CN116588515A - Automatic change low temperature storage facilities - Google Patents

Abstract

The application relates to the technical field of laboratory equipment, and particularly provides automatic low-temperature storage equipment, which comprises a box body assembly, a control assembly, a storage assembly and a refrigerating device, wherein the box body assembly is arranged on the refrigerating device and comprises a box body, a driving piece and a push rod, a storage cavity is arranged in the middle of the box body, an opening at the upper end of the storage cavity penetrates through the upper end face of the box body, and the storage assembly is used for entering and exiting the storage cavity from the opening; the upper end face of the box body is symmetrically provided with mounting cavities at two opposite sides of the storage cavity, and the driving piece and the push rod are both mounted in the mounting cavities; wherein, the setting of driving piece has realized the purpose of automatic rising storage module to suitable height, satisfies the user demand, alleviates the problem that the use is complicated, and refrigerating plant sets up in the lower extreme of box subassembly, reduces area when guaranteeing low temperature storage effect, effectively improves space utilization.

Description

Automatic change low temperature storage facilities

Technical Field

The application relates to the technical field of laboratory equipment, in particular to automatic low-temperature storage equipment.

Background

At present, laboratories often use cryogenic storage devices to store items at low temperatures, and the items that are primarily used for storage include: cell line material, blood, tissue, organs, seeds, and other reagents that require cryogenic storage are stored.

The low-temperature storage equipment in the current market is mainly divided into a vertical front door and a horizontal top door. The structure of the vertical front door opening of the low-temperature storage equipment is unfavorable for keeping cold quantity and avoiding cold air leakage; the low-temperature storage equipment with the horizontal top door has the advantages that the cold insulation capacity of the top door structure is good, lower temperature can be achieved, but the top door structure is inconvenient for storing and taking articles, the refrigerator case is to be placed on the side face of the storage box body for controlling the article taking height, the occupied area is large, the space utilization rate is poor, and the two forms can not completely meet the user demands.

Disclosure of Invention

The application aims to solve the problem that the existing low-temperature storage equipment cannot meet the demands of users.

In order to solve the problems, the application provides the following technical scheme:

the automatic low-temperature storage device comprises a box body assembly, a control assembly, a storage assembly and a refrigerating device, wherein the box body assembly is used for being arranged on the refrigerating device, the box body assembly comprises a box body, a driving piece and a push rod, a storage cavity is formed in the middle of the box body, an opening at the upper end of the storage cavity penetrates through the upper end face of the box body, and the storage assembly is used for entering and exiting the storage cavity from the opening;

the upper end face of the box body is symmetrically provided with mounting cavities at two opposite sides of the storage cavity, the driving piece and the push rod are both mounted in the mounting cavities, the lower end of the push rod is used for being connected with the driving piece, and one end of the push rod, which is far away from the driving piece, is connected with the upper end of the storage assembly; the driving piece is used for driving the push rod to enable the push rod to enter and exit the mounting cavity and enable the storage assembly to enter and exit the storage cavity at the same time;

the control assembly is arranged on the outer wall of the box body and used for controlling the driving piece to work.

Compared with the prior art, the automatic low-temperature storage device provided by the application has the following beneficial effects:

in this embodiment, since the opening at the upper end of the storage cavity penetrates through the upper end face of the box body assembly, the storage assembly is used for entering and exiting the storage cavity from the opening, when the control assembly controls the driving piece in the installation cavity to work so as to drive the push rod to move up and down, the push rod drives the storage assembly to move up and down so as to enter and exit the storage cavity of the box body, when the push rod pushes the storage assembly to move up and to the upper side of the box body, the storage assembly is exposed from the storage cavity, so that a user can conveniently place an article to be stored on the storage assembly, and when the push rod drives the storage assembly to move down to the storage assembly to retract into the storage cavity, the refrigeration device is used for refrigeration storage; wherein, the setting of driving piece has realized the purpose of automatic rising storage module to suitable height, satisfies the user demand, alleviates the problem that the use is complicated, and refrigerating plant sets up in the lower extreme of box subassembly, reduces area when guaranteeing low temperature storage effect, effectively improves space utilization.

Preferably, the driving piece comprises a mounting frame, a driving motor, a ball screw and a sliding block, wherein the driving motor is mounted on the mounting frame and is used for driving the ball screw to rotate;

the push rod is in sliding connection with the mounting frame, a thread groove is formed in the push rod, one end of the thread groove penetrates through the end part of the push rod, and the ball screw is in threaded connection with the inside of the thread groove;

the push rod is close to the one end outer wall of driving motor is provided with the sliding block, the inner wall of mounting bracket is followed the axial direction of push rod is provided with the sliding tray, the sliding block with sliding tray sliding connection.

Preferably, the driving piece further comprises a first synchronous wheel, a second synchronous wheel, a synchronous belt and a bearing, the driving end of the driving motor is connected with the first synchronous wheel, one end, close to the driving motor, of the ball screw is rotatably arranged on the mounting frame through the bearing, one end, close to the driving motor, of the ball screw is connected with the second synchronous wheel, and the synchronous belt is connected between the first synchronous wheel and the second synchronous wheel.

Preferably, the box assembly further comprises a guide rod and guide blocks, wherein the guide blocks are symmetrically arranged on two sides of the mounting frame in the mounting cavity, and guide holes are formed in the guide blocks in a penetrating mode; the upper end of the guide rod is fixedly connected with the upper end of the storage assembly, and the lower end of the guide rod is used for entering and exiting the guide hole.

Preferably, the storage assembly comprises a storage box and a storage box, the size of the storage box is matched with that of the storage cavity, the storage box is used for entering and exiting the storage cavity from the opening, a plurality of storage compartments are arranged in the storage box, and a plurality of storage boxes are used for being installed in the storage compartments.

Preferably, the storage assembly further comprises a storage cover, the storage cover is arranged at the upper end of the storage box, the projection of the storage cover on the horizontal plane is identical with the projection of the box body on the horizontal plane, and the push rod and the guide rod are both connected to the lower end face of the storage cover.

Preferably, the storage assembly further comprises a sealing landing, the sealing landing is arranged between the storage cover and the storage box, the sealing landing is provided with a first connecting surface and a second connecting surface which are oppositely arranged, the area of the first connecting surface is larger than that of the second connecting surface, the first connecting surface is connected with the storage cover, and the second connecting surface is consistent with the upper end surface of the storage box and is connected with the upper end surface of the storage box; the upper end face of the box body faces the opening, and a sealing groove is formed in the upper end face of the box body and matched with the sealing landing.

Preferably, the box assembly further comprises an access door, access holes are formed in two opposite side walls of the box body respectively, the access holes are communicated with the storage cavity, and the access door is installed at the access holes and used for covering the access holes.

Preferably, the control assembly comprises a control button, a scram button, a control display screen and a control system, wherein the control button, the scram button and the control display screen are all electrically connected with the control system, and the control system is used for controlling the driving piece.

Preferably, the automated cryogenic storage device further comprises rollers, and four rollers are disposed at four corners of the lower end surface of the refrigeration device.

Drawings

FIG. 1 is a schematic diagram of an overall structure of an automated cryogenic storage facility according to an embodiment of the present application;

FIG. 2 is a schematic diagram of an embodiment of the application after the automated cryogenic storage omits the body of the enclosure;

FIG. 3 is a schematic cross-sectional view of a driving member according to an embodiment of the present application;

FIG. 4 is a schematic view of a box body according to an embodiment of the present application;

FIG. 5 is a schematic diagram of a memory module according to an embodiment of the application.

Reference numerals illustrate:

1 box assembly, 11 box body, 110 seal groove, 12 driving piece, 121 mounting bracket, 122 driving motor, 123 ball screw, 124 sliding block, 125 sliding groove, 126 first synchronizing wheel, 127 second synchronizing wheel, 128 hold-in range, 129 bearing, 13 push rod, 130 screw thread groove, 14 storage cavity, 15 installation cavity, 16 guide rod, 17 guide block, 18 guiding hole, 19 access door, 2 control assembly, 21 control button, 22 scram button, 23 control display screen, 3 storage assembly, 31 storage box, 32 storage cover, 33 sealed landing, 4 refrigerating plant, 5 gyro wheel.

Detailed Description

Embodiments of the present application are described in further detail below with reference to the accompanying drawings and examples. The following examples are illustrative of the application but are not intended to limit the scope of the application.

In the description of the present application, it should be understood that the directions or positional relationships indicated by the terms "upper", "lower", "front", "rear", "left", "right", etc., are based on the directions or positional relationships shown in the drawings, are merely for convenience of describing the present application and simplifying the description, and do not indicate or imply that the components or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present application.

In the coordinate system XYZ provided herein, the positive direction of the X axis represents the right direction, the negative direction of the X axis represents the left direction, the positive direction of the Y axis represents the front direction, the negative direction of the Y axis represents the rear direction, the positive direction of the Z axis represents the upper direction, and the negative direction of the Z axis represents the lower direction; the Z-axis, X-axis, Y-axis are meant to be illustrative only and to simplify the description of the present application and are not indicative or implying that the components or elements referred to must have, be configured and operated in a particular orientation and therefore should not be construed as limiting the present application.

Referring to fig. 1-4, the automatic cryogenic storage device provided by the application comprises a box assembly 1, a control assembly 2, a storage assembly 3 and a refrigerating device 4, wherein the box assembly 1 is used for being arranged on the refrigerating device 4, the box assembly 1 comprises a box body 11, a driving piece 12 and a push rod 13, a storage cavity 14 is arranged in the middle of the box body 11, an opening at the upper end of the storage cavity 14 penetrates through the upper end face of the box body 11, and the storage assembly 3 is used for entering and exiting the storage cavity 14 from the opening;

referring to fig. 1-2, the upper end surface of the box body 11 is symmetrically provided with mounting cavities 15 on two opposite sides of the storage cavity 14, the driving member 12 and the push rod 13 are both mounted in the mounting cavities 15, the lower end of the push rod 13 is used for being connected with the driving member 12, and one end of the push rod 13 away from the driving member 12 is connected with the upper end of the storage assembly 3; the driving member 12 is configured to drive the push rod 13 to move the push rod 13 into and out of the mounting cavity 15 and simultaneously move the storage assembly 3 into and out of the storage cavity 14; the control assembly 2 is arranged on the outer wall of the box body 11, and the control assembly 2 is used for controlling the driving piece 12 to work.

In this embodiment, since the opening at the upper end of the storage cavity 14 penetrates through the upper end surface of the box body 11 of the box assembly 1, the storage assembly 3 is configured to enter and exit the storage cavity 14 from the opening, so that when the control assembly 2 controls the driving member 12 located in the installation cavity 15 to work to drive the push rod 13 to move up and down, the push rod 13 drives the storage assembly 3 to move up and down to enter and exit the storage cavity 14 of the box body 11, and when the push rod 13 pushes the storage assembly 3 to move up above the box body 11, the storage assembly 3 is exposed from the storage cavity 14, so that a user can conveniently place an article to be stored on the storage assembly 3, and when the push rod 13 drives the storage assembly 3 to move down to retract into the storage cavity 14, the refrigeration device 4 performs refrigeration storage; wherein, the setting of driving piece 12 has realized automatically will storage module 3 rises to the purpose of suitable height, satisfies the user demand, alleviates the complicated problem of use, just refrigerating plant 4 sets up the lower extreme of box subassembly 1 reduces area when guaranteeing low temperature storage effect, effectively improves space utilization.

Referring to fig. 2 to 3, the driving member 12 preferably includes a mounting frame 121, a driving motor 122, a ball screw 123, and a sliding block 124, wherein the driving motor 122 is mounted on the mounting frame 121, and the driving motor 122 is used for driving the ball screw 123 to rotate;

the push rod 13 is slidably connected with the mounting frame 121, a threaded groove 130 is formed in the push rod 13, one end of the threaded groove 130 penetrates through the end of the push rod 13, and the ball screw 123 is in threaded connection with the inside of the threaded groove 130; the push rod 13 is provided with the sliding block 124 near the outer wall of one end of the driving motor 122, the inner wall of the mounting frame 121 is provided with a sliding groove 125 along the axial direction of the push rod 13, and the sliding block 124 is slidably connected with the sliding groove 125.

Specifically, the mounting frame 121 is mounted in the mounting cavity 15, the driving motor 122 is mounted in an inner bottom of the mounting cavity 15 and is used for driving the ball screw 123, a sliding hole matched with the push rod 13 is formed in one end of the mounting frame 121 away from the driving motor 122, and the push rod 13 is located in the sliding hole and is in sliding connection with the sliding hole; the other end of the push rod 13 is mounted outside the ball screw 123 and is screwed with the ball screw 123.

In this embodiment, the driving motor 122 drives the ball screw 123 to rotate, because the ball screw 123 is in threaded connection with the inside of the push rod 13, when the ball screw 123 rotates, the rotational motion is converted into the linear motion, so that the push rod 13 enters and exits from the sliding hole into and out of the mounting frame 121, and further, the push rod 13 moves up and down, wherein, due to the arrangement of the sliding block 124 and the sliding groove 125, the push rod 13 is ensured not to rotate circumferentially when moving, so as to ensure the stability of the push rod 13 when moving.

Referring to fig. 2-3, preferably, the driving member 12 further includes a first synchronizing wheel 126, a second synchronizing wheel 127, a synchronous belt 128 and a bearing 129, the driving end of the driving motor 122 is connected with the first synchronizing wheel 126, one end of the ball screw 123 close to the driving motor 122 is rotatably disposed on the mounting frame 121 through the bearing 129, one end of the ball screw 123 close to the driving motor 122 is connected with the second synchronizing wheel 127, and the synchronous belt 128 is connected between the first synchronizing wheel 126 and the second synchronizing wheel 127.

In this embodiment, the driving motor 122 works to drive the first synchronizing wheel 126 to rotate, and since the first synchronizing wheel 126 and the second synchronizing wheel 127 are connected with the synchronous belt 128, the second synchronizing wheel 127 is further driven to rotate, so as to drive the ball screw 123 to rotate, the structure is simpler, so as to realize up-and-down movement of the push rod 13, and the automatic lifting of the storage component 3 is facilitated, and the operation is simple and the use is convenient.

In other embodiments, the driving member 12 may also be a hydraulic device, an actuating device, and a magnetic driving device.

Referring to fig. 2, preferably, the box assembly 1 further includes a guide rod 16 and a guide block 17, the guide blocks 17 are symmetrically disposed on two sides of the mounting frame 121 in the mounting cavity 15, and guide holes 18 are disposed through the guide blocks 17; the upper end of the guide rod 16 is fixedly connected with the upper end of the storage assembly 3, and the lower end of the guide rod 16 is used for entering and exiting the guide hole 18.

In this embodiment, the guide rod 16 has a guiding function, and the guide rod 16 and the guide hole 18 are matched with each other, so that the storage component 3 does not shift in position when moving up and down, which is beneficial to enabling the storage component 3 to accurately rise to a proper position at the upper end of the box body 11 and descend to retract into a proper position in the storage cavity 14 of the box body 11.

Referring to fig. 2, the storage assembly 3 preferably includes a storage box 31 and a storage box, the storage box 31 is sized to match the size of the storage cavity 14, the storage box 31 is used for entering and exiting the storage cavity 14 from the opening, a plurality of storage compartments are provided in the storage box 31, and a plurality of storage boxes are used for being installed in the storage compartments.

In this embodiment, the control component 2 controls the driving member 12 to drive the push rod 13 to drive the storage box 31 to move upwards to a preset proper position, a user opens the required storage box, and after taking out the required article, the user operates the control component 2 to move the storage box 31 with the storage box to a proper position in the storage cavity 14; the storage box is used for storing articles, only one storage compartment is opened, the structure is good in cold insulation, and the problem of cold air leakage in other areas is avoided.

Referring to fig. 1-2, preferably, the storage assembly 3 further includes a storage cover 32, the storage cover 32 is configured to be disposed at an upper end of the storage box 31, a projection of the storage cover 32 on a horizontal plane coincides with a projection of the box body 11 on the horizontal plane, and the push rod 13 and the guide rod 16 are both connected to a lower end face of the storage cover 32.

In this embodiment, the storage box 31 is matched with the storage cavity 14, when the storage box 31 is located in the storage cavity 14, the upper end of the storage box 31 is located at the opening of the storage cavity 14, and the storage cover 32 covers the outside of the opening and is located at the upper end of the box body 11, which is beneficial to strengthening the tightness of the box body 11 and solving the problem of leakage of cold air.

Referring to fig. 4 to 5, preferably, the storage assembly 3 further includes a sealing landing 33, the sealing landing 33 is disposed between the storage cover 32 and the storage box 31, the sealing landing 33 has a first connection surface and a second connection surface disposed opposite to each other, the first connection surface has an area larger than that of the second connection surface, and the first connection surface is connected to the storage cover 32, and the second connection surface is consistent with an upper end surface of the storage box 31 and connected to an upper end surface of the storage box 31; the upper end face of the box body 11 faces the opening, a sealing groove 110 is arranged at the opening, and the sealing groove 110 is matched with the sealing landing 33.

Specifically, the cross section of the sealing landing 33 is in an isosceles trapezoid structure, and the first connection surface and the second connection surface are respectively an upper bottom surface and a lower bottom surface of the sealing landing.

In this embodiment, the sealing step 33 and the sealing groove 110 are disposed to facilitate the connection between the storage cover 32 and the box body 11, thereby further facilitating the improvement of the sealing effect, enhancing the cold insulation function of the box body 11, and solving the problem of cold air leakage.

Referring to fig. 1, preferably, the box assembly 1 further includes an access door 19, access openings are respectively provided on two opposite side walls of the box body 11, and the access openings are communicated with the storage cavity 14, and the access door 19 is installed at the access openings and is used for covering the access openings.

In this embodiment, the access door 19 is configured to facilitate timely maintenance of the storage cavity 14, and when the storage box 31 is located in the storage cavity 14 and fails, a user may also open the access door 19 to perform maintenance on the storage box 31 through the access opening.

Referring to fig. 1, the control assembly 2 preferably includes a control button 21, a scram button 22, a control display screen 23, and a control system, and the control button 21, the scram button 22, and the control display screen 23 are all electrically connected to the control system, and the control system is used for controlling the driving member 12.

In particular, the control assembly 2 is located on a side wall of the housing body 11, in an ergonomic position.

In this embodiment, the control button 21 is used to cooperate with the control system to control the switch of the driving member 12, the emergency stop button 22 is used to control the driving member 12 to stop in emergency when the driving member 12 fails, and the control display screen 23 may display the working states and related data of the refrigeration device 4 and the driving member 12.

In other embodiments, the control assembly 2 may also be a voice control device and a remote control device.

Referring to fig. 1, preferably, the automated cryogenic storage apparatus further includes rollers 5, and four of the rollers 5 are disposed at four corners of a lower end surface of the cooling device 4.

In this embodiment, the rollers 5 are provided to facilitate flexible movement of the automated cryogenic storage equipment to a suitable location.

Although the present disclosure is described above, the scope of protection of the present disclosure is not limited thereto. Various changes and modifications may be made by one skilled in the art without departing from the spirit and scope of the disclosure, and these changes and modifications will fall within the scope of the application.

Claims (10)

1. The automatic low-temperature storage device is characterized by comprising a box body assembly (1), a control assembly (2), a storage assembly (3) and a refrigerating device (4), wherein the box body assembly (1) is used for being arranged on the refrigerating device (4), the box body assembly (1) comprises a box body (11), a driving piece (12) and a push rod (13), a storage cavity (14) is arranged in the middle of the box body (11), an opening at the upper end of the storage cavity (14) penetrates through the upper end face of the box body (11), and the storage assembly (3) is used for entering and exiting the storage cavity (14) from the opening;

the upper end face of the box body (11) is symmetrically provided with mounting cavities (15) on two opposite sides of the storage cavity (14), the driving piece (12) and the push rod (13) are both mounted in the mounting cavities (15), the lower end of the push rod (13) is used for being connected with the driving piece (12), and one end, far away from the driving piece (12), of the push rod (13) is connected with the upper end of the storage assembly (3); the driving piece (12) is used for driving the push rod (13) to enable the push rod (13) to enter and exit the mounting cavity (15) and enable the storage assembly (3) to enter and exit the storage cavity (14) at the same time;

the control assembly (2) is arranged on the outer wall of the box body (11), and the control assembly (2) is used for controlling the driving piece (12) to work.

2. The automated cryogenic storage plant of claim 1, wherein the drive (12) comprises a mounting frame (121), a drive motor (122), a ball screw (123) and a slider (124), the drive motor (122) being mounted to the mounting frame (121), and the drive motor (122) being configured to drive the ball screw (123) in rotation;

the push rod (13) is in sliding connection with the mounting frame (121), a threaded groove (130) is formed in the push rod (13), one end of the threaded groove (130) penetrates through the end portion of the push rod (13), and the ball screw (123) is in threaded connection with the inside of the threaded groove (130);

the push rod (13) is close to one end outer wall of the driving motor (122) is provided with the sliding block (124), the inner wall of the mounting frame (121) is provided with the sliding groove (125) along the axial direction of the push rod (13), and the sliding block (124) is in sliding connection with the sliding groove (125).

3. The automated cryogenic storage device of claim 2, wherein the drive member (12) further comprises a first synchronizing wheel (126), a second synchronizing wheel (127), a synchronous belt (128) and a bearing (129), the drive end of the drive motor (122) is connected with the first synchronizing wheel (126), one end of the ball screw (123) close to the drive motor (122) is rotatably arranged on the mounting frame (121) through the bearing (129), and one end of the ball screw (123) close to the drive motor (122) is connected with the second synchronizing wheel (127), and the synchronous belt (128) is connected between the first synchronizing wheel (126) and the second synchronizing wheel (127).

4. The automated cryogenic storage plant according to claim 2, characterized in that the tank assembly (1) further comprises a guide rod (16) and guide blocks (17), the guide blocks (17) are symmetrically arranged on both sides of the mounting rack (121) in the mounting cavity (15), and guide holes (18) are arranged on the guide blocks (17) in a penetrating manner; the upper end of the guide rod (16) is fixedly connected with the upper end of the storage assembly (3), and the lower end of the guide rod (16) is used for entering and exiting the guide hole (18).

5. The automated cryogenic storage plant according to claim 4, wherein the storage assembly (3) comprises a storage bin (31) and a storage box, the storage bin (31) being sized to match the size of the storage cavity (14), the storage bin (31) being adapted to access the storage cavity (14) from the opening, a plurality of storage compartments being provided in the storage bin (31), a plurality of the storage boxes being adapted to be mounted in the storage compartments.

6. The automated cryogenic storage plant of claim 5, wherein the storage assembly (3) further comprises a storage lid (32), the storage lid (32) is configured to be disposed at an upper end of the storage tank (31), and a projection of the storage lid (32) on a horizontal plane coincides with a projection of the tank body (11) on a horizontal plane, and the push rod (13) and the guide rod (16) are both connected to a lower end face of the storage lid (32).

7. The automated cryogenic storage plant of claim 6, wherein the storage assembly (3) further comprises a sealing landing (33), the sealing landing (33) being arranged between the storage lid (32) and the storage bin (31), the sealing landing (33) having oppositely arranged first and second connection faces, the first connection face having an area larger than the second connection face, and the first connection face being connected with the storage lid (32), the second connection face being congruent with an upper face of the storage bin (31) and being connected with an upper face of the storage bin (31); the upper end face of the box body (11) faces the opening, a sealing groove (110) is formed in the upper end face of the box body, and the sealing groove (110) is matched with the sealing landing (33).

8. The automated cryogenic storage plant according to claim 1, wherein the tank assembly (1) further comprises access doors (19), access openings being provided in opposite side walls of the tank body (11), respectively, the access openings being in communication with the storage chamber (14), the access doors (19) being mounted at the access openings for covering the access openings.

9. The automated cryogenic storage plant of claim 1, wherein the control assembly (2) comprises a control button (21), a scram button (22), a control display screen (23) and a control system, the control button (21), the scram button (22) and the control display screen (23) each being electrically connected to the control system, the control system being for controlling the drive (12).

10. The automated cryogenic storage plant of claim 1, further comprising rollers (5), four of the rollers (5) being disposed at four corners of the lower end face of the refrigeration unit (4).