CN112740999A

CN112740999A - From screening formula ultraviolet ray mutation device for biological breeding

Info

Publication number: CN112740999A
Application number: CN202011448474.4A
Authority: CN
Inventors: 葛保
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-12-11
Filing date: 2020-12-11
Publication date: 2021-05-04

Abstract

The invention discloses a self-screening ultraviolet mutagenesis device for biological breeding, which comprises a device shell, a rotating disc, a first large conveying pipe, a stir-frying plate and an ultraviolet lamp tube, wherein a servo motor is fixedly welded on the device shell, the output end of the servo motor is rotatably connected with a fixed shaft, a light-insulating plate is connected to a worm wheel through a screw, the light-insulating plate is movably connected to a light-insulating frame, the light-insulating frame is connected to the device shell through a screw, a light-transmitting hole is formed in the light-insulating frame, and the ultraviolet lamp tube is installed in the light-insulating frame through a bolt. This from screening formula ultraviolet mutagenesis device for biological breeding is provided with and separates the light frame, and the worm can drive through the worm wheel and separate the worn-out fur and rotate in separating the light frame, and can carry out the work of sheltering from of different degrees to each light trap under the rotation effect that each separates the worn-out fur, and then can convenient and fast's regulation ultraviolet tube shine intensity, has increased the stability in use and the convenience of device.

Description

From screening formula ultraviolet ray mutation device for biological breeding

Technical Field

The invention relates to the technical field of biological breeding, in particular to an ultraviolet mutagenesis device for self-screening type biological breeding.

Background

The agricultural biotechnology is a new technology for improving the production traits of animals and plants and microorganism varieties, cultivating new varieties of animals and plants and microorganisms, and producing biological pesticides, veterinary drugs and vaccines by applying biotechnology such as genetic engineering, fermentation engineering, cell engineering, enzyme engineering, molecular breeding and the like, the mutation breeding in the molecular breeding refers to a breeding method for obtaining a new biological variety by utilizing artificial mutation, and the artificial mutation methods are more, the most common and simple method is ultraviolet irradiation mutagenesis, which is based on the principle that cells, tissues (plant seeds), organs or organisms undergoing cell division undergo gene mutation by ultraviolet irradiation in an ultraviolet mutagenesis device, and the treated biological material is selected and cultured to obtain a new variety of the desired organism.

However, most of the existing ultraviolet mutagenesis devices for biological breeding have the following problems:

when the conventional ultraviolet mutagenesis device for biological breeding performs ultraviolet irradiation mutagenesis on seeds, due to the fact that the sizes of the seeds are uneven, the conventional ultraviolet mutagenesis device for biological breeding cannot perform stable screening, classifying and placing work on the seeds with different sizes in the working process, and the uniformity of light receiving of each seed cannot be ensured when the seeds with different sizes perform ultraviolet irradiation mutagenesis simultaneously, so that the stability of subsequent mutagenesis work cannot be ensured;

second, conventional ultraviolet mutagenesis device for biological breeding needs carry out ultraviolet irradiation mutagenesis work to a large amount of seeds simultaneously in the course of the work, and it is not good to lead to the mutagenesis effect to take place to pile up easily between seed and the seed, has reduced work efficiency simultaneously, and in the irradiation process of ultraviolet ray, and a large amount of seeds take place to pile up and produce high temperature easily, and conventional ultraviolet mutagenesis device for biological breeding can not carry out stable heat dissipation work to piled up seed.

Therefore, we have proposed a UV mutagenesis apparatus for self-screening biological breeding in order to solve the problems set forth above.

Disclosure of Invention

The invention aims to provide a self-screening type ultraviolet mutagenesis device for biological breeding, which solves the problems that the ultraviolet mutagenesis device for biological breeding in the market at present, which is provided by the background technology, can not stably screen, classify and place seeds with different sizes, the uniformity of light receiving of each seed can not be ensured when the seeds with different sizes are subjected to ultraviolet irradiation mutagenesis work simultaneously, the mutagenesis effect is not good due to easy accumulation between the seeds, the work efficiency is reduced, and the stable heat dissipation work can not be carried out on the accumulated seeds.

In order to achieve the purpose, the invention provides the following technical scheme: a self-screening ultraviolet mutagenesis device for biological breeding comprises a device shell, a rotating disc, a first large conveying pipe, a stir-frying plate and an ultraviolet lamp tube, wherein a servo motor is fixedly welded on the device shell, the output end of the servo motor is rotatably connected with a fixed shaft, the rotating disc is fixedly welded on the fixed shaft, a blanking groove is formed in the rotating disc, the rotating disc is rotatably connected in a fixed plate, the fixed plate is connected in the device shell through screws, the device shell is internally provided with a feeding frame, the device shell is internally provided with a separation frame, the device shell is internally provided with a mixing frame, the fixed shaft is fixedly welded with a first bevel gear, the first bevel gear is connected with a second bevel gear in a meshing manner, the second bevel gear is fixedly welded on a connecting shaft, the connecting shaft is rotatably connected on the mixing frame, and a first transmission belt is connected on the connecting shaft in a meshing manner, and first drive belt meshing connects on the hob, the hob rotates to be connected in spacing frame, and spacing frame screw connection is in device shell to bolted connection has the stand pipe on the spacing frame, and the bottom bolted connection of stand pipe is on mixing the frame moreover, rotate on the device shell and be connected with the worm, and mesh on the worm is connected with the worm wheel, bolted connection has the board that separates light on the worm wheel, and separates light board swing joint in the frame that separates light, separate light frame screw connection in device shell, and offered the light trap on the frame that separates light to ultraviolet tube is installed to bolt in the frame that separates light.

Preferably, the fixed shaft is connected with a second transmission belt in a meshed mode, a circular gear is fixedly welded to the top end of the fixed shaft, the circular gear is connected with a fixed block through a screw, the fixed block is rotatably connected with a connecting rod, and meanwhile the bottom end of the connecting rod is connected with a stir-frying plate through a screw.

Preferably, the blanking grooves are distributed on the rotating disc at equal angles, the diameter of each blanking groove is equal to that of the first large conveying pipe, and the diameter of each blanking groove is equal to that of the bottom opening of the feeding frame.

Preferably, there are first little conveyer pipe, first well conveyer pipe and first big conveyer pipe by left right side screw connection in proper order on the fixed plate, and the diameter of first little conveyer pipe, the diameter of first well conveyer pipe and the diameter of first big conveyer pipe are degressive step by step from left right side to first little conveyer pipe, first well conveyer pipe and first big conveyer pipe all are the spiral.

Preferably, the diameter of the spiral rod is equal to the diameter of the inner space of the limiting frame, the length of the spiral rod is greater than that of the limiting frame, and the spiral rods are distributed in the separation frame at equal intervals.

Preferably, the bottom of mixing the frame has the big conveyer pipe of conveyer pipe in the little conveyer pipe of second, second and the big conveyer pipe of second by left right side screw connection in proper order, and the overall structure of conveyer pipe in the little conveyer pipe of second, the second and the big conveyer pipe of second is the same with the overall structure of first little conveyer pipe, first well conveyer pipe and first big conveyer pipe respectively.

Preferably, the circular gears are symmetrically distributed on the left side and the right side of the mixing frame, the circular gears correspond to the connecting rods one by one through the fixing blocks, the tops of the adjacent connecting rods are rotatably connected, the connecting rods are fixed in the middle of the stir-frying plate, and the stir-frying plate is L-shaped.

Preferably, the worm wheel is symmetrically distributed on the left side and the right side of the worm, light-insulating plates are distributed on the worm wheel at equal angles, the outer walls of the light-insulating plates are attached to the inner wall of the light-insulating frame, and the length of each light-insulating plate is greater than that of the light-insulating frame.

Preferably, the light-blocking frame is provided with light holes at equal intervals, the central axis of the light-blocking frame and the central axis of the ultraviolet lamp tube are positioned on the same vertical central line, and the light-blocking frame is connected with the light-blocking plate through a bearing.

Compared with the prior art, the invention has the beneficial effects that: the ultraviolet mutagenesis device for self-screening biological breeding;

(1) the device is provided with a rotating disc, the rotating disc is combined with a blanking groove and can drive seeds in a feeding frame to rotate one by one, the seeds can be screened step by step under the action of a first small conveying pipe, a first middle conveying pipe and a first large conveying pipe, the diameters of which are gradually decreased from left to right, the irradiation duration of ultraviolet rays can be effectively prolonged under the spiral action of each conveying pipe, meanwhile, the phenomenon that the seeds are unevenly received due to accumulation can be effectively prevented, and the use stability and the high efficiency of the device are improved;

(2) the device is provided with the stir-frying plate, the circular gears on the two sides can drive the corresponding connecting rods to move outwards or inwards simultaneously by combining with the fixed blocks, and the connecting rods on the two sides can stably stir and fry the seeds in the mixing frame by combining with the stir-frying plate while moving outwards or inwards simultaneously, so that the stacked seeds can be stably stirred and radiated, meanwhile, the blanking speed is improved, the subsequent blanking blockage is prevented, and the use diversity and the safety of the device are improved;

(3) the device is provided with the light-proof frame, and the worm can drive through the worm wheel and separate the worn-out fur and rotate in the light-proof frame, and can carry out the work of sheltering from of different degrees to each light trap under the rotation effect that each separates the worn-out fur, and then can convenient and fast's regulation ultraviolet tube's the intensity of shining, has increased the stability in use and the convenience of device.

Drawings

FIG. 1 is a schematic overall side view of the present invention;

FIG. 2 is a schematic view of a rotating disk according to the present invention;

FIG. 3 is a schematic top view of the spacing frame of the present invention;

FIG. 4 is a schematic view of a guide tube structure according to the present invention;

FIG. 5 is a schematic view of a stir-frying plate according to the present invention;

FIG. 6 is a schematic view of the structure of FIG. 5 at A in accordance with the present invention;

FIG. 7 is a schematic view of the ultraviolet lamp tube of the present invention;

fig. 8 is a schematic top view of the light-shielding plate according to the present invention.

In the figure: 1. a device housing; 2. a servo motor; 3. a fixed shaft; 4. rotating the disc; 5. a discharging groove; 6. a fixing plate; 7. a feeding frame; 8. a first small delivery pipe; 9. a first intermediate delivery pipe; 10. a first large delivery pipe; 11. a separation frame; 12. a first bevel gear; 13. a second bevel gear; 14. a connecting shaft; 15. a first drive belt; 16. a screw rod; 17. a limiting frame; 18. a mixing frame; 19. a circular gear; 20. a fixed block; 21. a connecting rod; 22. turning over the frying plate; 23. a second small delivery pipe; 24. a second intermediate delivery pipe; 25. a second large delivery pipe; 26. a worm; 27. a worm gear; 28. a light-shielding plate; 29. a light-blocking frame; 30. a light-transmitting hole; 31. an ultraviolet lamp tube; 32. a guide tube; 33. a second belt.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-8, the present invention provides a technical solution: a self-screening ultraviolet mutagenesis device for biological breeding comprises a device shell 1, a servo motor 2, a fixed shaft 3, a rotating disc 4, a feeding groove 5, a fixed plate 6, a feeding frame 7, a first small delivery pipe 8, a first middle delivery pipe 9, a first large delivery pipe 10, a separation frame 11, a first bevel gear 12, a second bevel gear 13, a connecting shaft 14, a first transmission belt 15, a spiral rod 16, a limit frame 17, a mixing frame 18, a circular gear 19, a fixed block 20, a connecting rod 21, a stir-frying plate 22, a second small delivery pipe 23, a second middle delivery pipe 24, a second large delivery pipe 25, a worm 26, a worm wheel 27, a light baffle plate 28, a light baffle frame 29, a light hole 30, an ultraviolet lamp tube 31, a guide tube 32 and a second transmission belt 33, wherein the servo motor 2 is fixedly welded on the device shell 1, the output end of the servo motor 2 is rotatably connected with the fixed shaft 3, the rotating disc 4 is fixedly welded on the fixed shaft 3, a feeding groove 5 is arranged on the rotating disc 4, the rotating disc 4 is rotatably connected in a fixed plate 6, the fixed plate 6 is connected in a device shell 1 through screws, a feeding frame 7 is connected in the device shell 1 through screws, a separation frame 11 is connected in the device shell 1 through screws, a mixing frame 18 is connected in the device shell 1 through screws, a first conical gear 12 is fixedly welded on the fixed shaft 3, a second conical gear 13 is connected on the first conical gear 12 in a meshing manner, the second conical gear 13 is fixedly welded on the connecting shaft 14, the connecting shaft 14 is rotatably connected on the mixing frame 18, a first transmission belt 15 is connected on the connecting shaft 14 in a meshing manner, the first transmission belt 15 is connected on a spiral rod 16 in a meshing manner, the spiral rod 16 is rotatably connected in a limiting frame 17, the limiting frame 17 is connected in the device shell 1 through screws, a guide pipe 32 is connected on the limiting frame 17 through bolts, and the bottom end of the guide pipe 32 is connected on the, the device shell 1 is rotatably connected with a worm 26, the worm 26 is meshed with a worm wheel 27, the worm wheel 27 is connected with a light-insulating plate 28 through screws, the light-insulating plate 28 is movably connected into a light-insulating frame 29, the light-insulating frame 29 is connected into the device shell 1 through screws, a light-transmitting hole 30 is formed in the light-insulating frame 29, and an ultraviolet lamp tube 31 is installed on the light-insulating frame 29 through bolts.

The second transmission belt 33 is connected to the fixed shaft 3 in a meshed mode, the circular gear 19 is fixedly welded to the top end of the fixed shaft 3, the circular gear 19 is connected with the fixed block 20 through screws, the fixed block 20 is rotatably connected with the connecting rod 21, meanwhile, the stir-frying plate 22 is connected to the bottom end of the connecting rod 21 through screws, the stability of the work state of the stir-frying plate 22 on the connecting rod 21 can be guaranteed, and the use diversity of the device is improved.

The angular distribution such as silo 5 down is on rolling disc 4, and the diameter of silo 5 equals with the diameter of first big conveyer pipe 10 down to the diameter of silo 5 equals with the bottom opening diameter of feeding frame 7 down, can guarantee that silo 5 can carry out stable unloading work down, has increased the stability in use of device.

Fix plate 6 is last from left to right in proper order screwed connection have first little conveyer pipe 8, conveyer pipe 9 and first big conveyer pipe 10 in, and the diameter of first little conveyer pipe 8, the diameter of conveyer pipe 9 and the diameter of first big conveyer pipe 10 is degressive from left to right step by step, and first little conveyer pipe 8, conveyer pipe 9 and first big conveyer pipe 10 all are the spiral, it is long when effectively having increased ultraviolet irradiation, and then the work efficiency of device has been improved.

The diameter of the screw rod 16 is equal to the diameter of the inner space of the limiting frame 17, the length of the screw rod 16 is greater than that of the limiting frame 17, and the screw rods 16 are distributed in the separating frame 11 at equal intervals, so that the stability of the working state of the screw rod 16 in the limiting frame 17 can be ensured, and the use convenience of the device is improved.

Mix the bottom of frame 18 and have second little conveyer pipe 23, conveyer pipe 24 and the big conveyer pipe 25 of second from left to right screwed connection in proper order, and the overall structure of conveyer pipe 23 in the second, conveyer pipe 24 and the big conveyer pipe 25 of second is the same with the overall structure of first little conveyer pipe 8, conveyer pipe 9 and first big conveyer pipe 10 in the second respectively, can guarantee the stability of the little conveyer pipe 23 of second, conveyer pipe 24 and the big conveyer pipe 25 of second work effect on mixing frame 18 in the second.

The circular gears 19 are symmetrically distributed on the left side and the right side of the mixing frame 18, the circular gears 19 correspond to the connecting rods 21 one by one through the fixing blocks 20, the tops of the adjacent connecting rods 21 are rotatably connected, the connecting rods 21 are fixed in the middle of the stir-frying plate 22, and meanwhile, the stir-frying plate 22 is L-shaped, so that the stir-frying efficiency of the stir-frying plate 22 can be effectively improved, and the use efficiency of the device is effectively improved.

The worm wheel 27 is symmetrically distributed on the left side and the right side of the worm 26, the light-insulating plates 28 are distributed on the worm wheel 27 at equal angles, the outer walls of the light-insulating plates 28 are attached to the inner wall of the light-insulating frame 29, the length of the light-insulating plates 28 is larger than that of the light-insulating frame 29, and the adverse effect of the light-insulating plates 28 on the light-insulating frame 29 can be effectively avoided.

The light-transmitting holes 30 are equidistantly distributed on the light-shielding frame 29, the central axis of the light-shielding frame 29 and the central axis of the ultraviolet lamp tube 31 are positioned on the same vertical central line, and the light-shielding frame 29 is connected with the light-shielding plate 28 through the bearing, so that the connection state between the light-shielding frame 29 and the light-shielding plate 28 can be ensured to be stable, and further, the subsequent light-shielding plate 28 can be ensured to rotate in the light-shielding frame 29 to work stably.

The working principle is as follows: before the ultraviolet mutagenesis device for self-screening type biological breeding is used, the whole condition of the device needs to be checked firstly to determine that the device can work normally;

when the device starts to work, with reference to fig. 1 and 2, the fixed shaft 3 can be driven to rotate under the action of the servo motor 2, and then the rotating disc 4 can be driven to rotate in the fixed plate 6, at the moment, the rotating disc 4 can drive each discharging groove 5 to intermittently align with the bottom opening of the feeding frame 7, then the rotating disc 4 can drive the seeds in the feeding frame 7 to rotate one by one under the limiting action of the discharging grooves 5 and the fixed plate 6, at the moment, the seeds in each discharging groove 5 can be screened and screened step by step under the action of the first small conveying pipe 8, the first middle conveying pipe 9 and the first large conveying pipe 10 with diameters decreasing from left to right, then the irradiation duration of the ultraviolet lamp tube 31 can be effectively increased under the spiral action of the first small conveying pipe 8, the first middle conveying pipe 9 and the first large conveying pipe 10, and meanwhile, uneven accumulation of the seeds can be effectively prevented, then the screened seeds fall into a separation frame 11 for classified placement;

the seeds in the separation frame 11 can roll to the screw rods 16 under the action of the inclined plane at the bottom end face of the separation frame 11, and with reference to fig. 1-6, while the fixed shaft 3 rotates, the first bevel gear 12 can drive the connecting shaft 14 to rotate through the second bevel gear 13, at this time, the connecting shaft 14 can drive the screw rods 16 to rotate in the corresponding limit frames 17 through the first transmission belts 15, at this time, the screened seeds can be conveyed upwards under the rotation action of the screw rods 16, then the screw rods 16 can convey the seeds into the mixing frame 18 with the partition plates by combining with the guide pipes 32 on the limit frames 17, and can drive the circular gears 19 to rotate while the fixed shaft 3 rotates, and under the meshing rotation action of the circular gears 19 at both sides, the corresponding connecting rods 21 can be driven to move outwards or inwards simultaneously by the fixed blocks 20 at both sides, at the moment, the connecting rods 21 on the two sides move outwards or inwards simultaneously and are combined with the stir-frying plate 22 to perform stable stir-frying work on the seeds in the mixing frame 18, and the second driving belt 33 is combined to perform integral stir-frying work on the seeds in the mixing frame 18, so that stable stirring heat dissipation work can be performed on the conveyed and accumulated seeds, the blanking rate is improved, and subsequent blanking blockage is prevented;

the seeds in the mixing frame 18 can be subjected to secondary ultraviolet mutagenesis work under the action of the second small conveying pipe 23, the second middle conveying pipe 24 and the second large conveying pipe 25, with reference to fig. 1 and fig. 5-8, and in the working process of the ultraviolet lamp tube 31, a worker can drive the worm wheel 27 to rotate by rotating the worm 26, and further can drive each light-shielding plate 28 on the worm wheel 27 to rotate in the light-shielding frame 29, and can shield each light-transmitting hole 30 on the light-shielding frame 29 to different degrees under the rotating action of each light-shielding plate 28, so that the irradiation intensity of the ultraviolet lamp tube 31 can be conveniently and quickly adjusted, and further the stability of the subsequent seed mutagenesis work can be ensured, which is the working process of the whole device, and the contents not described in detail in the specification, such as the servo motor 2, the light-shielding plate 28 and the ultraviolet lamp tube 31, are well known to those skilled in the art.

Although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that various changes in the embodiments and/or modifications of the invention can be made, and equivalents and modifications of some features of the invention can be made without departing from the spirit and scope of the invention.

Claims

1. The utility model provides a from screening formula ultraviolet mutagenesis device for biological breeding, includes device shell (1), rolling disc (4), first big conveyer pipe (10), stir-fry board (22) and ultraviolet tube (31), its characterized in that: the device is characterized in that a servo motor (2) is fixedly welded on a shell (1), the output end of the servo motor (2) is rotatably connected with a fixed shaft (3), a rotating disc (4) is fixedly welded on the fixed shaft (3), a blanking groove (5) is formed in the rotating disc (4), the rotating disc (4) is rotatably connected in a fixed plate (6), the fixed plate (6) is connected in the device shell (1) through screws, a feeding frame (7) is connected in the device shell (1) through screws, a separation frame (11) is connected in the device shell (1) through screws, a mixing frame (18) is connected in the device shell (1) through screws, a first bevel gear (12) is fixedly welded on the fixed shaft (3), a second bevel gear (13) is connected in the first bevel gear (12) in a meshing manner, and the second bevel gear (13) is fixedly welded on a connecting shaft (14), and the connecting shaft (14) is rotationally connected on the mixing frame (18), the connecting shaft (14) is connected with a first transmission belt (15) in a meshing way, the first transmission belt (15) is connected on the screw rod (16) in a meshing way, the screw rod (16) is rotationally connected in the limiting frame (17), the limiting frame (17) is connected in the device shell (1) through a screw, the limiting frame (17) is connected with a guide pipe (32) through a bolt, the bottom end of the guide pipe (32) is connected on the mixing frame (18) through a bolt, the device shell (1) is rotationally connected with a worm (26), the worm (26) is connected with a worm wheel (27) in a meshing way, the worm wheel (27) is connected with a light insulation plate (28) through a screw, the light insulation plate (28) is movably connected in the light insulation frame (29), the light insulation frame (29) is connected in the device shell (1) through a screw, and the light insulation frame (29) is provided with a light hole, and an ultraviolet lamp tube (31) is installed in the light-proof frame (29) through bolts.

2. The apparatus according to claim 1, wherein the apparatus comprises: the second transmission belt (33) is connected to the fixed shaft (3) in a meshed mode, the circular gear (19) is fixedly welded to the top end of the fixed shaft (3), the circular gear (19) is connected with the fixed block (20) through a screw, the fixed block (20) is connected with the connecting rod (21) in a rotating mode, and meanwhile the bottom end of the connecting rod (21) is connected with the stir-frying plate (22) through a screw.

3. The apparatus according to claim 1, wherein the apparatus comprises: the feeding trough (5) is distributed on the rotating disc (4) at equal angles, the diameter of the feeding trough (5) is equal to that of the first large conveying pipe (10), and the diameter of the feeding trough (5) is equal to that of the bottom opening of the feeding frame (7).

4. The apparatus according to claim 1, wherein the apparatus comprises: fix plate (6) and go up by left side right side screw connection in proper order have first little conveyer pipe (8), first well conveyer pipe (9) and first big conveyer pipe (10), and the diameter of first little conveyer pipe (8), the diameter of conveyer pipe (9) and the diameter of first big conveyer pipe (10) is degressive step by step from left side right side to first little conveyer pipe (8), first well conveyer pipe (9) and first big conveyer pipe (10) all are the spiral.

5. The apparatus according to claim 1, wherein the apparatus comprises: the diameter of the spiral rod (16) is equal to the diameter of the inner space of the limiting frame (17), the length of the spiral rod (16) is greater than that of the limiting frame (17), and the spiral rod (16) is distributed in the separation frame (11) at equal intervals.

6. The apparatus according to claim 1, wherein the apparatus comprises: mix the bottom of frame (18) and have the big conveyer pipe of second (23), conveyer pipe (24) and second (25) in the second from left to right screw connection in proper order, and the overall structure of conveyer pipe (24) and the big conveyer pipe of second (25) is the same with the overall structure of first little conveyer pipe (8), first well conveyer pipe (9) and first big conveyer pipe (10) respectively in the little conveyer pipe of second (23), the second.

7. The ultraviolet mutagenesis device for self-screening biological breeding according to claim 2, characterized in that: the circular gears (19) are symmetrically distributed on the left side and the right side of the mixing frame (18), the circular gears (19) correspond to the connecting rods (21) one by one through the fixing blocks (20), the tops of the adjacent connecting rods (21) are in rotary connection, the connecting rods (21) are fixed in the middle of the turning and frying plate (22), and meanwhile the turning and frying plate (22) is L-shaped.

8. The apparatus according to claim 1, wherein the apparatus comprises: the worm wheel (27) is symmetrically distributed on the left side and the right side of the worm (26), light-insulating plates (28) are distributed on the worm wheel (27) at equal angles, the outer walls of the light-insulating plates (28) are attached to the inner wall of the light-insulating frame (29), and the length of each light-insulating plate (28) is larger than that of the light-insulating frame (29).

9. The apparatus according to claim 1, wherein the apparatus comprises: light holes (30) are equidistantly distributed on the light-shielding frame (29), the central axis of the light-shielding frame (29) and the central axis of the ultraviolet lamp tube (31) are positioned on the same vertical central line, and the light-shielding frame (29) is connected with the light-shielding plate (28) through a bearing.