CN112264208A

CN112264208A - Glass automated production processing equipment

Info

Publication number: CN112264208A
Application number: CN202011144363.4A
Authority: CN
Inventors: 刘斌
Original assignee: Shenzhen Lidong Technology Development Co ltd
Current assignee: Shenzhen Lidong Technology Development Co ltd
Priority date: 2020-10-23
Filing date: 2020-10-23
Publication date: 2021-01-26

Abstract

An automatic glass production and processing device comprises a shell, a transmission assembly, a positioning and cleaning assembly, an electrostatic powder scattering assembly, a powder spreading assembly, a recovery pipe and a controller; the feeding end of the shell is provided with a scanner, and the bottom end of the shell is provided with a first filter screen; the transmission assembly is arranged above the first filter screen; the positioning cleaning assembly is arranged at the feeding end; the powder spreading assembly is arranged at the discharge end; the electrostatic dusting assembly is arranged between the positioning cleaning assembly and the powder spreading assembly; a recovery chamber is arranged below the first filter screen; the recovery pipe is communicated with the recovery chamber and the electrostatic dusting assembly. According to the invention, the positioning cleaning assembly is used for pretreating the glass to be powdered, so that subsequent concentrated powder spreading is facilitated, and the powder spreading effect is improved; through the matching of stirring and hot air, the powder drying effect is good, and meanwhile, the bulk materials of the stirring piece are matched with the discharge pipe to rotate, so that the powder scattering is more uniform; the powder spreading plate moves up and down and left and right, the thickness of the powder is adjusted, redundant powder is removed, the waste of the powder is avoided, and the powder spreading effect is improved.

Description

Glass automated production processing equipment

Technical Field

The invention relates to the field of glass processing, in particular to automatic glass production and processing equipment.

Background

Glass is an amorphous inorganic non-metallic material, and is generally made of various inorganic minerals (such as quartz sand, borax, boric acid, barite, barium carbonate, limestone, feldspar, soda ash, etc.) as main raw materials, and a small amount of auxiliary raw materials are added. These powders tend to absorb moisture and agglomerate, resulting in uneven spraying amount and thickness, and dirt on the glass surface may affect the adhesion of the powder.

In order to solve the problems, the application provides automatic glass production and processing equipment.

Disclosure of Invention

Objects of the invention

In order to solve the technical problems in the background art, the invention provides glass automatic production processing equipment, which pretreats glass to be powdered through a positioning cleaning assembly, so that the surface of the glass is cleaned on one hand, and the position of the glass is adjusted on the other hand, so that the subsequent concentrated powder spreading is facilitated, the powder spreading effect is improved, and the waste of powder is reduced; the electrostatic powder scattering assembly is matched with hot air through stirring according to the actual humidity of the powder, so that the powder drying effect is good, the drying time is short, and meanwhile, the bulk material of the stirring piece is matched with the discharge pipe to rotate, so that the powder scattering is more uniform; the powder spreading plate in the powder spreading assembly moves up and down and left and right, so that the thickness of the powder can be adjusted, redundant powder is removed, the waste of the powder is avoided, and the powder spreading effect is improved.

(II) technical scheme

In order to solve the problems, the invention provides glass automatic production and processing equipment which comprises a shell, a transmission assembly, a positioning cleaning assembly, an electrostatic dusting assembly, a powder laying assembly, a recovery pipe and a controller, wherein the transmission assembly is arranged on the shell; the left end and the right end of the shell are opened, the feed end is provided with a scanner, and the bottom end is provided with a first filter screen; the transmission assembly is arranged above the first filter screen; the positioning cleaning assembly is arranged at the feeding end; the powder spreading assembly is arranged at the discharge end; the electrostatic dusting assembly is arranged between the positioning cleaning assembly and the powder spreading assembly; a recovery chamber is arranged below the first filter screen; the recovery pipe is communicated with the recovery chamber and the electrostatic dusting assembly; the positioning and cleaning assembly comprises a driving cylinder, a first mounting seat, a cleaning roller, a second mounting seat, a first lead screw, a positioning plate and a first driving motor; the driving cylinder is arranged at the top end of the shell; the first mounting seat moving up and down is connected with a telescopic rod end of the driving cylinder, and the lower end of the first mounting seat is open; the cleaning roller is rotatably arranged on the open end of the first mounting seat; the second mounting seat is arranged on one side, facing the feeding, of the first mounting seat; a first lead screw driven by a first driving motor is rotatably arranged on the second mounting seat, and two ends of the first lead screw are provided with reverse threads; the upper ends of the two groups of positioning plates are respectively in threaded connection with two ends of the first screw rod; the electrostatic powder scattering component comprises a powder loading box, a second driving motor, a rotating pipe, a first air outlet pipe, a second air outlet pipe, a three-way valve, a third air outlet pipe, a discharge pipe, a third driving motor, a stirring part, an electrostatic powder discharging box, a powder discharging pipe, a heating part and a fan; the air inlet end of the heating element is connected with the air outlet end of the fan, and the air outlet end of the heating element is connected with the second air outlet pipe; the three-way valve is arranged at the air outlet end of the second air outlet pipe and is connected with one end of the first air outlet pipe and one end of the rotating pipe; the powder containing box is arranged on the outer wall of the shell; the rotating pipe driven by the second driving motor is rotatably arranged in the powder containing box; the first air outlet pipes are provided with a plurality of groups, the plurality of groups of first air outlet pipes are dispersedly arranged on the side wall of the rotating pipe, and air outlet holes are formed in the first air outlet pipes; the air outlet hole is communicated with the second air outlet pipe; the upper end of a discharge pipe driven by a third driving motor is rotatably connected with the inner wall of the shell and is communicated with the powder containing box, and the lower end of the discharge pipe is communicated with the electrostatic discharge box; the other end of the third air outlet pipe is communicated with the electrostatic discharge box; the stirring piece is arranged inside the static discharging box; the powder outlet pipe is arranged at the bottom of the electrostatic powder outlet box; the powder spreading assembly comprises a moving piece, a second lead screw, a fourth driving motor, a fifth driving motor, a third lead screw and a powder spreading plate; the powder laying plate is provided with a sliding chute and a thread groove; a second lead screw driven by a fourth driving motor is rotatably arranged above the transmission assembly; the upper end of the moving piece is in threaded connection with the second lead screw, and the lower end of the moving piece is in sliding connection with the groove wall of the sliding groove; and a third lead screw driven by a fifth driving motor is arranged on two sides of the moving member along the vertical direction, the upper end of the third lead screw is rotatably connected with the moving member, and the lower end of the third lead screw is in threaded connection with a thread groove.

Preferably, the recovery pipe is provided with a suction pump.

Preferably, the air inlet end of the recovery pipe is communicated with the recovery chamber, and the air outlet end of the recovery pipe is communicated with the powder filling box.

Preferably, the positioning and cleaning assembly further comprises a mounting member, an elastic member and a mounting shaft; a lifting groove is formed in the inner wall of the first mounting seat; the mounting piece is connected with the wall of the lifting groove in a sliding manner; the elastic piece is arranged in the lifting groove, the upper end of the elastic piece is connected with the top of the lifting groove, and the lower end of the elastic piece is connected with the mounting piece; the one end of installation axle is rotated and is connected the installed part, and the scrub roller is cup jointed to the other end.

Preferably, the heating element comprises a heating box and a heating resistor; the heating resistor is arranged inside the heating box.

Preferably, a humidity detector is arranged inside the powder containing box.

Preferably, the electrostatic dusting assembly further comprises a first gear, a second gear, a transmission rod, a cleaning plate, a second filter screen, a stirring sheet and an electric control valve; the bottom of the powder filling box is provided with a discharge channel communicated with the discharge pipe; the second filter screen is arranged at the feed end of the discharge channel; the first gear is connected to the rotating tube in a bonding manner; the second gear is connected to the upper end of the transmission rod in a bonding mode and is in meshed connection with the first gear; the middle end of the transmission rod is rotatably connected with the second filter screen, and the lower end of the transmission rod is connected with the stirring sheet; the electric control valve is arranged at the discharge end of the discharge channel; the cleaning plate is connected with the side wall of the transmission rod and is positioned above the second filter screen.

Preferably, the electrostatic dusting assembly further comprises a third gear and a fourth gear; the third gear is in bonded connection with the discharge pipe; the fourth gear is connected with the main shaft of the third driving motor and is meshed with the third gear.

Preferably, the powder laying assembly further comprises a transmission belt; the fifth driving motor is arranged on the moving piece; and the transmission belt is respectively sleeved with a main shaft of the fifth driving motor and a third screw rod.

Preferably, the processing method of the automatic glass production and processing equipment is as follows:

s1, adding powder into the powder filling box, and sending signals to the fan, the heating element and the second driving motor by the controller according to the humidity condition of the powder to enable the first air outlet pipe to rotate to discharge air and dry the powder until the water content is reduced to a set threshold value;

s2, enabling the glass to enter the shell through the transmission assembly;

s3, the scanner scans the glass and transmits the size and thickness data to the controller;

s4, under the action of a signal of the controller, the driving cylinder pushes the first mounting seat to move up and down, the cleaning roller is contacted with the upper surface of the glass, the first lead screw rotates to drive the positioning plate to move, the glass is pushed to the middle position, and the glass is limited;

s5, opening the electric control valve, enabling the dry powder filtered by the second filter screen to enter the electrostatic discharging box and be scattered by the stirring part, and enabling the electrostatic discharging box to rotate to uniformly spray the powder onto the glass below;

s6, driving the moving part to move horizontally by rotating the second lead screw, driving the powder spreading plate to move up and down by rotating the third lead screw, adjusting the position of the powder spreading plate, spreading the powder on the surface of the glass, and scraping redundant powder;

s7, the redundant powder enters a recovery chamber and finally returns to a powder filling box through a recovery pipe.

The technical scheme of the invention has the following beneficial technical effects:

firstly, the glass to be powdered is pretreated under the action of the positioning cleaning assembly, so that the surface of the glass is cleaned on one hand, and the position of the glass is righted on the other hand, so that the subsequent concentrated powder spreading is facilitated, the powder spreading effect is improved, and the waste of powder is reduced; according to the invention, under the action of the electrostatic powder scattering assembly, the powder is dried by adopting the matching of stirring and hot air according to the actual humidity of the powder, so that the powder drying effect is good, the drying time is short, and meanwhile, the bulk material of the stirring part is matched with the discharge pipe to rotate, so that the powder scattering is more uniform; the powder spreading assembly is arranged, and the powder spreading plate moves up and down and left and right, so that the thickness of the powder can be adjusted, redundant powder is removed, the waste of the powder is avoided, and the powder spreading effect is improved;

the processing method has the advantages of strong automation, simple operation, labor saving and realization of reutilization of waste resources.

Drawings

Fig. 1 is a schematic structural diagram of an automatic glass production and processing device according to the present invention.

Fig. 2 is a schematic diagram of an internal structure of an automatic glass production and processing apparatus according to the present invention.

Fig. 3 is a cross-sectional view at a position a in an automatic glass manufacturing apparatus according to the present invention.

Fig. 4 is a right side view of a position a of the automatic glass manufacturing apparatus according to the present invention.

FIG. 5 is a schematic structural diagram of a mounting member of an automated glass manufacturing apparatus according to the present invention.

Fig. 6 is a cross-sectional view at B of an automated glass manufacturing apparatus according to the present invention.

Fig. 7 is a cross-sectional view at C of an automated glass manufacturing apparatus according to the present invention.

FIG. 8 is a right side view of a section C of an automated glass manufacturing apparatus according to the present invention.

Fig. 9 is an enlarged view of a position D in the automatic glass manufacturing apparatus according to the present invention.

The attached drawings are marked as follows: 1. a housing; 2. a transmission assembly; 3. positioning the cleaning assembly; 4. an electrostatic dusting assembly; 5. a powder paving component; 6. a first filter screen; 7. a recovery pipe; 8. a driving cylinder; 9. a first mounting seat; 10. installing a shaft; 11. a cleaning roller; 12. a second mounting seat; 13. a first lead screw; 14. positioning a plate; 15. a first drive motor; 16. an elastic member; 17. a movable mounting member; 18. powder filling box; 19. a second drive motor; 20. rotating the tube; 21. a first air outlet pipe; 22. a second air outlet pipe; 23. a three-way valve; 24. an air outlet; 25. a third air outlet pipe; 26. a discharge pipe; 27. a third gear; 28. a fourth gear; 29. a third drive motor; 30. a stirring member; 31. discharging the material box electrostatically; 32. a powder outlet pipe; 33. a heating box; 34. a heating resistor; 35. a fan; 36. a first gear; 37. a second gear; 38. a transmission rod; 39. cleaning the plate; 40. a second filter screen; 41. a stirring sheet; 42. an electrically controlled valve; 43. a moving member; 44. a second lead screw; 45. a fourth drive motor; 46. a fifth drive motor; 47. a third lead screw; 48. spreading a powder plate; 49. a transmission belt; 50. a chute; 51. a scanner.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention will be described in further detail with reference to the accompanying drawings in conjunction with the following detailed description. It should be understood that the description is intended to be exemplary only, and is not intended to limit the scope of the present invention. Moreover, in the following description, descriptions of well-known structures and techniques are omitted so as to not unnecessarily obscure the concepts of the present invention.

Example 1

As shown in fig. 1-9, the automatic glass production and processing equipment provided by the invention comprises a shell 1, a transmission assembly 2, a positioning and cleaning assembly 3, an electrostatic dusting assembly 4, a powder spreading assembly 5, a recovery pipe 7 and a controller; the left end and the right end of the shell 1 are opened, the feeding end is provided with a scanner 51, and the bottom end is provided with a first filter screen 6; the transmission assembly 2 is arranged above the first filter screen 6; the positioning cleaning assembly 3 is arranged at the feeding end; the powder spreading assembly 5 is arranged at the discharge end; the electrostatic dusting assembly 4 is arranged between the positioning cleaning assembly 3 and the powder spreading assembly 5; a recovery chamber is arranged below the first filter screen 6; the recovery pipe 7 is communicated with the recovery chamber and the electrostatic dusting assembly 4; the positioning and cleaning assembly 3 comprises a driving cylinder 8, a first mounting seat 9, a cleaning roller 11, a second mounting seat 12, a first lead screw 13, a positioning plate 14 and a first driving motor 15; the driving cylinder 8 is arranged at the top end of the shell 1; the first mounting seat 9 moving up and down is connected with the telescopic rod end of the driving cylinder 8, and the lower end of the first mounting seat is open; the cleaning roller 11 is rotatably arranged on the open end of the first mounting seat 9; the second mounting seat 12 is arranged on the first mounting seat 9 towards one side of the feeding material; a first lead screw 13 driven by a first driving motor 15 is rotatably arranged on the second mounting base 12, and two ends of the first lead screw are provided with reverse threads; two groups of positioning plates 14 are arranged, and the upper ends of the two groups of positioning plates 14 are respectively in threaded connection with two ends of the first screw rod 13; the electrostatic dusting component 4 comprises a dusting box 18, a second driving motor 19, a rotating pipe 20, a first air outlet pipe 21, a second air outlet pipe 22, a three-way valve 23, a third air outlet pipe 25, a discharge pipe 26, a third driving motor 29, a stirring part 30, an electrostatic discharge box 31, a dusting pipe 32, a heating part and a fan 35; the air inlet end of the heating element is connected with the air outlet end of the fan 35, and the air outlet end is connected with the second air outlet pipe 22; the three-way valve 23 is arranged at the air outlet end of the second air outlet pipe 22 and is connected with one end of the first air outlet pipe 21 and one end of the rotating pipe 20; the powder containing box 18 is arranged on the outer wall of the shell 1; a rotating pipe 20 driven by a second driving motor 19 is rotatably arranged in the powder containing box 18; the first air outlet pipes 21 are arranged in a plurality of groups, the plurality of groups of first air outlet pipes 21 are dispersedly arranged on the side wall of the rotating pipe 20, and air outlet holes 24 are arranged on the first air outlet pipes 21; the air outlet hole 24 is communicated with the second air outlet pipe 22; the upper end of a discharge pipe 26 driven by a third driving motor 29 is rotatably connected with the inner wall of the shell 1 and is communicated with the powder containing box 18, and the lower end is communicated with an electrostatic discharge box 31; the other end of the third air outlet pipe 25 is communicated with the static discharge box 31; the stirring piece 30 is arranged inside the static electricity discharging box 31; the powder outlet pipe 32 is arranged at the bottom of the electrostatic powder outlet box 31; the powder spreading assembly 5 comprises a moving member 43, a second lead screw 44, a fourth driving motor 45, a fifth driving motor 46, a third lead screw 47 and a powder spreading plate 48; the powder laying plate 48 is provided with a sliding groove 50 and a thread groove; a second lead screw 44 driven by a fourth driving motor 45 is rotatably arranged above the transmission assembly 2; the upper end of the moving member 43 is connected with the second lead screw 44 in a threaded manner, and the lower end is connected with the groove wall of the chute 50 in a sliding manner; and a third lead screw 47 driven by a fifth driving motor 46 is arranged on two sides of the moving member 43 along the vertical direction, the upper end of the third lead screw is rotatably connected with the moving member 43, and the lower end of the third lead screw is in threaded connection with the thread groove.

In an alternative embodiment, a suction pump is provided on the recovery pipe 7.

In an alternative embodiment, the inlet end of the recycling pipe 7 is communicated with the recycling chamber, and the outlet end is communicated with the powder box 18.

In an alternative embodiment, the positioning cleaning assembly 3 further comprises a mounting member 17, an elastic member 16 and a mounting shaft 10; a lifting groove is formed in the inner wall of the first mounting seat 9; the mounting piece 17 is connected with the groove wall of the lifting groove in a sliding manner; the elastic piece 16 is arranged in the lifting groove, the upper end of the elastic piece is connected with the top of the lifting groove, and the lower end of the elastic piece is connected with the mounting piece 17; one end of the mounting shaft 10 is rotatably connected with the mounting member 17, and the other end is sleeved with the cleaning roller 11.

In an alternative embodiment, the heating element comprises a heating box 33 and a heating resistor 34; the heating resistor 34 is disposed inside the heating box 33.

In an alternative embodiment, a moisture detector is disposed within the powder bin 18.

In an alternative embodiment, the electrostatic powdering assembly 4 further comprises a first gear 36, a second gear 37, a transmission rod 38, a cleaning plate 39, a second filter screen 40, a stirring blade 41 and an electrically controlled valve 42; the bottom of the powder containing box 18 is provided with a discharging channel communicated with a discharging pipe 26; the second filter screen 40 is arranged at the feeding end of the discharge channel; the first gear 36 is connected to the rotary tube 20 in a bonded manner; the second gear 37 is connected to the upper end of the transmission rod 38 in a bonding manner and is meshed with the first gear 36; the middle end of the transmission rod 38 is rotatably connected with a second filter screen 40, and the lower end of the transmission rod is connected with a stirring sheet 41; the electric control valve 42 is arranged at the discharge end of the discharge channel; a cleaning plate 39 is attached to the side wall of the drive link 38 and is located above the second filter screen 40.

In an alternative embodiment, the electrostatic dusting assembly 4 further comprises a third gear 27 and a fourth gear 28; the third gear 27 is in bonded connection with the discharge pipe 26; the fourth gear 28 is connected to the main shaft of the third driving motor 29 and is meshed with the third gear 27.

In an alternative embodiment, the dusting assembly 5 further comprises a conveyor belt 49; the fifth driving motor 46 is provided on the moving member 43; a transmission belt 49 is respectively sleeved on the main shaft of the fifth driving motor 46 and the third lead screw 47.

The invention pretreats the glass to be dusted by the action of the positioning cleaning component 3, on one hand, the surface of the glass is cleaned, on the other hand, the position of the glass is righted, so that the subsequent concentrated dusting is convenient, the dusting effect is improved, and the waste of powder is reduced; according to the invention, under the action of the electrostatic powder scattering assembly 4, the powder is dried by adopting the mixing and hot air matching according to the actual humidity of the powder, so that the powder drying effect is good, the drying time is short, and meanwhile, the stirring piece 30 and the bulk material are matched with the discharge pipe 26 to rotate, so that the powder scattering is more uniform; the powder spreading assembly 5 is arranged, the powder spreading plate 48 moves up and down and left and right, the thickness of the powder can be adjusted, redundant powder is removed, the waste of the powder is avoided, and the powder spreading effect is improved.

Example 2

The invention relates to automatic glass production and processing equipment, which comprises the following processing methods:

s1, adding powder into the powder filling box 18, and sending signals to the fan 35, the heating element and the second driving motor 19 by the controller according to the humidity condition of the powder, so that the first air outlet pipe 21 rotates to discharge air, and the powder is dried until the water content is reduced to a set threshold value;

s2, the glass enters the shell 1 through the transmission assembly 2;

s3, the scanner 51 scans the glass and transmits the size and thickness data to the controller;

s4, under the action of a signal of the controller, the driving cylinder 8 pushes the first mounting seat 9 to move up and down, the cleaning roller 11 is in contact with the upper surface of the glass, the first lead screw 13 rotates to drive the positioning plate 14 to move, the glass is pushed to the middle position, and the glass is limited;

s5, opening the electric control valve 42, allowing the dry powder filtered by the second filter screen 40 to enter the electrostatic discharging box 31 and be scattered by the stirring piece 30, and allowing the electrostatic discharging box 31 to rotate to uniformly spray the powder onto the glass below;

s6, the second screw rod 44 rotates to drive the moving member 43 to move horizontally, the third screw rod 47 rotates to drive the powder spreading plate 48 to move up and down, the position of the powder spreading plate 48 is adjusted, powder on the surface of the glass is spread, and redundant powder is scraped;

s7, the excess powder enters the recovery chamber and finally returns to the powder bin 18 through the recovery pipe 7.

It is to be understood that the above-described embodiments of the present invention are merely illustrative of or explaining the principles of the invention and are not to be construed as limiting the invention. Therefore, any modification, equivalent replacement, improvement and the like made without departing from the spirit and scope of the present invention should be included in the protection scope of the present invention. Further, it is intended that the appended claims cover all such variations and modifications as fall within the scope and boundaries of the appended claims or the equivalents of such scope and boundaries.

Claims

1. The glass automatic production and processing equipment is characterized by comprising a shell (1), a transmission assembly (2), a positioning cleaning assembly (3), an electrostatic dusting assembly (4), a powder laying assembly (5), a recovery pipe (7) and a controller; the left end and the right end of the shell (1) are opened, the feeding end is provided with a scanner (51), and the bottom end is provided with a first filter screen (6); the transmission assembly (2) is arranged above the first filter screen (6); the positioning cleaning assembly (3) is arranged at the feeding end; the powder spreading component (5) is arranged at the discharge end; the electrostatic dusting assembly (4) is arranged between the positioning cleaning assembly (3) and the powder spreading assembly (5); a recovery chamber is arranged below the first filter screen (6); the recovery pipe (7) is communicated with the recovery chamber and the electrostatic dusting assembly (4);

the positioning and cleaning assembly (3) comprises a driving cylinder (8), a first mounting seat (9), a cleaning roller (11), a second mounting seat (12), a first lead screw (13), a positioning plate (14) and a first driving motor (15); the driving cylinder (8) is arranged at the top end of the shell (1); the first mounting seat (9) moving up and down is connected with the telescopic rod end of the driving cylinder (8), and the lower end of the first mounting seat is open; the cleaning roller (11) is rotatably arranged on the open end of the first mounting seat (9); the second mounting seat (12) is arranged on one side, facing the feeding, of the first mounting seat (9); a first lead screw (13) driven by a first driving motor (15) is rotatably arranged on the second mounting seat (12), and two ends of the first lead screw are provided with reverse threads; two groups of positioning plates (14) are arranged, and the upper ends of the two groups of positioning plates (14) are respectively in threaded connection with the two ends of the first screw rod (13);

the electrostatic powder scattering component (4) comprises a powder containing box (18), a second driving motor (19), a rotating pipe (20), a first air outlet pipe (21), a second air outlet pipe (22), a three-way valve (23), a third air outlet pipe (25), a discharge pipe (26), a third driving motor (29), a stirring part (30), an electrostatic powder discharge box (31), a powder discharge pipe (32), a heating part and a fan (35); the air inlet end of the heating element is connected with the air outlet end of the fan (35), and the air outlet end is connected with the second air outlet pipe (22); the three-way valve (23) is arranged at the air outlet end of the second air outlet pipe (22) and is connected with one end of the first air outlet pipe (21) and one end of the rotating pipe (20); the powder containing box (18) is arranged on the outer wall of the shell (1); a rotating pipe (20) driven by a second driving motor (19) is rotationally arranged in the powder containing box (18); the first air outlet pipes (21) are arranged in a plurality of groups, the plurality of groups of first air outlet pipes (21) are dispersedly arranged on the side wall of the rotating pipe (20), and air outlet holes (24) are arranged on the first air outlet pipes (21); the air outlet hole (24) is communicated with the second air outlet pipe (22); the upper end of a discharge pipe (26) driven by a third driving motor (29) is rotatably connected with the inner wall of the shell (1) and is communicated with the powder containing box (18), and the lower end of the discharge pipe is communicated with an electrostatic discharge box (31); the other end of the third air outlet pipe (25) is communicated with the static discharge box (31); the stirring piece (30) is arranged inside the static discharging box (31); the powder outlet pipe (32) is arranged at the bottom of the static powder outlet box (31);

the powder spreading assembly (5) comprises a moving piece (43), a second lead screw (44), a fourth driving motor (45), a fifth driving motor (46), a third lead screw (47) and a powder spreading plate (48); the powder laying plate (48) is provided with a sliding chute (50) and a thread groove; a second lead screw (44) driven by a fourth driving motor (45) is rotationally arranged above the transmission assembly (2); the upper end of the moving piece (43) is in threaded connection with the second lead screw (44), and the lower end of the moving piece is in sliding connection with the groove wall of the sliding groove (50); and a third lead screw (47) driven by a fifth driving motor (46) is arranged on two sides of the moving member (43) along the vertical direction, the upper end of the third lead screw is rotatably connected with the moving member (43), and the lower end of the third lead screw is in threaded connection with a thread groove.

2. The automatic glass production and processing equipment according to claim 1, wherein the recovery pipe (7) is provided with a suction pump.

3. The automatic glass production and processing equipment according to claim 2, wherein the gas inlet end of the recovery pipe (7) is communicated with the recovery chamber, and the gas outlet end of the recovery pipe is communicated with the powder containing box (18).

4. The automated glass production and processing equipment according to claim 1, wherein the positioning and cleaning assembly (3) further comprises a mounting member (17), an elastic member (16) and a mounting shaft (10); a lifting groove is formed in the inner wall of the first mounting seat (9); the mounting piece (17) is connected with the groove wall of the lifting groove in a sliding manner; the elastic piece (16) is arranged in the lifting groove, the upper end of the elastic piece is connected with the top of the lifting groove, and the lower end of the elastic piece is connected with the mounting piece (17); one end of the mounting shaft (10) is rotatably connected with the mounting piece (17), and the other end is sleeved with the cleaning roller (11).

5. The automated glass manufacturing apparatus of claim 1, wherein the heating element comprises a heating box (33) and a heating resistor (34); the heating resistor (34) is disposed inside the heating box (33).

6. The automated glass manufacturing apparatus of claim 1, wherein a moisture detector is disposed within the powder bin (18).

7. The automatic glass production and processing equipment according to claim 1, wherein the electrostatic dusting assembly (4) further comprises a first gear (36), a second gear (37), a transmission rod (38), a cleaning plate (39), a second filter screen (40), a stirring sheet (41) and an electric control valve (42); the bottom of the powder containing box (18) is provided with a discharging channel communicated with a discharging pipe (26); the second filter screen (40) is arranged at the feeding end of the discharge channel; the first gear (36) is connected to the rotating tube (20) in a bonding manner; the second gear (37) is connected to the upper end of the transmission rod (38) in a bonding mode and is in meshed connection with the first gear (36); the middle end of the transmission rod (38) is rotatably connected with a second filter screen (40), and the lower end of the transmission rod is connected with a stirring sheet (41); the electric control valve (42) is arranged at the discharge end of the discharge channel; the cleaning plate (39) is connected with the side wall of the transmission rod (38) and is positioned above the second filter screen (40).

8. The automated glass manufacturing apparatus of claim 1, wherein the electrostatic powdering device (4) further comprises a third gear (27) and a fourth gear (28); the third gear (27) is connected with the discharge pipe (26) in a bonding way; the fourth gear (28) is connected with the main shaft of the third driving motor (29) and is meshed with the third gear (27).

9. The automated glass production and processing equipment according to claim 1, wherein the powder spreading assembly (5) further comprises a transmission belt (49); the fifth driving motor (46) is arranged on the moving member (43); and a transmission belt (49) is respectively sleeved with a main shaft of a fifth driving motor (46) and a third lead screw (47).

10. The automated glass production and processing apparatus of any one of claims 1-9, wherein the processing method is as follows:

s1, adding powder into the powder filling box (18), and sending signals to the fan (35), the heating element and the second driving motor (19) by the controller according to the humidity condition of the powder, so that the first air outlet pipe (21) rotates to discharge air, and the powder is dried until the water content is reduced to a set threshold value;

s2, the glass enters the shell (1) through the transmission assembly (2);

s3, the scanner (51) scans the glass and transmits the size and thickness data to the controller;

s4, under the action of a controller signal, a driving cylinder (8) pushes a first mounting seat (9) to move up and down, a cleaning roller (11) is in contact with the upper surface of the glass, a first lead screw (13) rotates to drive a positioning plate (14) to move, the glass is pushed to the middle position, and the glass is limited;

s5, opening an electric control valve (42), enabling the dry powder filtered by the second filter screen (40) to enter the electrostatic discharging box (31) and be scattered by the stirring piece (30), and enabling the electrostatic discharging box (31) to rotate to uniformly spray powder onto the glass below;

s6, the second lead screw (44) rotates to drive the moving piece (43) to move horizontally, the third lead screw (47) rotates to drive the powder spreading plate (48) to move up and down, the position of the powder spreading plate (48) is adjusted, powder on the surface of the glass is spread, and redundant powder is scraped;

s7, the excessive powder enters a recovery chamber and finally returns to the powder filling box (18) through a recovery pipe (7).