CN116689207A - Curtain wall surface nano material fusion permeation treatment device and treatment method - Google Patents

Abstract

The application provides a curtain wall surface nano material fusion permeation treatment device and a treatment method, wherein the curtain wall surface nano material fusion permeation treatment device comprises a turnover assembly, a storage box, two side plates, two first electric push rods, two clamping plates, a first driving motor, two supporting plates, four second electric push rods and a transverse plate; the two side plates are fixedly connected to the top of the storage box. According to the curtain wall surface nano material fusion permeation treatment device, the curtain wall is placed between the two clamping plates, the first electric push rod drives the clamping plates to move to fix the curtain wall, the curtain wall is coated through the coating roller, the first driving motor drives the belt to rotate through the belt pulley, the belt drives the first electric push rod to rotate through the other belt pulley, the first electric push rod drives the curtain wall to rotate through the clamping plates, and the curtain wall can be automatically turned over in the process of coating the surface of the curtain wall, so that the curtain wall surface nano material fusion permeation treatment device is formed, the curtain wall does not need to be manually turned over, further the labor force is reduced, and meanwhile, the coating permeation efficiency is improved.

Description

Curtain wall surface nano material fusion permeation treatment device and treatment method

Technical Field

The application relates to a nano material fusion permeation treatment device, in particular to a curtain wall surface nano material fusion permeation treatment device and a treatment method, and belongs to the technical field of curtain wall processing.

Background

The curtain wall is an outer wall protection of a building, is hung like a curtain, is also called a hanging wall, is a light wall body with a decorative effect commonly used in modern large-scale and high-rise buildings, consists of a structural frame and embedded plates, does not bear the load and the action of a main structure, is coated with nano materials on the surface of the curtain wall through a device in the production and processing process, can permeate into micro holes on the surface of the curtain wall, fills and repairs micro damages, forms a protective film, prevents pollutants, dust, moisture and other harmful substances from permeating into the surface of the curtain wall, and reduces the attachment and accumulation of the pollutants;

however, the existing coating device needs to manually overturn a processing curtain wall in the coating process, so that excessive manual labor is consumed, and meanwhile, the coating permeation efficiency is reduced.

Disclosure of Invention

In view of the above, the application provides a curtain wall surface nanomaterial fusion permeation processing device and a processing method, which are used for solving or relieving the technical problems in the prior art and at least providing a beneficial choice.

The technical scheme of the embodiment of the application is realized as follows: the nano material fusion permeation treatment device for the surface of the curtain wall comprises a turnover assembly, wherein the turnover assembly comprises a storage box, two side plates, two first electric push rods, two clamping plates, a first driving motor, two supporting plates, four second electric push rods and a transverse plate;

the two side plates are fixedly connected to the top of the storage box, the two first electric push rods are respectively and rotatably connected to the corresponding side plates, the two clamping plates are respectively and fixedly connected to the corresponding output ends of the first electric push rods, the first driving motor is fixedly connected to one side of one of the two side plates, the two end parts of one of the first electric push rods and the output shaft of the first driving motor are fixedly connected with belt pulleys, the two belt pulleys are in transmission connection with one belt, the two supporting plates are respectively and fixedly connected to one side of the storage box, the four second electric push rods are respectively and fixedly connected to the tops of the corresponding supporting plates, the transverse plates are fixedly connected to the output ends of the four second electric push rods, and coating rollers are arranged below the transverse plates.

Further preferably, a coating assembly is arranged on one side of the overturning assembly, and the coating assembly comprises a U-shaped plate, a reciprocating screw rod, a second driving motor and a moving block;

the U-shaped plate is fixedly connected to the bottom of the transverse plate, the reciprocating screw rod is rotationally connected between the inner walls of the two sides of the U-shaped plate, the second driving motor is fixedly connected to the left side of the U-shaped plate, the end part of the reciprocating screw rod extends out of the U-shaped plate and is fixedly connected with the output shaft of the second driving motor, and the moving block is in threaded connection with the reciprocating screw rod.

Further preferably, the bottom of the moving block is fixedly connected with a rectangular pipe, and the bottom of the rectangular pipe is communicated with and fixed with a plurality of spray heads.

Further preferably, the bottom of the rectangular tube is rotatably connected with the coating roller, and one side of the rectangular tube is communicated with and fixed with a hose.

Further preferably, a delivery pump is fixedly connected to the rear side of the storage box, a liquid inlet pipe of the delivery pump extends into the storage box, and a liquid outlet pipe of the delivery pump is communicated and fixed with a hose.

Further preferably, two square rods are welded between the inner walls of the two sides of the U-shaped plate, and the square rods are in sliding connection with the moving blocks.

Further preferably, a plurality of through holes are formed in the top of the storage box, and the distances among the through holes are equal.

Further preferably, the moving block is provided with a threaded hole, and the moving block is in threaded connection with the reciprocating screw rod through the threaded hole.

The application provides a curtain wall surface nano material fusion permeation treatment method, which comprises the following steps:

s1, placing a curtain wall between two clamping plates, and then starting a first electric push rod, wherein the first electric push rod drives the corresponding clamping plates to move, so that the two clamping plates fix the curtain wall;

s2, starting a conveying pump and a second driving motor, wherein the conveying pump pumps nano materials from the storage box, discharges the nano materials into the rectangular pipe through the hose, and sprays the nano materials onto the coating roller through a spray head below the rectangular pipe;

s3, starting a second electric push rod, wherein the second electric push rod can adjust the coating roller to be in contact with the surface of the curtain wall, meanwhile, the second driving motor drives the reciprocating screw rod to rotate, the reciprocating screw rod drives the moving block to move, the moving block slides on the square rod, and the moving block drives the coating roller to move through the rectangular pipe, so that the coating roller can reciprocate left and right to coat the surface of the curtain wall more uniformly;

s4, when the other surface needs to be coated, a second electric push rod is started, after the coating roller is moved upwards to a proper position, a first driving motor is started at the moment, the first driving motor drives a belt to rotate through a belt pulley, the belt drives another belt pulley to rotate, the other belt pulley drives a first electric push rod to rotate, and the first electric push rod drives a curtain wall to rotate through a clamping plate;

s5, the curtain wall drives another first electric push rod to rotate through another clamping plate, so that the curtain wall is turned over, the curtain wall is coated by adjusting the coating roller to be in contact with the other side of the curtain wall after the curtain wall is turned over, and the curtain wall can be automatically turned over in the process of coating the surface of the curtain wall, so that the curtain wall surface nano material fusion permeation treatment device is formed.

By adopting the technical scheme, the embodiment of the application has the following advantages:

according to the application, the curtain wall is placed between the two clamping plates, the first electric push rod drives the clamping plates to move, so that the two clamping plates fix the curtain wall, the curtain wall surface is coated more uniformly by left and right reciprocation of the coating roller, the first driving motor drives the belt to rotate through the belt pulley, the belt drives the other belt pulley to rotate, the other belt pulley drives the first electric push rod to rotate, the first electric push rod drives the curtain wall to rotate through the clamping plates, and the curtain wall drives the other first electric push rod to rotate through the other clamping plates, so that the curtain wall is turned over, and the curtain wall can be automatically turned over in the process of coating the surface of the curtain wall, so that the curtain wall surface nano material fusion osmosis treatment device is formed, the curtain wall does not need to be turned over manually, further the labor force is reduced, and the coating osmosis efficiency is improved.

The foregoing summary is for the purpose of the specification only and is not intended to be limiting in any way. In addition to the illustrative aspects, embodiments, and features described above, further aspects, embodiments, and features of the present application will become apparent by reference to the drawings and the following detailed description.

Drawings

In order to more clearly illustrate the embodiments of the application or the technical solutions in the prior art, the drawings that are necessary for the description of the embodiments or the prior art will be briefly described, it being obvious that the drawings in the following description are only some embodiments of the application and that other drawings can be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a perspective view of the present application;

FIG. 2 is a rear perspective view of the present application;

FIG. 3 is a right side perspective view of the present application;

fig. 4 is a perspective view showing connection of the U-shaped plate, the reciprocating screw rod, the square rod, the coating roller and the second driving motor.

Reference numerals: 1. a flip assembly; 2. a storage bin; 3. a side plate; 4. a first electric push rod; 5. a clamping plate; 6. a first driving motor; 7. a belt pulley; 8. a belt; 9. a support plate; 10. a second electric push rod; 11. a cross plate; 12. a coating assembly; 13. a U-shaped plate; 14. a reciprocating screw rod; 15. a second driving motor; 16. a moving block; 17. a rectangular tube; 18. a spray head; 19. a coating roller; 20. square rods; 21. a transfer pump; 22. a hose; 23. and a through hole.

Detailed Description

Hereinafter, only certain exemplary embodiments are briefly described. As will be recognized by those of skill in the pertinent art, the described embodiments may be modified in various different ways without departing from the spirit or scope of the present application. Accordingly, the drawings and description are to be regarded as illustrative in nature and not as restrictive.

Embodiments of the present application will be described in detail below with reference to the accompanying drawings.

As shown in fig. 1-4, the embodiment of the application provides a curtain wall surface nano material fusion permeation treatment device, which comprises a turnover assembly 1, wherein the turnover assembly 1 comprises a storage box 2, two side plates 3, two first electric pushing rods 4, two clamping plates 5, a first driving motor 6, two supporting plates 9, four second electric pushing rods 10 and a transverse plate 11;

two curb plates 3 fixed connection are in the top of storage case 2, two first electric putter 4 rotate respectively and connect on the curb plate 3 that corresponds, two splint 5 are fixed connection respectively in the output of the first electric putter 4 that corresponds, first driving motor 6 fixed connection is in one side of one curb plate 3 in two curb plates 3, the tip of one first electric putter 4 in two first electric putter 4 and the equal fixedly connected with belt pulley 7 on the output shaft of first driving motor 6, transmission is connected with same belt 8 on two belt pulleys 7, two backup pads 9 are fixed connection respectively in one side of storage case 2, four second electric putter 10 are fixed connection respectively in the top of backup pad 9 that corresponds, diaphragm 11 fixed connection is in the output of four second electric putter 10, the below of diaphragm 11 is equipped with coating roller 19, place the curtain between two splint 5, first electric putter 4 drives splint 5 and remove, make two first electric putter 5 carry out the curtain and coat more evenly through coating roller 19 left and right sides the surface, belt pulley driving motor 6 drives belt pulley 8 through the other curtain pulley 7, it rotates the other electric putter 7 and rotates the other curtain 4, it can rotate the other side of another curtain 4 to drive the manual work device through another, and the other side of the curtain 4 rotates, and the other side of the curtain 4 is rotated, and the other side of the manual work device is rotated, the other side of the curtain 4 is rotated, the other side of the curtain 4 is rotated, and is rotated, the curtain 5 is left, and is left by the curtain 5 is left.

In one embodiment, one side of the turnover assembly 1 is provided with a coating assembly 12, and the coating assembly 12 comprises a U-shaped plate 13, a reciprocating screw 14, a second driving motor 15 and a moving block 16;

the U-shaped plate 13 is fixedly connected to the bottom of the transverse plate 11, the reciprocating screw rod 14 is rotatably connected between the inner walls of the two sides of the U-shaped plate 13, the second driving motor 15 is fixedly connected to the left side of the U-shaped plate 13, the end part of the reciprocating screw rod 14 extends out of the U-shaped plate 13 and is fixedly connected with the output shaft of the second driving motor 15, and the moving block 16 is in threaded connection with the reciprocating screw rod 14.

In one embodiment, the bottom of the movable block 16 is fixedly connected with a rectangular pipe 17, the bottom of the rectangular pipe 17 is communicated and fixed with a plurality of spray heads 18, the bottom of the rectangular pipe 17 is rotationally connected with a coating roller 19, one side of the rectangular pipe 17 is communicated and fixed with a hose 22, the rear side of the storage box 2 is fixedly connected with a delivery pump 21, a liquid inlet pipe of the delivery pump 21 extends into the storage box 2, a liquid outlet pipe of the delivery pump 21 is communicated and fixed with the hose 22, the delivery pump 21 pumps nano materials out of the storage box 2 and discharges the nano materials into the rectangular pipe 17 through the hose 22, the nano materials are sprayed onto the coating roller 19 through the spray heads 18 below the rectangular pipe 17, and the surface of the curtain wall is coated through the coating roller 19.

In one embodiment, two square rods 20 are welded between the inner walls of the two sides of the U-shaped plate 13, the square rods 20 are in sliding connection with the moving block 16, threaded holes are formed in the moving block 16, the moving block 16 is in threaded connection with the reciprocating screw rod 14 through the threaded holes, the second driving motor 15 drives the reciprocating screw rod 14 to rotate, the reciprocating screw rod 14 drives the moving block 16 to move, the moving block 16 slides on the square rods 20, the moving block 16 drives the coating roller 19 to move through the rectangular tube 17, and the coating roller 19 can be used for coating the surface of the curtain wall more uniformly in a left-right reciprocating mode.

In one embodiment, the top of the storage tank 2 is provided with a plurality of through holes 23, the through holes 23 have equal intervals, and the excessive nano material can enter the storage tank 2 for storage through the through holes 23.

The application provides a curtain wall surface nano material fusion permeation treatment method, which comprises the following steps:

s1, placing a curtain wall between two clamping plates 5, and then starting a first electric push rod 4, wherein the first electric push rod 4 drives the corresponding clamping plates 5 to move, so that the two clamping plates 5 fix the curtain wall;

s2, starting a conveying pump 21 and a second driving motor 15, wherein the conveying pump 21 pumps nano materials out of the storage box 2, discharges the nano materials into the rectangular pipe 17 through a hose 22, and sprays the nano materials onto the coating roller 19 through a spray head 18 below the rectangular pipe 17;

s3, starting a second electric push rod 10, wherein the second electric push rod 10 can adjust a coating roller 19 to be in contact with the surface of the curtain wall, meanwhile, a second driving motor 15 drives a reciprocating screw rod 14 to rotate, the reciprocating screw rod 14 drives a moving block 16 to move, the moving block 16 slides on a square rod 20, and the moving block 16 drives the coating roller 19 to move through a rectangular pipe 17, so that the coating roller 19 can reciprocate left and right to coat the surface of the curtain wall more uniformly;

s4, when the other surface needs to be coated, a second electric push rod 10 is started, after the coating roller 19 is moved upwards to a proper position, a first driving motor 6 is started at the moment, the first driving motor 6 drives a belt 8 to rotate through a belt pulley 7, the belt 8 drives another belt pulley 7 to rotate, the other belt pulley 7 drives a first electric push rod 4 to rotate, and the first electric push rod 4 drives a curtain wall to rotate through a clamping plate 5;

s5, the curtain wall drives another first electric push rod 4 to rotate through another clamping plate 5, so that the curtain wall is overturned, the curtain wall is coated by adjusting the coating roller 19 to be in contact with the other side of the curtain wall after overturning, and the curtain wall can be overturned automatically in the process of coating the surface of the curtain wall, so that the curtain wall surface nano material fusion and permeation treatment device is formed.

The application works when in work: during the use, do not need the manual work to overturn processing curtain, and then reduce hand labor, improve coating infiltration efficiency simultaneously.

The foregoing is merely illustrative of the present application, and the present application is not limited thereto, and any person skilled in the art will readily recognize that various changes and substitutions are possible within the scope of the present application. Therefore, the protection scope of the present application shall be subject to the protection scope of the claims.

Claims (9)

1. The utility model provides a curtain surface nano material fuses infiltration processing apparatus, includes upset subassembly (1), its characterized in that: the overturning assembly (1) comprises a storage box (2), two side plates (3), two first electric pushing rods (4), two clamping plates (5), a first driving motor (6), two supporting plates (9), four second electric pushing rods (10) and a transverse plate (11);

the two side plates (3) are fixedly connected to the top of the storage box (2), the two first electric pushing rods (4) are respectively connected to the corresponding side plates (3) in a rotating mode, the two clamping plates (5) are respectively and fixedly connected to the corresponding output ends of the first electric pushing rods (4), the first driving motor (6) is fixedly connected to one side of one side plate (3) in the two side plates (3), the two end portions of one first electric pushing rod (4) in the first electric pushing rods (4) and the output shafts of the first driving motor (6) are respectively and fixedly connected with belt pulleys (7), the two belt pulleys (7) are connected with the same belt (8) in a transmission mode, the two supporting plates (9) are respectively and fixedly connected to one side of the storage box (2), the four second electric pushing rods (10) are respectively and fixedly connected to the top of the corresponding supporting plates (9), the cross plates (11) are fixedly connected to the output ends of the four second electric pushing rods (10), and the cross plates (11) are provided with coating rollers (19).

2. The curtain wall surface nanomaterial fusion osmotic treatment device of claim 1, wherein: one side of the overturning assembly (1) is provided with a coating assembly (12), and the coating assembly (12) comprises a U-shaped plate (13), a reciprocating screw rod (14), a second driving motor (15) and a moving block (16);

the U-shaped plate (13) is fixedly connected to the bottom of the transverse plate (11), the reciprocating screw rod (14) is rotationally connected between the inner walls of the two sides of the U-shaped plate (13), the second driving motor (15) is fixedly connected to the left side of the U-shaped plate (13), the end part of the reciprocating screw rod (14) extends out of the U-shaped plate (13) and is fixedly connected with the output shaft of the second driving motor (15), and the moving block (16) is in threaded connection with the reciprocating screw rod (14).

3. The curtain wall surface nanomaterial fusion osmotic treatment device of claim 2, wherein: the bottom of movable block (16) fixedly connected with rectangular pipe (17), the bottom intercommunication of rectangular pipe (17) is fixed with a plurality of shower nozzles (18).

4. The curtain wall surface nanomaterial fusion osmotic treatment device of claim 3, wherein: the bottom of the rectangular pipe (17) is rotationally connected with the coating roller (19), and one side of the rectangular pipe (17) is communicated and fixed with a hose (22).

5. The curtain wall surface nanomaterial fusion osmotic treatment device of claim 1, wherein: the rear side of the storage box (2) is fixedly connected with a conveying pump (21), a liquid inlet pipe of the conveying pump (21) extends into the storage box (2), and a liquid outlet pipe of the conveying pump (21) is communicated and fixed with a hose (22).

6. The curtain wall surface nanomaterial fusion osmotic treatment device of claim 2, wherein: two square rods (20) are welded between the inner walls of the two sides of the U-shaped plate (13), and the square rods (20) are in sliding connection with the moving blocks (16).

7. The curtain wall surface nanomaterial fusion osmotic treatment device of claim 1, wherein: a plurality of through holes (23) are formed in the top of the storage box (2), and the distances among the through holes (23) are equal.

8. The curtain wall surface nanomaterial fusion osmotic treatment device of claim 2, wherein: threaded holes are formed in the moving blocks (16), and the moving blocks (16) are in threaded connection with the reciprocating screw rod (14) through the threaded holes.

9. A curtain wall surface nanomaterial fusion penetration processing method according to any one of claims 1-8, characterized by comprising the steps of:

s1, placing a curtain wall between two clamping plates (5), and then starting a first electric push rod (4), wherein the first electric push rod (4) drives the corresponding clamping plates (5) to move, so that the two clamping plates (5) fix the curtain wall;

s2, starting a conveying pump (21) and a second driving motor (15) immediately, wherein the conveying pump (21) pumps nano materials out of the storage box (2) and discharges the nano materials into the rectangular pipe (17) through a hose (22), and then spraying the nano materials onto the coating roller (19) through a spray head (18) below the rectangular pipe (17);

s3, starting a second electric push rod (10), enabling a second electric push rod (10) to be capable of adjusting a coating roller (19) to be in contact with the surface of the curtain wall, enabling a second driving motor (15) to drive a reciprocating screw rod (14) to rotate, enabling the reciprocating screw rod (14) to drive a moving block (16) to move, enabling the moving block (16) to slide on a square rod (20), enabling the moving block (16) to drive the coating roller (19) to move through a rectangular pipe (17), and enabling the coating roller (19) to reciprocate left and right to coat the surface of the curtain wall more uniformly;

s4, when the other surface needs to be coated, a second electric push rod (10) is started, after the coating roller (19) moves upwards to a proper position, a first driving motor (6) is started at the moment, the first driving motor (6) drives a belt (8) to rotate through a belt pulley (7), the belt (8) drives another belt pulley (7) to rotate, the other belt pulley (7) drives the first electric push rod (4) to rotate, and the first electric push rod (4) drives a curtain wall to rotate through a clamping plate (5);

s5, the curtain wall drives another first electric push rod (4) to rotate through another clamping plate (5), so that the curtain wall is turned over, the curtain wall is coated by adjusting a coating roller (19) to be in contact with the other side of the curtain wall after the curtain wall is turned over, and the curtain wall can be automatically turned over in the process of coating the surface of the curtain wall, so that the curtain wall surface nano material fusion and permeation treatment device is formed.