CN112852631A

CN112852631A - Large-batch cell resuscitator capable of improving accurate temperature control

Info

Publication number: CN112852631A
Application number: CN202110235047.6A
Authority: CN
Inventors: 房文彬
Original assignee: Individual
Current assignee: Liu Anyan
Priority date: 2021-03-03
Filing date: 2021-03-03
Publication date: 2021-05-28
Anticipated expiration: 2041-03-03
Also published as: CN112852631B

Abstract

The invention provides a large-batch cell resuscitator capable of improving accurate temperature control, relates to the technical field of cell biology, and solves the problems that the uniform contact of heat generated by a barrel body and a heating pipe cannot be realized through structural improvement, the uniform contact of heat generated by a test tube and the heating pipe cannot be realized, and the elimination of a test tube heating dead angle cannot be realized; the heat generation by friction can not be realized through structural improvement, and the heat preservation protection of the heating pipe can not be realized through a friction heat generation structure. A large-batch cell resuscitator capable of improving accurate temperature control comprises a base; the welding has the cylindricality pole on the base, and rotates on the cylindricality pole and be connected with the staving. The third heating pipe is arranged in the friction seat, and the friction seat is of a concave structure; the third heating pipe forms an auxiliary heating structure of the barrel body; the friction seat forms a heat preservation structure of the third heating pipe.

Description

Large-batch cell resuscitator capable of improving accurate temperature control

Technical Field

The invention belongs to the technical field of cell biology, and particularly relates to a large-batch cell resuscitator capable of improving accurate temperature control.

Background

The main subjects of cell biology studies are various primary or subcultured cells or cell lines. In order to avoid the pollution caused by the cultured cells in the long-term in-vitro culture process or the gene mutation caused by multiple passages, an experimenter can freeze the cultured cells in the vigorous growth period, the frozen cells are stored in a cell freezing tube added with a cell freezing medium and then placed in liquid nitrogen at the temperature of-196 ℃, and the cells can be stored for a long time in the ultralow temperature environment. When the experiment is needed, an experimenter can revive the frozen cells at 37 ℃ to carry out the needed experiment, so that the genetic stability of the cells can be ensured to the maximum extent.

As in application No.: CN201510694871.2, the invention discloses a cell resuscitator, including the water bath, this cell resuscitator still includes: the lifting mechanism and the bearing device are arranged on the lifting mechanism; and the controller is electrically connected with the lifting mechanism and used for controlling the movement of the lifting mechanism and putting the bearing device into the water bath kettle. The invention realizes the automatic mass cell recovery process by combining the lifting mechanism and the controller, can accurately control the recovery time and temperature, records the recovery process parameters, avoids the possible pollution of water in the water bath on the cryopreserved cells, greatly improves the cell recovery quality, lightens the burden of operators and improves the working efficiency.

The cell resuscitator similar to the above application has the following disadvantages:

one is that the existing device has a single structure, cannot realize uniform contact between a barrel body and heating pipes to generate heat through structural improvement, cannot realize uniform contact between test tubes and heating pipes to generate heat, and cannot realize elimination of test tube heating dead angles; moreover, frictional heat generation cannot be realized through structural improvement, and the heat preservation protection of the heating pipe cannot be realized through a frictional heat generation structure.

Therefore, in view of the above, a large-scale cell resuscitator capable of improving the precise temperature control is provided by researching and improving the existing structure and defects, so as to achieve the purpose of higher practical value.

Disclosure of Invention

In order to solve the technical problems, the invention provides a large-batch cell resuscitator capable of improving accurate temperature control, aiming at solving the problems that the existing device has a single structure, cannot realize the uniform contact of heat generated by a barrel body and a heating pipe through structural improvement, cannot realize the uniform contact of heat generated by a test tube and the heating pipe, and cannot realize the elimination of the heating dead angle of the test tube; moreover, the friction heating structure can not realize the heat preservation protection of the heating pipe.

The invention relates to a purpose and an effect of a large-batch cell resuscitator capable of improving accurate temperature control, which are achieved by the following specific technical means:

a large-batch cell resuscitator capable of improving accurate temperature control comprises a base; a cylindrical rod is welded on the base, and a barrel body is rotatably connected to the cylindrical rod; the base is fixedly connected with a driving motor through a bolt, and the base is fixedly connected with an auxiliary structure; the auxiliary structure comprises a third heating pipe, the third heating pipe is arranged in the friction seat, and the friction seat is of a concave structure; the third heating pipe forms an auxiliary heating structure of the barrel body; the friction seat forms a heat preservation structure of the third heating pipe.

Furthermore, the base comprises fixing bolts, four fixing bolts are inserted into the base, and the four fixing bolts are fixedly connected with the embedded seat; the base is a concave seat-shaped structure, and the base forms an elastic anti-loosening structure for fixing the bolt.

Furthermore, the base also comprises first heating pipes which are arranged on the top end surface of the base in an annular array shape, and the first heating pipes are of cylindrical tubular structures; the first heating pipes are located below the barrel body, and the first heating pipes arranged in an annular array form jointly form an even heating structure of the barrel body.

Further, the staving is including placing the seat, rotating seat and test tube, place the seat welding in the staving, and place to rotate on the seat and be connected with six and rotate the seat, and every rotates and all pegs graft in the seat and has a test tube.

Further, the cylindrical rod comprises a mounting seat and a second heating pipe, the mounting seat is welded on the cylindrical rod, and the mounting seat is of an annular plate-shaped structure; the mounting seat is provided with second heating pipes in an annular array shape, the second heating pipes are located on the inner side of the barrel body, and the second heating pipes in the annular array shape form an even heating structure of the test tube.

Further, the barrel body comprises a gear B, and the gear B is welded on the outer side of the barrel body; the driving motor comprises a gear D, the rotating shaft of the driving motor is provided with the gear D, the gear D is meshed with the gear B, and the driving motor and the gear D jointly form a rotary driving type structure of the barrel body.

Furthermore, the cylindrical rod further comprises a gear A, and the gear A is welded on the cylindrical rod; the barrel body further comprises six gears C, and the six gears C are respectively welded on the six rotating seats; six gears C all mesh with gear A, and gear A constitutes six and rotates seat synchronous drive structure.

Furthermore, the auxiliary structure comprises a seat body, sliding rods, a friction seat and an elastic piece, wherein the seat body is fixedly connected to the base through bolts, the seat body is connected with the two sliding rods in a sliding manner, and the two sliding rods are of stepped shaft-shaped structures; the friction seat is connected with the two sliding rods in a welding mode, the two sliding rods are sleeved with the elastic piece in a sleeved mode, and the friction seat is in elastic contact with the outer wall of the barrel body.

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

through cylindricality pole, staving, driving motor and auxiliary structure's cooperation setting, at first when the staving rotates, can guarantee staving bottom and the even contact of first heating pipe production heat, secondly, can guarantee test tube and the even contact of second heating pipe production heat, once more, can eliminate the heating dead angle of test tube, can also guarantee the heat preservation of third heating pipe and the frictional heating of friction seat and staving at last, specifically as follows: firstly, the first heating pipes are arranged on the top end surface of the base in an annular array shape, and are of cylindrical tubular structures; the first heating pipes are positioned below the barrel body, and the first heating pipes arranged in an annular array form together form a uniform heating structure of the barrel body; the mounting seat is welded on the cylindrical rod and is of an annular plate-shaped structure; second heating pipes are arranged on the mounting seat in an annular array manner and are positioned on the inner side of the barrel body, and the second heating pipes arranged in the annular array manner jointly form a uniform heating structure of the test tube; a gear D is mounted on a rotating shaft of the driving motor, the gear D is meshed with the gear B, and the driving motor and the gear D jointly form a rotary driving type structure of the barrel body, so that the bottom of the barrel body can be uniformly heated, and the test tube can be uniformly contacted with the second heating tube to generate heat; six gears C are arranged and respectively welded on the six rotating seats; the six gears C are all meshed with the gear A, and the gear A forms a six-rotating-seat synchronous driving structure, so that when the barrel body rotates, the six rotating seats and the six test tubes are in a rotating state, and the heating dead angle of the test tubes is eliminated; secondly, the seat body is fixedly connected to the base through bolts, and two sliding rods are connected to the seat body in a sliding manner and are of stepped shaft-shaped structures; the friction seat is connected with the two sliding rods in a welding mode, the two sliding rods are respectively sleeved with an elastic piece in a sleeved mode, and the friction seat is in elastic contact with the outer wall of the barrel body, so that the barrel body can be uniformly heated through friction between the friction seat and the outer wall of the barrel body, and the elastic pieces can automatically feed when the friction seat is abraded; the third heating pipe is arranged in the friction seat, and the friction seat is of a concave structure; the third heating pipe forms an auxiliary heating structure of the barrel body; the friction seat forms a heat preservation structure of the third heating pipe.

Drawings

Fig. 1 is a schematic axial view of the present invention.

Fig. 2 is a schematic front view of the present invention.

Fig. 3 is a schematic cross-sectional structure of the present invention.

Fig. 4 is an enlarged schematic view of fig. 3 a according to the present invention.

Fig. 5 is an enlarged view of the structure of fig. 3B according to the present invention.

Fig. 6 is an enlarged view of the structure of fig. 3C according to the present invention.

FIG. 7 is a front view of the cylindrical rod and barrel of the present invention.

In the drawings, the corresponding relationship between the component names and the reference numbers is as follows:

1. a base; 101. fixing the bolt; 102. a first heating pipe; 2. a cylindrical rod; 201. a mounting seat; 202. a second heating pipe; 203. a gear A; 3. a barrel body; 301. a placing seat; 302. a rotating seat; 303. a test tube; 304. a gear B; 305. a gear C; 4. a drive motor; 401. a gear D; 5. an auxiliary structure; 501. a base body; 502. a slide bar; 503. a friction seat; 504. an elastic member; 505. and a third heating pipe.

Detailed Description

The embodiments of the present invention will be described in further detail with reference to the drawings and examples. The following examples are intended to illustrate the invention but are not intended to limit the scope of the invention.

In the description of the present invention, "a plurality" means two or more unless otherwise specified; the terms "upper", "lower", "left", "right", "inner", "outer", "front", "rear", "head", "tail", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are only for convenience in describing and simplifying the description, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, should not be construed as limiting the invention. Furthermore, the terms "first," "second," "third," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "connected" and "connected" are to be interpreted broadly, e.g., as being fixed or detachable or integrally connected; can be mechanically or electrically connected; may be directly connected or indirectly connected through an intermediate. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Example (b):

as shown in figures 1 to 7:

the invention provides a large-batch cell resuscitator capable of improving accurate temperature control, which comprises a base 1; a cylindrical rod 2 is welded on the base 1, and a barrel body 3 is rotatably connected on the cylindrical rod 2; the base 1 is fixedly connected with a driving motor 4 through bolts, and the base 1 is fixedly connected with an auxiliary structure 5; referring to fig. 3 and 5, the auxiliary structure 5 includes a third heating pipe 505, the third heating pipe 505 is installed in the friction seat 503, and the friction seat 503 is a concave structure; third heating pipe 505 constitutes an auxiliary heating structure of barrel 3; friction seat 503 constitutes a heat-insulating structure of third heating pipe 505.

Referring to fig. 1, the base 1 includes fixing bolts 101, four fixing bolts 101 are inserted into the base 1, and the four fixing bolts 101 are fixedly connected with the embedded seat; the base 1 is a concave seat-shaped structure, and the base 1 constitutes an elastic anti-loose structure of the fixing bolt 101.

Referring to fig. 2, the base 1 further includes a first heating pipe 102, the first heating pipes 102 are mounted on the top end surface of the base 1 in an annular array, and the first heating pipe 102 has a cylindrical tubular structure; the first heating pipes 102 are located below the barrel body 3, and the first heating pipes 102 installed in an annular array form together form a uniform heating structure of the barrel body 3.

Referring to fig. 3, the barrel 3 includes a placing seat 301, a rotating seat 302 and test tubes 303, the placing seat 301 is welded in the barrel 3, six rotating seats 302 are rotatably connected to the placing seat 301, and each rotating seat 302 is inserted with one test tube 303.

Referring to fig. 3, the cylindrical rod 2 includes a mounting seat 201 and a second heating pipe 202, the mounting seat 201 is welded on the cylindrical rod 2, and the mounting seat 201 has an annular plate-shaped structure; the second heating pipes 202 are mounted on the mounting seat 201 in an annular array manner, the second heating pipes 202 are located on the inner side of the barrel body 3, and the second heating pipes 202 mounted in an annular array manner jointly form an even heating structure of the test tubes 303.

Referring to fig. 3, the tub 3 includes a gear B304, the gear B304 being welded outside the tub 3; driving motor 4 includes gear D401, installs a gear D401 on driving motor 4's the axis of rotation, and gear D401 and gear B304 mesh to driving motor 4 and gear D401 have constituteed the rotary drive formula structure of staving 3 jointly, thereby can realize the even heating of staving 3 bottom and test tube 303 and the even contact of second heating pipe 202 production heat.

Referring to fig. 3 and 6, the cylindrical rod 2 further includes a gear a203, and one gear a203 is welded to the cylindrical rod 2; the barrel body 3 further comprises six gears C305, and the six gears C305 are respectively welded on the six rotating seats 302; six gears C305 are all meshed with the gear A203, and the gear A203 forms a synchronous driving structure of six rotating seats 302, so that when the barrel body 3 rotates, the six rotating seats 302 and six test tubes 303 are in a rotating state, and the heating dead angle of the test tubes 303 is eliminated.

Referring to fig. 3 and 4, the auxiliary structure 5 includes a seat body 501, a sliding rod 502, a friction seat 503 and an elastic member 504, wherein the seat body 501 is fixedly connected to the base 1 through a bolt, two sliding rods 502 are slidably connected to the seat body 501, and both sliding rods 502 are stepped shaft-shaped structures; the friction seat 503 is connected with the two sliding rods 502 by welding, the two sliding rods 502 are respectively sleeved with an elastic piece 504, and the friction seat 503 is elastically contacted with the outer wall of the barrel body 3, so that the barrel body 3 can be uniformly heated by the friction between the friction seat 503 and the outer wall of the barrel body 3, and the elastic pieces 504 can automatically feed when the friction seat 503 is worn.

The specific use mode and function of the embodiment are as follows:

when the driving motor 4 rotates, firstly, the first heating pipes 102 are installed on the top end surface of the base 1 in an annular array shape, and the first heating pipes 102 are cylindrical tubular structures; the first heating pipes 102 are positioned below the barrel body 3, and the first heating pipes 102 arranged in an annular array form jointly form a uniform heating structure of the barrel body 3; the mounting seat 201 is welded on the cylindrical rod 2, and the mounting seat 201 is of an annular plate-shaped structure; the second heating pipes 202 are arranged on the mounting seat 201 in an annular array, the second heating pipes 202 are positioned on the inner side of the barrel body 3, and the second heating pipes 202 arranged in the annular array form a uniform heating structure of the test tubes 303; a gear D401 is mounted on a rotating shaft of the driving motor 4, the gear D401 is meshed with the gear B304, and the driving motor 4 and the gear D401 jointly form a rotary driving type structure of the barrel body 3, so that the bottom of the barrel body 3 can be uniformly heated and the test tube 303 and the second heating pipe 202 can be uniformly contacted with each other to generate heat; six gears C305 are arranged, and the six gears C305 are respectively welded on the six rotating seats 302; the six gears C305 are all meshed with the gear A203, and the gear A203 forms a synchronous driving structure of six rotating seats 302, so that when the barrel body 3 rotates, the six rotating seats 302 and the six test tubes 303 are in a rotating state, and the heating dead angle of the test tubes 303 is eliminated; secondly, the seat body 501 is fixedly connected to the base 1 through bolts, and the seat body 501 is slidably connected with two sliding rods 502, and the two sliding rods 502 are both of stepped shaft-shaped structures; the friction seat 503 is connected with the two sliding rods 502 in a welding manner, the two sliding rods 502 are respectively sleeved with an elastic piece 504, and the friction seat 503 is in elastic contact with the outer wall of the barrel body 3, so that the barrel body 3 can be uniformly heated through friction between the friction seat 503 and the outer wall of the barrel body 3, and the elastic pieces 504 can automatically feed when the friction seat 503 is worn; the third heating pipe 505 is installed in the friction seat 503, and the friction seat 503 is a concave structure; third heating pipe 505 constitutes an auxiliary heating structure of barrel 3; the friction seat 503 constitutes a heat-insulating structure of the third heating pipe 505;

when in fixation, four fixing bolts 101 are inserted into the base 1, and the four fixing bolts 101 are fixedly connected with the embedded seat; the base 1 is a concave seat-shaped structure, and the base 1 constitutes an elastic anti-loose structure of the fixing bolt 101.

The embodiments of the present invention have been presented for purposes of illustration and description, and are not intended to be exhaustive or limited to the invention in the form disclosed. Many modifications and variations will be apparent to those of ordinary skill in the art. The embodiment was chosen and described in order to best explain the principles of the invention and the practical application, and to enable others of ordinary skill in the art to understand the invention for various embodiments with various modifications as are suited to the particular use contemplated.

Claims

1. The utility model provides a can improve big cell resuscitator of accurate temperature control which characterized in that: comprises a base (1); a cylindrical rod (2) is welded on the base (1), and a barrel body (3) is rotatably connected to the cylindrical rod (2); the base (1) is fixedly connected with a driving motor (4) through a bolt, and the base (1) is fixedly connected with an auxiliary structure (5); the auxiliary structure (5) comprises a third heating pipe (505), the third heating pipe (505) is installed in the friction seat (503), and the friction seat (503) is of a concave structure; the third heating pipe (505) forms an auxiliary heating structure of the barrel body (3); the friction seat (503) forms a heat preservation structure of the third heating pipe (505).

2. A large batch cell resuscitator capable of improving precise temperature control as claimed in claim 1, wherein: the base (1) comprises fixing bolts (101), four fixing bolts (101) are inserted into the base (1), and the four fixing bolts (101) are fixedly connected with the embedded seat; the base (1) is of a concave seat-shaped structure, and the base (1) forms an elastic anti-loosening structure of the fixing bolt (101).

3. A large batch cell resuscitator capable of improving precise temperature control as claimed in claim 1, wherein: the base (1) further comprises first heating pipes (102), the first heating pipes (102) are arranged on the top end face of the base (1) in an annular array shape, and the first heating pipes (102) are of cylindrical tubular structures; the first heating pipes (102) are located below the barrel body (3), and the first heating pipes (102) arranged in an annular array form jointly form a uniform heating structure of the barrel body (3).

4. A large batch cell resuscitator capable of improving precise temperature control as claimed in claim 1, wherein: staving (3) are including placing seat (301), rotating seat (302) and test tube (303), place seat (301) and weld in staving (3), and place seat (301) and go up to rotate and be connected with six and rotate seat (302), and all peg graft in every rotation seat (302) and have a test tube (303).

5. A large batch cell resuscitator capable of improving precise temperature control as claimed in claim 1, wherein: the cylindrical rod (2) comprises an installation seat (201) and a second heating pipe (202), the installation seat (201) is welded on the cylindrical rod (2), and the installation seat (201) is of an annular plate-shaped structure; second heating pipes (202) are mounted on the mounting seat (201) in an annular array manner, the second heating pipes (202) are located on the inner side of the barrel body (3), and the second heating pipes (202) mounted in an annular array manner jointly form an even heating structure of the test tubes (303).

6. A large batch cell resuscitator capable of improving precise temperature control as claimed in claim 1, wherein: the barrel body (3) comprises a gear B (304), and the gear B (304) is welded on the outer side of the barrel body (3); the driving motor (4) comprises a gear D (401), the gear D (401) is installed on the rotating shaft of the driving motor (4), the gear D (401) is meshed with the gear B (304), and the driving motor (4) and the gear D (401) jointly form a rotary driving structure of the barrel body (3).

7. A large batch cell resuscitator capable of improving precise temperature control as claimed in claim 1, wherein: the cylindrical rod (2) further comprises a gear A (203), and the gear A (203) is welded on the cylindrical rod (2); the barrel body (3) further comprises six gears C (305), and the six gears C (305) are respectively welded on six rotating seats (302); the six gears C (305) are all meshed with the gear A (203), and the gear A (203) forms a synchronous driving structure of six rotating seats (302).

8. A large batch cell resuscitator capable of improving precise temperature control as claimed in claim 1, wherein: the auxiliary structure (5) comprises a base body (501), sliding rods (502), a friction seat (503) and an elastic piece (504), wherein the base body (501) is fixedly connected to the base (1) through bolts, the base body (501) is connected with the two sliding rods (502) in a sliding mode, and the two sliding rods (502) are of stepped shaft-shaped structures; the friction seat (503) is connected with the two sliding rods (502) in a welding mode, the two sliding rods (502) are respectively sleeved with an elastic piece (504), and the friction seat (503) is in elastic contact with the outer wall of the barrel body (3).