one side is equipped with temperature controller 3, temperature controller 3 is linked together through the electric wire with strorage device 5.

Referring to fig. 2, the storage device 5 includes a protection cavity 51, a handle 52 and a storage slot 53, the storage slot 53 is disposed inside the protection cavity 51, the handle 52 is mounted on the storage slot 53, two protection baffles 1 are connected to the bottom of the protection cavity 51, and the protection cavity 51 is mounted on the machine body 4.

The protective baffle 1 is used for matching with the protective cavity 51, and when the experimenter pulls out the storage groove 53, the bottom of the storage groove 53 is blocked inside the protective cavity 51 through the protective baffle 1, so that the pulled-out storage groove 53 can be in an inclined state.

Referring to fig. 6, the storage slot 53 includes a storage cavity 531, a placement opening 532, a chuck 533, a movable adjusting member 534, an interface 535, and an auxiliary clamping member 536, the storage cavity 531 is provided with the placement opening 532, the chuck 533 is installed outside the storage cavity 531, the interface 535 is installed inside the chuck 533, six movable adjusting members 534 connected to the chuck 533 are installed inside the chuck 533, the six movable adjusting members 534 are connected to each other through the auxiliary clamping member 536, the storage cavity 531 is installed inside the frame 511, and the handle 52 is installed on the storage cavity 531.

Referring to fig. 7, the movable adjusting member 534 includes a movable member E1, a retracting sleeve E2, a contact E3, a housing E4, a clamping seat E5, and an overlapped elastic member E6, the movable member E1 is connected inside the housing E4 in a penetrating manner, one end of the movable member E1 is connected to the retracting sleeve E2, the other end of the movable member E6 is connected to the overlapped elastic member E6, one end of the overlapped elastic member E6, away from the movable member E1, is vertically inserted into the clamping seat E5, the clamping seat E5 is matched with the housing E4, the contact E3 is arranged at the top of the housing E4, the contact E3 is connected to the retracting sleeve E2, the housing E4 is connected inside the chuck 533, and the clamping seat E5 is connected to the auxiliary clamping member 536.

The overlapped elastic piece E6 is used for being matched with the shrinkage sleeve E2, when the chuck 533 moves, the contact E3 is pressed by external pressure to contract inwards under the action of the shrinkage sleeve E2, the shrinkage sleeve E2 presses the movable piece E1 downwards, the overlapped elastic piece E6 contracts downwards after being pressed, and the overlapped elastic piece E6 is effectively matched with the shell E4 to perform telescopic movement adjustment.

Referring to fig. 8, the auxiliary clip 536 includes a connecting shaft F1, two spring steel plates F2, a first reinforcing layer F3 and a second reinforcing layer F4, the two spring steel plates F2 are provided, the two spring steel plates F2 are connected to the connecting shaft F1, a first reinforcing layer F3 and a second reinforcing layer F4 are provided between the two spring steel plates F2, one end of the first reinforcing layer F3, which is far away from the spring steel plate F2, is engaged with the second reinforcing layer F4, and the connecting shaft F1 is fastened to the fastening seat E5.

Referring to fig. 8, the first reinforcing layer F3 and the second reinforcing layer F4 are connected in a buckling manner to form a rectangular structure.

The first reinforcing layer F3 is used for matching with the second reinforcing layer F4, the first reinforcing layer F3 and the second reinforcing layer F4 are buckled together and connected to the middle position of the springing steel plate F2, and the first reinforcing layer F3 and the second reinforcing layer F4 are both in a triangular structure, so that the springing steel plate F2 is effectively supported through the stability of the triangle.

The working principle of the above technical solution is explained as follows:

when the invention is used, the storage groove 53 is stably arranged in the protection cavity 51, the fixed seat 516 can penetrate and extend into the interface 535, so that the fixed seat 516 and the chuck 533 can be stably buckled together, the chuck 533 can drive the movable adjusting piece 534 to stably rotate and adjust the angle position in the fixed seat 516, after the storage groove 53 is stably arranged in the protection cavity 51, an experimenter pulls out the storage cavity 531 through the handle 52, the chuck 533 and the fixed seat 516 are tightly buckled together, so that the upper end of the storage cavity 531 is pulled, the chuck 533 can rotate by the pulling movement of the storage cavity 531, the shell E4 can move along with the chuck 533 in the rotating process, the contact head E3 at the top of the shell E4 can be butted with the top plate 515 to generate a certain counter pressure, the top plate 515 is internally provided with a triangular plate 512 in a compact state, and the triangular plate 512 supports the top plate 515 through the stability of the triangle, the top plate 515 is not easy to shrink and bend when being stressed, so that the opposite pressure generated between the contact E3 and the top plate 515 is transmitted to the shrink sleeve E2, the shrink sleeve E2 has the function of a telescopic bellows and can shrink inwards after being stressed, the pressure is transmitted to the movable piece E1, the movable piece E1 transmits the pressure to the overlapped elastic piece E6, the overlapped elastic piece E6 shrinks downwards along with the pressure, the angle of the storage cavity 531 needs to be adjusted, an experimenter continuously applies force to pull the handle 52, the chuck 533 rotates under the traction force transmitted by the storage groove 53, the chuck 533 drives the shell E4 to move continuously, the whole shell E4 is fixedly inserted on the chuck 533 through the clamping seat E5, the shell E4 is not easy to separate in the movement, and after the angle of the storage cavity 531 is adjusted to a certain position, the contact E3 slides to the groove from the top plate 515, after the contact E3 leaves the top plate 515, the spring arranged in the overlapped spring E6 can instantly generate resilience without being pressed, the overlapped spring E6 can rapidly extend upwards to push up the movable piece E1 after being subjected to the resilience of the internal spring, the movable piece E1 transmits the resilience to the contraction sleeve E2, the contraction sleeve E2 can drive the contact E3 to extend upwards and expand after being subjected to the resilience, so that the contact E3 can be directly abutted against the groove 514, the contact E3 is connected to the groove 514 and can impact on the groove 514 due to the resilience in the process of being connected with the groove 514, the groove 514 is of a concave arc structure and can concentrate and transmit the pressure to the middle position of the groove 514 after being impacted, the groove 514 presses the pressure downwards in the sealing air cushion C2, the sealing air cushion C2 is in a closed state, the air in the sealing air cushion C2 cannot be pressed outwards and can be expanded downwards and expanded towards two sides after being pressed, the impact force received by the sealing air cushion C2 is transmitted to the elastic piece C3 through the joint C1, the elastic piece C3 assists the sealing air cushion C2 to disperse the impact force, so that the sealing air cushion C2 and the elastic piece C3 can be matched with each other to absorb the impact force received by the groove 514 and relieve the pressure, the stability of the groove 514 is ensured, the contact E3 can be stably connected to the groove 514, and the angle of the storage cavity 531 is effectively adjusted to be in an inclined state;

after the contact head E3 is connected to the groove 514, the top plate 515 abuts against the spring steel plate F2, the spring steel plate F2 is provided with a first reinforcing layer F3 and a second reinforcing layer F4 inside, the first reinforcing layer F3 and the second reinforcing layer F4 are both made into triangular structures, and the spring steel plate F2 has better stability, the first reinforcing layer F3 and the second reinforcing layer F4 are buckled together and connected to the middle position of the spring steel plate F2, so that the spring steel plate F2 can be effectively reinforced, the spring steel plate F2 cannot be deformed and bent due to the pressing of the top plate 515, the top plate 515 can be stably connected to the spring steel plate F2, the movable position of the shell E4 is limited through the groove 514, the top plate 515 abuts against the spring steel plate F2, the position of the adjusted storage cavity 531 is limited by the mutual cooperation of the two, the storage cavity 531 is prevented from returning downwards after being adjusted, and the storage cavity 531 can be stably adjusted to be in an inclined state, the storage cavity 531 is adjusted to be in an inclined state, the patch D1 is tightly attached to the bottom of the inner side of the storage cavity 531, the storage cavity 531 is in an angle adjustment state, the rotary disc D6 can adjust the angle of the deformation pulling piece D4 under the action of the rotary rod D7, so that the deformation pulling piece D4 can move along with the movement of the storage cavity 531, the opening and closing piece D3 and the deformation pulling piece D4 are matched with each other to perform stretching and drawing movement adjustment on the storage cavity 531, the elasticity of the elastic strip D2 is used for connecting to increase the elastic force of the deformation pulling piece D4, so that the deformation pulling piece D4 can effectively draw the storage cavity 531, the phenomenon that the storage cavity 531 is toppled over after being adjusted to be in the inclined state is prevented, biological samples stored in the storage cavity 531 are effectively protected, after the storage cavity 531 is in the inclined state, the storage cavity 532 can be completely exposed under the action of the storage cavity 531, and an experimenter can quickly and effectively place the biological samples on the storage cavity 531 stably through the storage cavity 532, biological sample deposits the completion back, the experimenter receives the first end that promotes to deposit chamber 531, chuck 533 can drive the activity and transfer piece 534 and carry out the activity gyration on recess 514 and roof 515 under the effect of depositing chamber 531, restrict the position of holding tank 53 through protective baffle 1 cooperation protection chamber 51, effectively will deposit chamber 531 and inwards withdraw the leveling, make and deposit chamber 531 and can stably store the biological sample, rethread temperature controller 3 adjusts the inside temperature of organism 4, make the inside temperature of holding tank 53 can be fit for biology, can effectively guarantee biological activity, the experimenter can stabilize and carry out experimental study to the biological sample.

In summary, the novel synthetic biological sample storage system is formed by combining the protective baffle, the support legs, the temperature controller, the body and the storage device, when a biological sample is stored, an experimenter pulls out the storage tank from the inside of the protective cavity through the handle, the bottom of the storage tank is blocked and limited through the protective baffle, when the storage tank is pulled outwards, the bottom of the storage tank does not leave the protective cavity, so that the storage tank can be in an inclined state after being pulled outwards, the experimenter can store the biological sample conveniently, and after the biological sample is stored, the temperature of the body is controlled through the temperature controller, so that the activity of the biological sample is effectively maintained.

While there have been shown and described what are at present considered the fundamental principles and essential features of the invention and its advantages, it will be apparent to those skilled in the art that the invention is not limited to the details of the foregoing exemplary embodiments, but is capable of other specific forms without departing from the spirit or essential characteristics 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.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.