CN211637054U - Glass coating spraying equipment - Google Patents

Abstract

A glass coating spraying device comprises a conveying mechanism carrying glass to be treated to move and a plasma cleaning mechanism arranged above the conveying mechanism; the plasma cleaning mechanism comprises a fixed seat, a linear module arranged on the fixed seat and a plasma gun head assembly arranged on the linear module, and the plasma gun head assembly moves under the driving of the linear module; the plasma gun head assembly comprises a plasma gun head, a gun head seat and a dial, the plasma gun head is installed on the gun head seat, the dial and the gun head seat are connected to the linear module, and the gun head seat can rotate for a certain angle relative to the dial, so that the plasma gun head obliquely jets plasma out to glass to be treated to be cleaned. The plasma is utilized to clean the surface of the glass, so that the cleaning purpose is realized, the adhesive force of the sprayed film layer is increased, and the cleaning problem of the curved glass is solved.

Description

Glass coating spraying equipment

Technical Field

The utility model relates to a glass surface treatment technical field relates to a glass coating spraying equipment.

Background

The glass coating is formed by forming one or more thin film layers made of metal or chemical polymer materials such as chromium, titanium or stainless steel on the surface of glass, and the thin film layers can change the optical performance of the glass due to different chemical properties so as to meet certain specific requirements.

After the glass for the display screen is coated with the film, the surface of the glass is isolated from the outside, the film layer can prevent scratches, and a good protection effect is achieved. After the 3D glass cover plate of the mobile phone is coated with the film, the glass cover plate and the back plate can be more beautiful, and the effects of wear resistance, acid and alkali resistance and surface light reflection reduction can be achieved.

The spraying coating is a method for coating on glass, a spraying device is adopted to coat the film liquid on the surface of the mobile phone glass, the film layer has good adhesive force, the traditional spraying device is mainly used for plane glass, the traditional spraying device is not suitable for spraying 2.5D or 3D curved glass, and the problem of uneven or missing spraying is easily caused when the spraying is carried out on the curved glass.

Plasma surface treatment is a brand-new high-tech technology, and plasma is used to achieve effects that cannot be achieved by conventional cleaning methods. Plasma is a state of matter, also called the fourth state of matter, and is not common solid, liquid, and gas states. Sufficient energy is applied to the gas to ionize it into a plasma state, the "active" components of the plasma consisting essentially of: ions, electrons, atoms, reactive groups, excited species (metastable state), photons, and the like. Plasma cleaning is the treatment of glass surfaces by exploiting the properties of these active components to achieve cleaning and increase adhesion of subsequent coating layers.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a glass coating spraying equipment utilizes plasma to wash glass's surface, realizes clean purpose, increases the adhesive force of rete behind the spraying, solves curved surface glass's washing problem.

The utility model discloses a technical scheme below can be crossed realizes.

The technical scheme of the utility model is to provide a glass coating spraying device, which comprises a conveying mechanism carrying glass to be treated to move and a plasma cleaning mechanism arranged above the conveying mechanism;

the plasma cleaning mechanism comprises a fixed seat, a linear module arranged on the fixed seat and a plasma gun head assembly arranged on the linear module, and the plasma gun head assembly moves under the driving of the linear module;

the plasma gun head assembly comprises a plasma gun head, a gun head seat and a dial, the plasma gun head is installed on the gun head seat, the dial and the gun head seat are connected to the linear module, and the gun head seat can rotate for a certain angle relative to the dial, so that the plasma gun head obliquely jets plasma out to glass to be treated to be cleaned.

The effective effect of this technical scheme lies in, plasma cleaning before pending glass spraying, utilizes the ion wind to remove dust and destatics, and rotatable plasma rifle head is applied to 2.5D and 3D curved surface glass's washing, and the cleaning performance is better, and efficiency improves.

In one example of the technical scheme, further, in order to accurately adjust the angle of the plasma torch head, a pointer is arranged on the torch head seat, and the pointer is matched with the angle scale on the dial to indicate the rotating angle of the torch head seat relative to the dial.

The angle of the plasma gun head is adjusted, in order to fix the current angle of the plasma gun head, an arc-shaped locking groove is formed in the dial, a locking hole matched with the locking groove is formed in the gun head seat, and a locking screw rod is arranged in the locking hole and the locking groove to lock and fix the gun head seat and the dial.

In an example of the technical scheme, the plasma gun head assembly further comprises a buffer and a mounting seat, the mounting seat is connected to the linear module, one side of the buffer is connected to the mounting seat, and the other side of the buffer is connected to the gun head seat and the dial.

In addition, the bottom plate of the buffer is provided with a strip-shaped mounting hole, so that the height of the buffer on the mounting seat can be adjusted, and the height of the plasma gun head can be adjusted.

In an example of the technical scheme, further, in order to improve the cleaning efficiency and solve the problem that a single plasma gun head of curved glass has a dead angle, the linear module is a bidirectional linear module, and a pair of plasma gun head assemblies which move oppositely are mounted on the bidirectional linear module.

The pair of plasma gun head assemblies are cleaned in opposite directions, so that the problem that the bent part on the side surface of the curved glass cannot be cleaned is effectively solved.

In one example of the technical scheme, the device further comprises a spraying mechanism arranged above the conveying mechanism;

the spraying mechanism comprises a box body, an X-axis linear module, a Y-axis linear module and a nozzle assembly; the spray head assembly is connected to the Y-axis linear module and driven by the Y-axis linear module to move along the Y axis, the Y-axis linear module is connected to the X-axis linear module and driven by the X-axis linear module to move along the X axis, and the X-axis linear module is installed on the box body;

and an atomizing nozzle on the nozzle assembly extends into the box body, and the atomizing nozzle is used for atomizing and spraying the film liquid on the glass to be processed on the conveying mechanism.

In an example of this technical scheme, it is further, shower nozzle subassembly includes altitude mixture control board, shower nozzle buffer, carousel and atomizer, and the atomizer passes through shower nozzle support connection on the carousel, and the carousel can the pivoted connect on the shower nozzle buffer, and the shower nozzle buffer is connected on the altitude mixture control board, and the altitude mixture control board is installed on Y axle straight line module. The atomizing nozzle capable of rotating and adjusting the angle effectively solves the problem that the bent part of the side surface of the curved glass cannot be sprayed.

The angle of the atomizer is adjusted, and in order to fix the current angle of the atomizer, the turntable is provided with an arc-shaped limiting locking groove and a locking screw, and the turntable is locked on the atomizer buffer through the limiting locking groove and the locking screw.

Or in another example, the spray head assembly comprises a height adjusting plate, a spray head buffer, a slide rail assembly and an atomizing spray head, wherein the slide rail assembly comprises a slide rail and a slide block which are connected with each other, the slide rail is provided with a circular arc-shaped track, and the slide block is provided with a track groove corresponding to the track;

the atomizer passes through the shower nozzle leg joint on the slider, and the slide rail is installed on the shower nozzle buffer, and the shower nozzle buffer is connected on the altitude mixture control board, and the altitude mixture control board is installed on Y axle straight line module.

The spray head buffer also comprises a first spray head buffer and a second spray head buffer, the first spray head buffer is installed on the height adjusting plate, the second spray head buffer is installed on the upper buffer and the lower buffer of the first spray head, the atomizing spray head is installed on the second spray head buffer, the first spray head buffer is used for slowing down the vibration of the atomizing spray head due to up-down movement, the second spray head buffer is used for buffering the vibration of the atomizing spray head during horizontal movement, and therefore, the buffer can play a role only when the buffer direction is consistent with the moving direction of the buffering requirement.

In an example of the technical solution, the X-axis linear module is a linear module with an interpolation function, and includes a first linear sliding table, a second linear sliding table, a synchronous connecting rod, and an X-axis servo motor; the first linear sliding table, the second linear sliding table and the X-axis servo motor are arranged on the box body in parallel, and two ends of the Y-axis linear module are connected to the first linear sliding table and the second linear sliding table respectively; the synchronous connecting rod is connected between the first linear sliding table and the second linear sliding table; the X-axis servo motor drives the synchronous connecting rod to rotate, and drives the first linear sliding table and the second linear sliding table to work synchronously.

The utility model discloses in, for the example when placing to the equipment level, conveying mechanism is horizontal transport, and X axle direction indicates pending glass's moving direction on the conveying mechanism, and Y axle direction is perpendicular to pending glass's moving direction's direction on the level, and X axle direction can be understood as pending glass's horizontal transport direction, and Y axle direction can be understood as with X axle vertically horizontal direction.

In an example of the technical scheme, an air inlet is formed in the side face of the box body and is used for being connected with externally input constant-temperature and constant-humidity air, so that glass to be treated is sprayed in the box body under the constant-temperature and constant-humidity conditions.

The utility model discloses in, conveying mechanism's effect is that the drive pending glass moves forward, and defeated quick-witted mechanism can be belt conveyor line, wheel conveyor line or running roller transfer chain commonly used in the current being equipped with.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings required to be used in the description of the embodiments of the present invention will be briefly introduced below, and the drawings in the following description are only directed to some embodiments, and it is obvious for those skilled in the art that other drawings can be obtained according to these drawings without inventive labor.

Fig. 1 is an overall structural view of a glass coating spray coating apparatus in an embodiment of the present application.

Fig. 2 is an exploded view of the plasma cleaning mechanism in the embodiment of the present application.

Fig. 3 is an exploded view of a plasma torch head assembly in an embodiment of the present application.

Fig. 4 is a structural view of a conveying mechanism and a spraying mechanism in the embodiment of the present application.

Fig. 5 is a structural view of a spray mechanism in the embodiment of the present application.

Fig. 6 is an exploded view of the spray mechanism in the embodiment of the present application.

Fig. 7 is an exploded view of a showerhead assembly in an embodiment of the present application.

FIG. 8 is an exploded view of a showerhead assembly in another embodiment of the present application.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are exemplary and intended to be used for explaining the present invention, and should not be construed as limiting the present invention.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise" and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and to simplify the description, but do not indicate or imply that the device or element referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore should not be construed as limiting the present invention.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present invention, "a plurality" means two or more unless specifically limited otherwise.

In the present invention, unless otherwise expressly specified or limited, the terms "mounted," "connected," and "fixed" are to be construed broadly and may, for example, be fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood according to specific situations by those skilled in the art.

In the present disclosure, unless expressly stated or limited otherwise, the first feature "on" or "under" the second feature may comprise direct contact between the first and second features, or may comprise contact between the first and second features not directly. Also, the first feature being "on," "above" and "over" the second feature includes the first feature being directly on and obliquely above the second feature, or merely indicating that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature includes the first feature being directly under and obliquely below the second feature, or simply meaning that the first feature is at a lesser elevation than the second feature.

In addition, the technical solutions in the embodiments may be combined with each other, but it must be based on the realization of those skilled in the art, and when the technical solutions are contradictory or cannot be realized, the combination of the technical solutions should be considered to be absent, and is not within the scope of the present disclosure.

In the following description, suffixes such as "module", "part", "assembly", or "unit" are used only for convenience of description of the present invention, and do not have a specific meaning by themselves, and thus may be used mixedly.

The present invention will be described in further detail with reference to the accompanying drawings.

As shown in fig. 1, the present embodiment is a glass coating spraying machine, which includes a machine body 10, a conveying mechanism 20, a plasma cleaning mechanism 30 and a spraying mechanism 40, wherein the machine body 10 is a relatively closed box structure, the plasma cleaning mechanism and the spraying mechanism are disposed in the box structure, the box structure can effectively prevent dust and reduce the sectional area, a plasma cleaning suction opening 101 is disposed at the top of the machine body 10, a spraying suction opening 102 is disposed at the bottom of the machine body, and a powerful exhaust fan is installed at the spraying suction opening 102, so that a micro negative pressure is formed in the machine body, and an anti-overflow effect is achieved.

The front part of the machine body 10 is also provided with a control panel 103 with a display screen, and the front side and the rear side of the machine body are provided with a door 104 capable of being opened and closed, so that maintenance and adjustment of parts in the machine body are facilitated, and two ends of the conveying mechanism 20 are positioned outside the machine body, so that loading of glass to be processed and unloading of the processed glass are facilitated.

In this embodiment, taking the glass to be processed as a glass cover plate of a mobile phone as an example, the glass cover plate may be a planar glass cover plate or a glass cover plate with curved surfaces on both sides, and the structure of the spraying machine will be described in detail mainly for the coating spraying of the latter.

As shown in fig. 2, the plasma cleaning mechanism 30 is disposed above the conveying mechanism 20, and the plasma cleaning mechanism includes a fixing base 301 having a gantry structure, a linear module 302 mounted on the fixing base, and a plasma torch head assembly 310 mounted on the linear module 302, wherein the plasma torch head assembly 310 is driven by the linear module to move along the Y-axis direction.

In order to improve the cleaning efficiency and solve the problem that a single plasma gun head of curved glass has a dead angle, the linear module is a bidirectional linear module, a pair of plasma gun head assemblies 310 which move oppositely are arranged on the bidirectional linear module, specifically, the bidirectional linear module comprises a servo motor 3021 and a bidirectional linear sliding table 3022, and the two plasma gun head assemblies 310 are respectively arranged on the two sliding tables of the bidirectional linear sliding table 3022. The pair of plasma gun head assemblies are cleaned in opposite directions, so that the problem that the bent part on the side surface of the curved glass cannot be cleaned is effectively solved. As an example, the bidirectional linear module in the present embodiment is manufactured by silver-based technologies (china) limited, and has a high repetition precision and a dual-rail structure.

As shown in fig. 3, the plasma torch head assembly 310 includes a plasma torch head 311, a torch head base 312 and a scale 313, the plasma torch head 311 is mounted on the torch head base 312, the scale and the torch head base are connected to the linear module to move, and the torch head base 312 can rotate relative to the scale 313 by a certain angle, so that the plasma torch head obliquely jets plasma to the glass to be processed for cleaning.

The lower end of the plasma gun head 311 sprays plasma onto the glass cover plate below, and the plasma cleaning is to treat the glass cover plate by utilizing the properties of the active components, so that the cleaning purpose is realized, and the adhesive force of a subsequent coating film layer can be increased.

Rotatable plasma rifle head 311 is applied to 2.5D and 3D curved surface glass's washing, and the cleaning performance is better, and efficiency improves. In order to precisely adjust the angle of the plasma torch head, a pointer 3121 is provided on the torch head base 312, which is matched with an angle scale 3131 on the scale 313 to precisely indicate the angle of rotation of the torch head base 312 with respect to the scale 313.

After the angle of the plasma torch head is adjusted, in order to fix the current angle of the plasma torch head, an arc-shaped locking groove 3132 is arranged on the dial 313, a locking hole 3122 matched with the locking groove is arranged on the torch head seat, and a locking screw rod is arranged in the locking hole and the locking groove to lock and fix the torch head seat and the dial, and the locking screw rod is not shown in the figure.

Specifically, the plasma torch head assembly 310 further includes a buffer 314 and a mounting base 315, the mounting base is connected to the sliding table of the linear module 302, one side of the buffer 314 is connected to the mounting base, and the other side of the buffer 314 is connected to the torch head base and the dial. The buffer 314 plays a role of bidirectional buffer and shock absorption, and the top of the mounting seat 315 is further connected with a drag chain 303 for wiring through a drag chain support plate 3031.

In addition, the bottom plate of the buffer 314 is provided with a strip-shaped mounting hole 3141, so that the height position of the buffer 314 on the mounting seat can be adjusted to reach the height of the plasma gun head 311.

As shown in fig. 4, the spraying mechanism 40 is mounted on the conveying mechanism 20, and a plasma suction hood 320 is further provided in front of the spraying mechanism and behind the plasma cleaning mechanism, and communicates with the plasma cleaning suction port 101 of the machine body to draw the cleaned plasma out of the machine body.

Conveying mechanism 20 adopts the structure of wheeled transfer chain, conveying mechanism 20 is including the framework, both ends erect a plurality of guide arms 201 of pivoted in the framework, the wheel 202 and the driving motor 203 of cover on every guide arm, the framework is by the front beam 211 that the aluminium alloy was made, back beam 212, left beam 213 and right roof beam 214 combination constitute, the both ends of guide arm are connected and are rotated on left beam and right roof beam, the cover is equipped with a plurality of wheels on every guide arm, be provided with drive disk assembly in the inside of left beam and right roof beam, drive disk assembly is not shown in the figure, drive disk assembly can be the gear or the belt of connecting at the guide arm both ends, driving motor drives every guide arm through drive disk assembly and rotates.

For the convenience of disassembly and assembly of the sub-guide rods, each guide rod 201 is formed by connecting a plurality of guide rods through a coupling 204, the coupling plays a role in maintenance and quick disassembly and assembly, and the wheels are wear-resistant wheels made of UPE materials.

As shown in fig. 5 and 6, the spraying mechanism 40 includes a tank 401, an X-axis linear module 410, a Y-axis linear module 402, and a nozzle assembly 420; the shower nozzle subassembly is connected on the sharp module of Y axle and is followed the motion of Y axle under the drive of the sharp module of Y axle, and the sharp module of Y axle is connected on the sharp module of X axle and is followed the motion of X axle under the drive of the sharp module of X axle, and the sharp module of X axle is installed on box 401.

Specifically, the X-axis linear module 410 is a linear module having an interpolation function, and includes a first linear sliding table 411, a second linear sliding table 412, a synchronous link 413, and an X-axis servo motor 414; the first linear sliding table, the second linear sliding table and the X-axis servo motor are arranged on the box body 401 in parallel, and two ends of the Y-axis linear module are connected to the first linear sliding table and the second linear sliding table respectively; the synchronous connecting rod is connected between the first linear sliding table and the second linear sliding table; the X-axis servo motor drives the synchronous connecting rod to rotate, and drives the first linear sliding table and the second linear sliding table to work synchronously.

The Y-axis linear module 402 is a bidirectional linear module, on which a pair of nozzle assemblies 420 are mounted, which are arranged in an opposite motion, and the Y-axis linear module 402 in this embodiment is a bidirectional linear module manufactured by silver technologies (china) limited, which has high repetition accuracy and a dual-rail structure.

An air inlet 4011 is arranged on the side face of the box body 401 and is used for being connected with externally input constant-temperature and constant-humidity air to spray glass to be treated in the box body under the constant-temperature and constant-humidity condition, and the air inlet is communicated with the constant-temperature and constant-humidity air inlet 105 at the top of the machine body.

As shown in fig. 7, the showerhead assembly 420 includes a height adjustment plate 421, a first showerhead buffer 422, a second showerhead buffer 423, a turntable 427, and an atomizer 424, the atomizer 424 is coupled to the turntable 427 through a showerhead holder 425, the turntable is rotatably coupled to the second showerhead buffer 423, the second showerhead buffer 423 is coupled to the first showerhead buffer 422, the first showerhead buffer 422 is on the height adjustment plate, and the height adjustment plate is mounted on the Y-axis linear module.

The first spray head buffer is used for slowing down the vibration of the atomization spray head caused by up-down movement, and the second spray head buffer is used for buffering the vibration of the atomization spray head caused by horizontal movement.

The atomizing nozzle 424 on the nozzle assembly 420 extends into the box body, the atomizing nozzle is used for atomizing and spraying the film liquid on the glass to be processed on the conveying mechanism, and the atomizing nozzle capable of rotating and adjusting the angle effectively solves the problem that the curved part on the side surface of the curved glass cannot be sprayed.

The angle of the atomizer is adjusted, and in order to fix the current angle of the atomizer, the turntable 427 is provided with an arc-shaped limit locking groove 4271 and a locking screw 4272, and the turntable is locked on the second atomizer buffer 423 through the limit locking groove and the locking screw.

The atomizing nozzle 424 is connected with the liquid supply system by a pipe, the atomizing nozzle adopts a low-pressure atomizing nozzle, and the low-pressure atomizing nozzle can uniformly atomize the film liquid and spray the film liquid on the glass cover plate.

As shown in fig. 8, in another example, the nozzle assembly includes a height adjustment plate 421, a first nozzle buffer 422, a second nozzle buffer 423, a sliding rail assembly and an atomizing nozzle 424, wherein the sliding rail assembly includes a sliding rail 428 and a sliding block 429, the sliding rail is provided with a circular arc-shaped rail 4281, the sliding block is provided with a rail groove 4291 corresponding to the rail, and the sliding block slides on the sliding rail to adjust an angle between the atomizing nozzle and the horizontal plane, thereby effectively solving the problem that the curved portion of the side surface of the curved glass cannot be sprayed.

Atomizer 424 passes through shower nozzle support 425 to be connected on the slider, and the slide rail is installed on second shower nozzle buffer 423, and the shower nozzle buffer is connected on altitude mixture control board 421, and altitude mixture control board 421 install on the straight line module of Y axle, and altitude mixture control board has waist shape mounting hole, can adjust the height of its installation.

The first spray head buffer is used for slowing down the vibration of the atomization spray head caused by up-down movement, and the second spray head buffer is used for buffering the vibration of the atomization spray head caused by horizontal movement.

The buffer and the spray head buffer applied to the embodiment have the same structure, the structure mainly comprises two bases, a double-sliding rod connected between the two bases, a sliding block sleeved on the sliding rod and moving, and a spring, wherein the spring is compressed and arranged between the bases and the sliding block.

The spraying machine of the embodiment can be directly butted with a flat plate cleaning machine, or can use a carrying disc (a disc upper swinging sheet) which is placed on a wheel type conveying line and flows into the lower part of a plasma cleaning mechanism, when the carrying disc reaches a plasma processing area, a sensor senses that the carrying disc starts the plasma cleaning mechanism to carry out first cleaning, and after the first cleaning is finished, the second cleaning is carried out, and the second cleaning is finished;

when glass reachd the spraying district, the inductor senses, the direct module of X axle drives the shower nozzle subassembly and carries out the spraying with 1.2 meters S speed, the interpolation function of the direct module of X axle is realized to the direct module of Y axle, effectively reduce and leak the spout, the spraying district still is the constant temperature and humidity environment, automatically keep temperature humidity in controllable value, the return air that the powerful air exhauster was still increased the amount of wind is passed through to the spraying suction opening simultaneously, reduce the excessive plating in glass bottom, in order to improve the yield of glass apron, the good glass apron of spraying is carried next process through the conveyer belt and is toasted.

In the description herein, references to the description of the terms "one embodiment," "some embodiments," "an example," "a specific example," or "some examples" or the like mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The foregoing is a more detailed description of the present invention that is presented in conjunction with specific embodiments, and it is not to be understood that the specific embodiments of the present invention are limited to these descriptions. To the utility model belongs to the technical field of ordinary technical personnel, do not deviate from the utility model discloses under the prerequisite of design, can also make a plurality of simple deductions or replacement.

Claims (10)

1. A glass coating spraying device, which is characterized in that,

comprises a conveying mechanism carrying glass to be treated to move and a plasma cleaning mechanism arranged above the conveying mechanism;

the plasma cleaning mechanism comprises a fixed seat, a linear module arranged on the fixed seat and a plasma gun head assembly arranged on the linear module, and the plasma gun head assembly moves under the driving of the linear module;

the plasma gun head assembly comprises a plasma gun head, a gun head seat and a dial, the plasma gun head is installed on the gun head seat, the dial and the gun head seat are connected to the linear module, and the gun head seat can rotate for a certain angle relative to the dial, so that the plasma gun head obliquely jets plasma out to glass to be treated to be cleaned.

2. The glass-coating spraying apparatus according to claim 1,

and a pointer is arranged on the gun head seat and matched with the angle scales on the dial to indicate the rotating angle of the gun head seat relative to the dial.

3. The glass coating spray coating apparatus according to claim 2,

the gun head seat is characterized in that an arc-shaped locking groove is formed in the dial, a locking hole matched with the locking groove is formed in the gun head seat, and a locking screw rod is arranged in the locking hole and the locking groove to lock and fix the gun head seat and the dial.

4. The glass-coating spraying apparatus according to claim 1,

the plasma gun head assembly further comprises a buffer and a mounting seat, the mounting seat is connected to the linear module, one side of the buffer is connected to the mounting seat, and the other side of the buffer is connected with the gun head seat and the dial.

5. The glass-coating spraying apparatus according to claim 1,

the linear module is a bidirectional linear module, and a pair of plasma gun head assemblies which move oppositely are mounted on the bidirectional linear module.

6. The glass-coating spraying apparatus according to any one of claims 1 to 5,

the spraying mechanism is arranged above the conveying mechanism;

the spraying mechanism comprises a box body, an X-axis linear module, a Y-axis linear module and a nozzle assembly; the spray head assembly is connected to the Y-axis linear module and driven by the Y-axis linear module to move along the Y axis, the Y-axis linear module is connected to the X-axis linear module and driven by the X-axis linear module to move along the X axis, and the X-axis linear module is installed on the box body;

and an atomizing nozzle on the nozzle assembly extends into the box body, and the atomizing nozzle is used for atomizing and spraying the film liquid on the glass to be processed on the conveying mechanism.

7. The glass-coating spraying apparatus according to claim 6,

the shower nozzle subassembly includes altitude mixture control board, shower nozzle buffer, carousel and atomizer, and the atomizer passes through shower nozzle support connection on the carousel, and the carousel can the pivoted connect on the shower nozzle buffer, and the shower nozzle buffer is connected on the altitude mixture control board, and the altitude mixture control board is installed on Y axle straight line module.

8. The glass-coating spraying apparatus according to claim 7,

the rotary table is provided with an arc-shaped limiting locking groove and a locking screw, and the rotary table is locked on the spray head buffer through the limiting locking groove and the locking screw.

9. The glass-coating spraying apparatus according to claim 6,

the X-axis linear module is a linear module with an interpolation function and comprises a first linear sliding table, a second linear sliding table, a synchronous connecting rod and an X-axis servo motor; the first linear sliding table, the second linear sliding table and the X-axis servo motor are arranged on the box body in parallel, and two ends of the Y-axis linear module are connected to the first linear sliding table and the second linear sliding table respectively; the synchronous connecting rod is connected between the first linear sliding table and the second linear sliding table; the X-axis servo motor drives the synchronous connecting rod to rotate, and drives the first linear sliding table and the second linear sliding table to work synchronously.

10. The glass-coating spraying apparatus according to claim 6,

the sprayer assembly comprises a height adjusting plate, a sprayer buffer, a slide rail assembly and an atomizing sprayer, wherein the slide rail assembly comprises a slide rail and a slide block which are connected with each other, the slide rail is provided with an arc-shaped track, and the slide block is provided with a track groove corresponding to the track;

the atomizer passes through the shower nozzle leg joint on the slider, and the slide rail is installed on the shower nozzle buffer, and the shower nozzle buffer is connected on the altitude mixture control board, and the altitude mixture control board is installed on Y axle straight line module.

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