CN116059946A

CN116059946A - Graphene reinforced titanium dioxide production and processing equipment

Info

Publication number: CN116059946A
Application number: CN202310023399.4A
Authority: CN
Inventors: 杨杰; 宋志敏; 江兆潭; 轩海城
Original assignee: Shandong Woxi New Material Technology Co ltd
Current assignee: Shandong Woxi New Material Technology Co ltd
Priority date: 2023-01-09
Filing date: 2023-01-09
Publication date: 2023-05-05
Anticipated expiration: 2043-01-09
Also published as: CN116059946B

Abstract

The graphene reinforced titanium dioxide production and processing equipment comprises a bottom plate, wherein a fixed cylinder is fixedly connected to the bottom plate, a cover plate is arranged at the top end of the fixed cylinder, the cover plate is an annular plate, a support frame is fixedly connected to the cover plate, a fixed rod is fixedly connected to the support frame, a crown gear is fixedly connected to the support frame in a rotating mode, and the crown gear is connected with the cover plate in a rotating mode; the bottom surface of the crown gear is fixedly connected with a rotating frame, the rotating frame is provided with a fixed gear and a rotating gear, the fixed gear is coaxial with the crown gear, the fixed gear is fixedly connected with the rotating frame, the rotating gear is meshed with the fixed gear, the rotating gear is rotationally connected with the rotating frame, and the rotating gear is connected with a stirring assembly; the fixed rod is also connected with a storage component and a feeding component, the storage component is positioned at the top end of the fixed rod, and the feeding component is positioned below the storage component; the problems that the preparation process is troublesome and the labor cost is high in the existing graphene reinforced titanium dioxide production and processing equipment are effectively solved.

Description

Graphene reinforced titanium dioxide production and processing equipment

Technical Field

The invention relates to the technical field of medical assistance, in particular to graphene reinforced titanium dioxide production and processing equipment.

Background

The biggest characteristic of graphene is that the movement speed of electrons in the graphene can reach 1/300 of the speed of light, which is far greater than the movement speed of electrons in a general conductor, so that the properties of electrons in graphene or more precisely what should be called "charge carriers" and relativistic neutrinos are very similar.

Titanium dioxide is an important raw material for preparing inorganic materials, the particle size of the titanium dioxide is between 1nm and 100 mu m, and the nano titanium dioxide has large specific surface area, high surface energy and large proportion of surface atoms due to the self dimension reaching the nano level, so that the titanium dioxide has special properties common to a plurality of nano materials. And its characteristic three major effects: surface effects, small size effects, and macroscopic quantum tunneling effects. Macroscopic exhibits special optical, thermal, magnetic and mechanical properties. The nano titanium dioxide plays an important role of an electron transfer carrier in manufacturing new generation solar energy such as dye sensitized solar cells, quantum dot solar cells and the like due to the special properties of the nano titanium dioxide, and is an important material and a component for manufacturing the next generation solar cells.

At present, few methods are available for fully and uniformly mixing graphene and titanium dioxide for production and preparation, and the titanium dioxide slurry compounded with the graphene overcomes the defects of poor conductivity and mechanical property of an electrode prepared from titanium dioxide with a single component. The application range of titanium dioxide in the field of the currently emerging energy materials is expanded, however, the preparation process of graphene reinforced titanium dioxide production and processing equipment in the prior art is troublesome, and the labor cost is high.

Disclosure of Invention

Aiming at the situation, in order to overcome the defects of the prior art, the invention provides the graphene reinforced titanium dioxide production and processing equipment, and the problems of troublesome preparation process and high labor cost of the existing graphene reinforced titanium dioxide production and processing equipment are effectively solved through the design.

In order to achieve the above purpose, the present invention provides the following technical solutions:

the graphene reinforced titanium dioxide production and processing equipment comprises a bottom plate, wherein a fixed cylinder is fixedly connected to the bottom plate, a cover plate is detachably connected to the top end of the fixed cylinder, the cover plate is an annular plate, a fixing frame is fixedly connected to the cover plate, a fixing rod is fixedly connected to the fixing frame, a crown gear is rotatably connected to the fixing rod, and the crown gear is rotatably connected with the cover plate; the bottom surface of the crown gear is fixedly connected with a rotating frame, the rotating frame is provided with a fixed gear and a rotating gear, the fixed gear is coaxial with the crown gear, the fixed gear is fixedly connected with the rotating frame, the rotating gear is meshed with the fixed gear, the rotating gear is rotationally connected with the rotating frame, and the rotating gear is connected with a stirring assembly; the fixed rod is also connected with a storage component and a feeding component, the storage component is positioned at the top end of the fixed rod, and the feeding component is positioned below the storage component; the cover plate is provided with a first feeding port and a second feeding port, and the second feeding port is matched with the feeding assembly.

Further, the stirring assembly comprises a rotating shaft fixedly connected with the rotating gear, the bottom end of the rotating shaft penetrates through the rotating frame, the bottom end of the rotating frame is fixedly connected with a fixed disc, a rotating rod is connected to the fixed disc, and the bottom end of the rotating rod is fixedly connected with a stirring plate; the lifting rod is connected in the fixed rod in a lifting way, the bottom end of the lifting rod is rotationally connected with a lifting plate, the rotating rod is rotationally connected with the fixed disc, the top end of the rotating rod is fixedly connected with a limit column, a groove matched with the limit column is formed in the lifting plate, and the groove is positioned above the fixed disc and coaxial with the fixed disc; the fixed rod is further connected with a first threaded rod in a threaded mode, the bottom end of the first threaded rod is rotationally connected with the lifting rod, and the top end of the first threaded rod is fixedly connected with a first adjusting knob.

Further, a power motor is fixedly connected to the fixing frame, the output end of the power motor is fixedly connected with a driving shaft, and a limiting groove matched with the driving shaft is formed in the lifting rod; the driving shaft is fixedly connected with a driving gear, the driving gear is meshed with the crown gear, the driving shaft is fixedly connected with a driving plate, the fixing rod is rotatably connected with a driven sheave matched with the driving plate, the top end of the driven sheave is fixedly connected with a rotating plate, and the feeding component is connected with the rotating plate.

Further, the feeding assemblies are multiple, a first sliding groove is formed in the rotating plate, a sliding frame is connected to the first sliding groove in a sliding mode, a feeding cylinder is fixedly connected to the sliding frame, a fixed groove is formed in the feeding cylinder, and a fixed ring matched with the fixed groove is arranged on the sliding frame; a first extension spring is further arranged between the sliding frame and the rotating plate, and two ends of the first extension spring are fixedly connected with the sliding frame and the rotating plate; fixedly connected with fixed column on the carriage, fixedly connected with and spacing post matched with fixed plate on the dead lever, the fixed plate is located the top of carriage, and fixed plate and dead lever cooperation drive the carriage slide on the rotor plate.

Further, the top fixedly connected with of reinforced section of thick bamboo feeds in raw materials and covers and be equipped with the trompil on the reinforced apron, and the last lift of reinforced apron is connected with the regulating plate, rotates on the regulating plate and is connected with the second threaded rod, second threaded rod and reinforced apron threaded connection, the other end fixedly connected with second adjust knob of second threaded rod.

Further, a second chute is further arranged at the bottom of the charging barrel, a baffle is connected in a sliding manner in the second chute and matched with the lower opening of the charging barrel, a driving plate is fixedly connected to the baffle and matched with the second charging opening, and a bulge matched with the driving plate is arranged at the second charging opening; and a second stretching spring is fixedly connected between the baffle plate and the driving plate, one end of the second stretching spring is fixedly connected with the driving plate, and the other end of the second stretching spring is fixedly connected with the feeding cylinder.

Further, the number of the stock components is multiple, the stock components comprise stock barrels fixedly connected with the fixed rods, the bottom ends of the stock barrels are connected with sliding plates in a sliding mode, and through holes matched with the stock barrels are formed in the sliding plates; the sliding plate is also fixedly connected with a pressing plate, the pressing plate is fixedly connected with a compression spring, and the other end of the compression spring is fixedly connected with the stock cylinder; the sliding plate penetrates through one end of the storage barrel and is fixedly connected with a limiting plate, a fixed block is fixedly connected to the fixed column, and the other end of the sliding plate is matched with the fixed block.

Further, a first scraping plate and a second scraping plate are fixedly connected to the rotating frame, and the first scraping plate, the second scraping plate and the stirring assembly are uniformly arranged in the circumference; the first scraping plate is matched with the inner wall of the fixed cylinder, and the second scraping plate is matched with the bottom of the fixed cylinder; the cover plate is also provided with a first charging hole.

Further, the heights of the sliding plates on the material storage assemblies are different, and the heights of the fixing blocks on the sliding frame are the same as the heights of the corresponding sliding plates.

Further, a first feeding hole is further formed in the cover plate, and a discharging hole is formed in the fixed cylinder.

The invention has novel structure, ingenious conception and simple and convenient operation, and has the following advantages compared with the prior art:

1. the device uses the fixed cylinder as a preparation container, and the titanium dioxide powder is put into the fixed cylinder so as to treat the titanium dioxide powder by putting various materials into the fixed cylinder.

2. This device stores various raw materials through stock subassembly, and the convenience is further mixed various materials, realizes preparing graphene reinforcing titanium dioxide, improves the efficiency of preparation flow, reduces operating personnel's working strength.

3. This device adds acid solution, graphene solution and curing agent in the fixed section of thick bamboo through reinforced subassembly one by one, carries out acidizing to titanium dioxide powder in proper order, mixes graphene and titanium dioxide powder and carries out the solidification to it.

4. The device is used for stirring and mixing the raw materials entering the fixed cylinder through the stirring assembly, so that the titanium dioxide powder is ensured to be fully processed.

5. The device scrapes down the mixture remained on the inner wall and the bottom of the fixed cylinder through the first scraping plate and the second scraping plate, and reduces the raw material loss in the preparation process.

Drawings

FIG. 1 is an isometric view of the overall structure of the present invention;

FIG. 2 is an isometric view of a crown gear of the present invention;

FIG. 3 is a cross-sectional view of a fixture cartridge of the present invention;

FIG. 4 is a cross-sectional view of a turret according to the present invention;

FIG. 5 is an isometric view of a lifter plate of the present invention;

FIG. 6 is an isometric view of a holding pan of the present invention;

FIG. 7 is an isometric view of a sheave and a rotating plate of the present invention;

FIG. 8 is an isometric view of a charging assembly of the present invention;

FIG. 9 is an isometric view of a baffle of the present invention;

FIG. 10 is a cross-sectional view of a feed cartridge of the present invention;

FIG. 11 is an isometric view of a stock assembly of the present invention;

fig. 12 is an isometric view of a cartridge of the present invention.

Reference numerals in the drawings: 1. a fixed cylinder; 2. a bottom plate; 3. a cover plate; 4. a charging assembly; 5. a first adjustment knob; 6. a first threaded rod; 7. a stock component; 8. a first feed inlet; 9. a fixing frame; 10. a power motor; 11. a second feed inlet; 12. a lifting rod; 13. a fixed rod; 14. a crown gear; 15. a drive gear; 16. a rotating frame; 17. a first scraper; 18. a fixed gear; 19. a second scraper; 20. a stirring assembly; 21. rotating the gear; 22. a limit groove; 23. a rotating shaft; 24. a lifting plate; 25. a groove; 26. a rotating lever; 27. a fixed plate; 28. a stirring plate; 29. a limit column; 30. an active dial; 31. a driven sheave; 32. a rotating plate; 33. fixing the column; 34. a fixed block; 35. a first extension spring; 36. a carriage; 37. a first chute; 38. a fixing plate; 39. a charging barrel; 40. a fixing groove; 41. a driving plate; 42. a second tension spring; 43. a baffle; 44. a second chute; 45. a charging cover plate; 46. an adjusting plate; 47. a second threaded rod; 48. a fixing ring; 49. a sliding plate; 50. a compression spring; 51. a stock barrel; 52. a pressing plate; 53. a through hole; 54. and a limiting plate.

Detailed Description

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

As shown in fig. 1, 3 and 4, the graphene reinforced titanium dioxide production and processing equipment comprises a bottom plate 2, wherein a fixed cylinder 1 is fixedly connected to the bottom plate 2, a cover plate 3 is detachably connected to the top end of the fixed cylinder 1, the cover plate 3 is an annular plate, a fixing frame 9 is fixedly connected to the cover plate 3, a fixing rod 13 is fixedly connected to the fixing frame 9, a crown gear 14 is rotatably connected to the fixing rod 13, and the crown gear 14 is rotatably connected with the cover plate 3; the bottom surface of the crown gear 14 is fixedly connected with a rotating frame 16, the rotating frame 16 is provided with a fixed gear 18 and a rotating gear 21, the fixed gear 18 is coaxial with the crown gear 14, the fixed gear 18 is fixedly connected with the rotating frame 16, the rotating gear 21 is meshed with the fixed gear 18, the rotating gear 21 is rotationally connected with the rotating frame 16, and the rotating gear 21 is connected with a stirring assembly 20; the fixed rod 13 is also connected with a stock component 7 and a feeding component 4, the stock component 7 is positioned at the top end of the fixed rod 13, and the feeding component 4 is positioned below the stock component 7; the cover plate 3 is provided with a first feeding port 8 and a second feeding port 11, and the second feeding port 11 is matched with the feeding component 4; the cover plate 3 is also provided with a first feeding hole 8, and the fixed cylinder 1 is provided with a discharging hole.

When the invention is used, an operator firstly sequentially adds an acid solution, a graphene solution and a curing agent into a corresponding storage component 7, then puts titanium dioxide powder into a fixed cylinder 1 through a first feeding port 8, then controls a feeding component 4 to work, and the feeding component 4 sequentially adds the acid solution, the graphene solution and the curing agent in the storage component 7 into the fixed cylinder 1; simultaneously, the crown gear 14 is controlled to rotate, the crown gear 14 drives the rotating frame 16 to rotate, the rotating gear 21 is driven to rotate in the rotating process of the rotating frame 16, the rotating gear 21 is meshed with the fixed gear 18 to rotate in the rotating process of the rotating gear 21, and the rotating gear 21 drives the stirring assembly 20 to stir raw materials in the fixed cylinder 1, so that the titanium dioxide powder is fully processed; the preparation method comprises the steps of taking a fixed cylinder 1 as a preparation container, putting titanium dioxide powder into the fixed cylinder 1 so as to treat the titanium dioxide powder by putting various materials into the fixed cylinder 1, and taking out the prepared graphene reinforced titanium dioxide through a discharge hole; various raw materials are stored through the storage component 7, so that the various materials are convenient to mix further, the preparation of graphene reinforced titanium dioxide is realized, the efficiency of a preparation process is improved, and the working intensity of operators is reduced; sequentially adding an acid solution, a graphene solution and a curing agent into the fixed cylinder 1 through the feeding assembly 4, sequentially acidizing titanium dioxide powder, mixing graphene and titanium dioxide powder and curing the mixture; the raw materials entering the fixed cylinder 1 are stirred and mixed through the stirring assembly 20, so that the titanium dioxide powder is ensured to be fully processed.

As shown in fig. 1, 5 and 6, the stirring assembly 20 includes a rotating shaft 23 fixedly connected with the rotating gear 21, the bottom end of the rotating shaft 23 penetrates through the rotating frame 16, a fixed disk 27 is fixedly connected to the bottom end of the rotating frame 16, a rotating rod 26 is connected to the fixed disk 27, and a stirring plate 28 is fixedly connected to the bottom end of the rotating rod 26; lifting rod 12 is connected in lifting manner in fixed rod 13, lifting plate 24 is connected at the bottom end of lifting rod 12 in a rotating manner, rotating rod 26 is connected with fixed disk 27 in a rotating manner, limit column 29 is fixedly connected at the top end of rotating rod 26, groove 25 matched with limit column 29 is arranged on lifting plate 24, groove 25 is located above fixed disk 27 and is coaxial with fixed disk 27; the fixed rod 13 is further connected with a first threaded rod 6 in a threaded manner, the bottom end of the first threaded rod 6 is rotationally connected with the lifting rod 12, and the top end of the first threaded rod 6 is fixedly connected with a first adjusting knob 5.

When the stirring device is used, the rotating gear 21 drives the rotating shaft 23 to rotate, the rotating shaft 23 drives the fixed disc 27 to rotate, and the rotating disc drives the rotating rod 26 and the stirring plate 28 to stir raw materials in the fixed cylinder 1; meanwhile, the first threaded rod 6 can be driven to rotate through the first adjusting knob 5, the first threaded rod 6 drives the lifting rod 12 to slide up and down along the fixed rod 13 through threaded connection, the lifting rod 12 drives the lifting plate 24 to slide up and down, the lifting plate 24 is matched with the limit post 29 through the groove 25 to drive the rotating rod 26 to rotate around the fixed disc 27, and the angle of the stirring plate 28 is adjusted to realize the adjustment of stirring intensity; raw materials that will get into in the fixed section of thick bamboo 1 stir the mixture through stirring subassembly 20, guarantee to carry out abundant processing to titanium dioxide powder, simultaneously adjust the angle of dwang 26 and stirring board 28 and can adjust stirring intensity, guarantee the raw materials intensive mixing in the fixed section of thick bamboo 1.

As shown in fig. 2 and 7, the fixed frame 9 is fixedly connected with a power motor 10, the output end of the power motor 10 is fixedly connected with a driving shaft, and the lifting rod 12 is provided with a limit groove 22 matched with the driving shaft; the driving shaft is fixedly connected with a driving gear 15, the driving gear 15 is meshed with the crown gear 14, the driving shaft is fixedly connected with a driving plate 30, the fixing rod 13 is rotatably connected with a driven sheave 31 matched with the driving plate 30, the top end of the driven sheave 31 is fixedly connected with a rotating plate 32, and the charging assembly 4 is connected with the rotating plate 32.

When the invention is used, an operator controls the power motor 10 to work, the power motor 10 drives the driving shaft to rotate, the driving shaft drives the driving gear 15 and the driving dial 30 to rotate, and the driving gear 15 is meshed to drive the crown gear 14 to rotate; the driving plate 30 is matched with the driven grooved pulley 31 to drive the driven grooved pulley 31 to intermittently rotate, the driven grooved pulley 31 drives the feeding component 4 to work through the rotating plate 32, and the feeding component 4 sequentially adds the raw materials in the stock component 7 into the fixed cylinder 1; through the arrangement of the driving plate 30 and the driven grooved pulley 31, the intermittent rotation of the rotating plate 32 can be controlled when the rotary drum is used, and the raw materials in the stock drum 51 are sequentially added into the fixed drum 1.

As shown in fig. 7, 8 and 9, the plurality of charging assemblies 4 are provided, the rotating plate 32 is provided with a first chute 37, the first chute 37 is slidably connected with a sliding frame 36, the sliding frame 36 is fixedly connected with a charging barrel 39, the charging barrel 39 is provided with a fixed slot 40, and the sliding frame 36 is provided with a fixed ring 48 matched with the fixed slot 40; a first extension spring 35 is further arranged between the sliding frame 36 and the rotating plate 32, and two ends of the first extension spring 35 are fixedly connected with the sliding frame 36 and the rotating plate 32; the fixed column 33 is fixedly connected to the sliding frame 36, the fixed rod 13 is fixedly connected with the fixed plate 38 matched with the limit column 29, the fixed plate 38 is positioned above the sliding frame 36, and the fixed plate 38 is matched with the fixed rod 13 to drive the sliding frame 36 to slide on the rotating plate 32; a second chute 44 at the bottom of the charging barrel 39, a baffle 43 is also connected in the second chute 44 in a sliding way, the baffle 43 is matched with the lower opening of the charging barrel, a driving plate 41 is also fixedly connected on the baffle 43, the driving plate 41 is matched with the second charging opening 11, and a bulge matched with the driving plate 41 is arranged at the second charging opening 11; a second extension spring 42 is fixedly connected between the baffle 43 and the driving plate 41, one end of the second extension spring 42 is fixedly connected with the driving plate 41, and the other end of the second extension spring 42 is fixedly connected with the charging barrel 39.

When the invention is used, the rotating plate 32 drives the sliding frame 36 to rotate around the fixed rod 13, the sliding frame 36 drives the charging barrel 39 to rotate through the cooperation of the fixed ring 48 and the fixed groove 40, the first tension spring 35 between the rotating plate 32 and the sliding frame 36 has a tendency of driving the sliding frame 36 to slide towards the fixed rod 13, and the sliding frame 36 slides towards the fixed rod 13 when the charging barrel 39 rotates to the second charging hole 11 due to the cooperation of the fixed plate 38 and the fixed column 33; under the action of a second extension spring 42, the baffle 43 shields the lower opening of the charging barrel 39, so that raw materials in the charging barrel 39 are ensured to be stored in the charging barrel 39, when the sliding frame 36 drives the charging barrel 39 to slide towards the fixed rod 13, the driving plate 41 is matched with a bulge at the position of the second charging opening 11 to drive the baffle 43 to slide, the baffle 43 cancels shielding of the lower opening of the charging barrel 39, raw materials in the charging barrel 39 enter the fixed barrel 1 through the second charging opening 11, and when the rotating plate 32 continuously drives the sliding frame 36 to rotate, the driving plate 41 is separated from the bulge, and under the action of the second extension spring 42, the baffle 43 shields the lower opening of the charging barrel 39; the acid solution, the graphene solution and the curing agent are sequentially added into the fixed cylinder 1 through the feeding assembly 4, the titanium dioxide powder is sequentially subjected to acidizing treatment, and the graphene and the titanium dioxide powder are mixed and cured.

As shown in fig. 10, the top end of the charging barrel 39 is fixedly connected with a charging cover plate 45, an opening is formed in the charging cover plate 45, an adjusting plate 46 is connected to the charging cover plate 45 in a lifting manner, a second threaded rod 47 is rotatably connected to the adjusting plate 46, the second threaded rod 47 is in threaded connection with the charging cover plate 45, and a second adjusting knob is fixedly connected to the other end of the second threaded rod 47.

When the invention is used, an operator can adjust the capacity in the charging barrel 39 according to different requirements of different raw materials, so as to control the charging amount of different raw materials: the second threaded rod 47 is driven to rotate by the second adjusting knob, the second threaded rod 47 is connected with the charging cover plate 45 in a threaded manner to slide up and down, and the second threaded rod 47 drives the adjusting plate 46 to slide up and down along the charging cover plate 45, so that the purpose of adjusting the content of the charging barrel 39 is achieved; through the arrangement of the adjusting plate 46 and the feeding cover plate 45, the invention can control the addition amount of different raw materials when in use, and improve the accuracy of the preparation process.

As shown in fig. 11 and 12, the number of the stock components 7 is plural, the stock components 7 include a stock cylinder 51 fixedly connected with the fixing rod 13, the bottom end of the stock cylinder 51 is slidably connected with a sliding plate 49, and the sliding plate 49 is provided with a through hole 53 matched with the stock cylinder 51; the sliding plate 49 is also fixedly connected with a pressing plate 52, the pressing plate 52 is fixedly connected with a compression spring 50, and the other end of the compression spring 50 is fixedly connected with a stock cylinder 51; the sliding plate 49 penetrates through one end of the stock barrel 51 and is fixedly connected with a limiting plate 54, the fixed column 33 is fixedly connected with a fixed block 34, and the other end of the sliding plate 49 is matched with the fixed block 34; the height of the sliding plates 49 on the plurality of stock assemblies 7 is different, and the height of the fixed blocks 34 on the sliding frame 36 is the same as the height of the corresponding sliding plates 49.

When the invention is used, an operator sequentially puts an acid solution, a graphene solution and a curing agent into the first storage barrel 51 on the right side of the second charging opening 11 in a clockwise sequence, when the rotating plate 32 drives the sliding frame 36 to rotate, the sliding frame 36 slides along the rotating plate 32 through the cooperation of the fixed column 33 and the fixed plate 38, when the charging barrel 39 is positioned below the storage barrel 51, the fixed block 34 also cooperates with the sliding plate 49 on the storage barrel 51 to control the sliding plate 49 to slide, the sliding plate 49 slides along the storage barrel 51, and the through hole 53 on the raw material sliding plate 49 in the storage barrel 51 enters the charging barrel 39; the rotating plate 32 continues to drive the sliding plate 49 to rotate, the fixed block 34 is separated from the sliding plate 49, the sliding plate 49 slides along the storage barrel 51 under the action of the pressing plate 52 and the compression spring 50, and the sliding plate 49 shields the lower opening of the storage barrel 51; in addition, the material storage component 7 and the material feeding component 4 are correspondingly matched, and the corresponding fixed blocks 34 are high with the corresponding sliding plates 49, so that only the corresponding fixed blocks 34 can control the corresponding sliding plates 49 to slide, and raw materials in the material storage barrel 51 enter the material feeding barrel 39; various raw materials are stored through the storage component 7, so that various materials can be conveniently and further mixed, the preparation of the graphene reinforced titanium dioxide is realized, the efficiency of a preparation process is improved, and the working intensity of operators is reduced.

As shown in fig. 4, the rotating frame 16 is also fixedly connected with a first scraper 17 and a second scraper 19, and the first scraper 17, the second scraper 19 and the stirring assembly 20 are uniformly arranged in circumference; the first scraping plate 17 is matched with the inner wall of the fixed cylinder 1, and the second scraping plate 19 is matched with the bottom of the fixed cylinder 1.

When the invention is used, the rotating frame 16 also drives the first scraping plate 17 and the second scraping plate 19 to rotate, the first scraping plate 17 cleans the inner wall of the fixed cylinder 1, the second scraping plate 19 cleans the bottom of the fixed cylinder 1, so that raw materials are prevented from adhering to the inside of the fixed cylinder 1 in the treatment process, and the loss of the raw materials and the defects in the preparation process are avoided; the residual mixture on the inner wall and the bottom of the fixed cylinder 1 is scraped off by the first scraping plate 17 and the second scraping plate 19, so that the loss of raw materials in the preparation process is reduced.

The application process of the invention comprises the following steps:

when the invention is used, an operator firstly puts acid solution, graphene solution and curing agent into the fixed cylinder 1 from the first storage cylinder 51 at the right side of the second charging port 11 in sequence clockwise, then puts titanium dioxide powder into the fixed cylinder 1 through the first charging port 8, then controls the power motor 10 to work, the power motor 10 drives the driving shaft to rotate, the driving shaft drives the driving gear 15 and the driving dial 30 to rotate, the driving gear 15 is meshed to drive the crown gear 14 to rotate, and the crown gear 14 drives the stirring assembly 20 to work; the driving plate 30 is matched with the driven grooved pulley 31 to drive the driven grooved pulley 31 to intermittently rotate, the driven grooved pulley 31 drives the rotating plate 32 to rotate, and the rotating plate 32 drives the feeding component 4 to work;

when the rotating plate 32 drives the sliding frame 36 to rotate, the sliding frame 36 also drives the charging barrel 39 to rotate through the cooperation of the fixed ring 48 and the fixed groove 40, the first tension spring 35 between the rotating plate 32 and the sliding frame 36 has a tendency of driving the sliding frame 36 to slide towards the fixed rod 13, the sliding frame 36 slides along the rotating plate 32 through the cooperation of the fixed column 33 and the fixed plate 38, when the charging barrel 39 is positioned below the storage barrel 51, the fixed block 34 also cooperates with the sliding plate 49 on the storage barrel 51 to control the sliding plate 49 to slide, the sliding plate 49 slides along the storage barrel 51, and the through hole 53 on the raw material sliding plate 49 in the storage barrel 51 enters the charging barrel 39; the rotating plate 32 continues to drive the sliding plate 49 to rotate, the fixed block 34 is separated from the sliding plate 49, the sliding plate 49 slides along the storage barrel 51 under the action of the pressing plate 52 and the compression spring 50, and the sliding plate 49 shields the lower opening of the storage barrel 51; meanwhile, the material storage component 7 and the material feeding component 4 are correspondingly matched, and the corresponding fixed blocks 34 and the corresponding sliding plates 49 are the same in height, so that only the corresponding fixed blocks 34 can control the corresponding sliding plates 49 to slide, and raw materials in the material storage barrel 51 enter the material feeding barrel 39;

in addition, the capacity in the charging barrel 39 can be adjusted according to the different required amounts of different raw materials, so that the charging amount of the different raw materials is controlled: the second threaded rod 47 is driven to rotate by the second adjusting knob, the second threaded rod 47 is connected with the charging cover plate 45 in a threaded manner to slide up and down, and the second threaded rod 47 drives the adjusting plate 46 to slide up and down along the charging cover plate 45, so that the purpose of adjusting the content of the charging barrel 39 is achieved;

because the fixed plate 38 is matched with the fixed column 33, when the charging barrel 39 rotates to the second charging port 11, the sliding frame 36 slides to the fixed rod 13; under the action of a second extension spring 42, the baffle 43 shields the lower opening of the charging barrel 39, so that raw materials in the charging barrel 39 are ensured to be stored in the charging barrel 39, when the sliding frame 36 drives the charging barrel 39 to slide towards the fixed rod 13, the driving plate 41 is matched with a bulge at the position of the second charging opening 11 to drive the baffle 43 to slide, the baffle 43 cancels shielding of the lower opening of the charging barrel 39, raw materials in the charging barrel 39 enter the fixed barrel 1 through the second charging opening 11, and when the rotating plate 32 continuously drives the sliding frame 36 to rotate, the driving plate 41 is separated from the bulge, and under the action of the second extension spring 42, the baffle 43 shields the lower opening of the charging barrel 39;

the crown gear 14 drives the rotating frame 16 to rotate, the rotating gear 21 is driven to rotate in the rotating process of the rotating frame 16, the rotating gear 21 is meshed with the fixed gear 18 to rotate in the rotating process, the rotating gear 21 drives the rotating shaft 23 to rotate, the rotating shaft 23 drives the fixed disc 27 to rotate, and the rotating disc drives the rotating rod 26 and the stirring plate 28 to stir raw materials in the fixed cylinder 1; meanwhile, the first threaded rod 6 can be driven to rotate through the first adjusting knob 5, the first threaded rod 6 vertically slides along the fixed rod 13 through threaded connection, the first threaded rod 6 drives the lifting rod 12 to vertically slide, the lifting rod 12 drives the lifting plate 24 to vertically slide, the lifting plate 24 is matched with the limiting column 29 through the groove 25 to drive the rotating rod 26 to rotate around the fixed disc 27, and the angle of the stirring plate 28 is adjusted to realize the adjustment of stirring intensity; the rotating frame 16 also drives the first scraping plate 17 and the second scraping plate 19 to rotate, the first scraping plate 17 cleans the inner wall of the fixed cylinder 1, and the second scraping plate 19 cleans the bottom of the fixed cylinder 1 to prevent raw materials from being stuck in the fixed cylinder 1 in the treatment process; and taking out the prepared graphene reinforced titanium dioxide through a discharge hole.

Finally, it should be noted that: the foregoing description is only illustrative of the preferred embodiments of the present invention, and 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 modifications may be made to the embodiments described, or equivalents may be substituted for elements thereof, and any modifications, equivalents, improvements or changes may be made without departing from the spirit and principles of the present invention.

Claims

1. The utility model provides a graphite alkene reinforcing titanium dioxide production and processing equipment, includes bottom plate (2), fixedly connected with fixed cylinder (1) on bottom plate (2), the top of fixed cylinder (1) can be dismantled and be connected with apron (3), its characterized in that: the cover plate (3) is an annular plate, the cover plate (3) is fixedly connected with a fixing frame (9), the fixing frame (9) is fixedly connected with a fixing rod (13), the fixing rod (13) is rotationally connected with a crown gear (14), and the crown gear (14) is rotationally connected with the cover plate (3); the stirring device is characterized in that a rotating frame (16) is fixedly connected to the bottom surface of the crown gear (14), a fixed gear (18) and a rotating gear (21) are arranged on the rotating frame (16), the fixed gear (18) is coaxial with the crown gear (14), the fixed gear (18) is fixedly connected with the rotating frame (16), the rotating gear (21) is meshed with the fixed gear (18), the rotating gear (21) is rotationally connected with the rotating frame (16), and a stirring assembly (20) is connected to the rotating gear (21); the fixed rod (13) is also connected with a stock component (7) and a feeding component (4), the stock component (7) is positioned at the top end of the fixed rod (13), and the feeding component (4) is positioned below the stock component (7); the cover plate (3) is provided with a first feeding hole (8) and a second feeding hole (11), and the second feeding hole (11) is matched with the feeding component (4).

2. The graphene-reinforced titanium dioxide production and processing equipment according to claim 1, wherein: the stirring assembly (20) comprises a rotating shaft (23) fixedly connected with the rotating gear (21), the bottom end of the rotating shaft (23) penetrates through the rotating frame (16), a fixed disc (27) is fixedly connected with the bottom end of the rotating frame (16), a rotating rod (26) is connected to the fixed disc (27), and a stirring plate (28) is fixedly connected with the bottom end of the rotating rod (26); lifting rods (12) are connected in the fixed rods (13) in a lifting manner, lifting plates (24) are rotatably connected to the bottom ends of the lifting rods (12), rotating rods (26) are rotatably connected with fixed discs (27), limiting columns (29) are fixedly connected to the top ends of the rotating rods (26), grooves (25) matched with the limiting columns (29) are formed in the lifting plates (24), and the grooves (25) are located above the fixed discs (27) and coaxial with the fixed discs (27); the fixed rod (13) is further connected with a first threaded rod (6) in a threaded mode, the bottom end of the first threaded rod (6) is rotationally connected with the lifting rod (12), and the top end of the first threaded rod (6) is fixedly connected with a first adjusting knob (5).

3. The graphene-reinforced titanium dioxide production and processing equipment according to claim 1, wherein: the fixed frame (9) is fixedly connected with a power motor (10), the output end of the power motor (10) is fixedly connected with a driving shaft, and the lifting rod (12) is provided with a limit groove (22) matched with the driving shaft; the driving shaft is fixedly connected with a driving gear (15), the driving gear (15) is meshed with the crown gear (14), the driving shaft is fixedly connected with a driving plate (30), the fixing rod (13) is rotatably connected with a driven sheave (31) matched with the driving plate (30), the top end of the driven sheave (31) is fixedly connected with a rotating plate (32), and the feeding component (4) is connected with the rotating plate (32).

4. The graphene-reinforced titanium dioxide production and processing equipment according to claim 1, wherein: the feeding components (4) are multiple, a first chute (37) is formed in the rotating plate (32), a sliding frame (36) is connected to the first chute (37) in a sliding mode, a feeding cylinder (39) is fixedly connected to the sliding frame (36), a fixed groove (40) is formed in the feeding cylinder (39), and a fixed ring (48) matched with the fixed groove (40) is arranged on the sliding frame (36); a first extension spring (35) is further arranged between the sliding frame (36) and the rotating plate (32), and two ends of the first extension spring (35) are fixedly connected with the sliding frame (36) and the rotating plate (32); fixed column (33) is fixedly connected to sliding frame (36), fixed plate (38) matched with limit column (29) is fixedly connected to fixed rod (13), fixed plate (38) is located above sliding frame (36), and fixed plate (38) and fixed rod (13) cooperate to drive sliding frame (36) to slide on rotating plate (32).

5. The graphene-reinforced titanium dioxide production and processing equipment according to claim 4, wherein: the top fixedly connected with of reinforced section of thick bamboo (39) is reinforced apron (45), is equipped with the trompil on reinforced apron (45), and reinforced apron (45) go up and down to be connected with regulating plate (46), rotate on regulating plate (46) and be connected with second threaded rod (47), second threaded rod (47) and reinforced apron (45) threaded connection, the other end fixedly connected with second adjust knob of second threaded rod (47).

6. The graphene-reinforced titanium dioxide production and processing equipment according to claim 4, wherein: the bottom of the charging barrel (39) is also connected with a baffle plate (43) in a sliding manner, the baffle plate (43) is matched with the lower opening of the charging barrel, the baffle plate (43) is also fixedly connected with a driving plate (41), the driving plate (41) is matched with a second charging opening (11), and a bulge matched with the driving plate (41) is arranged at the second charging opening (11); a second extension spring (42) is fixedly connected between the baffle plate (43) and the driving plate (41), one end of the second extension spring (42) is fixedly connected with the driving plate (41), and the other end of the second extension spring (42) is fixedly connected with the charging barrel (39).

7. The graphene-reinforced titanium dioxide production and processing equipment according to claim 4, wherein: the number of the material storage assemblies (7) is multiple, each material storage assembly (7) comprises a fixed transverse plate fixedly connected with a fixed rod (13), a material storage barrel (51) is fixedly connected to the fixed transverse plate, a sliding plate (49) is slidably connected to the bottom end of each material storage barrel (51), and through holes (53) matched with the material storage barrels (51) are formed in the sliding plate (49); the sliding plate (49) is also fixedly connected with a pressing plate (52), the pressing plate (52) is fixedly connected with a compression spring (50), and the other end of the compression spring (50) is fixedly connected with a stock cylinder (51); one end of the sliding plate (49) penetrates through the storage barrel (51) and is fixedly connected with a limiting plate (54), the fixed column (33) is fixedly connected with a fixed block (34), and the other end of the sliding plate (49) is matched with the fixed block (34).

8. The graphene-reinforced titanium dioxide production and processing equipment according to claim 1, wherein: the rotating frame (16) is fixedly connected with a first scraping plate (17) and a second scraping plate (19), and the first scraping plate (17), the second scraping plate (19) and the stirring assembly (20) are uniformly arranged in the circumference; the first scraping plate (17) is matched with the inner wall of the fixed cylinder (1), and the second scraping plate (19) is matched with the bottom of the fixed cylinder (1).

9. The graphene-reinforced titanium dioxide production and processing equipment according to claim 7, wherein: the heights of the sliding plates (49) on the plurality of stock components (7) are different, and the heights of the fixed blocks (34) on the sliding frame (36) are the same as the heights of the corresponding sliding plates (49).

10. The graphene-reinforced titanium dioxide production and processing equipment according to claim 1, wherein: the cover plate (3) is also provided with a first feeding hole (8), and the fixed cylinder (1) is provided with a discharge hole.