CN111889324B

CN111889324B - Low-E glass manufacturing and processing technology

Info

Publication number: CN111889324B
Application number: CN202010835578.4A
Authority: CN
Inventors: 柳兆华; 李翔
Original assignee: Kaili Kairong Glass Co ltd
Current assignee: KAILI KAIRONG GLASS Co.,Ltd.
Priority date: 2020-08-19
Filing date: 2020-08-19
Publication date: 2021-05-14
Anticipated expiration: 2040-08-19
Also published as: CN111889324A

Abstract

The invention relates to a manufacturing and processing technology of Low-E glass, which uses a glass coating device, wherein the glass coating device comprises a base frame, a feeding coating unit and a fixed limiting unit, wherein the inner wall of the rear end of the base frame is provided with the feeding coating unit, and the outer end surface of the feeding coating unit is uniformly provided with the fixed limiting unit; the glass is clamped and fixed, and the frame is driven to be combined with the glass to form the liquid storage frame through linkage of the mechanical transmission mechanism, so that the problem that the surface of the glass is too smooth and is difficult to store coating liquid, and effective coating on the surface of the glass is difficult to carry out is solved; according to the invention, through the design of the feeding structure and the feeding route, one end face of the glass is sequentially coated and dried for forming in the feeding process, and then the other end face of the glass is coated and dried for forming, so that the problem of low glass coating efficiency caused by coating one surface of one glass at a time is solved.

Description

Low-E glass manufacturing and processing technology

Technical Field

The invention relates to the technical field of glass production, in particular to a manufacturing and processing technology of Low-E glass.

Background

Low-E glass is also called Low-emissivity glass, and is a film product formed by plating a plurality of layers of metal or other compounds on the surface of the glass. The coating layer has the characteristics of high visible light transmission and high mid-far infrared ray reflection, so that the coating layer has excellent heat insulation effect and good light transmission compared with common glass and traditional coating glass for buildings. Therefore, the novel and expensive Low-E glass in the coated glass family is made to stand out and becomes the focus of attention of people.

The following problems are encountered in the coating of glass by the dipping method: firstly, the surface of the glass is too smooth, coating liquid is difficult to remain on the surface, and the coating liquid is gathered into drops and deposited on the surface of the glass to form a point, so that the coating on the surface of the glass is incomplete, and the effective coating on the surface of the glass is difficult to carry out; secondly, because coating liquid needs to be reserved on the surface of the glass, the glass cannot be coated on two sides at the same time, but the coating on one side of a single piece of glass at one time greatly influences the coating efficiency of the glass.

Disclosure of Invention

The invention aims to provide a Low-E glass manufacturing and processing technology which has the advantages of accelerating crushing, sorting according to particle size and the like and solves the problems.

The manufacturing and processing technology of the Low-E glass uses a glass coating device, the glass coating device comprises a base frame, a feeding coating unit and a fixing limiting unit, and the manufacturing and processing technology of the glass by adopting the glass coating device further comprises the following steps:

s1, equipment checking: performing a routine check on the device before starting the device;

s2, cutting operation: cutting the glass into fixed shapes by manual or mechanical assistance;

s3, cleaning: cleaning the surface of the glass with clear water so as to remove dust and impurities;

s4, fixing operation: clamping and fixing the glass by a fixing and limiting unit;

s5, coating: sequentially coating two ends of the glass by feeding a coating unit;

the inner wall of the rear end of the base frame is provided with a feeding film coating unit, and the outer end face of the feeding film coating unit is uniformly provided with a fixed limiting unit; the fixed limiting unit clamps and fixes the glass, and the film coating unit is fed to sequentially coat the two ends of the glass;

the feeding film coating unit comprises a mounting plate, a driving mechanism, a transmission shaft, a feeding belt, a filling opening, a recovery frame, a heating plate and a filling frame, wherein the mounting plate is arranged between the inner walls of the left end and the right end of a base frame; the driving mechanism drives the feeding belt to operate through the transmission shaft, the feeding belt simultaneously drives the fixed limiting units to feed along tracks, the filling port fills coating liquid on the upper end face of the glass below the feeding belt, the recovery frame collects the redundant coating liquid for next use, the heating plate dries the surface of the glass passing through the feeding belt so as to enable the coating liquid to be solidified and formed, the filling frame fills the coating liquid on the other end face of the glass below the lower conveying belt, and the heating plate dries the surface of the glass passing through the feeding belt so as to sequentially coat two sides of the glass.

The fixed limit unit comprises an L-shaped support frame, a placing seat, a double-shaft motor and a threaded column, the cooperation piece, feed the board, fixed suction cup, deposit liquid mechanism and auxiliary spring, two L type support frame symmetries set up both ends around feeding the belt, the mount is erect between two L type support frames through rotating the connected mode, the feed chute has been seted up to the mount front end, logical groove has been seted up on mount top, the motor chamber has been seted up in the mount, motor chamber lower extreme inner wall is provided with the double-shaft motor through the motor cabinet, the double-shaft motor output both ends symmetry is provided with the screw thread post about, the cooperation piece is connected with the screw thread post through the threaded connection mode, cooperation piece front end is provided with the feed plate, feed the inboard evenly be provided with fixed suction cup along length direction, deposit liquid mechanism and set up on mount lower extreme inner wall, the mount lower extreme is connected with auxiliary spring with feeding the belt. The double-shaft motor drives the feeding plate to feed inwards through the matching of the threaded column and the matching block, so that the glass is clamped and fixed through the fixed sucker, the liquid storage mechanism is driven to produce liquid storage frames on the upper end face and the lower end face of the glass when the feeding plate feeds inwards, the coating liquid is stored through a certain volume, and the auxiliary spring prevents the placing seat from excessively inclining.

As a preferable scheme of the invention, the heating plate is positioned between the recovery frame and the filling frame.

As a preferable scheme of the present invention, the driving mechanism includes a driving motor, an incomplete gear and a rotary gear, the driving motor is disposed on an inner wall of a rear end of the driving cavity through a motor base, the incomplete gear is disposed at a front end of an output end of the driving motor, the rotary gear is disposed on the inner wall of the rear end of the driving cavity through a bearing, the incomplete gear is connected with the rotary gear in a meshing manner, and a front end of the rotary gear is connected with a rear end of a transmission shaft located on a left side. The driving motor drives the feeding belt to operate intermittently through the matching of the incomplete gear and the rotating gear.

As a preferred scheme of the invention, the feeding belt is uniformly provided with square notches, and the square notches are positioned between the L-shaped supporting frames which are symmetrically arranged. The square notch is convenient for filling and recycling the coating liquid.

As a preferable scheme of the invention, the liquid storage mechanism comprises a driven plate, a sliding column, a lower pressing frame, a reset spring, a sealing gasket, a turning wheel and a connecting steel cable, wherein the driven plate is arranged at the upper end of a feeding plate, lower pressing grooves are symmetrically formed in the left and right sides of the upper end of a base, the sliding column is arranged on the inner wall of the upper end of each lower pressing groove, the lower pressing frame is connected with the sliding column in a sliding mode, the reset spring is arranged at the upper end of the lower pressing frame, the sealing gasket is arranged on the inner wall of the lower pressing frame, the turning wheel is arranged on the inner wall of the upper end of the lower pressing groove, and the driven. The feeding plate drives the driven plate to feed inwards, the connecting steel cable is anti-loose and limits the pressing frame, and therefore the restoring spring pushes the pressing frame inwards, the pressing frame is clamped with the outer end of the glass, the upper liquid storage frame and the lower liquid storage frame are formed, and the problem that the film coating on the surface of the glass is incomplete due to too little film coating liquid on the surface of the glass is solved.

In a preferred embodiment of the present invention, two sealing gaskets are provided, and are arranged in a vertically symmetrical manner, and the sealing gasket at the upper end is in an outward-inward inclined structure from bottom to top.

(III) advantageous effects

1. The glass is clamped and fixed, and the frame is driven to be combined with the glass to form the liquid storage frame through linkage of the mechanical transmission mechanism, so that the problem that the surface of the glass is too smooth and is difficult to store coating liquid, and effective coating on the surface of the glass is difficult to carry out is solved; according to the invention, through the design of the feeding structure and the feeding route, one end face of the glass is sequentially coated and dried for forming in the feeding process, and then the other end face of the glass is coated and dried for forming, so that the problem of low glass coating efficiency caused by coating one surface of one glass at a time is solved.

2. The double-shaft motor drives the feeding plate to feed inwards through the matching of the threaded column and the matching block, so that the glass is clamped and fixed through the fixed sucker, the feeding plate drives the driven plate to feed inwards, the connecting steel cable prevents looseness and limit of the lower pressing frame, the return spring pushes the lower pressing frame inwards, the lower pressing frame is clamped with the outer end of the glass, an upper liquid storage frame and a lower liquid storage frame are formed, and the problem that the film coating on the surface of the glass is incomplete due to the fact that the film coating liquid on the surface of the glass is too little is solved.

Drawings

The invention is further illustrated with reference to the following figures and examples.

FIG. 1 is a flow chart of the process for coating glass according to the present invention;

FIG. 2 is a schematic structural view of the present invention;

FIG. 3 is a schematic cross-sectional view of section A-A of FIG. 2 in accordance with the present invention;

FIG. 4 is an enlarged view of a portion I of FIG. 2 in accordance with the present invention;

FIG. 5 is a schematic view of a part of the structure of the fixing and limiting unit of the present invention;

FIG. 6 is an enlarged view of a portion II of FIG. 5 in accordance with the present invention;

Detailed Description

The embodiments of the invention will be described in detail below with reference to the drawings, but the invention can be implemented in many different ways as defined and covered by the claims.

As shown in fig. 1 to 6, a Low-E glass manufacturing process uses a glass coating device, the glass coating device includes a base frame 1, a feeding coating unit 2 and a fixing and limiting unit 3, and the glass manufacturing process using the glass coating device further includes the following steps:

s4, fixing operation: the glass is clamped and fixed through the fixing and limiting unit 3;

s5, coating: sequentially coating the two ends of the glass by feeding the coating unit 2;

the inner wall of the rear end of the base frame 1 is provided with a feeding film coating unit 2, and the outer end face of the film coating unit is uniformly provided with a fixed limiting unit 3; the fixed limiting unit 3 clamps and fixes the glass, and the film coating unit 2 is fed to sequentially coat the two ends of the glass;

the fixed limiting unit 3 comprises L-shaped supporting frames 31, a placing seat 32, a double-shaft motor 33, threaded columns 34, a matching block 35, a feeding plate 36, a fixed sucking disc 37, a liquid storage mechanism 38 and an auxiliary spring 39, wherein the two L-shaped supporting frames 31 are symmetrically arranged at the front end and the rear end of a feeding belt 24, the placing seat 32 is erected between the two L-shaped supporting frames 31 in a rotating connection mode, a feeding groove is formed in the front end of the placing seat 32, a through groove is formed in the top end of the placing seat 32, a motor cavity is formed in the placing seat 32, the double-shaft motor 33 is arranged on the inner wall of the lower end of the motor cavity through the motor seat, the threaded columns 34 are symmetrically arranged at the left end and the right end of the output end of the double-shaft motor 33, the matching block 35 is connected with the threaded columns 34 in a threaded connection mode, the feeding plate 36 is arranged at the front end of the matching block 35, an auxiliary spring 39 is connected to the lower end of the seat 32 and the feed belt 24. The feeding belt 24 is evenly provided with square notches which are positioned between the L-shaped supporting frames 31 which are symmetrically arranged. The square notch is convenient for filling and recycling the coating liquid. The double-shaft motor 33 drives the feeding plate 36 to feed inwards through the matching of the threaded column 34 and the matching block 35, so that the glass is clamped and fixed through the fixed sucker 37, the feeding plate 36 drives the liquid storage mechanism 38 to produce liquid storage frames on the upper end face and the lower end face of the glass when feeding inwards, the coating liquid is stored through a certain volume, and the auxiliary spring 39 prevents the placing seat from deflecting excessively.

The feeding film coating unit 2 comprises a mounting plate 21, a driving mechanism, a transmission shaft 23, a feeding belt 24, a filling port 25, a recovery frame 26, a heating plate 27 and a filling frame 28, wherein the mounting plate 21 is arranged between the inner walls of the left end and the right end of a base frame 1, a driving cavity is formed in the base frame 1, the driving mechanism is arranged on the inner wall of the rear end of the driving cavity, the transmission shaft 23 is erected between the mounting plate 21 and the inner wall of the rear end of the base frame 1 through a bearing, the feeding belt 24 is sleeved on the outer wall of the transmission shaft 23, the filling port 25 is arranged on the inner wall of the upper end of the base frame 1, the recovery frame 26 is arranged on the inner wall of the left side of the rear end of the base frame 1, the recovery frame 26 is positioned below the filling port 25, the heating plate 27 is arranged between the inner walls; the heating plate 27 is located between the recovery frame 26 and the filling frame 28. The driving mechanism drives a feeding belt 24 to operate through a transmission shaft 23, the feeding belt 24 simultaneously drives a plurality of fixed limiting units 3 to feed along tracks, a filling port 25 fills coating liquid on the upper end face of glass located below, a recovery frame 26 collects the redundant coating liquid for next use, a heating plate 27 dries the surface of the glass passing through, so that the coating liquid is solidified and formed, a filling frame 28 fills the coating liquid on the other end face of the glass running below the lower conveying belt, and the surface of the glass passing through is dried through the heating plate 27, so that two sides of the glass are sequentially coated.

The driving mechanism comprises a driving motor 221, an incomplete gear 222 and a rotating gear 223, the driving motor 221 is arranged on the inner wall of the rear end of the driving cavity through a motor base, the incomplete gear 222 is arranged at the front end of the output end of the driving motor 221, the rotating gear 223 is arranged on the inner wall of the rear end of the driving cavity through a bearing, the incomplete gear 222 is connected with the rotating gear 223 in a meshing mode, and the front end of the rotating gear 223 is connected with the rear end of the transmission shaft 23 on the left side. The driving motor 221 drives the feeding belt 24 to intermittently operate through the cooperation of the incomplete gear 222 and the rotating gear 223.

The liquid storage mechanism 38 comprises a driven plate 381, a sliding column 382, a lower pressing frame 383, a return spring 384, a sealing gasket 385, a turning wheel 386 and a connecting steel cable 387, the driven plate 381 is arranged at the upper end of the feeding plate 36, pressing grooves are symmetrically formed in the left and right of the upper end of the base, the sliding column 382 is arranged on the inner wall of the upper end of the lower pressing groove, the lower pressing frame 383 is connected with the sliding column 382 in a sliding mode, the return spring 384 is arranged at the upper end of the lower pressing frame 383, the sealing gasket 385 is arranged on the inner wall of the lower pressing frame 383, the turning wheel 386 is arranged on the inner wall of the upper end of the lower pressing groove, and the driven plate 381 and the lower pressing frame. The two sealing gaskets 385 are symmetrically arranged up and down, and the sealing gasket 385 at the upper end is of an outward-inward inclined structure from bottom to top. The feeding plate 36 drives the driven plate 381 to feed inwards, the connecting steel cable 387 releases the limit of the lower pressing frame, so that the return spring 384 pushes the lower pressing frame 383 inwards, the lower pressing frame 383 is clamped with the outer end of the glass, an upper liquid storage frame and a lower liquid storage frame are formed, and the problem that the coating on the surface of the glass is incomplete due to the fact that the coating liquid on the surface of the glass is too little is solved.

The working process is as follows: the double-shaft motor 33 drives the feeding plate 36 to feed inwards through the matching of the threaded column 34 and the matching block 35, so that the glass is clamped and fixed through the fixed sucker 37, the feeding plate 36 feeds inwards to drive the lower pressing frame 383 to be clamped with the outer end of the glass, so that an upper liquid storage frame and a lower liquid storage frame are formed, and the driving motor 221 drives the feeding belt 24 to run intermittently through the matching of the incomplete gear 222 and the rotating gear 223. Thus, one end face of the glass is coated and dried for forming in sequence in the feeding process, and then the other end face of the glass is coated and dried for forming.

The above description is only a preferred embodiment of the present invention and is not intended to limit the present invention, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims

1. The utility model provides a Low-E glass manufacturing and processing technology, it has used a glass coating device, this a glass coating device includes base frame (1), feeds coating unit (2) and fixed spacing unit (3), its characterized in that: the manufacturing and processing technology of the glass by adopting the glass coating device further comprises the following steps:

s4, fixing operation: the glass is clamped and fixed through a fixing and limiting unit (3);

s5, coating: sequentially coating the two ends of the glass by feeding a coating unit (2);

the inner wall of the rear end of the base frame (1) is provided with a feeding film coating unit (2), and the outer end surface of the feeding film coating unit (2) is uniformly provided with a fixed limiting unit (3);

the feeding film coating unit (2) comprises a placing plate (21), a driving mechanism, a transmission shaft (23), a feeding belt (24), a filling opening (25), a recovery frame (26), a heating plate (27) and a filling frame (28), wherein the placing plate (21) is arranged between the inner walls of the left end and the right end of the base frame (1), a driving cavity is formed in the base frame (1), the driving mechanism is arranged on the inner wall of the rear end of the driving cavity, the transmission shaft (23) is arranged between the placing plate (21) and the inner wall of the rear end of the base frame (1) through a bearing frame, the feeding belt (24) is sleeved on the outer wall of the transmission shaft (23), the filling opening (25) is formed in the inner wall of the upper end of the base frame (1), the recovery frame (26) is arranged on the inner wall of the left side of the rear end of the base frame (1), the recovery frame (26) is positioned below the filling opening (25), the heating plate, a filling frame (28) is arranged on the right side of the inner wall of the rear end of the base frame (1);

the fixed limiting unit (3) comprises L-shaped support frames (31), a placing seat (32), a double-shaft motor (33), threaded columns (34), a matching block (35), a feeding plate (36), a fixed suction disc (37), a liquid storage mechanism (38) and an auxiliary spring (39), wherein the two L-shaped support frames (31) are symmetrically arranged at the front end and the rear end of a feeding belt (24), the placing seat (32) is erected between the two L-shaped support frames (31) in a rotating connection mode, a feeding groove is formed in the front end of the placing seat (32), a through groove is formed in the top end of the placing seat (32), a motor cavity is formed in the placing seat (32), the double-shaft motor (33) is arranged on the inner wall of the lower end of the motor cavity through a motor seat, the threaded columns (34) are symmetrically arranged at the left end and the right end of the output end of the double-shaft motor (33), and the matching block, the front end of the matching block (35) is provided with a feeding plate (36), the inner end of the feeding plate (36) is uniformly provided with fixed suckers (37) along the length direction, the liquid storage mechanisms (38) are symmetrically arranged on the inner walls of the upper end and the lower end of the placing seat (32), and the lower end of the placing seat (32) is connected with an auxiliary spring (39) through a feeding belt (24).

2. The Low-E glass manufacturing process of claim 1, wherein: the heating plate (27) is positioned between the recovery frame (26) and the filling frame (28).

3. The Low-E glass manufacturing process of claim 1, wherein: the driving mechanism comprises a driving motor (221), an incomplete gear (222) and a rotating gear (223), the driving motor (221) is arranged on the inner wall of the rear end of the driving cavity through a motor base, the incomplete gear (222) is arranged at the front end of the output end of the driving motor (221), the rotating gear (223) is arranged on the inner wall of the rear end of the driving cavity through a bearing, the incomplete gear (222) is connected with the rotating gear (223) in a meshing mode, and the front end of the rotating gear (223) is connected with the rear end of a transmission shaft (23) on the left side.

4. The Low-E glass manufacturing process of claim 1, wherein: the feeding belt (24) is evenly provided with square notches, and the square notches are located between the L-shaped supporting frames (31) which are symmetrically arranged.

5. The Low-E glass manufacturing process of claim 1, wherein: the liquid storage mechanism (38) comprises a driven plate (381), a sliding column (382), a lower pressing frame (383), a return spring (384), a sealing gasket (385), a turning wheel (386) and a connecting steel cable (387), wherein the driven plate (381) is arranged at the upper end of the feeding plate (36), lower pressing grooves are symmetrically formed in the inner walls of the upper end and the lower end of the placing seat (32), the sliding column (382) is arranged on the inner wall of the upper end of each lower pressing groove, the lower pressing frame (383) is connected with the sliding column (382) in a sliding mode, the return spring (384) is arranged at the upper end of the lower pressing frame (383), the sealing gasket (385) is arranged on the inner wall of the lower pressing frame (383), the turning wheel (386) is arranged on the inner wall of the upper end of the lower pressing groove, and the driven plate (381) and the lower pressing frame (383.

6. The Low-E glass manufacturing process of claim 5, wherein: the sealing gasket (385) is provided with two sealing gaskets which are symmetrically arranged up and down, and the sealing gasket (385) at the upper end is of an outward-inward inclined structure from bottom to top.