CN112293239A

CN112293239A - Automatic supply biological cultivation household utensils of culture solution

Info

Publication number: CN112293239A
Application number: CN202011158131.4A
Authority: CN
Inventors: 苏红艳
Original assignee: Guangzhou Aibang Construction Technology Co ltd
Current assignee: Guangzhou Aibang Construction Technology Co ltd
Priority date: 2020-10-26
Filing date: 2020-10-26
Publication date: 2021-02-02

Abstract

The invention relates to a biological cultivation vessel, in particular to a biological cultivation vessel capable of automatically supplying culture solution. The invention aims to provide a biological cultivation vessel which can automatically add nutrient solution into a cultivation vessel and does not need to automatically supply the nutrient solution by a worker all the time beside the cultivation vessel. A biological cultivation vessel for automatically supplying a culture solution, comprising: the top of the base is provided with a supporting mechanism; the automatic supply mechanism is arranged on the supporting mechanism. After the culture dish and the nutrient solution are put well by the staff of the supporting mechanism and the automatic feeding mechanism, the automatic nutrient solution adding work of the culture dish can be realized.

Description

Automatic supply biological cultivation household utensils of culture solution

Technical Field

The invention relates to a biological cultivation vessel, in particular to a biological cultivation vessel capable of automatically supplying culture solution.

Background

When the cultivation work is carried out on organisms, culture solution needs to be added into a cultivation dish for the growth of the organisms, the work is carried out manually at present, but when the work is carried out manually, the amount of the culture solution in the cultivation dish needs to be observed all the time, the addition of the culture solution is stopped when the amount is too much, the addition of the culture solution is stopped when the amount is too small, and therefore the need that a worker always keeps beside the cultivation dish, the worker cannot carry out other work, and the amount of the added culture solution is difficult to grasp manually.

Therefore, it is necessary to design a biological cultivation vessel capable of automatically adding nutrient solution into the cultivation vessel without the need of the worker always beside the cultivation vessel for automatically supplying the nutrient solution.

Disclosure of Invention

In order to overcome the problem that workers need to be beside a culture dish all the time, other work cannot be carried out, and the amount of added nutrient solution cannot be easily mastered manually. The invention aims to provide a biological cultivation vessel which can automatically add nutrient solution into a cultivation vessel without the need of automatically supplying the nutrient solution by a worker at the side of the cultivation vessel all the time.

The technical scheme is as follows: a biological cultivation vessel for automatically supplying a culture solution, comprising:

the top of the base is provided with a supporting mechanism;

the automatic supply mechanism is arranged on the supporting mechanism.

Further, the supporting mechanism includes:

the middle of the top of the base is symmetrically provided with a supporting seat;

the middle of the top of the base is symmetrically provided with support legs;

the box body is connected between the tops of the support legs;

the rubber pipes are symmetrically arranged on two sides in the box body and penetrate through the supporting seats on the two sides;

the cover plate is arranged at the top of the box body;

place the board, base top both sides all are equipped with places the board, and the rubber tube part of both sides all is in the board top of placing of homonymy.

Further, the automatic feeding mechanism includes:

the baffle plate is arranged in the box body, and holes are formed in the two sides of the baffle plate;

the screen meshes are arranged at the positions of the holes of the partition plate;

the two sides of the bottom of the partition board are provided with first sliding rails;

piston, all slidingtype are equipped with the piston on the first slide rail, and the piston bottom all is equipped with cursory ball.

Further, still including turbo mechanism, turbo mechanism is including:

the servo motor is arranged at the bottom in the box body;

the output shafts on the two sides of the servo motor are connected with the turbofan.

Further, still including flip mechanism, flip mechanism is including:

the rotating shaft is rotatably arranged on one side of the top of the box body, and one side of the cover plate is connected with the rotating shaft;

the torsional springs are connected between the two sides of the rotating shaft and the box body;

the bayonet lock is arranged on one side of the bottom of the cover plate.

Further, still including chucking mechanism, chucking mechanism is including:

the clamping blocks are arranged at two parts of one side of the box body in a sliding manner;

the first springs are connected between the clamping blocks and the box body;

the two sides of the outer wall of the box body are symmetrically provided with the hollow cylinders;

first wedge, all slidingtype are equipped with first wedge in the hollow cylinder, all are connected with the second spring between first wedge and the hollow cylinder inner wall.

Further, still including release mechanism, release mechanism includes:

the middle of the top of the base is symmetrically provided with a second bearing seat, and a rotating rod is connected between the second bearing seats;

the two sides of the rotating rod are provided with second gears;

and the third racks are arranged on two sides of the bottom of the pull rod and are meshed with the second gear.

Further, still including rising the mechanism, rising the mechanism and including:

the two sides of the top of the base are respectively provided with a plurality of first bearing seats, and rotating rods are connected between the first bearing seats on the two sides;

the rotating rods are provided with a plurality of first gears;

the bottom of the pull rod is uniformly provided with a plurality of second racks;

the two sides of the top of the base are provided with a plurality of second sliding rails;

the second wedge-shaped blocks are arranged on the second slide rails in a sliding manner;

third springs are connected between the second wedge-shaped block and the top of the base;

the first rack and the upper side of the first bearing seat are both provided with a first rack in a sliding mode, the first rack is matched with the second wedge-shaped block, and the first rack and the second rack are both meshed with the first gear.

Further, still including clamping mechanism, clamping mechanism is including:

the inner sides of the pull rods are provided with a plurality of clamping blocks;

and the pull rod and the placing plate are connected with three fourth springs.

The invention achieves the following effects: after the culture dish and the nutrient solution are placed by the staff of the supporting mechanism and the automatic supply mechanism, the work of automatically adding the nutrient solution into the culture dish can be realized; the flow speed of the nutrient solution can be increased by the arranged turbine mechanism, and meanwhile, the stirring operation can be carried out when different nutrient solutions are added, so that the nutrient solutions are fully mixed; through the cooperation between the clamping mechanism, the lifting mechanism and the loosening mechanism, the culture dish can be clamped, and meanwhile, the culture dish can be taken out conveniently.

Drawings

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

FIG. 2 is a schematic view of a first partial body structure according to the present invention.

FIG. 3 is a schematic view of a second partial body structure according to the present invention.

Fig. 4 is a perspective view of a third embodiment of the present invention.

Fig. 5 is a perspective view of a fourth embodiment of the present invention.

FIG. 6 is a schematic view of a fifth partial body structure according to the present invention.

FIG. 7 is a schematic view of a sixth partial body structure according to the present invention.

FIG. 8 is a schematic view of a seventh partial body structure according to the present invention.

Number designation in the figures: 1. the device comprises a base, 2, a supporting mechanism, 20, a supporting seat, 21, a supporting foot, 22, a rubber tube, 23, a box body, 24, a cover plate, 25, a placing plate, 3, an automatic supply mechanism, 30, a separating plate, 31, a first slide rail, 32, a piston, 33, a screen, 34, a floating ball, 4, a turbine mechanism, 40, a servo motor, 41, a turbofan, 5, a flip mechanism, 50, a clamping pin, 51, a rotating shaft, 52, a torsion spring, 6, a clamping mechanism, 60, a clamping block, 61, a hollow cylinder, 62, a first wedge block, 63, a first spring, 64, a second spring, 7, a lifting mechanism, 70, a first bearing seat, 71, a first gear, 72, a first rack, 73, a second slide rail, 74, a second wedge block, 75, a third spring, 76, a second rack, 8, a release mechanism, 80, a second bearing seat, 81, a second gear, 82, a third rack, 83, a pull rod, 9, a second slide rail, a second wedge block, clamping mechanism, 90, clamping piece, 91, fourth spring.

Detailed Description

The above-described scheme is further illustrated below with reference to specific examples. It should be understood that these examples are for illustrative purposes and are not intended to limit the scope of the present application. The conditions used in the examples may be further adjusted according to the conditions of the particular manufacturer, and the conditions not specified are generally the conditions in routine experiments.

Example 1

A biological cultivation vessel capable of automatically supplying culture solution is shown in figure 1 and comprises a base 1, a supporting mechanism 2 and an automatic supply mechanism 3, wherein the supporting mechanism 2 is arranged at the top of the base 1, and the automatic supply mechanism 3 is arranged on the supporting mechanism 2.

As shown in fig. 1 and 2, the supporting mechanism 2 includes a supporting seat 20, supporting legs 21, rubber tubes 22, a box body 23, a cover plate 24 and a placing plate 25, the supporting seat 20 is symmetrically arranged in the middle of the top of the base 1 in a front-back manner, the supporting legs 21 are symmetrically arranged in the middle of the top of the base 1 in a left-right manner, the box body 23 is connected between the tops of the supporting legs 21, the rubber tubes 22 are symmetrically arranged in the box body 23 in a front-back manner, the rubber tubes 22 all penetrate through the supporting seats 20 in the front-back direction, the cover plate 24 is placed on the top of the box body 23, the placing plate 25 is arranged on the left-right side of.

As shown in fig. 3, the automatic supply mechanism 3 includes a partition 30, a first slide rail 31, a piston 32, a screen 33 and a floating ball 34, the partition 30 is disposed in the box 23, holes are formed in both sides of the partition 30, the screen 33 is disposed in the holes of the partition 30, the first slide rail 31 is disposed on both sides of the bottom of the partition 30, the piston 32 is slidably disposed on the first slide rail 31, and the floating ball 34 is disposed at the bottom of the piston 32.

When culture solution needs to be automatically supplied to the biological cultivation vessel, a worker can place the biological cultivation vessel on the placing plate 25, the biological cultivation vessel is positioned between the inner ends of the rubber tubes 22 on the front side and the rear side of the left side and the right side, the rubber tubes 22 are communicated with the biological cultivation vessel, the cover plate 24 is opened, two different nutrient solutions can be added simultaneously if needed, the two nutrient solutions can be respectively poured into the box body 23, the nutrient solutions are blocked by the partition plate 30 and are not mixed together temporarily, then the cover plate 24 is covered back, the nutrient solutions fall on the bottom of the box body 23 through the screen 33 and are mixed together gradually, if only one nutrient solution needs to be added, the nutrient solution is directly guided into the box body 23, residues in the nutrient solution are blocked by the screen 33 and stay on the partition plate 30, the nutrient solution flows into each biological cultivation vessel along with the rubber tubes 22, when the nutrient solution on the bottom of the box body 23 is gradually increased, the floating ball 34 is, cursory ball 34 upward movement drives piston 32 upward movement, piston 32 upward movement can block the hole of baffle 30, just stop the unloading work to the nutrient solution this moment, after the nutrient solution reduces gradually, piston 32 and cursory ball 34 downward movement under the effect of gravity, just begin the unloading work of nutrient solution once more, the biological growth condition in the culture dish can be observed to the staff, if need not the nutrient solution, the staff can open apron 24, take out unnecessary nutrient solution in the box 23, clear up the residue on the screen cloth 33, it can to take away the culture dish after 24 lid returns with the apron.

Example 2

On the basis of embodiment 1, as shown in fig. 3, the device further includes a turbine mechanism 4, the turbine mechanism 4 includes a servo motor 40 and a turbofan 41, the servo motor 40 is disposed at the bottom of the box 23, and the output shafts on the front and rear sides of the servo motor 40 are connected to the turbofan 41.

As shown in fig. 4 and 5, the portable electronic device further comprises a flip mechanism 5, the flip mechanism 5 comprises a latch 50, a rotating shaft 51 and a torsion spring 52, the rotating shaft 51 is rotatably arranged on the right side of the top of the box body 23, the torsion springs 52 are respectively connected between the front side and the rear side of the rotating shaft 51 and the box body 23, the right side of the cover plate 24 is connected with the rotating shaft 51, and the latch 50 is arranged on the left side of the bottom of the cover plate.

As shown in fig. 4 and 5, the clamping device further comprises a clamping mechanism 6, the clamping mechanism 6 comprises a clamping block 60, a hollow cylinder 61, a first wedge block 62, a first spring 63 and a second spring 64, the clamping block 60 is slidably arranged on the left side and the right side of the lower side of the box 23, the first spring 63 is connected between the clamping block 60 and the box 23, the hollow cylinder 61 is symmetrically arranged on the left side and the right side of the outer wall of the box 23 in the front-back direction, the first wedge block 62 is slidably arranged in the hollow cylinder 61, and the second spring 64 is connected between the first wedge block 62 and the inner wall of the hollow cylinder 61.

Initially, the torsion spring 52 is compressed, a worker can firstly pull the bayonet 50 to separate the bayonet 50 from the box body 23, so that the rotating shaft 51 rotates under the action of the torsion spring 52, the rotating shaft 51 rotates to drive the cover plate 24 to rotate, at the moment, the feed inlet of the box body 23 is not blocked, the worker can add nutrient solution, after the addition is finished, the cover plate 24 rotates again to shield the feed inlet of the box body 23, the torsion spring 52 is compressed, so that the bayonet 50 is matched with the box body 23 to avoid the cover plate 24 rotating under the action of the torsion spring 52, then, the servo motor 40 can be started to work, the output shaft of the servo motor 40 rotates to drive the turbofan 41 to rotate, the turbofan 41 rotates to accelerate the flow speed of the nutrient solution, meanwhile, the stirring work can be carried out when different nutrient solutions are added, when the nutrient solutions are temporarily not required to be added into a culture dish, the servo motor 40 stops working, the first spring 63 is compressed, the fixture block 60 can block the hole of the partition plate 30, feeding work of nutrient solution is stopped, the fixture block 60 moves inwards to enable the first wedge-shaped block 62 to move outwards, the second spring 64 is compressed, after the fixture block 60 moves to a position where the fixture block does not contact with the first wedge-shaped block 62, the first wedge-shaped block 62 moves and resets under the action of the second spring 64, accordingly, the fixture block 60 can be prevented from moving and resetting under the action of the first spring 63, the culture dish can be taken away, if the device needs to be used, the culture dish can be placed by a worker, the first wedge-shaped block 62 is pulled to be away from each other, the second spring 64 is compressed, and therefore the fixture block 60 moves and resets under the action of the first spring 63 to be free of blocking the hole of the partition plate 30, and the device can be used for feeding work of the culture dish again.

As shown in fig. 7, the vehicle seat further comprises a release mechanism 8, the release mechanism 8 comprises a second bearing seat 80, a second gear 81, a third rack 82 and a pull rod 83, the pull rod 83 is slidably arranged on the placing plate 25, the second bearing seats 80 are symmetrically arranged in the front and back of the middle of the top of the base 1, a rotating rod is connected between the second bearing seats 80, the second gear 81 is arranged on each of the front side and the back side of the rotating rod, the third rack 82 is arranged on each of the front side and the back side of the bottom of the pull rod 83, and the third racks 82 are meshed with the second gear 81.

As shown in fig. 6, the lifting mechanism 7 is further included, the lifting mechanism 7 includes a first bearing seat 70, a first gear 71, and a first rack 72, second slide rail 73, second wedge 74, third spring 75 and second rack 76, base 1 top left and right sides all is equipped with three first bearing 70, all be connected with the dwang between the first bearing 70 of left and right sides, all be equipped with three first gear 71 on the dwang, three second rack 76 evenly is equipped with in pull rod 83 bottom, base 1 top left and right sides all is equipped with three second slide rail 73, all slidingly be equipped with second wedge 74 on the second slide rail 73, second wedge 74 slides on placing plate 25, all be connected with third spring 75 between second wedge 74 and the base 1 top, first bearing 70 upside all is slidingly equipped with first rack 72, first rack 72 and the cooperation of second wedge 74, first rack 72 and second rack 76 all mesh with first gear 71.

As shown in fig. 8, the clamping device 9 is further included, the clamping device 9 includes clamping blocks 90 and fourth springs 91, three clamping blocks 90 are respectively disposed on the inner sides of the pull rods 83, and three fourth springs 91 are respectively connected between the pull rods 83 and the placing plate 25.

The culture dish is placed on the placing plate 25, the culture dish is positioned at the top of the second wedge-shaped block 74 at the moment, the culture dish can be clamped with the placing plate 25 under the action of the fourth spring 91 and the clamping block 90, the fourth spring 91 is stretched, so that the position of the culture dish can be fixed, the culture dish cannot swing, and the work of culturing organisms is facilitated, when the organisms do not need to add nutrient solution and take out the culture dish, a worker can pull the left pull rod 83 to move leftwards or pull the right pull rod 83 to move rightwards, the pull rod 83 at the other side can be moved in an opposite direction through the third rack 82, the rotating rod and the second gear 81, so that the pull rods 83 at the left side and the right side are far away from each other, the pull rods 83 move to drive the clamping block 90 to move, so that the culture dish is released, the second rack 76 is also driven by the movement of the pull rods 83, so that the first racks 72 at the left side and the right side are moved to approach each other through, the first rack 72 moves to drive the second wedge-shaped block 74 to move upwards, the third spring 75 is stretched, the second wedge-shaped block 74 moves upwards to push the culture dish to move upwards, so that the worker can take out the culture dish, the pull rod 83 can be loosened after the culture dish is taken out, the pull rod 83 and the clamping block 90 move to reset under the action of the fourth spring 91, the third rack 82 and the second gear 81, the second wedge-shaped block 74 moves downwards to reset under the action of the third spring 75, and meanwhile, the first rack 72 and the second rack 76 both move to reset, so that the culture dish can be used for clamping work and ejection work of the culture dish again.

The above-mentioned embodiments are merely preferred embodiments of the present invention, which are not intended to limit the scope of the present invention, and therefore, all equivalent changes made by the contents of the claims of the present invention should be included in the claims of the present invention.

Claims

1. A biological cultivation vessel capable of automatically supplying culture solution is characterized by comprising:

the device comprises a base (1), wherein a supporting mechanism (2) is arranged at the top of the base (1);

the automatic feeding mechanism (3) is arranged on the supporting mechanism (2).

2. A biological growth vessel with automatic feeding of culture solution according to claim 1, wherein the support means (2) comprises:

the middle of the top of the base (1) is symmetrically provided with the supporting seat (20);

the middle of the top of the base (1) is symmetrically provided with support legs (21);

the box body (23) is connected between the tops of the support legs (21);

the rubber tubes (22) are symmetrically arranged on two sides in the box body (23), and the rubber tubes (22) penetrate through the supporting seats (20) on the two sides;

the cover plate (24) is arranged at the top of the box body (23);

the base is characterized in that the base comprises a placing plate (25), the placing plate (25) is arranged on each of two sides of the top of the base (1), and the rubber pipes (22) on the two sides are located above the placing plate (25) on the same side.

3. A biological growth vessel for automatic feeding of culture solution according to claim 1, wherein the automatic feeding means (3) comprises:

the box body (23) is internally provided with a clapboard (30), and both sides of the clapboard (30) are provided with holes;

the screen (33) is arranged at the hole position of the clapboard (30);

the two sides of the bottom of the partition plate (30) are provided with first sliding rails (31);

the piston (32) and the first sliding rail (31) are both provided with the piston (32) in a sliding manner, and the bottom of the piston (32) is provided with the floating ball (34).

4. A biological growth vessel for automatic feeding of culture solution according to claims 2 and 3, further comprising a turbine mechanism (4), wherein the turbine mechanism (4) comprises:

the servo motor (40) is arranged at the bottom in the box body (23);

the output shafts on the two sides of the turbofan (41) and the servo motor (40) are connected with the turbofan (41).

5. The biological cultivation vessel as claimed in claim 4, further comprising a lid-turning mechanism (5), wherein the lid-turning mechanism (5) comprises:

the rotating shaft (51) is rotatably arranged on one side of the top of the box body (23), and one side of the cover plate (24) is connected with the rotating shaft (51);

the torsion springs (52) are connected between the two sides of the rotating shaft (51) and the box body (23);

a bayonet (50), and one side of the bottom of the cover plate (24) is provided with the bayonet (50).

6. The biological cultivation vessel as claimed in claim 5, further comprising a chucking mechanism (6), wherein the chucking mechanism (6) comprises:

the fixture blocks (60) are arranged at two parts of one side of the box body (23) in a sliding manner;

the first spring (63) is connected between the fixture block (60) and the box body (23);

the two sides of the outer wall of the box body (23) are symmetrically provided with the hollow cylinders (61);

the hollow cylinder (61) is internally provided with a first wedge block (62) in a sliding manner, and a second spring (64) is connected between the first wedge block (62) and the inner wall of the hollow cylinder (61).

7. The biological cultivation vessel as claimed in claim 6, further comprising a release mechanism (8), wherein the release mechanism (8) comprises:

the middle of the top of the base (1) is symmetrically provided with the second bearing blocks (80), and rotating rods are connected between the second bearing blocks (80);

the two sides of the rotating rod are provided with second gears (81);

third rack (82), pull rod (83) bottom both sides all are equipped with third rack (82), and third rack (82) all meshes with second gear (81) mutually.

8. The biological cultivation vessel as claimed in claim 7, further comprising a lifting mechanism (7), wherein the lifting mechanism (7) comprises:

the device comprises a first bearing seat (70), a plurality of first bearing seats (70) are arranged on two sides of the top of a base (1), and rotating rods are connected between the first bearing seats (70) on the two sides;

a plurality of first gears (71) are arranged on the rotating rod;

the bottom of the pull rod (83) is uniformly provided with a plurality of second racks (76);

the two sides of the top of the base (1) are provided with a plurality of second sliding rails (73);

the second wedge-shaped blocks (74) are arranged on the second slide rails (73) in a sliding manner;

the third spring (75) is connected between the second wedge-shaped block (74) and the top of the base (1);

the upper sides of the first rack (72) and the first bearing seat (70) are both provided with the first rack (72) in a sliding mode, the first rack (72) is matched with the second wedge-shaped block (74), and the first rack (72) and the second rack (76) are both meshed with the first gear (71).

9. The biological cultivation vessel as claimed in claim 8, further comprising a clamping mechanism (9), wherein the clamping mechanism (9) comprises:

the inner sides of the clamping blocks (90) and the pull rods (83) are respectively provided with a plurality of clamping blocks (90);

and three fourth springs (91) are connected between the pull rod (83) and the placing plate (25).