CN220012588U - Carbon dioxide incubator of layering culture - Google Patents

Abstract

The utility model relates to a carbon dioxide incubator for layered culture, which aims to solve the technical problem that the spacing between supporting plates is inconvenient to adjust at present and comprises an incubator main body, an adjusting assembly and a clamping assembly; the adjusting component is arranged in the incubator main body; the adjusting component comprises a limit groove, a placing plate, a wedge-shaped groove, a supporting shaft and an opening groove; the limit grooves are arranged in the incubator body in a linear array; the plurality of placing plates are arranged in the incubator body in a linear array; the wedge-shaped groove is formed on the placing plate; the two support shafts are symmetrically arranged at two ends of the limit groove, and the end parts penetrate through the wedge-shaped groove to extend to the outside; the open slot is arranged in the middle of the wedge-shaped slot; the clamping assembly is arranged on the supporting shaft, and the spacing between the placing plates is conveniently adjusted by arranging the adjusting assembly and the clamping assembly, so that the problem that most of supporting plates and carbon dioxide incubators are fixed in the prior art, and the plates cannot be placed when placed in culture dishes with a spacing higher than the supporting plates is solved.

Description

Carbon dioxide incubator of layering culture

Technical Field

The utility model relates to the technical field of carbon dioxide incubators, in particular to a carbon dioxide incubator for layered culture.

Background

The carbon dioxide incubator is a device for culturing cells/tissues in vitro by simulating and forming a growth environment similar to cells/tissues in organisms in the incubator, wherein the incubator requires a stable temperature (37 ℃), a stable CO2 level (5%), a constant pH value (pH value: 7.2-7.4) and a high relative saturation humidity (95%), and is an advanced instrument for culturing cells, tissues and bacteria, and is a key device necessary for developing immunology, oncology, genetics and bioengineering.

In order to improve the cultivation efficiency of carbon dioxide incubator, can set up the inside multilayer structure of carbon dioxide incubator, through placing a plurality of layer boards and improve cultivation efficiency, but among the prior art, layer board and carbon dioxide incubator are mostly fixed, when putting into the culture dish that is higher than the layer board interval, then can't put into it, need look for the carbon dioxide incubator of suitable layer board interval to increased use cost, in view of this, we propose a carbon dioxide incubator of layering cultivation.

Disclosure of Invention

The utility model aims to overcome the defects of the prior art, adapt to the actual needs, and provide a carbon dioxide incubator for layered culture so as to solve the technical problem that the spacing between supporting plates is inconvenient to adjust at present.

In order to achieve the purpose of the utility model, the technical scheme adopted by the utility model is as follows: the carbon dioxide incubator comprises an incubator main body, an adjusting component and a clamping component; the adjustment assembly is disposed within the incubator body; the adjusting component comprises a limit groove, a placing plate, a wedge-shaped groove, a supporting shaft and an opening groove; the limit grooves are arranged in the incubator main body in a linear array; the plurality of placing plates are arranged in the incubator main body in a linear array; the wedge-shaped groove is formed in the placing plate; the two supporting shafts are symmetrically arranged at two ends of the limiting groove, and the end parts penetrate through the wedge-shaped groove and extend to the outside; the open slot is arranged in the middle of the wedge-shaped slot; the clamping assembly is arranged on the supporting shaft.

Preferably, the limit groove is of a v-shaped structure, the tip of the limit groove is upwards arranged, the cross section of the limit groove is of an L-shaped structure, and the support shaft is in sliding fit with the limit groove.

Preferably, the wedge-shaped groove is of a v-shaped structure, the tip end of the wedge-shaped groove is upwards arranged, the shape of the wedge-shaped groove is matched with that of the limiting groove, and the support shaft is in sliding fit with the wedge-shaped groove.

Preferably, the support shaft is composed of a limiting block and a sliding shaft, and the sliding shaft is of a T-shaped structure.

Preferably, the clamping assembly comprises an insertion block, a slot, a chute, a spring, a clamping block and a clamping groove; the inserting block is fixedly arranged on one side, close to the sliding shaft, of the limiting block; the slot is formed in one side of the sliding shaft, which is close to the limiting block; the two sliding grooves are symmetrically arranged on two sides of the insertion block; the spring is arranged in the chute, and one end of the spring is connected with the inner wall of the chute; the clamping block is connected with the other end of the spring; the two clamping grooves are symmetrically arranged on two sides of the inner wall of the slot; wherein the plug block is in plug-in fit with the slot; wherein the clamping block is in sliding fit with the chute; wherein, the fixture block cooperates with the clamping groove in a clamping way.

Preferably, the clamping block is of an isosceles triangle structure, and the inclined surface of the clamping block is close to and far away from the sliding shaft.

Compared with the prior art, the utility model has the beneficial effects that:

1. according to the utility model, the adjusting assembly and the clamping assembly are arranged, and the distance between the placing plates is conveniently adjusted by utilizing the functions of the adjusting assembly and the clamping assembly, so that the problems that in the prior art, the supporting plates and the carbon dioxide incubator are mostly fixed, when the culture dishes with the distance higher than the supporting plates are placed, the plates cannot be placed, and the carbon dioxide incubator with the proper distance between the supporting plates needs to be searched are solved, and the use cost is increased are solved.

2. According to the utility model, the sliding shaft has a disassembling function by arranging the inserting block, the inserting groove, the sliding groove, the spring, the clamping block and the clamping groove, and utilizing the effects of inserting block and inserting groove insertion fit, clamping block and sliding groove sliding fit, clamping block and clamping groove clamping fit and spring elasticity, so that the sliding shaft can be replaced after being damaged, and the practicability of the utility model is improved.

3. According to the utility model, the clamping block is arranged into an isosceles triangle structure, and the inclined surface of the clamping block is arranged close to and far away from the sliding shaft, so that the clamping block is conveniently separated from the clamping connection with the clamping groove, the sliding shaft is convenient to detach, and the practicability of the utility model is improved.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present utility model;

FIG. 2 is a cross-sectional view of the overall structure of the present utility model;

FIG. 3 is a schematic view of a placement plate structure of the present utility model;

FIG. 4 is a cross-sectional view of a support shaft structure of the present utility model;

FIG. 5 is a split cross-sectional view of a support shaft structure of the present utility model;

FIG. 6 is an enlarged schematic view of the utility model at A;

FIG. 7 is an enlarged schematic view of the utility model at B;

in the figure:

1. an incubator body; 2. an adjustment assembly; 3. a clamping assembly;

201. a limit groove; 202. placing a plate; 203. wedge-shaped grooves; 204. a support shaft; 205. an open slot;

2041. a limiting block; 2042. a slide shaft;

301. inserting blocks; 302. a slot; 303. a chute; 304. a spring; 305. a clamping block; 306. a clamping groove.

Detailed Description

The utility model is further illustrated by the following examples in conjunction with the accompanying drawings:

example 1: a carbon dioxide incubator for layered culture, see fig. 1 to 7, comprises an incubator body 1, an adjusting component 2 and a clamping component 3; the adjusting component 2 is arranged in the incubator main body 1; wherein, the adjusting component 2 comprises a limit groove 201, a placing plate 202, a wedge-shaped groove 203, a supporting shaft 204 and an open groove 205; the limit grooves 201 are arranged in the incubator main body 1 in a linear array; a plurality of placing plates 202 are arranged in a linear array in the incubator body 1; the wedge-shaped groove 203 is arranged on the placing plate 202; the two support shafts 204 are symmetrically arranged at two ends of the limit groove 201, and the end parts of the two support shafts penetrate through the wedge-shaped groove 203 to extend to the outside; the open slot 205 is arranged in the middle of the wedge-shaped slot 203; the clamping assembly 3 is arranged on the support shaft 204. According to the utility model, by arranging the adjusting component 2 and the clamping component 3 and utilizing the functions of the adjusting component 2 and the clamping component 3, the device provided by the utility model is convenient for adjusting the distance between the placing plates 202, so that the problems that in the prior art, most of the supporting plates and the carbon dioxide incubator are fixed, when a culture dish with a distance higher than the supporting plates is placed, the culture dish cannot be placed, and a carbon dioxide incubator with a proper supporting plate distance needs to be searched, and the use cost is increased are solved.

Specifically, the limiting groove 201 is of a v-shaped structure, the tip of the limiting groove 201 is upwards arranged, the cross section of the limiting groove 201 is of an L-shaped structure, and the supporting shaft 204 is in sliding fit with the limiting groove 201. According to the utility model, the limit groove 201 is arranged in a v-shaped structure, the tip of the limit groove 201 is upwards arranged, the cross section of the limit groove 201 is arranged in an L-shaped structure, and the support shaft 204 and the limit groove 201 are arranged in a sliding fit, so that the support shaft 204 is limited to slide in the limit groove 201, and the support shaft 204 can be in a horizontal state to play a role in supporting the placing plate 202.

Further, the wedge-shaped groove 203 is in a v-shaped structure, the tip of the wedge-shaped groove 203 is upwards arranged, the wedge-shaped groove 203 is matched with the limit groove 201 in shape, and the support shaft 204 is in sliding fit with the wedge-shaped groove 203. According to the utility model, the wedge-shaped groove 203 is arranged in a v-shaped structure, the tip of the wedge-shaped groove 203 is upwards arranged, the shape of the wedge-shaped groove 203 is matched with the shape of the limit groove 201, and the support shaft 204 is in sliding fit with the wedge-shaped groove 203, so that the placing plate 202 can be conveniently adjusted and supported.

Still further, the support shaft 204 is formed by a limiting block 2041 and a sliding shaft 2042, and the sliding shaft 2042 has a T-shaped structure; the size of the open slot 205 is greater than the sum of the diameter sizes of the two slide shafts 2042. According to the utility model, the support shaft 204 is formed by the limiting block 2041 and the sliding shaft 2042, and the sliding shaft 2042 is in a T-shaped structure, so that the position of the placing plate 202 cannot deviate.

It should be noted that the clamping assembly 3 includes an insert block 301, a slot 302, a chute 303, a spring 304, a clamping block 305 and a clamping groove 306; the insert 301 is fixedly arranged on one side of the limiting block 2041, which is close to the sliding shaft 2042; the slot 302 is arranged on one side of the sliding shaft 2042 close to the limiting block 2041; the two sliding grooves 303 are symmetrically arranged on two sides of the insertion block 301; the spring 304 is arranged in the chute 303, and one end of the spring is connected with the inner wall of the chute 303; the clamping block 305 is connected with the other end of the spring 304; the two clamping grooves 306 are symmetrically arranged on two sides of the inner wall of the slot 302; wherein, the plug 301 is in plug-in fit with the slot 302; wherein, the clamping block 305 is in sliding fit with the sliding groove 303; wherein, the clamping block 305 is matched with the clamping groove 306 in a clamping way; the size of the insert block 301 is matched with the size of the inner wall of the slot 302, the maximum size of the clamping block 305 is matched with the size of the inner wall of the chute 303, and when the clamping block 305 is clamped with the clamping groove 306, the end part of the insert block 301 is contacted with the inner wall of the slot 302. According to the utility model, by arranging the insert block 301, the slot 302, the sliding groove 303, the spring 304, the clamping block 305 and the clamping groove 306, and utilizing the insert block 301 and the slot 302 in an inserting fit, the clamping block 305 and the sliding groove 303 in a sliding fit, the clamping block 305 and the clamping groove 306 in a clamping fit and the spring 304 in an elastic action, the sliding shaft 2042 has a disassembling function, and the sliding shaft 2042 can be replaced after being damaged, so that the practicability of the utility model is improved.

It is noted that the latch 305 has an isosceles triangle structure, and the inclined surface of the latch 305 is disposed close to and far from the sliding shaft 2042. According to the utility model, the clamping block 305 is arranged into an isosceles triangle structure, and the inclined surface of the clamping block 305 is arranged close to and far away from the sliding shaft 2042, so that the clamping block 305 is conveniently separated from the clamping connection with the clamping groove 306, the sliding shaft 2042 is convenient to detach, and the practicability of the utility model is improved.

Working principle: when the height of the culture dish to be placed is higher than the spacing between the placing plates 202, firstly, when the placing plates 202 are moved upwards, the two sliding shafts 2042 relatively move in the wedge-shaped grooves 203, when the two sliding shafts 2042 relatively move in the wedge-shaped grooves 203, the two limiting blocks 2041 relatively move in the limiting grooves 201 until the two sliding shafts 2042 are separated from the wedge-shaped grooves 203 from the opening grooves 205, at this time, the placing plates 202 are detached, the two supporting shafts 204 slide away from each other in the limiting grooves 201 due to the self gravity until the two supporting shafts 204 slide to the lowest end of the limiting grooves 201, after finding a proper position, the two supporting shafts 204 in the limiting grooves 201 are relatively moved to the highest point, then the detached placing plates 202 are placed in the wedge-shaped grooves 203 from the opening grooves 205, at this time, the placing plates 202 are released, due to the self-gravity of the two support shafts 204, the two slide shafts 2042 are enabled to slide in the wedge-shaped groove 203 in a deviating way and the two limiting blocks 2041 are enabled to slide in the limiting groove 201 in a deviating way until the slide shafts 2042 and the limiting blocks 2041 move to the lowest ends of the wedge-shaped groove 203 and the wedge-shaped groove 203, at the moment, the position of the placing plate 202 is fixed, when the slide shafts 2042 need to be replaced, the slide shafts 2042 are pulled towards the door direction of the incubator main body 1, the slide shafts 2042 start to move towards the door direction of the incubator main body 1, when the slide shafts 2042 move towards the door direction of the incubator main body 1, the inner walls of the clamping grooves 306 are enabled to press the inclined surfaces of the clamping blocks 305, the clamping blocks 305 start to slide into the sliding grooves 303, when the clamping blocks 305 slide into the sliding grooves 303, the clamping blocks 305 are enabled to press the springs 304, the springs 304 are enabled to be stressed and contracted until the end parts of the clamping blocks 305 are contacted with the inner walls of the slots 302, at the moment, the springs 304 are not contracted, and the inserting blocks 301 are gradually separated from the insertion connection with the slots 302, until the insert 301 is completely separated from the insertion of the slot 302, at this time, the spring 304 is not stressed, and starts to stretch, so that the clamp block 305 slides in the opposite direction in the chute 303, until the clamp block 305 returns to the original position, at this time, the detachment of the end part of the limiting block 2041 and the slide shaft 2042 is completed, when the limiting block 2041 and the slide shaft 2042 are required to be installed, the insertion opening of the slot 302 is aligned with the end part of the insert 301, the slide shaft 2042 is moved away from the box door direction of the incubator body 1, so that the insert 301 and the slot 302 are gradually inserted, and when the insertion opening of the slot 302 contacts the inclined surface of the clamp block 305, the slide shaft 2042 is continuously moved away from the box door direction of the incubator body 1, at this time, the clamp block 305 starts to slide in the chute 303, and when the clamp block 305 slides in the chute 303, the clamp block 305 is extruded by the spring 304, so that the spring 304 is stressed and contracted until the end part of the clamp block 305 contacts the inner wall of the clamp groove 306, at this time, the spring 304 gradually stretches, so that the clamp block 305 slides in the opposite direction in the direction of the chute 303, until the end part of the clamp block 305 contacts the inner wall of the clamp groove 306, and the installation of the slide shaft 2042 is completed, or the detachment of the slide plate 2042 is repeated.

The embodiments of the present utility model are disclosed as preferred embodiments, but not limited thereto, and those skilled in the art will readily appreciate from the foregoing description that various modifications and variations can be made without departing from the spirit of the present utility model.

Claims (6)

1. A carbon dioxide incubator for layered culture, comprising:

an incubator body (1);

an adjusting assembly (2) arranged within the incubator body (1);

the adjusting assembly (2) comprises a limit groove (201), a placing plate (202), a wedge-shaped groove (203), a supporting shaft (204) and an open groove (205); the limit grooves (201) are arranged in the incubator main body (1) in a linear array; the plurality of placing plates (202) are arranged in the incubator main body (1) in a linear array; the wedge-shaped groove (203) is arranged on the placing plate (202); the two supporting shafts (204) are symmetrically arranged at two ends of the limiting groove (201), and the end parts penetrate through the wedge-shaped groove (203) to extend to the outside; the open slot (205) is arranged in the middle of the wedge-shaped slot (203);

and the clamping assembly (3) is arranged on the supporting shaft (204).

2. The carbon dioxide incubator for layered culture according to claim 1, wherein the limit groove (201) has a v-shaped structure, the tip of the limit groove (201) is upward, the cross section of the limit groove (201) has an L-shaped structure, and the support shaft (204) is slidably matched with the limit groove (201).

3. The carbon dioxide incubator for layered culture according to claim 2, wherein the wedge-shaped groove (203) has a v-shaped structure, the tip of the wedge-shaped groove (203) is arranged upwards, the shape of the wedge-shaped groove (203) is matched with the shape of the limit groove (201), and the support shaft (204) is in sliding fit with the wedge-shaped groove (203).

4. A carbon dioxide incubator for layered culture as claimed in claim 3, wherein the support shaft (204) is composed of a stopper (2041) and a sliding shaft (2042), and the sliding shaft (2042) has a T-shaped structure.

5. The carbon dioxide incubator of claim 4, wherein the clamping assembly (3) comprises:

the inserting block (301) is fixedly arranged at one side of the limiting block (2041) close to the sliding shaft (2042);

the slot (302) is arranged on one side of the sliding shaft (2042) close to the limiting block (2041);

the number of the sliding grooves (303) is two, and the sliding grooves are symmetrically arranged on two sides of the insertion block (301);

the spring (304) is arranged in the chute (303), and one end of the spring is connected with the inner wall of the chute (303);

the clamping block (305) is connected with the other end of the spring (304);

the number of the clamping grooves (306) is two, and the clamping grooves are symmetrically arranged on two sides of the inner wall of the slot (302);

wherein the plug block (301) is in plug-in fit with the slot (302);

wherein the clamping block (305) is in sliding fit with the sliding groove (303);

wherein, fixture block (305) and draw-in groove (306) joint cooperation.

6. The carbon dioxide incubator for layered culture according to claim 5, wherein the fixture block (305) has an isosceles triangle structure, and the inclined surface of the fixture block (305) is disposed close to and away from the sliding shaft (2042).