CN220724197U - Cytogenetics culture rack - Google Patents

Abstract

The utility model discloses a cytogenetics culture rack, and relates to the technical field of cell culture racks. The culture support mechanism comprises a support table, wherein the top of the support table is provided with a mounting plate, the bottom of the support table is fixedly connected with a placement seat, the bottom of the placement seat is fixedly provided with a antiskid plate, the inside of the support table is provided with a support damping component, and the support damping component is connected with the mounting plate; the utility model can support the culture rack for use, is favorable for stably installing and using the culture rack, improves the stability of the culture rack in the use process, reduces the vibration amplitude of the culture rack in the adjustment process, improves the stability of placing the cell culture test tubes, can limit the cell culture test tubes, is favorable for limiting and clamping a plurality of culture test tubes, and ensures the stability of placing the culture test tubes, thereby improving the quality of cell culture in the culture test tubes.

Description

Cytogenetics culture rack

Technical Field

The utility model relates to the technical field of cell culture frames, in particular to a cytogenetics culture frame.

Background

Cells are not uniformly defined, and the more common references are: cells are the fundamental structural and functional units of an organism. The cell body shape is very tiny, and can be seen under a microscope, and the shape is various. Mainly comprises a cell nucleus and cytoplasm, and has a cell membrane on the surface. The cell wall is arranged outside the cell membrane of the higher plant, the plastid is arranged in the cytoplasm, and chloroplasts, vacuoles and mitochondria are arranged in the body. Animal cells have no cell wall, often a central body in the cytoplasm, and higher plant cells have no. The cells have the functions of movement, nutrition, reproduction and the like.

The utility model has the beneficial effects that a plurality of culture bottles can be placed at the same time, the placing and taking are convenient and quick, the door opening and closing events of the culture box are reduced, the temperature drop of the culture box is avoided, the influence on the gas cell culture is avoided, the inclination angle can be adjusted, the contact area between the cells and the culture bottles is adjusted, and the culture effect is improved.

At present, when cytogenetic research, need use cell culture frame to place the cell test tube, and above-mentioned device is to placing the access to the blake bottle, and can adjust inclination, improve the cultivation effect, but above-mentioned device is inconvenient to carry out spacing depositing to cultivateing the test tube in the use, be unfavorable for guaranteeing the steadiness of cultivateing the test tube in-process of placing, influence the effect of placing of cell culture in vitro, and above-mentioned device is in the use, appear cultivateing the condition of frame vibrations when adjusting to cultivateing the frame angle easily, be unfavorable for guaranteeing the stability of cultivateing the frame use, consequently we need to provide a cytogenetic culture frame.

Disclosure of Invention

The utility model provides a cytogenetics culture rack which has the advantages of being capable of limiting and placing a culture tube and improving the use stability of the culture rack, thereby solving the problems in the background art.

In order to achieve the above purpose, the utility model is realized by the following technical scheme: a cytogenetic culture rack comprising: the culture supporting mechanism comprises a supporting table, the top of the supporting table is provided with a mounting plate, the bottom of the supporting table is fixedly connected with a placing seat, the bottom of the placing seat is fixedly provided with a antiskid plate, the inside of the supporting table is provided with a supporting shock absorption component, and the supporting shock absorption component is connected with the mounting plate; and

cultivate adjustment mechanism, cultivate adjustment mechanism includes first mount, culture plate, test tube hole groove and spacing centre gripping subassembly, first mount fixed connection is in the one end at mounting panel top, the other end fixedly connected with second mount at mounting panel top, control panel is installed to one side of first mount, the culture plate sets up between first mount and second mount, and the quantity of culture plate is two, the test tube hole groove is seted up in the surface of culture plate, spacing centre gripping subassembly is installed in the culture plate, and the quantity of spacing centre gripping subassembly is the multiunit, the internally mounted of first mount has rotation adjustment subassembly.

As the cytogenetic culture rack, the supporting shock absorption assembly comprises a first shock absorption block, a shock absorber, a second shock absorption block and a buffer spring, wherein the first shock absorption block is fixedly arranged in the supporting table, the shock absorber is fixedly arranged on the first shock absorption block, the second shock absorption block is fixedly arranged at the top end of the first shock absorption block, the top of the second shock absorption block is fixedly connected with the bottom of the mounting plate, and the buffer spring is arranged between the first shock absorption block and the second shock absorption block.

As the cytogenetics culture rack, the limiting clamping assembly comprises a limiting slide tube, a limiting slide ring, a reset spring, a connecting rod and a limiting clamp ring, wherein the limiting slide tube is fixedly arranged in a culture plate, the limiting slide ring is connected in the limiting slide tube in a sliding manner, the reset spring is arranged between the limiting slide tube and the limiting slide ring, the connecting rod is fixedly connected to the limiting slide ring, the limiting clamp ring is fixedly arranged at one end of the limiting slide ring, and the limiting clamp ring is matched with a test tube hole groove.

The utility model relates to a cytogenetic culture rack, which comprises an electric control telescopic rod, a movable sliding block, a movable sliding chute, a sliding toothed plate, a first rotating shaft rod, a driven gear and a second rotating shaft rod, wherein the electric control telescopic rod is fixedly arranged in a first fixing frame, the movable sliding block is fixedly connected with the output end of the electric control telescopic rod, the movable sliding chute is arranged in the first fixing frame and is matched with the movable sliding block for use, the sliding toothed plate is slidably connected in the first fixing frame, the sliding toothed plate is fixedly connected with the movable sliding block, the first rotating shaft rod is arranged in the first fixing frame, one end of the first rotating shaft rod is fixedly connected with a culture plate, the driven gear is fixedly arranged at the other end of the first rotating shaft rod, the driven gear is matched with the sliding toothed plate for use, the second rotating shaft rod is arranged in a second fixing frame, and one end of the second rotating shaft rod is fixedly connected with the culture plate.

As the cytogenetics culture rack, the number of the test tube hole grooves is multiple, and the test tube hole grooves are distributed at equal intervals.

As the cytogenetic culture rack provided by the utility model, the number of the supporting shock-absorbing components is multiple, and the supporting shock-absorbing components are distributed in an array.

The utility model provides a cytogenetics culture rack. The beneficial effects are as follows:

the cytogenetics culture rack can support the culture rack through the arrangement of the culture supporting mechanism, the supporting table, the mounting plate, the placing seat, the antiskid plate and the supporting damping component, is favorable for stably mounting and using the culture rack, improves the stability of the culture rack in the use process, reduces the vibration amplitude of the culture rack in the adjustment process, and improves the stability of placing the cell culture test tube;

through cultivateing adjustment mechanism, first mount, second mount, control panel, culture plate, test tube hole groove, spacing clamping assembly and rotation adjustment assembly's setting, can carry out spacing placing to the cell culture test tube, be favorable to carrying out spacing centre gripping to a plurality of culture test tubes, guarantee to cultivate the steadiness that the test tube was placed to can promote the quality of cell culture in the culture test tube.

Drawings

FIG. 1 is a schematic perspective view of the present utility model;

FIG. 2 is a side view of a three-dimensional structure of the present utility model;

FIG. 3 is a cross-sectional view of a first partial structure of the present utility model;

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

FIG. 5 is a cross-sectional view of a third partial structure of the present utility model;

FIG. 6 is an enlarged view of the structure of FIG. 3A in accordance with the present utility model;

fig. 7 is an enlarged view of the structure at B in fig. 5 according to the present utility model.

In the figure: 1. a culture support mechanism; 101. a support table; 102. a mounting plate; 103. a placement seat; 104. a cleat; 105. supporting the shock absorbing assembly; 10501. a first damper block; 10502. a damper; 10503. a second damper block; 10504. a buffer spring; 2. a culture adjusting mechanism; 201. a first fixing frame; 202. the second fixing frame; 203. a control panel; 204. a culture plate; 205. a test tube hole groove; 206. a limit clamping assembly; 20601. a limit slide tube; 20602. a limiting slip ring; 20603. a return spring; 20604. a connecting rod; 20605. a limiting snap ring; 207. a rotation adjustment assembly; 20701. an electric control telescopic rod; 20702. moving the slide block; 20703. moving the chute; 20704. sliding toothed plates; 20705. a first rotating shaft; 20706. a driven gear; 20707. and a second rotating shaft lever.

Detailed Description

The technical solutions of the present embodiments will be clearly and completely described below with reference to the drawings in the present embodiments, and it is apparent that the described embodiments are only some embodiments of the present utility model, not all embodiments. All other embodiments, based on the embodiments herein, which would be within the purview of one of ordinary skill in the art without the creative effort, are contemplated as falling within the scope of the present utility model.

Referring to fig. 1 to 7, the present utility model provides a technical solution: the utility model provides a cytogenetics cultivates frame, including cultivateing supporting mechanism 1, cultivate supporting mechanism 1 includes supporting bench 101, mounting panel 102 is installed at the top of supporting bench 101, the bottom fixedly connected with of supporting bench 101 places seat 103, the bottom fixedly mounted of placing seat 103 has antiskid ribbed tile 104, the internally mounted of supporting bench 101 has support damper 105, and support damper 105 is connected with mounting panel 102, through cultivate supporting mechanism 1, supporting bench 101, mounting panel 102, place seat 103, antiskid ribbed tile 104 and support damper 105's setting, can support the use to cultivate the frame, be favorable to stable to installing the use to cultivateing the frame, improve the stability of cultivateing in the frame use, reduce the range of cultivateing the frame vibrations in the adjustment process, promote the steadiness that cell culture test tube placed; and

cultivate adjustment mechanism 2, cultivate adjustment mechanism 2 includes first mount 201, culture plate 204, test tube hole groove 205 and spacing centre gripping subassembly 206, first mount 201 fixed connection is in the one end at mounting panel 102 top, the other end fixedly connected with second mount 202 at mounting panel 102 top, control panel 203 is installed to one side of first mount 201, culture plate 204 sets up between first mount 201 and second mount 202, and culture plate 204's quantity is two, test tube hole groove 205 is seted up in culture plate 204's surface, spacing centre gripping subassembly 206 is installed in culture plate 204, and spacing centre gripping subassembly 206's quantity is the multiunit, the internally mounted of first mount 201 has rotation adjustment subassembly 207.

Referring to fig. 6, the supporting damper assembly 105 includes a first damper block 10501, a damper 10502, a second damper block 10503 and a damper spring 10504, the first damper block 10501 is fixedly installed in the supporting table 101, the damper 10502 is fixedly installed on the first damper block 10501, the second damper block 10503 is fixedly installed at the top end of the first damper block 10501, the top of the second damper block 10503 is fixedly connected with the bottom of the mounting plate 102, the damper spring 10504 is installed between the first damper block 10501 and the second damper block 10503, the damper support can be performed on the mounting plate 102 through the arrangement of the first damper block 10501, the damper 10502 and the second damper block 10503, and the use effect of the damper 10502 can be improved through the arrangement of the damper spring 10504.

Referring to fig. 7, the spacing clamping assembly 206 includes a spacing slide tube 20601, a spacing slide ring 20602, a return spring 20603, a connecting rod 20604 and a spacing snap ring 20605, the spacing slide tube 20601 is fixedly installed in the culture plate 204, the spacing slide ring 20602 is slidingly connected in the spacing slide tube 20601, the return spring 20603 is installed between the spacing slide tube 20601 and the spacing slide ring 20602, the connecting rod 20604 is fixedly connected on the spacing slide ring 20602, the spacing snap ring 20605 is fixedly installed at one end of the spacing slide ring 20602, and the spacing snap ring 20605 is matched with the test tube hole slot 205 for use, the connecting rod 20604 can be propped up through the arrangement of the spacing slide tube 20601, the spacing slide ring 20602 and the return spring 20603, and the culture test tube in the test tube hole slot 205 can be spacing clamped through the arrangement of the connecting rod 20604 and the spacing snap ring 20605.

Referring to fig. 4, the rotation adjusting assembly 207 includes an electric control telescopic rod 20701, a moving slide block 20702, a moving slide groove 20703, a sliding toothed plate 20704, a first rotating shaft 20705, a driven gear 20706 and a second rotating shaft 20707, wherein the electric control telescopic rod 20701 is fixedly installed in the first fixing frame 201, the moving slide block 20702 is fixedly connected to the output end of the electric control telescopic rod 20701, the moving slide groove 20703 is arranged in the first fixing frame 201, the moving slide groove 20703 is matched with the moving slide block 20702, the sliding toothed plate 20704 is slidingly connected in the first fixing frame 201, the sliding toothed plate 20704 is fixedly connected with the moving slide block 20702, the first rotating shaft 20705 is installed in the first fixing frame 201, one end of the first rotating shaft 20705 is fixedly connected with the culture plate 204, the driven gear 20706 is fixedly installed at the other end of the first rotating shaft 20705, the driven gear 20706 is matched with the sliding toothed plate 20704, the second rotating shaft 20707 is installed in the second fixing frame 202, one end of the second rotating 20707 is fixedly connected with the culture plate 204, the sliding toothed plate 20703 can slide through the moving slide block 20701 and the moving slide block 20702, and the sliding toothed plate 20703 can be driven by the sliding toothed plate 20705, and the sliding toothed plate can be driven by the sliding toothed plate 20703 through the moving slide toothed plate 3703 and the sliding toothed plate along the sliding toothed plate tracks, thereby the sliding toothed plate 20703, and the sliding toothed plate 20703 can be set up by the sliding toothed plate along the sliding toothed plate through the sliding toothed plate 20703.

Referring to fig. 2, the number of test tube wells 205 is plural, and the test tube wells 205 are equally distributed. Through the setting of test tube hole groove 205, can conveniently carry out spacing to a plurality of culture test tubes and place.

Referring to fig. 3, the number of the supporting damper assemblies 105 is multiple, and the supporting damper assemblies 105 are distributed in an array, so that the damping effect of the mounting plate 102 in use can be improved by the arrangement of the supporting damper assemblies 105.

When the culture support mechanism is used, firstly, a cell culture staff places the culture support mechanism 1 on a culture workbench, then places a antiskid plate 104 at the bottom of a placing seat 103 on a table top, then the cell culture staff extracts genetically cultured cells into a culture test tube, then carries out culture treatment on the cells in the culture test tube, and then carries out screw cap on a tube cap of the culture test tube;

then, a plurality of culture tubes filled with culture cells are sequentially placed into the tube hole grooves 205 on the culture plate 204 by a culture staff, the placed culture tubes are subjected to limit clamping through the limit clamping assembly 206, at the moment, the limit slip ring 20602 is pushed to slide towards one end of the limit slip tube 20601 through the reaction of the reset spring 20603, and then the limit slip ring 20605 is attached to the surface of the culture tubes by the connecting rod 20604, so that the culture tubes are subjected to limit fixing;

in the cell culture process, when the angle of the culture tube needs to be obliquely adjusted according to the culture requirement, the rotation adjusting assembly 207 is started to work through the control panel 203, at this time, the moving slide block 20702 is driven to slide in the moving slide groove 20703 through the expansion of the electric control telescopic rod 20701, and then the moving slide block 20702 drives the sliding toothed plate 20704 to lift and slide, so that the first rotating shaft 20705, the culture plate 204 and the second rotating shaft 20707 are driven to obliquely rotate through the meshing of the driven gear 20706 and the sliding toothed plate 20704, and the culture plate 204 is adjusted to a proper oblique angle, and the mounting plate 102 is subjected to shock absorption support through the supporting shock absorbing assembly 105 in the angle oblique adjustment process.

The foregoing is only a preferred embodiment of the present utility model, but the scope of the present utility model is not limited thereto, and any person skilled in the art, who is within the scope of the present utility model, should make equivalent substitutions or modifications according to the technical scheme of the present utility model and the inventive concept thereof, and should be covered by the scope of the present utility model.

Claims (6)

1. A cytogenetic culture rack comprising:

the culture supporting mechanism (1), the culture supporting mechanism (1) comprises a supporting table (101), a mounting plate (102) is mounted at the top of the supporting table (101), a placing seat (103) is fixedly connected to the bottom of the supporting table (101), a antiskid plate (104) is fixedly mounted at the bottom of the placing seat (103), a supporting shock absorption component (105) is mounted in the supporting table (101), and the supporting shock absorption component (105) is connected with the mounting plate (102); and

cultivate adjustment mechanism (2), cultivate adjustment mechanism (2) including first mount (201), culture plate (204), test tube hole groove (205) and spacing centre gripping subassembly (206), first mount (201) fixed connection is in the one end at mounting panel (102) top, the other end fixedly connected with second mount (202) at mounting panel (102) top, control panel (203) are installed to one side of first mount (201), culture plate (204) set up between first mount (201) and second mount (202), and culture plate (204) quantity is two, test tube hole groove (205) are seted up in culture plate (204) surface, spacing centre gripping subassembly (206) are installed in culture plate (204), and the quantity of spacing centre gripping subassembly (206) is the multiunit, the internally mounted of first mount (201) has rotation adjustment subassembly (207).

2. A cytogenetic culture rack as claimed in claim 1, wherein: the supporting vibration damper assembly (105) comprises a first vibration damper block (10501), a vibration damper (10502), a second vibration damper block (10503) and a buffer spring (10504), wherein the first vibration damper block (10501) is fixedly installed in a supporting table (101), the vibration damper (10502) is fixedly installed on the first vibration damper block (10501), the second vibration damper block (10503) is fixedly installed at the top end of the first vibration damper block (10501), the top of the second vibration damper block (10503) is fixedly connected with the bottom of a mounting plate (102), and the buffer spring (10504) is installed between the first vibration damper block (10501) and the second vibration damper block (10503).

3. A cytogenetic culture rack as claimed in claim 1, wherein: spacing centre gripping subassembly (206) include spacing slide (20601), spacing sliding ring (20602), reset spring (20603), connecting rod (20604) and spacing snap ring (20605), spacing slide (20601) fixed mounting is in culture plate (204), spacing sliding ring (20602) sliding connection is in spacing slide (20601), reset spring (20603) is installed between spacing slide (20601) and spacing sliding ring (20602), connecting rod (20604) fixed connection is on spacing sliding ring (20602), spacing snap ring (20605) fixed mounting is in the one end of spacing sliding ring (20602), and spacing snap ring (20605) and test tube hole groove (205) cooperation use.

4. A cytogenetic culture rack as claimed in claim 1, wherein: the rotation adjusting component (207) comprises an electric control telescopic rod (20701), a moving sliding block (20702), a moving sliding groove (20703), a sliding toothed plate (20704), a first rotating shaft rod (20705), a driven gear (20706) and a second rotating shaft rod (20707), the electric control telescopic rod (20701) is fixedly installed in the first fixing frame (201), the moving sliding block (20702) is fixedly connected to the output end of the electric control telescopic rod (20701), the moving sliding groove (20703) is formed in the first fixing frame (201), the moving sliding groove (20703) is matched with the moving sliding block (20702), the sliding toothed plate (20704) is slidingly connected in the first fixing frame (201), the sliding toothed plate (20704) is fixedly connected with the moving sliding toothed plate (20702), the first rotating shaft rod (20705) is installed in the first fixing frame (201), one end of the first rotating shaft rod (20705) is fixedly connected with the culture plate (204), the driven gear (20706) is fixedly installed at the other end of the first rotating shaft rod (20705) and the driven gear (20706) is matched with the second rotating shaft rod (20702), and the second rotating shaft rod (20706) is fixedly installed at the second end (20707).

5. A cytogenetic culture rack as claimed in claim 1, wherein: the number of the test tube hole grooves (205) is multiple, and the test tube hole grooves (205) are distributed at equal intervals.

6. A cytogenetic culture rack as claimed in claim 1, wherein: the number of the supporting shock absorption assemblies (105) is multiple, and the supporting shock absorption assemblies (105) are distributed in an array.