CN213623865U - Glass breaking and laminating equipment - Google Patents

Abstract

The utility model relates to glass splitting and laminating equipment, which comprises a splitting device and a laminating device; the splitting device comprises a feeding assembly, a splitting assembly and a discharging assembly, wherein the feeding assembly is used for conveying the cut large glass to a splitting station, the splitting assembly is used for splitting the large glass positioned at the splitting station into small glass, and the discharging assembly is used for conveying the small glass to a transfer station; the lamination device comprises an accommodating assembly, a material taking assembly and a switching assembly, wherein the accommodating assembly comprises a first lamination jig and a second lamination jig which are used for accommodating small glass, the material taking assembly is used for conveying the small glass from a transfer station to the first lamination jig or the second lamination jig which is positioned at a material receiving station, and the switching assembly is used for driving the first lamination jig and the second lamination jig to move so that the first lamination jig and the second lamination jig are alternately positioned at the material receiving station. Utilize the utility model discloses a glass lobe of a leaf lamination equipment can save the work of artifical lobe of a leaf and lamination, is showing and is improving production efficiency.

Description

Glass breaking and laminating equipment

Technical Field

The utility model relates to a technical field is made in the glass production, especially relates to a glass lobe of a leaf lamination equipment.

Background

The cover glass is mainly applied to the outermost layer of the touch screen, and is also called strengthened optical glass, a glass window, a strengthened mobile phone lens and the like. The main raw material of the product is ultrathin plate glass, and the ultrathin plate glass has the functions of impact resistance, scratch resistance, oil stain resistance, fingerprint resistance, light transmittance enhancement and the like after being subjected to cutting, CNC engraving, thinning, strengthening, film coating, printing and other processes. After the cover plate glass is attached to the outer surface layer of the touch screen, the function of protecting the touch screen is achieved on one hand, and different colors, patterns and markers can be printed on the other hand, so that the functions of decorating and beautifying products are achieved. Since the touch era, the capacitive touch screen solution has become the mainstream of man-machine interaction of mobile terminals such as mobile phones, tablets and touch notebooks by virtue of the advantages of stable performance, good touch feeling and the like. No matter what touch technology, the cover plate is an indispensable protection component, and cover plate glass has become the mainstream of cover plate because of its characteristics such as high light transmissivity, strong scratch resistance.

At present, raw materials used for mobile phone cover plate glass are large-size plates, the products need to be cut before processing, and then the products are manually broken into small glass plates and are stacked in order for subsequent operation. After manual slicing, the lamination is carried out, so that the efficiency is slow, the labor cost is high, and the reject ratio of manual operation is high.

SUMMERY OF THE UTILITY MODEL

Based on this, it is necessary to provide a glass breaking and laminating apparatus which automatically performs glass breaking and laminating work.

The glass breaking and laminating equipment comprises a breaking device and a laminating device;

the splitting device comprises a feeding assembly, a splitting assembly and a discharging assembly, wherein the feeding assembly is used for conveying the cut large glass to a splitting station, the splitting assembly is used for splitting the large glass positioned at the splitting station into small glass, and the discharging assembly is used for conveying the small glass to a transfer station;

the lamination device comprises an accommodating assembly, a material taking assembly and a switching assembly, wherein the accommodating assembly comprises a first lamination jig and a second lamination jig which are used for accommodating small glass, the first lamination jig and the second lamination jig are located at a material receiving station, the material taking assembly is used for conveying the small glass to the first lamination jig or the second lamination jig which is located at the material receiving station from the transferring station, and the switching assembly is used for driving the first lamination jig and the second lamination jig to move so that the first lamination jig and the second lamination jig are alternately located at the material receiving station.

The utility model discloses a glass lobe of a leaf lamination equipment only needs to place the large glass that cuts out the cutting line on the material loading subassembly when using, after large glass was transported the lobe of a leaf station, can make the large glass that is located the lobe of a leaf station split into small glass along the cutting line through the lobe of a leaf subassembly, then transport to transporting the station through the unloading subassembly. Then, the material taking assembly can convey the small glass positioned at the transferring station to the first lamination jig or the second lamination jig positioned at the material receiving station, and when one lamination jig is full, the switching assembly can drive the first lamination jig and the second lamination jig to move, so that the full lamination jig is rotated to other positions to be in butt joint with subsequent equipment of the CNC automatic line, and the other lamination jig is rotated to the material receiving station to continuously receive the small glass from the material taking assembly, and continuous operation is realized. Utilize the utility model discloses a glass lobe of a leaf lamination equipment can save the work of artifical lobe of a leaf and lamination, reduces cost of labor and defective rate, and first lamination tool and second lamination tool can be located alternately and receive the material station, makes empty lamination tool receive the small glass that gets the material subassembly and transport, and full lamination tool then docks with follow-up processing equipment, is showing and is improving production efficiency.

In one embodiment, the accommodating assembly further includes a substrate, the switching assembly is connected to the substrate and is configured to drive the substrate to rotate, and the first lamination jig and the second lamination jig are disposed on the substrate and symmetrically distributed along a rotation axis of the substrate.

In one embodiment, the lamination device further comprises a lamination sensor connected with the switching assembly, and the lamination sensor is used for detecting the number of small pieces of glass put into the first lamination jig or the second lamination jig positioned at the receiving station.

In one embodiment, the laminating apparatus further comprises a first air blowing assembly disposed adjacent to the take-off assembly for removing glass cullet from the lower surface during transportation of the small piece of glass by the take-off assembly.

In one embodiment, the material taking assembly comprises a three-dimensional moving mechanism and a grabbing piece, the grabbing piece is used for grabbing the small glass, and the three-dimensional moving mechanism is connected with the grabbing piece and used for driving the grabbing piece to move.

In one embodiment, the lamination jig comprises a lamination base and a plurality of limiting pieces arranged on the lamination base, wherein the limiting pieces are arranged at intervals and in parallel, so that a containing bin is formed between every two adjacent limiting pieces.

In one embodiment, the lamination base is further provided with an anti-sticking hair brush, and the anti-sticking hair brush is arranged adjacent to the limiting sheet and used for preventing small pieces of glass stacked in the accommodating bin from being mutually stuck.

In one embodiment, the glass splitting assembly comprises a pressing mechanism and a lifting mechanism, wherein the pressing mechanism is used for pressing a large piece of glass located at the glass splitting station downwards, the lifting mechanism is used for bending the large piece of glass located at the glass splitting station upwards, and the pressing mechanism and the lifting mechanism are matched for splitting the large piece of glass into small pieces of glass.

In one embodiment, the glass breaking device further comprises a second blowing assembly, wherein the second blowing assembly is arranged adjacent to the blanking assembly and is used for removing glass scraps on the upper surface in the process of conveying the small pieces of glass by the blanking assembly.

In one embodiment, the glass breaking and laminating device further comprises a box body, the breaking device and the laminating device are arranged on the box body, and a plurality of support legs and a plurality of rollers are arranged at the bottom of the box body.

Drawings

Fig. 1 is a schematic structural view of a glass breaking and laminating apparatus according to an embodiment of the present invention;

FIG. 2 is a schematic structural view of a breaking device in the glass breaking and laminating apparatus shown in FIG. 1;

FIG. 3 is a schematic structural view of a lamination device in the glass breaking and laminating apparatus shown in FIG. 1;

FIG. 4 is a schematic view of another view of the lamination assembly shown in FIG. 3;

FIG. 5 is a schematic view of a lamination jig in the lamination apparatus shown in FIG. 3;

fig. 6 is a schematic structural diagram of another view angle of the lobe device shown in fig. 2.

Detailed Description

In order to facilitate understanding of the present invention, the present invention will be described more fully hereinafter with reference to the accompanying drawings. The preferred embodiments of the present invention are shown in the drawings. The invention may, however, 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.

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used in the description of the invention herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

Referring to fig. 1, a glass breaking and laminating apparatus 100 according to an embodiment of the present invention includes a breaking device 10 and a laminating device 20.

Referring to fig. 2, the glass breaking apparatus 10 includes a feeding assembly 11, a breaking assembly 12 and a discharging assembly 13, wherein the feeding assembly 11 is used for conveying the cut large glass to the breaking station, the breaking assembly 12 is used for breaking the large glass at the breaking station into small glass along a cutting line, and the discharging assembly 13 is used for conveying the small glass to the transfer station.

Referring to fig. 3, the lamination device 20 includes an accommodating assembly 21, a material taking assembly 22 and a switching assembly (not shown), the accommodating assembly 21 includes a first lamination jig 211 and a second lamination jig 212 for accommodating small glass, the first lamination jig 211 and the second lamination jig 212 are located at the material receiving station, the material taking assembly 22 is used for conveying the small glass from the transferring station to the first lamination jig 211 or the second lamination jig 212 located at the material receiving station, and the switching assembly is used for driving the first lamination jig 211 and the second lamination jig 212 to move, so that the first lamination jig 211 and the second lamination jig 212 are alternately located at the material receiving station.

The utility model discloses a glass lobe of a leaf lamination equipment 100 when using, only need to cut out the large glass of cutting out the line of cut and place on material loading subassembly 11, after large glass was transported the lobe of a leaf station, can make the large glass who is located the lobe of a leaf station split into small glass along the line of cut through lobe of a leaf subassembly 12, then transport to transporting the station through unloading subassembly 13. Then, the material taking assembly 22 can convey the small glass pieces at the transferring station to the first lamination jig 211 or the second lamination jig 212 at the material receiving station, and when one lamination jig is full, the switching assembly can drive the first lamination jig 211 and the second lamination jig 212 to move, so that the full lamination jig can be switched to other positions to be in butt joint with subsequent equipment of the CNC automatic line, and the other lamination jig is switched to the material receiving station to continue to receive the small glass pieces from the material taking assembly 22, thereby realizing continuous operation. Utilize the utility model discloses a glass lobe of a leaf lamination equipment 100 can save the work of artifical lobe of a leaf and lamination, reduces cost of labor and defective rate, and first lamination tool 211 and second lamination tool 212 can be located alternately and receive the material station, makes empty lamination tool receive the small glass who gets material subassembly 22 and transport, and full lamination tool then docks with follow-up processing equipment, is showing and is improving production efficiency.

In a specific example, the housing assembly 21 further includes a substrate 213, the switching assembly is connected to the substrate 213 and is used for driving the substrate 213 to rotate, and the first lamination jig 211 and the second lamination jig 212 are disposed on the substrate 213 and are symmetrically distributed along a rotation axis of the substrate 213. Thus, the substrate 213 is driven to rotate by the switching assembly, so as to drive the first lamination jig 211 and the second lamination jig 213 to rotate, and the first lamination jig 211 and the second lamination jig 213 are alternately positioned at the material receiving station. It is understood that the manner of driving the substrate 213 by the switching assembly is not limited thereto, and may be adjusted according to the requirement, for example, the substrate 213 may also be driven to perform a linear reciprocating motion, and the positions of the first lamination fixture 211 and the second lamination fixture 212 may be adjusted accordingly. Optionally, the switching element is disposed at the bottom of the substrate 213.

In a specific example, the housing assembly may further include more lamination jigs, such as a third lamination jig and the like. It can be understood that the number of the lamination jigs is not limited, and can be increased as required, so as to increase the number of the stacked glass in each accommodating assembly 21, and when more lamination jigs are symmetrically distributed along the rotating shaft of the substrate 213, the rotating angle of the substrate 213 required for switching different lamination jigs to be located at the receiving station is also reduced.

In one specific example, the lamination device 20 further includes a lamination sensor (not shown) connected to the switching assembly, and the lamination sensor is used for detecting the number of small pieces of glass placed in the first lamination jig 211 or the second lamination jig 212 at the receiving station. Thus, when the lamination sensor detects that the number of small glass pieces put into the first lamination jig 211 or the second lamination jig 212 positioned at the receiving station reaches a preset number, the switching component can automatically drive the lamination jig to switch positions. Alternatively, the lamination sensors are provided on the substrate 213, and the number may be set as desired.

In one particular example, the laminating device 20 further includes a first blowing assembly 24, the first blowing assembly 24 being disposed adjacent the take off assembly 22 for removing glass debris from the lower surface of the small piece of glass during transportation of the small piece of glass by the take off assembly 22. So, through first subassembly 24 of blowing glass lower surface stained glass piece when can clean the lobe of a leaf to surface cleanliness factor when guaranteeing the product lamination reduces the fish tail. Optionally, the first blowing assembly 24 is disposed on the substrate 213 and below the material taking assembly 22. Alternatively, the angle of the blowing port of the first blowing assembly 24 may be arbitrarily adjusted.

In one specific example, referring to fig. 4, the material taking assembly 22 includes a three-dimensional moving mechanism 221 and a gripping member 222, the gripping member 222 is used for gripping a small piece of glass, and the three-dimensional moving mechanism 221 is connected with the gripping member 222 for driving the gripping member 222 to move. Specifically, the three-dimensional moving mechanism 221 includes a first traverse module, a second traverse module, and a lift module, the first traverse module is connected to the lift module, the second traverse module is connected to the first traverse module, a moving direction of the first traverse module is the same as an extending direction of the discharging assembly 13 and is perpendicular to a moving direction of the second traverse module, and the grasping member 222 is connected to the second traverse module, so that the grasping member 222 can move three-dimensionally.

In a specific example, referring to fig. 5, the first lamination jig 211 includes a lamination base 2111 and a plurality of limiting plates 2112 disposed on the lamination base 2111, the limiting plates 2112 are spaced and arranged in parallel, so that a receiving bin is formed between two adjacent limiting plates 2112, and the receiving bins are arranged in a straight line. Therefore, the accommodating capacity of the lamination jig can be further increased, the grabbing piece 222 can conveniently discharge materials, and 104 sheets can be stacked in each accommodating bin in the embodiment.

In one specific example, the lamination base 2111 is further provided with an anti-sticking brush 2113, and the anti-sticking brush 2113 is disposed adjacent to the stopper plate 2112 for preventing small pieces of glass stacked in the storage compartment from sticking to each other. When the small glass pieces are taken out from the storage compartment in the following, the anti-sticking brush 2113 can provide a certain resistance so as to prevent the small glass pieces from sticking to each other and simultaneously take out the small glass pieces. Optionally, the number of the anti-sticking brushes is multiple and is arranged around the accommodating bin, and in the embodiment, the number of the anti-sticking brushes 2113 is 4.

In one specific example, as shown in fig. 6, the breaking assembly 12 includes a pressing mechanism 121 and a lifting mechanism 122, the pressing mechanism 121 is used for pressing the large glass at the breaking station downwards, and the lifting mechanism 122 is used for bending the large glass at the breaking station upwards, so that the large glass is broken along the existing cutting line to form the small glass. Alternatively, the pressing mechanism 121 and the lifting mechanism 122 are both air cylinders, but are not limited thereto.

In a specific example, the breaking device 12 further comprises a second blowing assembly 123, and the second blowing assembly 123 is arranged adjacent to the blanking assembly 13 and used for removing glass scraps on the upper surface of the small pieces of glass during the conveying of the small pieces of glass by the blanking assembly 13. So, through the second subassembly 123 of blowing glass piece that the glass upper surface is infected with when can cleaning the lobe of a leaf to surface cleanliness factor when guaranteeing the product lamination reduces the fish tail. Alternatively, the angle of the blowing port of the second blowing assembly 123 may be arbitrarily adjusted.

In a specific example, the glass breaking and laminating device 100 further comprises a box body 101, the breaking device 10 and the laminating device 20 are arranged on the box body 101, a plurality of support legs 102 and a plurality of rollers 103 are arranged at the bottom of the box body 101, the box body 101 can be used for containing articles and placing materials, the support legs 102 can enable the device to be stable, and the rollers 103 can facilitate the movement of the device, so that the use is more flexible.

In one specific example, the feeding assembly 11 comprises a conveyor belt and a side positioning member, wherein the conveyor belt is used for carrying and moving the large glass, and the side positioning member is used for limiting the side of the large glass.

In a specific example, referring to fig. 1, the lobe splitting apparatus 10 includes a plurality of feeding assemblies 11, lobe splitting assemblies 12, and discharging assemblies 13, wherein the plurality of feeding assemblies 11 are arranged in parallel, the plurality of lobe splitting assemblies 12 are arranged in parallel, and the plurality of discharging assemblies 13 are arranged in parallel. Correspondingly, the lamination device 20 includes a plurality of accommodating assemblies 21, a plurality of material taking assemblies 22 and a plurality of switching assemblies, the plurality of material taking assemblies 22 are arranged in parallel, the plurality of accommodating assemblies 21 are arranged in parallel, and the plurality of switching assemblies and the accommodating assemblies 21 are arranged in a one-to-one correspondence. Therefore, mass processing can be simultaneously carried out, and the production efficiency is improved.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only represent some embodiments of the present invention, and the description thereof is specific and detailed, but not to be construed as limiting the scope of the present invention. It should be noted that, for those skilled in the art, without departing from the spirit of the present invention, several variations and modifications can be made, which are within the scope of the present invention. Therefore, the protection scope of the present invention should be subject to the appended claims.

Claims (10)

1. The glass breaking and laminating equipment is characterized by comprising a breaking device and a laminating device;

the splitting device comprises a feeding assembly, a splitting assembly and a discharging assembly, wherein the feeding assembly is used for conveying the cut large glass to a splitting station, the splitting assembly is used for splitting the large glass positioned at the splitting station into small glass, and the discharging assembly is used for conveying the small glass to a transfer station;

the lamination device comprises an accommodating assembly, a material taking assembly and a switching assembly, wherein the accommodating assembly comprises a first lamination jig and a second lamination jig which are used for accommodating small glass, the first lamination jig and the second lamination jig are located at a material receiving station, the material taking assembly is used for conveying the small glass to the first lamination jig or the second lamination jig which is located at the material receiving station from the transferring station, and the switching assembly is used for driving the first lamination jig and the second lamination jig to move so that the first lamination jig and the second lamination jig are alternately located at the material receiving station.

2. The glass breaking and laminating device of claim 1, wherein the accommodating assembly further comprises a base plate, the switching assembly is connected with the base plate and is used for driving the base plate to rotate, and the first laminating jig and the second laminating jig are arranged on the base plate and are symmetrically distributed along a rotating shaft of the base plate.

3. The glass breaking and laminating device according to claim 1, wherein the laminating device further comprises a laminating sensor connected with the switching assembly, and the laminating sensor is used for detecting the number of small pieces of glass put into the first laminating jig or the second laminating jig positioned at the receiving station.

4. The glass breaking and laminating apparatus of claim 1, wherein the laminating device further comprises a first blowing assembly disposed adjacent the take-off assembly for removing glass debris from the lower surface during transport of the small piece of glass by the take-off assembly.

5. The glass breaking and laminating apparatus according to any one of claims 1 to 4, wherein the material taking assembly comprises a three-dimensional moving mechanism and a gripping member, the gripping member is used for gripping the small piece of glass, and the three-dimensional moving mechanism is connected with the gripping member and is used for driving the gripping member to move.

6. The glass breaking and laminating device according to claim 5, wherein the laminating jig comprises a laminating base and a plurality of limiting pieces arranged on the laminating base, and the limiting pieces are arranged at intervals and in parallel so that a containing bin is formed between every two adjacent limiting pieces.

7. The glass breaking and laminating equipment according to claim 6, wherein an anti-sticking brush is further arranged on the laminating base, and the anti-sticking brush is arranged adjacent to the limiting piece and used for preventing small pieces of glass stacked in the accommodating bin from being stuck with each other.

8. The glass breaking and laminating apparatus of any one of claims 1 to 4, wherein the breaking assembly comprises a hold-down mechanism for holding down a large piece of glass at the breaking station and a lift mechanism for bending the large piece of glass upward, the hold-down mechanism and the lift mechanism cooperating to break the large piece of glass into smaller pieces of glass.

9. The glass breaking and laminating apparatus according to any one of claims 1 to 4, wherein the breaking device further comprises a second blowing assembly disposed adjacent to the blanking assembly and configured to remove glass chips from an upper surface during conveyance of the small pieces of glass by the blanking assembly.

10. The glass breaking and laminating apparatus according to any one of claims 1 to 4, further comprising a box, wherein the breaking device and the laminating device are disposed on the box, and a plurality of support legs and a plurality of rollers are disposed at the bottom of the box.

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