CN212860769U - Solar photovoltaic backplate glass processing silk screen printing machine - Google Patents

Abstract

The utility model discloses a solar photovoltaic backboard glass processing screen printing machine, which comprises a feeding platform, a printing platform, a discharging platform and a shuttle mechanism; the feeding platform comprises a feeding platform frame, a feeding belt, a feeding positioning and clamping mechanism and a feeding positioning and jacking mechanism; the printing platform comprises a printing platform frame, a printing platform bedplate and a printing platform net rack mechanism, wherein the bedplate sucker group is arranged on the printing platform bedplate, and a scraper is arranged on the printing platform net rack mechanism; the discharging platform comprises a discharging platform frame and a discharging belt; the shuttle mechanism comprises a plurality of shuttle belts, a transmission mechanism and a lifting mechanism, and each shuttle belt is provided with a shuttle sucker group and a shuttle anti-slip block. The utility model discloses the automatic scraping of automatic positioning can be realized to the silk screen printing machine, and the user can select once to print multi-disc glass or appoint arbitrary station once to print a slice glass, and when arbitrary station needs clean otter board, changes the otter board or changes the scraper, does not influence the printing progress of other stations, and the operating efficiency is high.

Description

Solar photovoltaic backplate glass processing silk screen printing machine

Technical Field

The utility model belongs to the technical field of the processing of solar photovoltaic glass, in particular to solar photovoltaic backplate glass processing silk screen printing machine.

Background

At present, solar power generation assemblies develop rapidly, pursuits of unit area generated energy of assembly factories are higher and higher, research and test are carried out, and the solar power generation assemblies are actually applied to gaps among battery pieces, one layer of high-reflection glaze is printed in the gaps among the battery pieces through a screen printing machine, so that the generated energy of the assemblies can be effectively improved, and the solar power generation assemblies are the existing solar double-glass double-sided power generation assemblies.

The solar backboard screen printing glass processing flow comprises the following steps: the method comprises the steps of firstly, preparing a raw sheet (float glass or rolled glass), → a sheet loading machine → an edge grinding machine → a cleaning machine → a perforating machine → a cleaning machine → a screen printing machine → a drying machine → a continuous toughening furnace → a cleaning machine → a sheet unloading machine (a continuous production line is formed by the control of a line roller way). In order to ensure the efficient production of the continuous toughening furnace, each process before toughening needs to be matched with the production beat of the toughening furnace.

Traditional silk screen printing machine equipment location is loaded down with trivial details, and troublesome poeration causes work efficiency to be low and extravagant cost of labor, and the inaccurate pattern that causes again easily offsets at silk screen printing in-process pattern, and the probability of silk screen printing failure is very improved. In addition, the silk screen printing machine has a plurality of uncertain factors in the production process: such as cleaning the screen plate, replacing the scraper, etc., causing the screen printer to become a bottleneck of the whole glass processing line. At present, the solar glass processing factory adopts an additional screen printing machine to solve the problem, the control of a connecting line roller way is more complex due to the mode, and the layout of the factory building has certain limitation.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a solar photovoltaic backplate glass processing silk screen printing machine that silk screen printing precision is high, operating efficiency is high.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

a solar photovoltaic backboard glass processing screen printer comprises a feeding platform, a printing platform, a discharging platform and a shuttle mechanism, wherein the feeding platform, the printing platform and the discharging platform are connected in sequence;

the feeding platform comprises a feeding platform frame, and a feeding belt, a feeding positioning and clamping mechanism and a feeding positioning and jacking mechanism which are arranged on the feeding platform frame;

the printing platform comprises a printing platform frame, a printing platform bedplate and a printing platform net rack mechanism, wherein the printing platform bedplate and the printing platform net rack mechanism are arranged on the printing platform frame;

the discharging platform comprises a discharging platform frame and a discharging belt arranged on the discharging platform frame;

the shuttle mechanism comprises a plurality of shuttle belts, a transmission mechanism and a lifting mechanism, and each shuttle belt is provided with a shuttle sucker group and a shuttle anti-slip block.

Furthermore, the feeding platform and the printing platform are respectively provided with a plurality of stations with the same number, the discharging platform is a lengthened discharging platform, and the shuttle mechanism is a lengthened shuttle mechanism.

Furthermore, the feeding belt is a lengthened feeding belt, and a plurality of sets of feeding positioning and clamping mechanisms and feeding positioning and jacking mechanisms are arranged;

the printing platform bedplate and the printing platform net rack mechanism are provided with a plurality of sets, each set of printing platform bedplate is provided with the bedplate sucker group, and each set of printing platform net rack mechanism is provided with the scraper;

the discharging belt is a lengthened discharging belt;

and a plurality of sets of shuttle sucker groups and shuttle anti-skidding blocks are arranged on each shuttle belt.

Furthermore, the screen printing machine further comprises a control unit, and the control unit controls the screen printing machine to select a simplex mode or a multistation mode.

Still further, the number of said feeding stations and printing stations is 2-6.

The beneficial effects of the utility model reside in that:

1. the utility model discloses the silk screen printing machine can realize automatic positioning at glass's printing in-process, scrapes the seal automatically, realizes automatic printing through the automatic walking of shuttle mechanism between feeding platform, print platform and ejection of compact platform, and the printing precision is high, and the operating efficiency is high.

2. The utility model discloses the silk screen printing machine can add the printing station, and each printing station does not influence each other, and the user can select once to print multi-disc glass or appoint wherein arbitrary station once to print a slice glass according to the demand, and arbitrary station need clean the otter board, when changing the otter board or changing the scraper, does not influence the printing progress of other stations, and the operating efficiency is high.

Drawings

FIG. 1 is a schematic structural diagram of a single-station screen printing machine in example 1;

FIG. 2 is a schematic view of a frame structure according to embodiment 1;

FIG. 3 is a schematic view of the feed and exit belts of example 1;

FIG. 4 is a schematic view showing a platen structure of the printing platform according to embodiment 1;

FIG. 5 is a schematic view showing the structure of a printing table rack mechanism according to example 1;

FIG. 6 is a schematic structural view of a feeding positioning and clamping mechanism in embodiment 1;

FIG. 7 is a schematic structural view of a feeding positioning jacking mechanism in the embodiment 1;

FIG. 8 is a schematic structural view of a shuttle mechanism according to embodiment 1;

FIG. 9 is an enlarged view of portion A of FIG. 8;

FIG. 10 is a schematic structural diagram of a double-station screen printer according to embodiment 2;

FIG. 11 is a view showing the position of the glass in the double-station printing mode according to example 2;

FIG. 12 is a second view showing the position of the glass in the double-station printing mode according to example 2;

wherein: 1. a feeding platform; 1-1, a feeding platform station A; 1-2, a feeding platform station B; 11. a feeding platform frame; 12. a feeding belt; 13. a feeding positioning and clamping mechanism; 14. a feeding positioning jacking mechanism; 2. a printing platform; 2-1, printing platform station A; 2-2, a printing platform station B; 21. a printing platform frame; 22. a printing deck platen; 23. a printing platform grid mechanism; 24. a table plate sucker group; 3. a discharge platform; 31. a discharge platform frame; 32. a discharge belt; 4. a shuttle mechanism; 41. a shuttle belt; 42. a shuttle sucker group; 43. a shuttle anti-slip block; 5. glass to be printed; 6. the glass has been printed.

Detailed Description

To better illustrate the objects, aspects and advantages of the present invention, the present invention will be further described with reference to specific embodiments. The present invention may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the concept of the invention to those skilled in the art, and the present invention will only be defined by the appended claims.

Example 1: single-station screen printer

As shown in fig. 1-9, a solar photovoltaic backboard glass processing screen printer comprises a feeding platform 1, a printing platform 2, a discharging platform 3 and a shuttle mechanism 4 for conveying printed glass among the feeding platform 1, the printing platform 2 and the discharging platform 3, wherein the feeding platform 1, the printing platform 2 and the discharging platform 3 are connected in sequence;

the feeding platform 1 comprises a feeding platform frame 11, a feeding belt 12, a feeding positioning and clamping mechanism 13 and a feeding positioning and jacking mechanism 14, wherein the feeding belt 12, the feeding positioning and clamping mechanism and the feeding positioning and jacking mechanism 14 are arranged on the feeding platform frame 11;

the printing platform 2 comprises a printing platform frame 21, a printing platform bedplate 22 and a printing platform net rack mechanism 23, wherein the printing platform bedplate 22 and the printing platform net rack mechanism 23 are arranged on the printing platform frame 21, a bedplate sucker group 24 is arranged on the printing platform bedplate 22, and a scraper is arranged on the printing platform net rack mechanism 23;

the discharging platform 3 comprises a discharging platform frame 31 and a discharging belt 32 arranged on the discharging platform frame 31;

the shuttle mechanism 4 comprises a plurality of shuttle belts 41, a transmission mechanism and a lifting mechanism, and each shuttle belt 41 is provided with a shuttle sucker group 42 and a shuttle anti-slip block 43.

The working process is as follows: glass to be printed is conveyed to a feeding positioning jacking mechanism 14 through a feeding belt 12, the feeding positioning jacking mechanism 14 jacks up the glass and then realizes accurate mechanical positioning through a feeding positioning clamping mechanism 13, after the positioning is finished, a shuttle mechanism 4 is lifted up and the feeding positioning jacking mechanism 14 descends, the glass falls onto a shuttle sucker group 42, the shuttle sucker group 42 sucks the glass (the positioned glass is ensured to be fixed) and then conveys the glass to be printed to a printing platform 2 through the shuttle mechanism 4, at the moment, a shuttle anti-skid block 43 jacks up the printed glass through a shuttle anti-skid block 43 and then conveys the glass to be printed to a discharging platform 3 from the printing platform 2, after the shuttle mechanism 4 is stopped and stabilized, the shuttle sucker group 42 releases vacuum and the shuttle mechanism 4 descends, the glass to be printed falls onto the printing platform 2 (the glass is sucked by a sucker bedplate group 24) and the printed glass falls onto a discharging belt 32, and the printing is finished by a printing platform net rack mechanism 23, the discharging belt 32 conveys the printed glass to the next process, and the descending shuttle mechanism 4 returns to be ready to meet the next piece of glass, so that the continuous screen printing work of the glass is finished in a reciprocating way.

Example 2: double-station screen printer

As shown in fig. 10 to 12, the same portions as those of embodiment 1 will not be described repeatedly, except,

the feeding platform 1 and the printing platform 2 are both provided with double stations, the discharging platform 3 is a lengthened discharging platform, and the shuttle mechanism 4 is a lengthened shuttle mechanism.

The feeding belt 12 is a lengthened feeding belt, and the feeding positioning and clamping mechanism 13 and the feeding positioning and jacking mechanism 14 are provided with two sets; the printing platform bedplate 22 and the printing platform net rack mechanism 23 are provided with two sets, each set of printing platform bedplate 22 is provided with a bedplate sucker group 24, and each set of printing platform net rack mechanism 23 is provided with a scraper; the discharging belt 32 is a lengthened discharging belt; each shuttle belt 41 is provided with two sets of shuttle sucker groups 42 and shuttle anti-slip blocks 43.

The screen printing machine further comprises a control unit, and the control unit controls the screen printing machine to select a simplex mode or a duplex mode.

The working process is as follows: the printing modes of the double-station screen printer are 3 types: the station A is independently selected for printing, the station B is independently selected for printing, the stations A and 2 are selected for printing simultaneously, and 3 modes can be freely switched.

When the station A or the station B is selected for independent printing, the working condition is the same as that of the single-station silk screen printing machine in the embodiment 1.

When double-station printing is selected: a first piece of glass 5 to be printed is conveyed to a feeding positioning jacking mechanism 14 of a feeding platform station A by a feeding belt 12 and jacked up by the feeding positioning jacking mechanism 14, a feeding positioning clamping mechanism 13 finishes mechanical positioning, simultaneously, the feeding belt 12 restarts the feeding positioning jacking mechanism 14 for conveying a second piece of glass 5 to be printed to a feeding platform station B, the feeding positioning jacking mechanism 14 of the station B jacks up, the feeding positioning clamping mechanism 13 of the station B finishes mechanical positioning, when the double stations are positioned, a shuttle mechanism 4 is lifted and the double-positioning feeding positioning jacking mechanism 14 descends, the glass falls onto two shuttle sucker groups 42 of the shuttle mechanism 4, after the shuttle sucker groups 42 suck the glass (the positioned glass is ensured to be fixed), the two pieces of glass 5 to be printed are conveyed to the station A and the station B of the printing platform 2 by the shuttle mechanism 4, at this time, a shuttle block 43 on the shuttle belt 41 conveys the two pieces of printed glass 6 to a discharging platform 3, after the shuttle mechanism 4 is stopped stably, the shuttle sucker group 42 releases vacuum and the shuttle mechanism 4 descends, two pieces of glass 5 to be printed fall on the double stations of the printing platform 2 and the printed glass 6 falls on the discharging belt 32 of the discharging platform 3, the glass is sucked by the double station platen sucker group 24 on the printing platform 2, the double station printing platform net rack mechanism 23 finishes printing, the discharging belt 32 conveys the printed glass 6 to the next procedure, the descending shuttle mechanism 4 returns to prepare to meet the next set of glass, and thus the continuous screen printing work of one set of two pieces of glass is finished in a reciprocating mode.

It should be understood that the above examples are only for clarity of illustration and are not intended to limit the embodiments. Other variations and modifications will be apparent to persons skilled in the art in light of the above description. And are neither required nor exhaustive of all embodiments. And obvious variations or modifications can be made without departing from the scope of the invention.

Claims (5)

1. The utility model provides a solar photovoltaic backplate glass processing silk screen printing machine which characterized in that: comprises a feeding platform (1), a printing platform (2) and a discharging platform (3) which are connected in sequence, and a shuttle mechanism (4) for conveying printing glass among the feeding platform (1), the printing platform (2) and the discharging platform (3);

the feeding platform (1) comprises a feeding platform frame (11), and a feeding belt (12), a feeding positioning and clamping mechanism (13) and a feeding positioning and jacking mechanism (14) which are arranged on the feeding platform frame (11);

the printing platform (2) comprises a printing platform frame (21), a printing platform bedplate (22) and a printing platform net rack mechanism (23), wherein the printing platform bedplate (22) and the printing platform net rack mechanism (23) are arranged on the printing platform frame (21), a bedplate sucker group (24) is arranged on the printing platform bedplate (22), and a scraper is arranged on the printing platform net rack mechanism (23);

the discharging platform (3) comprises a discharging platform frame (31) and a discharging belt (32) arranged on the discharging platform frame (31);

the shuttle mechanism (4) comprises a plurality of shuttle belts (41), a transmission mechanism and a lifting mechanism, and each shuttle belt (41) is provided with a shuttle sucker group (42) and a shuttle anti-skid block (43).

2. The solar photovoltaic backboard glass processing screen printing machine according to claim 1, wherein: the feeding platform (1) and the printing platform (2) are respectively provided with a plurality of stations with the same number, the discharging platform (3) is a lengthened discharging platform, and the shuttle mechanism (4) is a lengthened shuttle mechanism.

3. The solar photovoltaic backboard glass processing screen printing machine according to claim 2, wherein: the feeding belt (12) is a lengthened feeding belt, and a plurality of sets of feeding positioning and clamping mechanisms (13) and feeding positioning and jacking mechanisms (14) are arranged;

the printing platform bedplate (22) and the printing platform net rack mechanism (23) are provided with a plurality of sets, each set of printing platform bedplate (22) is provided with the bedplate sucker group (24), and each set of printing platform net rack mechanism (23) is provided with the scraper;

the discharging belt (32) is a lengthened discharging belt;

each shuttle belt (41) is provided with a plurality of sets of shuttle sucker groups (42) and shuttle anti-slip blocks (43).

4. The solar photovoltaic backboard glass processing screen printing machine according to claim 2, wherein: the screen printing machine further comprises a control unit, and the control unit controls the screen printing machine to select a simplex mode or a multistation mode.

5. The solar photovoltaic backboard glass processing screen printing machine according to claim 2, wherein: the number of the feeding platforms (1) and the number of the printing platforms (2) are 2-6.

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