CN114272853A - Nano antibacterial coating manufacturing installation - Google Patents

Abstract

The invention relates to the field of nano materials, in particular to a nano antibacterial coating manufacturing device, wherein a nano titanium preparation guide rail is fixedly connected above a hood, a titanium solution preparation device is arranged in the hood in a sliding manner through the nano titanium preparation guide rail and quickly injects titanium alkoxide into anhydrous alcohol in a manner similar to an injector so as to achieve the purpose of fully mixing the components in an anhydrous environment, a liquid injection tank is fixedly connected at the middle position in the hood for mixing operation, a process control device below the liquid injection tank is arranged in the hood through a gel lifting lead screw thread and distributes the action sequence among components, a gel sol device is fixedly connected at the bottom of the hood so as to stably and uniformly drop anhydrous alcohol-titanium alkoxide solution into a gel barrel, a filler adding device is rotatably arranged in the hood through a bearing to perform filler sintering on the gel sol, the function of preparing the nano antibacterial coating under the industrial anhydrous environment is completed.

Description

Nano antibacterial coating manufacturing installation

Technical Field

The invention relates to the field of nano materials, in particular to a device for manufacturing a nano antibacterial coating.

Background

Along with the improvement of living standard of people, the requirements on indoor decoration are continuously improved, the treatment of toxic gas of formaldehyde brought by various sizing materials used in decoration is also paid attention, and sulfur dioxide and nitrogen dioxide are two main outdoor air pollutants, so that the indoor and outdoor clear toxic gas becomes a scientific research direction; the nanometer bacteriostatic coating of the nanometer titanium dioxide photocatalytic coating is produced in a batch and high-efficiency mode by utilizing the characteristic that the nanometer titanium dioxide photocatalytic coating can decompose most pollutants under ultraviolet irradiation to generate carbon dioxide and water, wherein in the production process of titanium dioxide by adopting a gel sol method, titanium alkoxide is required to be added into absolute ethyl alcohol in an anhydrous environment for operation, and the efficient production of the titanium nanometer bacteriostatic coating is ensured by maintaining the anhydrous environment while ensuring the efficient and automatic operation of equipment, so that the nanometer bacteriostatic coating manufacturing device is invented.

Disclosure of Invention

The invention relates to the field of nano materials, in particular to a nano antibacterial coating manufacturing device, wherein a nano titanium preparation guide rail is fixedly connected above a hood, a titanium solution preparation device is arranged in the hood in a sliding manner through the nano titanium preparation guide rail and quickly injects titanium alkoxide into anhydrous alcohol in a manner similar to an injector so as to achieve the purpose of fully mixing the components in an anhydrous environment, a liquid injection tank is fixedly connected at the middle position in the hood for mixing operation, a process control device below the liquid injection tank is arranged in the hood through a gel lifting lead screw thread and distributes the action sequence among components, a gel sol device is fixedly connected at the bottom of the hood so as to stably and uniformly drop anhydrous alcohol-titanium alkoxide solution into a gel barrel, a filler adding device is rotatably arranged in the hood through a bearing to perform filler sintering on the gel sol, the function of preparing the nano antibacterial coating under the industrial anhydrous environment is completed.

In order to solve the technical problem, a manufacturing device of a nano antibacterial coating is characterized in that: the titanium solution preparation device is arranged in the hood in a sliding mode through the nano-titanium preparation guide rail and quickly injects titanium alkoxide into anhydrous alcohol in a manner similar to an injector so as to achieve the purpose of fully mixing the titanium alkoxide in the anhydrous environment, the liquid injection tank is fixedly connected to the middle position in the hood to perform mixing operation, the process control device below the liquid injection tank is arranged in the hood through a gel lifting lead screw in a threaded mode and distributes the action sequence among the components, the gel sol device is fixedly connected to the bottom of the hood so as to stably and uniformly dropwise add anhydrous alcohol-titanium alkoxide solution into the gel barrel, the filler adding device is rotatably arranged in the hood through a bearing and performs filler sintering on the gel sol, and the function of preparing the nano antibacterial coating in the industrial anhydrous environment is achieved.

As a further optimization of the technical scheme, the nano antibacterial coating manufacturing device of the invention is characterized in that a waterless injection transmission screw nut is rotatably arranged on the titanium solution preparation device through a bearing, a waterless injection transmission screw is threadedly arranged on the waterless injection transmission screw nut, a counter is fixedly connected on the waterless injection transmission screw, a waterless injection main screw nut is rotatably arranged on the titanium solution preparation device through a bearing, the waterless injection main screw nut is threadedly arranged on a waterless injection piston, the waterless injection piston is threadedly arranged on a guide nut, the guide nut is fixedly connected on a waterless injection cavity, an installation square steel a is fixedly connected on a main mounting plate, the installation square steel a is fixedly connected on a machine cover, the waterless cavity mounting plate is fixedly connected on the waterless injection cavity, a sliding plate of a linear motor is fixedly connected on the waterless cavity mounting plate, the linear motor is fixedly connected on the main mounting plate, a transmission guide post nut is rotatably arranged on the main mounting plate through a bearing, the injection head is fixedly connected on the waterless injection cavity, and the mounting square steel b is fixedly connected on the hood.

As a further optimization of the technical scheme, in the process control device of the nano antibacterial coating manufacturing device, a liquid discharging piston plate is slidably arranged below a liquid filling box, a liquid discharging piston plate mounting block is fixedly connected to the liquid discharging piston plate, a mounting block clamping block is fixedly connected to the liquid discharging piston plate mounting block, one end of a lifting support rod a is hinged to a mounting square steel a, the other end of the lifting support rod a is hinged to a mounting square steel b, a guide hinge block is hinged to the lifting support rod a, one end of the lifting support rod b is hinged to the mounting square steel a, the other end of the lifting support rod b is hinged to the mounting square steel b, a pull rod is hinged to the rear end of the guide hinge block, a liquid discharging piston screw nut is fixedly connected to the mounting block clamping block, the liquid discharging piston screw nut is threadedly mounted on a liquid discharging piston screw, the liquid discharging piston screw is rotatably mounted on a machine cover through a bearing, the swing rod is hinged to the pull rod, the action connecting rod is rotatably mounted on the swing rod, the balance wheel is rotatably mounted on the action connecting rod, the transmission shaft a is fixedly connected to the balance wheel, the transmission shaft a is rotatably mounted on the hood through a bearing, the transmission shaft b is rotatably mounted on the hood through a bearing, the transmission shaft c is rotatably mounted on the hood through a bearing, the driven sheave is fixedly connected to the transmission shaft c, the driving sheave is meshed with the driven sheave, the driving sheave is fixedly connected to the transmission shaft c, the driving bevel gear is fixedly connected to the transmission shaft c, the driven double-half bevel gear is fixedly connected to the liquid discharging piston screw rod, and the driven double-half bevel gear is meshed with the driving bevel gear.

As a further optimization of the technical scheme, the gel tube of the gel sol device of the nano antibacterial coating manufacturing device of the invention is fixedly connected on a gel tube mounting block which is fixedly connected on a gel displacement slide block which is fixedly connected on a gel slide rail which is fixedly connected on a gel lifting plate which is fixedly connected on a gel lifting lead screw which is mounted on a gel barrel bearing plate through a lead screw nut, the gel barrel bearing plate is rotatably mounted inside a hood through a bearing, a gel displacement cylinder is fixedly connected on the gel barrel bearing plate, a gel barrel is fixedly connected on the gel barrel bearing plate, a lifting motor mounting plate is fixedly connected on the gel barrel bearing plate through an upright post, a gel lifting motor is fixedly connected on the lifting motor mounting plate, a steering gear is fixedly connected on the gel barrel bearing plate, a steering power belt wheel is rotatably mounted on the hood through a rotating shaft, the power toothed belt is meshed with the steering power belt wheel, the steering rack is fixedly connected on the power toothed belt, and the transition pipe is fixedly connected on the gel barrel.

As a further optimization of the technical scheme, the feeding ring in the filler adding device is rotatably installed inside the hood through a bearing, the central power gear shaft is rotatably installed on the hood, the transition gear shaft is rotatably installed on the hood, the filler spray head is fixedly connected to the feeding ring, the sintering barrel is fixedly connected to the other end of the transition pipe, and the sintering barrel is fixedly connected inside the hood.

As a further optimization of the technical scheme, the titanium solution preparation device comprises two installation square steels a, two linear motors and two installation square steels b, and a plurality of injection heads.

As a further optimization of the technical scheme, the process control device of the device for manufacturing the nano antibacterial coating comprises two lifting support rods a, two guide hinge blocks, two lifting support rods b, two pull rods, two liquid discharging piston screw nuts, two liquid discharging piston screws, two swing rods, two action connecting rods, two balance wheels, two transmission shafts a, two transmission shafts b, two driven grooved wheels, two driving bevel teeth and two driven half bevel teeth.

As a further optimization of the technical scheme, the gel tube mounting block, the gel displacement slide block, the gel slide rail, the gel lifting plate and the steering power belt pulley are all two in the gel sol device, and the number of the gel lifting screw rods and the number of the upright columns are four.

As a further optimization of the technical scheme, six filler nozzles are arranged in the filler adding device of the nano antibacterial coating manufacturing device.

The manufacturing device of the nano antibacterial coating has the beneficial effects that:

the invention relates to robot-related equipment, in particular to a nano antibacterial coating manufacturing device, wherein a nano titanium preparation guide rail is fixedly connected above a hood, a titanium solution preparation device is arranged in the hood in a sliding manner through the nano titanium preparation guide rail and quickly injects titanium alkoxide into anhydrous alcohol in a manner similar to an injector so as to achieve the purpose of fully mixing the titanium alkoxide in an anhydrous environment, a liquid injection tank is fixedly connected at the middle position in the hood for mixing operation, a process control device below the liquid injection tank is arranged in the hood through a gel lifting lead screw thread and distributes the action sequence among components, a gel sol device is fixedly connected at the bottom of the hood so as to stably and uniformly dropwise add anhydrous alcohol-titanium alkoxide solution into a gel barrel, a filler adding device is rotatably arranged in the hood through a bearing to perform filler sintering on the gel sol, the function of preparing the nano antibacterial coating under the industrial anhydrous environment is completed.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

Fig. 1 is a schematic view of the overall structure of the present invention.

Fig. 2 is a schematic view of the overall structure of the present invention.

FIG. 3 is a schematic structural view of a titanium solution preparing apparatus according to the present invention.

FIG. 4 is a first schematic structural diagram of a process control apparatus according to the present invention.

FIG. 5 is a second schematic structural diagram of a process control apparatus according to the present invention.

FIG. 6 is a third schematic structural diagram of a process control apparatus according to the present invention.

FIG. 7 is a first schematic structural view of a gel sol device and a filler adding device according to the present invention.

FIG. 8 is a schematic structural view of a gel sol device and a filler adding device according to the present invention.

In the figure: 1. a hood; 2. preparing a guide rail by using nano titanium; 3. a titanium solution preparation device; 301. a waterless injection drive lead screw nut; 302. a waterless injection drive screw; 303. a main screw nut for water-free injection; 304. a waterless injection piston; 305. a counter; 306. a guide nut; 307. an anhydrous injection cavity; 308. a main mounting plate; 309. mounting square steel a; 310. a water-free cavity mounting plate; 311. a linear motor; 312. a drive guide post nut; 313. an injection head; 314. mounting square steel b; 4. a liquid injection tank; 5. a process control device; 501. a liquid discharge piston plate; 502. a liquid discharging piston plate mounting block; 503. installing a block clamping block; 504. a lifting support rod a; 505. a guide hinge block; 506. a lifting support rod b; 507. a pull rod; 508. a tapping piston screw nut; 509. a tapping piston screw; 510. a swing rod; 511. an action connecting rod; 512. a balance wheel; 513. a transmission shaft a; 514. a transmission shaft b; 515. a transmission shaft c; 516. a passive sheave; 517. a driving sheave; 518. driving bevel gears; 519. passive double-half bevel gear; 6. a sol-gel device; 601. a gel barrel bearing plate; 602. a gel displacement cylinder; 603. a gel tube mounting block; 604. a gel displacement slide block; 605. a gel slide rail; 606. a gel lifting plate; 607. a gel bucket; 608. a lifting motor mounting plate; 609. a column; 610. a gel lifting motor; 611. a steering gear; 612. a gel lifting lead screw; 613. a steering power pulley; 614. a power toothed belt; 615. a steering rack; 616. a transition duct; 7. a filler addition device; 701. a central power gear shaft; 702. a transition gear shaft; 703. a filler nozzle; 704. and (5) sintering the barrel.

Detailed Description

The first embodiment is as follows:

below combine fig. 1, 2, 3, 4, 5, 6, 7, 8 for solving above-mentioned technical problem, a nanometer antibacterial coating manufacturing installation, guide rail 2 is prepared to 1 top rigid coupling nanometer titanium of aircraft bonnet, titanium solution preparation facilities prepares guide rail 2 slidable mounting in aircraft bonnet 1 through nanometer titanium, annotate the inside intermediate position of liquid case 4 rigid coupling in aircraft bonnet 2, annotate process control device 5 of liquid case 4 below and install in aircraft bonnet 1 through gel elevating screw 612 screw thread, gel sol device rigid coupling is in aircraft bonnet 1 bottom, it installs inside aircraft bonnet 1 through bearing rotation to pack to add device 7.

The second embodiment is as follows:

the present embodiment will be described with reference to fig. 1, 2, 3, 4, 5, 6, 7, and 8, and the present embodiment further describes an embodiment, in which a waterless injection drive lead screw nut 301 is rotatably mounted on the titanium solution preparation apparatus 3 through a bearing, a waterless injection drive lead screw 302 is threadedly mounted on the waterless injection drive lead screw nut 301, a counter 305 is fixedly connected to the waterless injection drive lead screw 302, a waterless injection main lead screw nut 303 is rotatably mounted on the titanium solution preparation apparatus 3 through a bearing, the waterless injection main lead screw nut 303 is threadedly mounted on a waterless injection piston 304, the waterless injection piston 304 is threadedly mounted on a guide nut 306, the guide nut 306 is fixedly connected to a waterless injection cavity 307, a mounting square steel a309 is fixedly connected to a main mounting plate 308, a mounting square steel a309 is fixedly connected to the housing 1, a waterless cavity mounting plate 310 is fixedly connected to the waterless injection cavity 307, the slide plate of the linear motor 311 is fixedly connected to the anhydrous cavity mounting plate 310, the linear motor 311 is fixedly connected to the main mounting plate 308, the transmission guide post nut 312 is rotatably mounted on the main mounting plate 308 through a bearing, the injection head 313 is fixedly connected to the anhydrous injection cavity 307, the mounting square steel b314 is fixedly connected to the hood 1, the linear motor 311 drives the anhydrous cavity mounting plate 310 to displace, meanwhile, the power source on the anhydrous injection transfer screw 302 drives the anhydrous injection transfer screw 302 to rotate, the anhydrous injection transfer screw 302 drives the anhydrous injection main screw 303 to rotate through a belt pulley, the anhydrous injection piston 304 is driven to displace up and down relative to the guide nut 306, positive and negative pressure is controlled on the cavity part in the anhydrous injection cavity 307, and titanium alkoxide in the injection tank 4 is absorbed and injected to one end of the injection tank containing anhydrous alcohol.

The third concrete implementation mode:

in the process control device 5, a tapping piston plate 501 is slidably mounted below a liquid injection tank 4, a tapping piston plate mounting block 502 is fixedly connected to the tapping piston plate 501, a mounting block clamping block 503 is fixedly connected to the tapping piston plate mounting block 502, one end of a lifting strut a504 is hinged to a mounting square steel a309, the other end of the lifting strut a504 is hinged to a mounting square steel b314, a guide hinge block 505 is hinged to the lifting strut a504, one end of the lifting strut b506 is hinged to the mounting square steel a309, the other end of the lifting strut b506 is hinged to the mounting square steel b314, a pull rod 507 is hinged to the rear end of the guide hinge block 505, a tapping piston lead screw nut 508 is fixedly connected to the mounting block clamping block 503, the tapping piston lead screw nut 508 is threadedly mounted on a tapping piston lead screw 509, a liquid discharging piston screw 509 is rotatably arranged on a hood 1 through a bearing, a swing rod 510 is hinged on a pull rod 507, an action connecting rod 511 is rotatably arranged on the swing rod 510, a balance wheel 512 is rotatably arranged on the action connecting rod 511, a transmission shaft a513 is fixedly connected on the balance wheel 512, the transmission shaft a513 is rotatably arranged on the hood 1 through a bearing, a transmission shaft b514 is rotatably arranged on the hood 1 through a bearing, a transmission shaft c515 is rotatably arranged on the hood 1 through a bearing, a driven sheave 516 is fixedly connected on the transmission shaft c515, the driving sheave 517 is engaged with the driven sheave 516, the driving sheave 517 is fixedly connected on the transmission shaft c515, a driven double-half conical tooth 519 is fixedly connected on the liquid discharging piston screw 509, the driven double-half conical tooth 519 is engaged with the driving conical tooth 518, the transmission shaft c provides power for rotation, the driving conical tooth 518 is engaged with the driven double-half conical tooth 519 to drive 508 to perform reciprocating intermittent forward and backward movement, the mixed liquid in the liquid injection box 4 is discharged, meanwhile, the driving sheave 517 drives the driven sheave 516 to engage, the gear on the transmission shaft b515 and the gear on the transmission shaft a514 are used for carrying out transmission ratio scaling, the balance wheel 512 rotates to drive the swing rod 510, the swing rod 510 drives the pull rod 507 to swing, the guide hinge block 505 is pushed to drive the lifting support rod a504 and the lifting support rod b506 to carry out hinge motion, the main mounting plate 308 is driven to lift, the waterless injection cavity 307 is driven to lift, and the displacement of the waterless injection cavity 307 relative to the liquid injection box 4 and the opening and closing of the bottom of the liquid injection box 4 are realized.

The fourth concrete implementation mode:

the present embodiment will be described with reference to fig. 1, 2, 3, 4, 5, 6, 7, and 8, and the present embodiment will be further described with reference to the first embodiment, wherein the gel tube of the gel sol device 6 is fixedly connected to the gel tube mounting block 603, the gel tube mounting block 603 is fixedly connected to the gel displacement slider 604, the gel displacement slider 604 is fixedly connected to the gel slide rail 605, the gel slide rail 605 is fixedly connected to the gel lifting plate 606, the gel lifting plate 606 is fixedly connected to the gel lifting screw 612, the gel lifting screw 612 is threadedly mounted on the gel barrel receiving plate 601 through a screw nut, the gel barrel receiving plate 601 is rotatably mounted inside the hood 1 through a bearing, the gel displacement cylinder 602 is fixedly connected to the gel barrel receiving plate 601, the gel barrel 607 is fixedly connected to the gel barrel receiving plate 601, the lifting motor mounting plate 608 is fixedly connected to the gel barrel receiving plate 601 through a column 609, the gel lifting motor 610 is fixedly connected to the lifting motor mounting plate 608, a steering gear 611 is fixedly connected on the gel barrel bearing plate 601, a steering power belt wheel 613 is rotatably arranged on the hood 1 through a rotating shaft, a power toothed belt 614 is meshed with the steering power belt wheel 613, a steering rack 615 is fixedly connected on the power toothed belt 614, a transition pipe 616 is fixedly connected on the gel barrel 607, a gel lifting motor 610 is turned on to drive a gel lifting screw rod 612 to rotate, so that the gel barrel bearing plate 601 is lifted to drive the gel pipe to be butted with the injection tank 4, after the liquid discharging piston plate 501 is closed, the gel lifting screw 612 descends, then the gel displacement cylinder 602 pushes the gel tube to the middle position of the gel barrel 607, then the steering power belt wheel 613 drives the power toothed belt 614 to move, the steering rack 615 and the steering gear 611 are pulled to be meshed, the gel barrel receiving plate 601 is rotated, and the gel tube rotates 180 degrees around the gel barrel 607 to uniformly drop the gel and then is conveyed into the sintering barrel 704 through the transition tube 616.

The fifth concrete implementation mode:

the following describes the present embodiment with reference to fig. 1, 2, 3, 4, 5, 6, 7, and 8, and the present embodiment further describes an embodiment, in which a feeding ring in the filler adding device 7 is rotatably installed inside the hood 1 through a bearing, a central power gear shaft 701 is rotatably installed on the hood 1, a transition gear shaft 702 is rotatably installed on the hood 1, a filler spray nozzle 703 is fixedly connected to the feeding ring, a sintering bucket 704 is fixedly connected to the other end of the transition pipe 616, the sintering bucket 704 is fixedly connected inside the hood 1, the central power gear shaft 701 is meshed with the transition gear shaft 702, then the transition gear shaft 702 is meshed with a gear ring on the feeding ring, and the corresponding filler spray nozzle 703 is subjected to filler sintering against the sintering bucket 704 to complete the preparation of the nano antibacterial coating.

The sixth specific implementation mode:

in the following, the present embodiment will be described with reference to fig. 1, 2, 3, 4, 5, 6, 7, and 8, and the present embodiment further describes an embodiment two, where there are two installation square steels a309, two linear motors 311, and two installation square steels b314 in the titanium solution preparation apparatus 3, and there are several injection heads 313.

The seventh embodiment:

in the following, the present embodiment will be described with reference to fig. 1, 2, 3, 4, 5, 6, 7, and 8, and a third embodiment will be further described in the present embodiment, in the process control device 5, two lift support rods a504, two guide hinge blocks 505, two lift support rods b506, two pull rods 507, two tapping piston screw nuts 508, two tapping piston screw 509, two swing rods 510, two motion connection rods 511, two balance wheels 512, two transmission shafts a513, two transmission shafts b514, two driven grooved wheels 516, two driven grooved wheels 517, two driven tapered teeth 518, and two driven double-half tapered teeth 519 are provided.

The specific implementation mode is eight:

the present embodiment will be described with reference to fig. 1, 2, 3, 4, 5, 6, 7, and 8, and the fourth embodiment will be further described in the present embodiment, in which there are two gel tube mounting blocks 603, two gel displacement sliders 604, two gel slide rails 605, two gel lifting plates 606, and two steering power pulleys 613, and four gel lifting screws 612 and four columns 609 in the gel sol device 6.

The specific implementation method nine:

the present embodiment will be described below with reference to fig. 1, 2, 3, 4, 5, 6, 7, and 8, and the fourth embodiment will be further described with reference to the present embodiment, in which six filler nozzles 703 are provided in the filler addition device 7.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims (9)

1. The utility model provides a bacteriostatic coating manufacturing installation of nanometer, includes aircraft bonnet (1), nanometer titanium preparation guide rail (2), titanium solution preparation facilities (3), annotates liquid case (4), process control device (5), gel sol device (6), packs and adds device (7), its characterized in that: aircraft bonnet (1) top rigid coupling nanometer titanium preparation guide rail (2), titanium solution preparation facilities prepare guide rail (2) slidable mounting in aircraft bonnet (1) through nanometer titanium, annotate liquid case (4) rigid coupling in the inside intermediate position of aircraft bonnet (2), process control device (5) of annotating liquid case (4) below are installed in aircraft bonnet (1) through gel elevating screw (612) screw thread, gel sol device rigid coupling is in aircraft bonnet (1) bottom, it installs inside aircraft bonnet (1) to fill material interpolation device (7) through the bearing rotation.

2. The apparatus for manufacturing a nano antibacterial coating according to claim 1, wherein: the device is characterized in that a waterless injection transmission lead screw nut (301) is installed on the titanium solution preparation device (3) in a rotating mode through a bearing, a waterless injection transmission lead screw (302) is installed on the waterless injection transmission lead screw nut (301) in a threaded mode, a counter (305) is fixedly connected to the waterless injection transmission lead screw (302), a waterless injection main lead screw nut (303) is installed on the titanium solution preparation device (3) in a rotating mode through the bearing, the waterless injection main lead screw nut (303) is installed on a waterless injection piston (304) in a threaded mode, the waterless injection piston (304) is installed on a guide nut (306) in a threaded mode, the guide nut (306) is fixedly connected to a waterless injection cavity (307), an installation square steel a (309) is fixedly connected to a main installation plate (308), the installation square steel a (309) is fixedly connected to a hood (1), the waterless cavity installation plate (310) is fixedly connected to the waterless injection cavity (307), and a sliding plate of a linear motor (311) is fixedly connected to the waterless cavity installation plate (310), the linear motor (311) is fixedly connected to the main mounting plate (308), the transmission guide post nut (312) is rotatably mounted on the main mounting plate (308) through a bearing, the injection head (313) is fixedly connected to the waterless injection cavity (307), and the mounting square steel b (314) is fixedly connected to the hood (1).

3. The apparatus for manufacturing a nano antibacterial coating according to claim 1, wherein: in the process control device (5), a liquid discharging piston plate (501) is slidably arranged below a liquid filling box (4), a liquid discharging piston plate mounting block (502) is fixedly connected on the liquid discharging piston plate (501), a mounting block clamping block (503) is fixedly connected on the liquid discharging piston plate mounting block (502), one end of a lifting support rod a (504) is hinged on a mounting square steel a (309), the other end of the lifting support rod a (504) is hinged on a mounting square steel b (314), a guide hinge block (505) is hinged on the lifting support rod a (504), one end of the lifting support rod b (506) is hinged on the mounting square steel a (309), the other end of the lifting support rod b (506) is hinged on the mounting square steel b (314), a pull rod (507) is hinged on the rear end of the guide hinge block (505), a liquid discharging piston screw nut (508) is fixedly connected on the mounting block clamping block (503), and a liquid discharging piston screw nut (508) is threadedly mounted on a liquid discharging piston screw (509), a liquid discharging piston screw rod (509) is rotatably arranged on a hood (1) through a bearing, a swing rod (510) is hinged on a pull rod (507), an action connecting rod (511) is rotatably arranged on the swing rod (510), a balance wheel (512) is rotatably arranged on the action connecting rod (511), a transmission shaft a (513) is fixedly connected on the balance wheel (512), the transmission shaft a (513) is rotatably arranged on the hood (1) through a bearing, a transmission shaft b (514) is rotatably arranged on the hood (1) through a bearing, a transmission shaft c (515) is rotatably arranged on the hood (1) through a bearing, a driven sheave (516) is fixedly connected on the transmission shaft c (515), a driving sheave (517) is meshed with a driven sheave (516), the driving sheave (517) is fixedly connected on the transmission shaft c (515), a driving conical tooth (518) is fixedly connected on the transmission shaft c (515), a driven double-half conical tooth (519) is fixedly connected on the liquid discharging piston screw rod (509), the passive double-half bevel teeth (519) are meshed with the active bevel teeth (518).

4. The apparatus for manufacturing a nano antibacterial coating according to claim 1, wherein: the gel tube of the gel sol device (6) is fixedly connected on a gel tube mounting block (603), the gel tube mounting block (603) is fixedly connected on a gel displacement slide block (604), the gel displacement slide block (604) is fixedly connected on a gel slide rail (605), the gel slide rail (605) is fixedly connected on a gel lifting plate (606), the gel lifting plate (606) is fixedly connected on a gel lifting lead screw (612), the gel lifting lead screw (612) is arranged on a gel barrel bearing plate (601) through a lead screw nut thread, the gel barrel bearing plate (601) is rotatably arranged in the hood (1) through a bearing, a gel displacement cylinder (602) is fixedly connected on the gel barrel bearing plate (601), a gel barrel (607) is fixedly connected on the gel barrel bearing plate (601), a lifting motor mounting plate (608) is fixedly connected on the gel barrel bearing plate (601) through a vertical column (609), and a gel lifting motor (610) is fixedly connected on the lifting motor mounting plate (608), the steering gear (611) is fixedly connected to the gel barrel bearing plate (601), the steering power belt wheel (613) is rotatably mounted on the hood (1) through a rotating shaft, the power toothed belt (614) is meshed with the steering power belt wheel (613), the steering rack (615) is fixedly connected to the power toothed belt (614), and the transition pipe (616) is fixedly connected to the gel barrel (607).

5. The apparatus for manufacturing a nano antibacterial coating according to claim 1, wherein: a feeding ring in the filler adding device (7) is rotatably installed inside a hood (1) through a bearing, a central power gear shaft (701) is rotatably installed on the hood (1), a transition gear shaft (702) is rotatably installed on the hood (1), a filler spray head (703) is fixedly connected to the feeding ring, a sintering barrel (704) is fixedly connected to the other end of a transition pipe (616), and the sintering barrel (704) is fixedly connected inside the hood (1).

6. The device for manufacturing a nano antibacterial coating according to claim 2, wherein: the titanium solution preparation device (3) is provided with two installation square steels a (309), two linear motors (311) and two installation square steels b (314), and the number of the injection heads (313) is several.

7. The apparatus for manufacturing a nano antibacterial coating according to claim 3, wherein: the working procedure control device (5) is provided with two lifting support rods a (504), two guide hinge blocks (505), two lifting support rods b (506), two pull rods (507), two liquid discharging piston screw nuts (508), two liquid discharging piston screw rods (509), two oscillating rods (510), two action connecting rods (511), two balance wheels (512), two transmission shafts a (513), two transmission shafts b (514), two driven grooved wheels (516), two driving grooved wheels (517), two driving bevel gears (518) and two driven half bevel gears (519).

8. The device for manufacturing a nano antibacterial coating according to claim 4, wherein: the gel device is characterized in that the gel device comprises two gel tube mounting blocks (603), two gel displacement sliding blocks (604), two gel sliding rails (605), two gel lifting plates (606) and two steering power pulleys (613) in the gel sol device (6), and four gel lifting screw rods (612) and four upright posts (609).

9. A nano antibacterial coating manufacturing device according to claim 5, characterized in that: six filling nozzles (703) are arranged in the filling adding device (7).

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