CN116355756A

CN116355756A - Constant temperature incubator of cell culture

Info

Publication number: CN116355756A
Application number: CN202310230601.0A
Authority: CN
Inventors: 冷玉娇; 卓成柳
Original assignee: Shenzhen Yiai Health Management Co ltd
Current assignee: Shenzhen Yiai Health Management Co ltd
Priority date: 2023-03-11
Filing date: 2023-03-11
Publication date: 2023-06-30

Abstract

The invention relates to the technical field of constant temperature incubator for cell culture, in particular to a constant temperature incubator for cell culture, which comprises an incubator main body, wherein a box door is arranged on the incubator main body, a constant temperature device is arranged on one side of the incubator main body, a microscope is arranged at the upper end of the incubator main body, and a bracket mechanism with lifting and opening functions is arranged in the incubator main body; secondly, when the ocular needs to be replaced, the ocular returns to the initial position through adjusting the microscope, under the action of the rebound force of the spring, the two groups of plugboards are automatically combined, so that the guide pipe is closed, and the microscope is more convenient to adjust because the microscope is positioned at the outer side of the incubator main body, and meanwhile, the opening and closing of the inside of the guide pipe can be realized through adjusting the lifting of the microscope, so that the condition that the external air enters into the incubator main body through the faucet pipe and the guide pipe when the ocular is replaced is avoided.

Description

Constant temperature incubator of cell culture

Technical Field

The invention relates to the technical field of constant temperature incubators for cell culture, in particular to a constant temperature incubator for cell culture.

Background

The constant temperature incubator is a generic name of a constant temperature cavity, is widely applied to scientific research departments such as medical and health, medical industry, biochemistry, industrial production, agricultural science and the like, and is mainly used for culturing various microorganisms or tissues, cells and other organisms, and when the cells or embryos are cultured, the growth condition of the cells or embryos needs to be observed at any time so as to record data or adjust a culture scheme, so that the required cells or embryos are cultured. In the prior art, a microscope is arranged in a constant temperature incubator, so that a worker can observe cells in a culture dish in real time.

In actual use, because the microscope is installed in the constant temperature incubator, lead to the constant temperature incubator inner space to diminish, make the staff get and put the culture dish very inconvenient, secondly because when using the microscope, on the one hand the microscope needs to be adjusted, on the other hand it is isolated with the external world to accomplish that the cell is cultivated in the constant temperature incubator, therefore when adjusting the microscope, the staff can not open the constant temperature incubator and operate, then just set up two sets of operation mouths in constant temperature incubator one side, the rubber glove is connected to the operation mouth inboard, during operation, stretch into the rubber glove with the hand through the operation mouth in, make the operation of hand take rubber glove adjust the microscope, because rubber glove is located the constant temperature incubator inside, therefore cause the constant temperature incubator inner space to further diminish, during operation microscope is taken to the rubber glove fixed connection operation mouth, lead to the hand range of motion limited, make other operations such as the staff at the adjustment microscope, change objective are very inconvenient.

Disclosure of Invention

The invention aims to provide a constant temperature incubator for cell culture, which solves the problems in the prior art.

In order to achieve the above purpose, the present invention provides the following technical solutions: a constant temperature incubator for cell culture comprises an incubator main body, wherein a box door is arranged on the incubator main body, a constant temperature device is arranged on one side of the incubator main body, a microscope is arranged at the upper end of the incubator main body, and a bracket mechanism with lifting and opening and closing functions is arranged in the incubator main body;

the bracket mechanism comprises a tray, three groups of rectangular holes are formed in the tray at equal angles, the rectangular holes are inserted into the movable carrier, the middle of the tray is connected with the rotating shaft, one side of the tray is provided with a lug, the upper end of the lug is fixedly connected with the connecting rod, and the connecting rod is connected with the docking mechanism.

Preferably, the movable carrier comprises a lifting block, a limit groove is formed in the upper end face of the lifting block, two groups of L-shaped clamping plates are arranged on two sides of the limit groove, two groups of guide posts are symmetrically arranged between the two groups of L-shaped clamping plates, the L-shaped clamping plates are connected with pin shafts in a plugging mode, and the lower ends of the lifting block are connected with rollers in a screwing mode.

Preferably, the L-shaped clamping plate comprises a plate body, a first distance-changing hole is formed in the plate body, an arc-shaped surface is formed at one end of the plate body, two groups of through holes are symmetrically formed in the plate body, the lifting block is in sliding connection with the rectangular hole, the culture dish is placed in the limiting groove, and the culture dish is located between the two groups of plate bodies.

Preferably, the docking mechanism comprises a connecting pipe, a spring is sleeved on the connecting pipe, the connecting pipe is connected with a guide pipe in a plugging mode, two groups of jacks are symmetrically formed in two sides of the guide pipe, the jacks are connected with plugging components in a plugging mode, the plugging components are connected with sliding rods in a plugging mode, and L-shaped rods are arranged on the plugging components.

Preferably, the plugging assembly comprises a plugboard, plugboard plugholes are formed in one end of the plugboard, a guide hole is formed in one end of the plugboard, the upper end face of the plugboard is fixedly connected with a support plate, and a second variable-distance hole is formed in the support plate.

Preferably, the upper port of the connecting pipe is opposite to a group of ocular on the microscope, the guide pipe is fixedly connected with the connecting rod, the sliding rod is slidingly connected with the guide hole, and the sliding rod is fixed in the mounting groove.

Preferably, the incubator main body up end sets up the mounting groove, and the symmetry sets up two sets of inclined planes on the lug to the lug is fixed in the incubator main body, and the pivot connects the incubator main body soon, and docking mechanism places in the mounting groove.

Preferably, the guide post is connected with the through hole in a sliding manner, the guide post is fixed on the lifting block, the pin shaft is inserted into the first variable-pitch hole, the pin shaft is connected with the first variable-pitch hole in a sliding manner, one end of the pin shaft is welded in the rectangular hole, and the roller is connected with the bottom surface of the incubator body in a rolling manner.

Preferably, two groups of L-shaped rods are symmetrically and fixedly connected to two sides of the upper end of the connecting pipe, the end parts of the L-shaped rods are inserted into the second variable-pitch holes, and the end parts of the L-shaped rods are slidably connected with the second variable-pitch holes.

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

1. the microscope is adjusted to enable one group of ocular to move downwards, the moved ocular is inserted into the faucet tube, the ocular can extrude the faucet tube along with the ocular inserted into the faucet tube, the faucet tube moves downwards along the guide tube and compresses the spring, the faucet tube drives two groups of L-shaped rods, at the moment, the end parts of the L-shaped rods are positioned at the turning parts of the second variable-pitch holes, therefore, the end parts of the downwards moved L-shaped rods can extrude the turning parts of the second variable-pitch holes, the support plate drives the inserting plates to slide along the sliding rods, the two groups of inserting plates move back until the end parts of the L-shaped rods stagger the turning parts of the second variable-pitch holes, the two groups of inserting plates move back to open the inside of the guide tube, the ocular can continuously push the faucet tube to move downwards until the lower end of the faucet tube extends into the incubator body, and then the eyepiece is returned to the initial position through the microscope, and the two groups of inserting plates are automatically combined under the rebound force of the spring, so that the microscope is positioned at the outer side of the incubator body, the microscope is more convenient to adjust, and the inside the guide tube can be replaced through the lifting of the microscope, and the inside the incubator body can be prevented from being opened and closed with the outside air when the inside of the incubator body is required to be replaced.

2. The rotating shaft drives the tray to rotate, the rotating tray enables the rollers on the three groups of movable carriers to roll along the bottom surface of the incubator main body, along with the rolling of the rollers, the rollers on one group of movable carriers firstly contact with the inverted inclined surface arranged on one side of the lug, the rollers roll upwards along the inverted inclined surface, meanwhile, the inverted inclined surface pushes the lifting block to support the culture dish to slide upwards along the rectangular hole through the rollers, the culture dish moves upwards in the rotating process, the rollers continuously approach the bearing pipe extending into the incubator main body until the rollers are located at the highest point of the lug, the culture dish is close to the lower end of the bearing pipe, the lower end of the bearing pipe is opposite to the culture dish, therefore, the eyepiece can observe cells in the culture dish through the bearing pipe, after observation, the rotating shaft continues to rotate, the rollers on one group of movable carriers roll downwards along the inverted inclined surface arranged on the other side of the lug, and meanwhile, the rollers on the other group of movable carriers roll upwards along the lug again, so that the culture dish can be conveniently observed by workers in turn.

Drawings

FIG. 1 is a schematic diagram of the present invention.

FIG. 2 is a schematic view of the incubator body, microscope, bracket mechanism, and culture dish assembly in section of the present invention.

FIG. 3 is a schematic view of a tray mechanism and culture dish assembly according to the present invention.

Fig. 4 is an assembly schematic view of the docking mechanism of the present invention.

FIG. 5 is a schematic diagram of the combination of the mobile carrier and the culture dish according to the present invention.

Fig. 6 is a schematic diagram of a tray and lifting block combination according to the present invention.

In the figure: 1. an incubator body; 10. a mounting groove; 2. a door; 3. a thermostat device; 4. a microscope; 5. a bracket mechanism; 6. a culture dish; 501. a tray; 502. a rectangular hole; 503. a movable carrier; 504. a rotating shaft; 505. a bump; 5051. an inverted slope; 506. a receiving rod; 507. a docking mechanism; 5031. a lifting block; 5032. a limit groove; 5033. a roller; 5034. an L-shaped clamping plate; 5035. a guide post; 5036. a pin shaft; 41. a plate body; 42. a first variable-pitch hole; 43. an arc surface; 44. a through hole; 5071. a socket pipe; 5072. a spring; 5073. a guide tube; 5074. a jack; 5075. a plugging assembly; 5076. a slide bar; 5077. an L-shaped rod; 51. inserting plate; 52. a guide hole; 53. a support plate; 54. and a second pitch-changing hole.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Referring to fig. 1 to 6, the present invention provides a technical solution: a constant temperature incubator for cell culture comprises an incubator body 1, wherein a box door 2 is arranged on the incubator body 1, a constant temperature device 3 is arranged on one side of the incubator body 1, a microscope 4 is arranged at the upper end of the incubator body 1, a bracket mechanism 5 with lifting and opening functions is arranged in the incubator body 1, an installation groove 10 is arranged on the upper end surface of the incubator body 1, a docking mechanism 507 is arranged in the installation groove 10, the docking mechanism 507 comprises a faucet 5071, a spring 5072 is sleeved on the faucet 5071, the faucet 5071 is connected with a guide pipe 5073 in a plugging manner, two groups of jacks 5074 are symmetrically arranged on two sides of the guide pipe 5073, a plugging assembly 5075 is connected with a plugging slide rod 5076 in a plugging manner, an L-shaped rod 5077 is arranged on the plugging assembly 5075, the plugging assembly 5075 comprises a plug board 51, the plug jack 5074 is connected with one end of the plug board 51, a guide hole 52 is formed in the upper end surface of the plug board 51 is fixedly connected with a support board 53, a distance-changing hole two 54 is arranged on the support board 53, the upper port of the bearing pipe 5071 is opposite to a group of ocular on the microscope 4, the guide pipe 5073 is fixedly connected with the bearing rod 506, the sliding rod 5076 is slidingly connected with the guide hole 52, the sliding rod 5076 is fixed in the mounting groove 10, two groups of L-shaped rods 5077 are symmetrically and fixedly connected at two sides of the upper end of the bearing pipe 5071, the end part of each L-shaped rod 5077 is connected with the corresponding distance-changing hole II 54 in a plugging manner, the end part of each L-shaped rod 5077 is slidingly connected with the corresponding distance-changing hole II 54, the culture dish 6 contains culture solution, cell samples are positioned in the culture solution, when the cells are cultured, three groups of culture dishes 6 are respectively placed in the limiting grooves 5032 on the three groups of lifting blocks 5031, the limiting grooves 5032 play a role in positioning the culture dish 6, then the box door 2 is closed, the constant-temperature culture of the cell samples in the culture dish 6 is realized by setting the constant-temperature device 3, when the cell growth condition in the culture dish 6 needs to be observed, by adjusting the microscope 4, a group of ocular move downwards, the moved ocular is inserted into the faucet 5071, as the ocular is inserted into the faucet 5071, the ocular is extruded into the faucet 5071, the faucet 5071 is moved downwards along the guide tube 5073, and the spring 5072 is compressed, and simultaneously the faucet 5071 drives two groups of L-shaped rods 5077, at the moment, the end part of the L-shaped rod 5077 is positioned at the turning part of the second variable pitch hole 54, therefore, the end part of the L-shaped rod 5077 moved downwards is extruded into the turning part of the second variable pitch hole 54, the support plate 53 drives the inserting plate 51 to slide along the sliding rod 5076, the two groups of inserting plates 51 are moved back until the end part of the L-shaped rod 5077 is opened inside the guide tube 5073, the ocular is continuously pushed to move downwards until the lower end of the faucet 5071 extends into the incubator body 1, and then the ocular is replaced by adjusting the microscope 4, and under the rebound of the spring 5072, so that the two groups of ocular can automatically slide along the sliding rod 5076, and the two groups of inserting plates 51 are closed inside the guide tube 5073 by adjusting the microscope body 5073, and simultaneously, the microscope body is closed by adjusting the microscope body 5073, and the air is more convenient to change the microscope body inside the microscope body 1.

The bracket mechanism 5 comprises a tray 501, three groups of rectangular holes 502 are equiangularly arranged on the tray 501, a movable carrier 503 is inserted into the rectangular holes 502, a rotating shaft 504 is connected to the middle part of the tray 501, a bump 505 is arranged on one side of the tray 501, the upper end of the bump 505 is fixedly connected with a receiving rod 506, the receiving rod 506 is connected with a docking mechanism 507, the movable carrier 503 comprises a lifting block 5031, the upper end surface of the lifting block 5031 is provided with a limit groove 5032, the lower end of the lifting block 5031 is rotatably connected with a roller 5033, two groups of inverted inclined planes 5051 are symmetrically arranged on the bump 505, the bump 505 is fixed in the incubator body 1, the rotating shaft 504 is rotatably connected with the incubator body 1, the roller 5033 is in rolling connection with the bottom surface of the incubator body 1, a culture dish 6 is placed in the limit groove 5032, and the culture dish 6 is positioned between the two groups of plate bodies 41, wherein after the eyepiece and the receiving tube 5071 extend into the incubator body 1, the rotating shaft 504 drives the tray 501 to rotate, the rotating tray 501 enables the rollers 5033 on the three groups of movable carriers 503 to roll along the bottom surface of the incubator body 1, along with the rolling of the rollers 5033, the rollers 5033 on one group of movable carriers 503 will firstly contact the inverted inclined surface 5051 arranged on one side of the protruding block 505, the rollers 5033 roll upwards along the inverted inclined surface 5051, meanwhile, the inverted inclined surface 5051 pushes the lifting block 5031 to slide upwards along the rectangular hole 502 along the culture dish 6 through the rollers 5033, so that the culture dish 6 moves upwards in the rotating process, and continuously approaches the bearing pipe 5071 extending into the incubator body 1 until the rollers 5033 are positioned at the highest point of the protruding block 505, at this time, the culture dish 6 is close to the lower end of the bearing pipe 5071, and the lower end of the bearing pipe 5071 is right against the culture dish 6, therefore, the observation of cells in the culture dish 6 can be realized through the bearing pipe 5071, after the observation, the rotation of the rotating shaft 504 is continued under the action of gravity, the rollers 5033 on one set of movable carriers 503 roll down along the inverted inclined plane 5051 arranged on the other side of the protruding block 505, and meanwhile, the rollers 5033 on the other set of movable carriers 503 roll up along the protruding block 505 again, so that the operator can conveniently and alternately observe the plurality of groups of culture dishes 6.

Two groups of L-shaped clamping plates 5034 are arranged on two sides of the limiting groove 5032, two groups of guide posts 5035 are symmetrically arranged between the two groups of L-shaped clamping plates 5034, the L-shaped clamping plates 5034 are connected with pin shafts 5036 in a plugging mode, the L-shaped clamping plates 5034 comprise a plate body 41, a first distance-changing hole 42 is formed in the plate body 41, an arc-shaped surface 43 is arranged at one end of the plate body 41, two groups of through holes 44 are symmetrically formed in the plate body 41, a lifting block 5031 is in sliding connection with the rectangular hole 502, the guide posts 5035 are in sliding connection with the through holes 44, the guide posts 5035 are fixed on the lifting block 5031, the pin shafts 5036 are connected with the first distance-changing hole 42 in a plugging mode, one end of each pin shaft 5036 is welded in the rectangular hole 502, the first distance-changing hole 42 is not in a straight hole, and when the roller 5033 rolls upwards along the reverse inclined surface 5051, the lifting block 5031 and the two groups of L-shaped clamping plates 5034 slide upwards along the rectangular holes 502, at the moment, the two groups of pin shafts 5036 slide along the first two groups of variable-pitch holes 42 respectively, the pin shafts 5036 are positioned at the turning positions of the first variable-pitch holes 42, the guide posts 5035 press the turning positions of the first variable-pitch holes 42 to enable the plate bodies 41 to move towards the culture dish 6, so that the two groups of plate bodies 41 move towards each other along the guide posts 5035 until the pin shafts 5036 stagger the turning positions of the first variable-pitch holes 42, at the moment, the culture dish 6 is clamped between the arc-shaped surfaces 43 at the end parts of the two groups of plate bodies 41, thereby realizing the fixation of the culture dish 6, avoiding the deflection of the culture dish 6 in the rotation and lifting processes, and ensuring that the culture dish 6 is positioned in the limiting groove 5032.

In the use process, three groups of culture dishes 6 are respectively placed in the limiting grooves 5032 on the three groups of lifting blocks 5031, the limiting grooves 5032 play a role in positioning the culture dishes 6, then the box door 2 is closed, constant-temperature culture is realized on cell samples in the culture dishes 6 by setting the constant-temperature device 3, when the cell growth condition in the culture dishes 6 needs to be observed, a group of ocular lenses are downwards moved by adjusting the microscope 4, the moved ocular lenses are inserted into the bearing pipes 5071, the ocular lenses press the bearing pipes 5071 along with the insertion of the ocular lenses into the bearing pipes 5071, the bearing pipes 5071 downwards move along the guide pipes 5073, the springs 5072 are compressed, meanwhile, the bearing pipes 5071 drive the two groups of L-shaped rods 5077, at the moment, the end parts of the L-shaped rods 5077 are positioned at the corners of the second distance-changing holes 54, therefore, the end parts of the L-shaped rods 5077 downwards move can press the corners of the second distance-changing holes 54, the support plates 53 drive the insertion plates 51 to slide along the insertion plates 5076, the two sets of plugboards 51 move back until the end parts of the L-shaped rods 5077 are staggered from the turning parts of the second variable pitch holes 54, the two sets of plugboards 51 moving back open the inside of the guide tube 5073, the ocular continues to push the bearing tube 5071 to move downwards until the lower end of the bearing tube 5071 extends into the incubator body 1, then the rotating shaft 504 is rotated, the rotating shaft 504 drives the tray 501 to rotate, the rotating tray 501 enables the rollers 5033 on the three sets of movable carriers 503 to roll along the bottom surface of the incubator body 1, the rollers 5033 on one set of movable carriers 503 firstly contact the inverted inclined surface 5051 arranged on one side of the protruding block 505 along the inverted inclined surface 5051 along the rolling of the rollers 5033, the inverted inclined surface 5051 pushes the lifting block 5031 to slide upwards along the rectangular hole 502 to support the culture dish 6 through the rollers 5033, the culture dish 6 is enabled to move upwards in the rotating process, and continuously approaches the connecting pipe 5071 extending into the incubator body 1 until the roller 5033 is positioned at the highest point of the convex block 505, at this time, the culture dish 6 is close to the lower end of the connecting pipe 5071, when the roller 5033 rolls upwards along the inverted inclined plane 5051, the lifting block 5031 and the two groups of L-shaped clamping plates 5034 slide upwards along the rectangular hole 502, at this time, the two groups of pins 5036 slide along the two groups of variable-pitch holes I42 respectively, and because the pins 5036 are positioned at the corners of the variable-pitch holes I42, the guide posts 5035 press the corners of the variable-pitch holes I42 to enable the plate 41 to move towards the culture dish 6, so that the two groups of plate 41 move towards each other along the guide posts 5035 until the pins 5036 are staggered from the corners of the variable-pitch holes I42, at this time, the culture dish 6 is clamped between the arc surfaces 43 at the ends of the two groups of the plate 41, and finally, the ocular lens can realize observation of cells in the culture dish 6 through the connecting pipe 5071.

Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims

1. The utility model provides a constant temperature incubator of cell culture, includes the incubator main part, set up the chamber door in the incubator main part, incubator main part one side sets up constant temperature equipment, and incubator main part upper end sets up microscope, its characterized in that: a bracket mechanism with lifting and opening functions is arranged in the incubator main body;

the bracket mechanism comprises a tray, three groups of rectangular holes are formed in the tray at equal angles, the rectangular holes are inserted into the movable carrier, the middle of the tray is connected with a rotating shaft, one side of the tray is provided with a protruding block, the upper end of the protruding block is fixedly connected with a bearing rod, and the bearing rod is connected with the docking mechanism.

2. A constant temperature incubator for cell culture according to claim 1, wherein: the movable carrier comprises a lifting block, a limit groove is formed in the upper end face of the lifting block, two groups of L-shaped clamping plates are arranged on two sides of the limit groove, two groups of guide posts are symmetrically arranged between the L-shaped clamping plates, the L-shaped clamping plates are connected with pin shafts in an inserting mode, and the lower ends of the lifting block are connected with idler wheels in a rotating mode.

3. A constant temperature incubator for cell culture according to claim 2, wherein: the L-shaped clamping plate comprises a plate body, a first distance-changing hole is formed in the plate body, an arc-shaped surface is formed in one end of the plate body, two groups of through holes are symmetrically formed in the plate body, the lifting blocks are slidably connected with the rectangular holes, a culture dish is placed in the limiting groove, and the culture dish is located between the two groups of plate bodies.

4. A constant temperature incubator for cell culture according to claim 1, wherein: the butt joint mechanism comprises a connecting pipe, a spring is sleeved on the connecting pipe, the connecting pipe is connected with a guide pipe in a plugging mode, two groups of jacks are symmetrically formed in two sides of the guide pipe, the jacks are connected with plugging components in a plugging mode, the plugging components are connected with sliding rods in a plugging mode, and L-shaped rods are arranged on the plugging components.

5. The incubator of claim 4, wherein: the plugging assembly comprises a plugboard, the plugboard is plugged with jacks, one end of the plugboard is provided with a guide hole, the upper end face of the plugboard is fixedly connected with a support plate, and a second distance-changing hole is formed in the support plate.

6. The incubator of claim 4, wherein: the upper port of the connecting pipe is opposite to a group of ocular on the microscope, the guiding pipe is fixedly connected with the connecting rod, the sliding rod is connected with the guiding hole in a sliding way, and the sliding rod is fixed in the mounting groove.

7. A constant temperature incubator for cell culture according to claim 1, wherein: the incubator is characterized in that the upper end face of the incubator body is provided with an installation groove, two groups of inverted inclined planes are symmetrically arranged on the protruding blocks, the protruding blocks are fixed in the incubator body, the rotating shaft is screwed with the incubator body, and the docking mechanism is placed in the installation groove.

8. A constant temperature incubator for cell culture according to claim 3, wherein: the guide post is connected with the through hole in a sliding manner, the guide post is fixed on the lifting block, the pin shaft is inserted into the first variable-pitch hole, the pin shaft is connected with the first variable-pitch hole in a sliding manner, one end of the pin shaft is welded in the rectangular hole, and the roller is connected with the bottom surface of the incubator main body in a rolling manner.

9. The incubator of claim 4, wherein: two groups of L-shaped rods are symmetrically and fixedly connected to two sides of the upper end of the bearing pipe, the end parts of the L-shaped rods are inserted into the second variable-pitch holes, and the end parts of the L-shaped rods are slidably connected with the second variable-pitch holes.