CN110744914B - Equipment of full-automatic prism silk screen printing window face - Google Patents

Abstract

The invention discloses a full-automatic prism silk-screen window surface device which comprises a large plate, a feeding mechanism, a material plate sliding mechanism, a material taking and discharging mechanism, a silk-screen platform mechanism, a silk-screen mechanism and a material receiving mechanism, wherein after a material plate filled with prisms reaches the material plate sliding mechanism through the feeding mechanism, the material taking and discharging mechanism transfers the prisms on the material plate to a jig on a silk-screen platform through a vacuum suction nozzle, and then the silk-screen mechanism controls a silk-screen head to descend to a silk-screen plate to print patterns on the surfaces of the prisms in a silk-screen mode. The invention has simple working principle and high automation degree, better saves the labor cost and has good market use value.

Description

Equipment of full-automatic prism silk screen printing window face

Technical Field

The invention relates to the technical field of mobile phone camera equipment, in particular to automatic equipment for periscopic telephoto lens vacuum adsorption prism window surface silk screen printing.

Background

Prism, a transparent object enclosed by two intersecting planes that are not parallel to each other, for splitting or dispersing light beams. Typically, the prisms are polyhedrons made of a transparent material (e.g., glass, crystal, etc.). The application of the optical instrument is wide, and the optical instrument mainly focuses on electronic equipment and science frontier technology, such as a projector, various laser treatment equipment, a telescope, a microscope and the like.

In the existing industrial application, pictures and texts such as a commodity label and the like are often required to be printed on the surface of a prism, the prism is manually clamped by a tweezers and placed on a platform for silk screen printing, the surface of the prism is easily damaged, dust is easily generated, and the defects of low silk screen printing efficiency, high reject ratio, high labor cost and the like exist in the operation.

Disclosure of Invention

The invention aims to provide the prism silk-screen printing equipment which is simple in structure, reasonable in design and convenient to use, aiming at the defects and shortcomings of the prior art. To achieve the purpose, the invention adopts the following technical scheme.

The utility model provides an equipment of full-automatic prism silk screen printing window face which characterized in that includes:

a large plate;

the feeding mechanism comprises a first bottom plate arranged on the large plate, a first guide shaft arranged on the first bottom plate, a first air cylinder arranged on the large plate and the first bottom plate, a push plate arranged on the first air cylinder and the first guide shaft, a material receiving box arranged on the push plate, a first supporting plate arranged on the large plate, a second air cylinder arranged on the first supporting plate, a slide rail arranged on the first supporting plate, and a slide block, one end of the slide block is arranged on the second air cylinder, the other end of the slide block is arranged on the slide rail, and the first air cylinder is used for pushing the feeding box to ascend along the vertical direction;

the material plate slipping mechanism is arranged on the large plate and comprises a plurality of second supporting plates arranged on the large plate, a long plate arranged on the second supporting plates, a side plate arranged on the side surface of the second supporting plates, a material plate arranged on the long plate, a belt transmission mechanism arranged on the side plate and a liftable material pushing support arranged on the belt transmission mechanism;

the material taking and placing mechanism is arranged on the large plate and comprises a plurality of third supporting plates arranged on the large plate, a first X-direction module arranged on the third supporting plates, a first Y-direction module arranged on the first X-direction module, a CCD device arranged on the first Y-direction module, a first Z-direction module arranged on the first Y-direction module and a vacuum suction nozzle arranged on the first Z-direction module, wherein a belt transmission mechanism (205) is used for driving a material pushing support (207) to move along the X-direction material taking and placing mechanism (3) so as to push a material plate (206) to move along the X-direction material taking and placing mechanism (3) until the material plate reaches a set position and stop, the first Z-direction module is used for driving the vacuum suction nozzle to descend, and the vacuum suction nozzle is used for sucking a prism in the material plate;

the screen printing platform mechanism is arranged on the large board and comprises a second Y-direction module arranged on the large board, an R-direction rotating module arranged on the second Y-direction module and a rotatable jig arranged on the R-direction rotating module, wherein the first Y-direction module and the first X-direction module convey the prism sucked by the vacuum suction nozzle to the jig (406) of the screen printing platform;

the screen printing mechanism comprises a first mounting plate arranged on the large plate, a second Z-direction module arranged on the first mounting plate, a second X-direction module arranged on the second Z-direction module, a guide rail arranged on the second X-direction module, a third air cylinder arranged on the guide rail, a screen printing head assembly arranged on the guide rail, a mounting plate arranged on the second X-direction module, a connecting plate arranged on the mounting plate and a screen printing screen plate arranged on the connecting plate;

the material receiving mechanism is arranged on the large plate and comprises a second bottom plate, a second guide shaft, a fourth cylinder and a material receiving box, wherein the second bottom plate is arranged on the large plate, the second guide shaft is arranged on the second bottom plate, the fourth cylinder is arranged on the large plate and the second bottom plate, and the material receiving box is arranged on the fourth cylinder.

Further, the feeding mechanism further comprises a first linear bearing arranged on the first guide shaft and the first bottom plate.

Furthermore, a pair of opposite side surfaces of the feeding box of the feeding mechanism are provided with empty grooves.

Further, flitch glide machanism still includes the jacking subassembly that sets up on belt drive mechanism, the other end of jacking subassembly set up in push away the material support.

Further, silk screen printing microscope carrier mechanism still includes sets up in the rotor plate of R to rotatory module, sets up in the tool mount pad and the driving motor of mounting panel, sets up in the tool installation axle of tool mount pad and sets up in the shaft coupling of driving motor and tool installation axle.

Further, the screen printing head assembly comprises a screen printing scraper and an ink scraper.

Furthermore, the silk screen plate is provided with meshes and is made of plastic materials.

Furthermore, a pair of opposite side surfaces of the material receiving box of the material receiving mechanism is provided with an empty groove.

Further, the flitch is equipped with a plurality of recesses of the size of being fit for with the prism.

Further, the vacuum suction nozzle is wrapped with silica gel.

The invention has the following beneficial effects: the equipment for silk-screen of the prism has high automation degree, solves the problem of clamping damage by a clamp by adopting the rubber suction nozzle vacuum adsorption prism, ensures that the position of the prism is not deviated by the vacuum adsorption of the silk-screen jig during silk-screen printing, solves the precision problem, improves the production efficiency, and has simple manual operation, easy adjustment, stable machine performance and high yield.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the structures shown in the drawings without creative efforts.

FIG. 1 is a schematic view of the overall structure of the present invention;

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

FIG. 3 is a schematic view of a flitch slide mechanism of the invention;

FIG. 4 is a schematic view of the drop feed mechanism of the present invention;

FIG. 5 is a schematic view of a screen printing carrier mechanism of the present invention;

FIG. 6 is a schematic view of a silk-screen printing mechanism of the present invention;

FIG. 7 is a schematic view of a receiving mechanism of the present invention.

Reference numerals

In the attached drawings, 1-a feeding mechanism; 101-a first guide shaft; 102-a first backplane; 103-a first linear bearing; 104-a first cylinder; 105-a feeding box; 106-a first support plate; 107-second cylinder; 108-a guide rail; 109-a slider; 110-a push plate; 2-a flitch sliding mechanism; 201-a second support plate; 202-long plate; 203-a baffle; 204-side plate; 205-belt drive; 206-material plate; 207-pushing the material support; 3-taking and placing a material mechanism; 301-a third support plate; 302-a first X-direction module; 303-a first Y-direction module; 304-a first CCD device; 305-a vacuum nozzle; 306-a first Z-direction module; 4-screen printing platform mechanism; 401-second Y-direction module; a 402-R direction rotation module; 403-rotating plate; 404-a jig mounting seat; 405-a drive motor; 406-a jig; 407-tool mounting shaft; 408 a coupler; 5-a silk-screen printing mechanism; 501-a first mounting plate; 502-second direction Z module; 503-a second X-direction module; 504-screen printing head assembly; 504.1-screen printing scraper; 504.2-ink squeegee; 505-a mounting plate; 506-a connecting plate; 507-screen printing a screen plate; 508-a third cylinder; 509-cross rail; 6-a material receiving mechanism; 601-a second guide shaft; 602-a second backplane; 603-a second linear bearing; 604-a fourth cylinder; 605-collecting box.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

It should be noted that all the directional indicators (such as up, down, left, right, front, and rear … …) in the embodiment of the present invention are only used to explain the relative position relationship between the components, the movement situation, etc. in a specific posture (as shown in the drawing), and if the specific posture is changed, the directional indicator is changed accordingly.

In addition, the descriptions related to "first", "second", etc. in the present invention are 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 at least one such feature. In addition, technical solutions between various embodiments may be combined with each other, but must be realized by a person skilled in the art, and when the technical solutions are contradictory or cannot be realized, such a combination should not be considered to exist, and is not within the protection scope of the present invention.

In the present invention, unless otherwise expressly stated or limited, the terms "connected," "secured," and the like are to be construed broadly, and for example, "secured" may be a fixed connection, a removable connection, or an integral part; can be mechanically or electrically connected; they may be directly connected or indirectly connected through intervening media, or they may be connected internally or in any other suitable relationship, unless expressly stated otherwise. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

The invention is further described below with reference to the accompanying drawings.

Referring to fig. 1 to 7, an apparatus for screen printing a window surface of a full-automatic prism, comprising:

a large plate 7;

the feeding mechanism (1) comprises a first bottom plate (102) arranged on a large plate, a first guide shaft (101) arranged on the first bottom plate, a first air cylinder (104) arranged on the large plate and the first bottom plate, a push plate (110) arranged on the first air cylinder and the first guide shaft, a feeding box (105) arranged on the push plate, a first supporting plate (106) arranged on the large plate, a second air cylinder (107) arranged on the first supporting plate, a slide rail (108) arranged on the first supporting plate, and a slide block (109) with one end arranged on the second air cylinder and the other end arranged on the slide rail;

the material plate slipping mechanism 2 is arranged on the large plate, and the material plate slipping mechanism 2 comprises a plurality of second supporting plates 201 arranged on the large plate, a long plate 202 arranged on the second supporting plates, side plates 204 arranged on the side surfaces of the second supporting plates, a material plate 206 arranged on the long plate, a belt transmission mechanism 205 arranged on the side plates, and a liftable material pushing support 207 arranged on the belt transmission mechanism;

the material taking and placing mechanism 3 is arranged on the large plate and comprises a plurality of third supporting plates 301 arranged on the large plate, a first X-direction module 302 arranged on the third supporting plates, a first Y-direction module 303 arranged on the first X-direction module, a CCD device 304 arranged on the first Y-direction module, a first Z-direction module arranged on the first Y-direction module and a vacuum suction nozzle 305 arranged on the first Z-direction module 306;

the screen printing carrier mechanism 4 is arranged on the large board and comprises a second Y-direction module 401 arranged on the large board, an R-direction rotating module 402 arranged on the second Y-direction module and a rotatable jig 406 arranged on the R-direction rotating module;

the screen printing mechanism 5 is arranged on the large plate and comprises a first mounting plate 501 arranged on the large plate, a second Z-direction module 502 arranged on the first mounting plate, a second X-direction module 503 arranged on the second Z-direction module, a guide rail 509 arranged on the second X-direction module, a third air cylinder 508 arranged on the guide rail, a screen printing head assembly 504 arranged on the guide rail, a mounting plate 505 arranged on the second X-direction module, a connecting plate 506 arranged on the mounting plate and a screen printing screen plate 507 arranged on the connecting plate;

the material receiving mechanism 6 is arranged on the large plate and comprises a second bottom plate 602 arranged on the large plate, a second guide shaft 601 arranged on the second bottom plate, a fourth cylinder 604 arranged on the large plate and the second bottom plate, and a material receiving box 605 arranged on the fourth cylinder.

Further, the feeding mechanism 1 further includes a first linear bearing 103 disposed on the first guide shaft and the first base plate.

Further, a pair of opposite side surfaces of the feeding box 105 of the feeding mechanism is provided with an empty groove.

Further, the flitch slide mechanism 2 further includes a jacking assembly disposed on the belt transmission mechanism 205, and the other end of the jacking assembly is disposed on the material pushing support 207.

Further, the screen printing stage mechanism 4 further includes a rotating plate 403 disposed on the R-direction rotating module, a jig mounting base 404 and a driving motor 405 disposed on the mounting plate, a jig mounting shaft 407 disposed on the jig mounting base, and a coupling 408 disposed on the driving motor and the jig mounting shaft.

Further, the screen head assembly 504 includes a screen squeegee 504.1 and an ink squeegee 504.2.

Furthermore, the silk screen 507 is provided with meshes and is made of plastic material.

Further, a pair of opposite side surfaces of the receiving box 605 of the receiving mechanism is provided with an empty groove.

Further, the material plate 206 is provided with a plurality of grooves with sizes matched with the prisms.

The implementation action process of the invention is as follows:

the working principle and the process are as follows:

manually placing a material plate 206 filled with prisms on a material feeding box 105 of a material feeding mechanism 1, pushing the material feeding box to ascend along the vertical direction through a first air cylinder 104, then pushing a slide block 109 to move towards a material plate sliding mechanism 2 along a guide rail 108 by a second air cylinder 107, pushing the material plate to a long plate 202 of the material plate sliding mechanism 2, then jacking a material pushing support 207 by a jacking component of the material plate sliding mechanism, driving the material pushing support to move a material taking and placing mechanism 3 along the X direction through a belt transmission mechanism 205, further pushing the material plate 206 to move towards the material taking and placing mechanism 3 along the X direction until a set position is reached and stopped, then after the material taking and placing mechanism 3 positions a vacuum suction nozzle 305 through a first CCD device 304, driving the vacuum suction nozzle to descend through a first Z-direction module, driving the prism suction nozzle in the material plate 206 to ascend through the first Z-direction module, and then transporting the prisms sucked by the vacuum suction nozzle to a jig 406 of a silk screen printing platform through the first Y-direction module and the first X-direction module, after the prism is positioned on the jig, the prism is positioned under a screen printing head component 504 of the screen printing device 5 along with the second Y-direction module by a second CCD device (not shown in the figure) arranged on the second Y-direction module, then a third air cylinder 508 of the screen printing mechanism 5 drives a cross guide rail to drive the screen printing head component 504 to descend onto a screen printing screen plate 507, an ink scraping plate is extruded by the screen printing scraping plate to enable ink to print a picture on the prism through meshes of the screen printing screen plate, the position of the prism is changed by the R-direction rotating module 402 and the driving motor 405, and the picture is printed at different positions of the prism.

After the silk screen printing on prism surface is accomplished, R resets to rotation module and driving motor, and the tool loosens, and the second Y gets back to the original point to the module, absorbs the prism and transports to the flitch through first Y to module, first X to module, first CCD device and vacuum suction nozzle, prepares the silk screen printing work of next prism.

When all the prisms on one material plate are finished by screen printing, the fourth cylinder 604 of the material receiving device 6 pushes the material receiving box to a height matched with the long plate 202 of the material plate sliding mechanism 2, meanwhile, the jacking component of the material plate sliding mechanism 2 jacks up the material pushing support 207, and the belt transmission mechanism 205 drives the material pushing support to push the material plate 206 to move along the length direction of the long plate until the material receiving box is reached and stopped.

The above description is only a preferred embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications and equivalents of the present invention, which are made by the contents of the present specification and the accompanying drawings, or directly/indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims (9)

1. The utility model provides an equipment of full-automatic prism silk screen printing window face which characterized in that includes:

a large plate (7);

the feeding mechanism (1) is arranged on the large plate;

the feeding mechanism (1) comprises a first bottom plate (102) arranged on a large plate, a first guide shaft (101) arranged on the first bottom plate, a first air cylinder (104) arranged on the large plate and the first bottom plate, a push plate (110) arranged on the first air cylinder and the first guide shaft, a feeding box (105) arranged on the push plate, a first supporting plate (106) arranged on the large plate, a second air cylinder (107) arranged on the first supporting plate, a sliding rail (108) arranged on the first supporting plate, and a sliding block (109) with one end arranged on the second air cylinder and the other end arranged on the sliding rail, wherein the first air cylinder (104) is used for pushing the feeding box to ascend along the vertical direction;

the material plate sliding mechanism (2) is arranged on a large plate, the material plate sliding mechanism (2) comprises a plurality of second supporting plates (201) arranged on the large plate, a long plate (202) arranged on the second supporting plates, a side plate (204) arranged on the side surface of the second supporting plates, a material plate (206) arranged on the long plate, a belt transmission mechanism (205) arranged on the side plate and a liftable material pushing support (207) arranged on the belt transmission mechanism, wherein the material plate (206) is provided with a plurality of grooves with the size matched with the prism, a material loading box (105) is pushed to ascend along the vertical direction by a first cylinder (104), then a second cylinder (107) pushes a sliding block (109) to move to the material plate sliding mechanism (2) along a guide rail (108), the material plate is pushed to the long plate (202) of the material plate sliding mechanism (2), and the second cylinder (107) is used for pushing the sliding block (109) to move to the material plate sliding mechanism (2) along the guide rail (108), pushing the material plate to a long plate (202) of the material plate sliding mechanism (2);

the material taking and placing mechanism (3) is arranged on the large plate and comprises a plurality of third supporting plates (301) arranged on the large plate, a first X-direction module (302) arranged on the third supporting plates, a first Y-direction module (303) arranged on the first X-direction module, a CCD device (304) arranged on the first Y-direction module, a first Z-direction module (306) arranged on the first Y-direction module and a vacuum suction nozzle (305) arranged on the first Z-direction module, wherein the belt transmission mechanism (205) is used for driving the material pushing support (207) to move along the X-direction material taking and placing mechanism (3) so as to push the material plate (206) to move along the X-direction material taking and placing mechanism (3) until the material plate reaches a set position and stop, the first Z-direction module is used for driving the vacuum suction nozzle to descend, and the vacuum suction nozzle is used for sucking the prisms in the material plate;

the screen printing carrying table mechanism (4) is arranged on the large board and comprises a second Y-direction module (401) arranged on the large board, an R-direction rotating module (402) arranged on the second Y-direction module and a rotatable jig (406) arranged on the R-direction rotating module, and the first Y-direction module and the first X-direction module convey the prism sucked by the vacuum suction nozzle to the jig (406) of the screen printing carrying table;

the screen printing mechanism (5) is arranged on the large plate and comprises a first mounting plate (501) arranged on the large plate, a second Z-direction module (502) arranged on the first mounting plate, a second X-direction module (503) arranged on the second Z-direction module, a guide rail (509) arranged on the second X-direction module, a third air cylinder (508) arranged on the guide rail, a screen printing head assembly (504) arranged on the guide rail, a mounting plate (505) arranged on the second X-direction module, a connecting plate (506) arranged on the mounting plate and a screen printing screen plate (507) arranged on the connecting plate;

a material receiving mechanism (6) arranged on the large plate;

the material receiving mechanism (6) comprises a second bottom plate (602) arranged on the large plate, a second guide shaft (601) arranged on the second bottom plate, a fourth cylinder (604) arranged on the large plate and the second bottom plate, and a material receiving box (605) arranged on the fourth cylinder.

2. The apparatus for fully automatically screen-printing the window surface of the prism as claimed in claim 1, wherein the feeding mechanism (1) further comprises a first linear bearing (103) disposed on the first guide shaft and the first base plate.

3. The apparatus for fully automatic screen printing of prism window surface according to claim 1, wherein a pair of opposite side surfaces of the feeding box (105) of the feeding mechanism is provided with a hollow groove.

4. The equipment for fully automatically screen-printing the window surface of the prism as claimed in claim 1, wherein the material plate sliding mechanism (2) further comprises a jacking assembly arranged on the belt transmission mechanism (205), and the other end of the jacking assembly is arranged on the material pushing support (207).

5. The device for screen printing of the window surface of the full-automatic prism as claimed in claim 1, wherein the screen printing stage mechanism (4) further comprises a rotating plate (403) arranged on the R-direction rotating module, a jig mounting seat (404) and a driving motor (405) arranged on the mounting plate, a jig mounting shaft (407) arranged on the jig mounting seat, and a coupling (408) arranged on the driving motor and the jig mounting shaft.

6. The apparatus of claim 1, wherein the screen assembly (504) comprises a screen squeegee (504.1) and an ink squeegee (504.2).

7. The apparatus for fully automatically screen-printing window surfaces of prisms according to claim 1, wherein the screen printing plate (507) is provided with meshes and is made of plastic.

8. The apparatus for fully automatic screen printing of prism window surface according to claim 1, wherein a pair of opposite side surfaces of the material receiving box (605) of the material receiving mechanism is provided with a hollow groove.

9. The apparatus of claim 1, wherein the vacuum nozzle is coated with silicone.

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