CN112876100A

CN112876100A - Intelligent glass and intelligent production line thereof

Info

Publication number: CN112876100A
Application number: CN202110125466.4A
Authority: CN
Inventors: 高礼平
Original assignee: Individual
Current assignee: Individual
Priority date: 2021-01-29
Filing date: 2021-01-29
Publication date: 2021-06-01

Abstract

The invention discloses intelligent glass and an intelligent production line of the intelligent glass, wherein the intelligent glass comprises a mirror surface hollow glass assembly, a first fixing frame, a second fixing frame, an LED lamp, an induction touch switch and a graphene film battery. In addition, this intelligent glass's wisdom production line includes feed mechanism, feeding mechanism, laminating mechanism, coating mechanism, equipment mechanism and control box, during production, earlier through control box start-up machine, and at this moment, feed mechanism, laminating mechanism, coating mechanism and equipment mechanism can work of mutually supporting, and required intelligent glass is produced simply swiftly.

Description

Intelligent glass and intelligent production line thereof

Technical Field

The invention relates to the field of glass manufacturing, in particular to intelligent glass and an intelligent production line of the intelligent glass.

Background

The existing common glass, such as hollow glass, is applied to a plurality of fields due to the characteristics of simple structure and convenient use. However, when the hollow glass is used in a dark environment, the mirror surface of the hollow glass is also dark, and the displayed image is also dark, which undoubtedly affects the use and satisfaction of the user.

Therefore, it is necessary to provide a technical means to solve the above-mentioned drawbacks.

Disclosure of Invention

The invention aims to overcome the defects of the prior art and provide intelligent glass to solve the problem that the use of hollow glass in the prior art is influenced in a dark environment.

The invention is realized in such a way that the intelligent glass comprises a mirror surface hollow glass assembly, a first fixing frame, a second fixing frame, an LED lamp, an induction touch switch and a graphene film battery;

the mirror surface hollow glass assembly is formed by laminating a plurality of mirror surface hollow glasses, the mirror surface hollow glasses are arranged in parallel, and the central lines of the mirror surface hollow glasses are overlapped;

the two first fixing frames are respectively arranged at the left side and the right side of the mirror surface hollow glass assembly and are respectively in sliding connection with the left side and the right side of the mirror surface hollow glass assembly;

the two second fixed frames are respectively arranged at the front side and the rear side of the mirror surface hollow glass assembly and are respectively in sliding connection with the front side and the rear side of the mirror surface hollow glass assembly; two ends of any one second fixed frame are abutted against the two first fixed frames;

four LED lamps are arranged, wherein two LED lamps are respectively and correspondingly embedded into the two first fixing frames, and the other two LED lamps are respectively and correspondingly embedded into the two second fixing frames;

the number of the induction touch switches is four, two induction touch switches are respectively arranged on the two first fixing frames, and each induction touch switch is correspondingly electrically connected with the LED lamp arranged on the same first fixing frame; the other two induction touch switches are respectively arranged on the two second fixed frames, and each induction touch switch is correspondingly electrically connected with the LED lamp arranged on the same second fixed frame;

the graphene film battery is arranged in the first fixing frame and/or the second fixing frame and is respectively electrically connected with the LED lamp and the induction touch switch.

The invention also provides an intelligent production line of the intelligent glass, which is applied to the intelligent glass and comprises the following components:

the feeding mechanism is used for feeding the hollow glass arranged at the placing position to a specified position;

the feeding mechanism is used for receiving the hollow glass fed by the feeding mechanism and feeding the hollow glass to a specified position; the feeding mechanism is arranged adjacent to the feeding mechanism;

the laminating mechanism is used for receiving the hollow glass fed by the feeding mechanism, mutually laminating the received hollow glass and then conveying the laminated hollow glass to a specified position; the laminating mechanism is arranged adjacent to the feeding mechanism;

the coating mechanism is used for receiving the laminated hollow glass sent by the laminating mechanism, performing coating operation on the laminated hollow glass to form the mirror surface hollow glass assembly, and then sending the mirror surface hollow glass assembly to a specified position; the coating mechanism is arranged adjacent to the laminating mechanism;

the assembling mechanism is used for receiving the mirror surface hollow glass assembly sent by the film coating mechanism and assembling the mirror surface hollow glass assembly with the prepared first fixing frame, the second fixing frame, the LED lamp, the induction touch switch and the graphene film battery to form required intelligent glass; the assembling mechanism is arranged adjacent to the film coating mechanism;

the control box is used for controlling the feeding mechanism, the laminating mechanism, the film coating mechanism and the assembling mechanism to work; the control box is arranged at the side end of the feeding mechanism and is respectively and electrically connected with the feeding mechanism, the laminating mechanism, the film coating mechanism and the assembling mechanism.

Compared with the prior art, the invention has the beneficial effects that:

1. the utility model provides an intelligence glass includes mirror surface cavity glass assembly, first fixed frame, the fixed frame of second, the LED lamp, response touch switch and graphite alkene film battery, in view of the above, through the distribution in the fixed frame inboard LED lamp of first fixed frame and second and the cooperation of response touch switch, when the user uses under the darker circumstances of light, accessible response touch switch opens the LED lamp to this produces sufficient luminance, convenience of customers uses.

2. The intelligent production line of the intelligent glass comprises a feeding mechanism, a laminating mechanism, a coating mechanism, an assembling mechanism and a control box, wherein during production, a machine is started through the control box, and at the moment, the feeding mechanism can feed the hollow glass arranged at a placing position to the feeding mechanism; then, the feeding mechanism feeds the hollow glass to the attaching mechanism; the attaching mechanism attaches the hollow glass to each other and then sends the hollow glass to the film coating mechanism; the coating mechanism carries out coating operation on the attached hollow glass to form a mirror surface hollow glass assembly, and then the mirror surface hollow glass assembly is sent to the assembling mechanism; afterwards, the assembly mechanism can assemble the mirror surface hollow glass assembly together with the prepared first fixed frame, the second fixed frame, the LED lamp, the induction touch switch and the graphene film battery to form the required intelligent glass, and the whole intelligent glass is simple and fast to produce.

Drawings

FIG. 1 is a schematic structural diagram of a smart glass according to an embodiment of the present invention;

FIG. 2 is an exploded view of a smart glass according to an embodiment of the present invention;

FIG. 3 is a schematic structural diagram of an intelligent production line for smart glass according to an embodiment of the present invention;

FIG. 4 is a schematic structural diagram of a feeding mechanism of an intelligent production line for intelligent glass according to an embodiment of the present invention;

FIG. 5 is a schematic structural diagram of a feeding mechanism of an intelligent production line for intelligent glass according to an embodiment of the present invention;

FIG. 6 is a schematic structural diagram of a bonding mechanism of an intelligent production line for smart glass according to an embodiment of the present invention;

FIG. 7 is a schematic structural diagram of a clamping transmission assembly in a bonding mechanism of an intelligent production line for intelligent glass according to an embodiment of the present invention;

FIG. 8 is a schematic structural diagram of another embodiment of a laminating mechanism of an intelligent production line for smart glass according to the present invention;

fig. 9 is a schematic structural diagram of a coating mechanism and an assembling mechanism of an intelligent glass production line according to an embodiment of the present invention.

Detailed Description

In order to make the technical means, the creation characteristics, the achievement purposes and the effects of the invention easy to understand, the invention is further described with the specific embodiments.

The first embodiment is as follows:

referring to fig. 1 and fig. 2, the present embodiment relates to a smart glass 200, which includes a mirror-surface hollow glass assembly 210, a first fixing frame 220, a second fixing frame 230, an LED lamp 240, an inductive touch switch 250, and a graphene thin film battery (labeled in the figures), and the following describes the portions of the smart glass 200 further:

the mirror surface hollow glass assembly 210 is formed by laminating a plurality of mirror surface hollow glass 211, the plurality of mirror surface hollow glass 211 are arranged in parallel, and the central lines of the plurality of mirror surface hollow glass 211 are overlapped;

two first fixing frames 220 are provided, the two first fixing frames 220 are respectively provided at the left and right sides of the mirror surface hollow glass assembly 210, and the two first fixing frames 220 are respectively connected with the left and right sides of the mirror surface hollow glass assembly 210 in a sliding manner;

two second fixing frames 230 are provided, the two second fixing frames 230 are respectively provided at the front and rear sides of the mirror surface hollow glass assembly 210, and the two second fixing frames 230 are respectively connected with the front and rear sides of the mirror surface hollow glass assembly 210 in a sliding manner; both ends of any one of the second fixing frames 230 abut against the two first fixing frames 220;

four LED lamps 240 are provided, wherein two LED lamps 240 are respectively and correspondingly embedded in the two first fixing frames 220, and the other two LED lamps 240 are respectively and correspondingly embedded in the two second fixing frames 230;

four induction touch switches 250 are provided, wherein two induction touch switches 250 are respectively arranged on two first fixing frames 220, and each induction touch switch 250 is correspondingly and electrically connected with the LED lamp 240 arranged on the same first fixing frame 220; the other two induction touch switches 250 are respectively arranged on the two second fixing frames 230, and each induction touch switch 250 is correspondingly and electrically connected with the LED lamp 240 arranged on the same second fixing frame 230;

the graphene film battery is arranged in the first fixing frame 220 and/or the second fixing frame 230 and is electrically connected with the LED lamp 240 and the inductive touch switch 250, respectively; the graphene thin film battery in this embodiment may be disposed in the first fixing frame 220, the second fixing frame 230, or both the first fixing frame 220 and the second fixing frame 230.

Accordingly, through the matching of the LED lamps 240 and the inductive touch switch 250 distributed inside the first and

second fixing frames

220 and 230, if the user uses the LED lamp 240 under dark light, the LED lamp 240 can be turned on through the inductive touch switch 250, so that sufficient brightness is generated, and the user can use the LED lamp conveniently.

Referring to fig. 2, the smart glass 200 of the present embodiment further includes a fixing member 260, wherein the fixing member 260 is respectively embedded in both the first fixing frame 220 and the second fixing frame 230, and specifically, the fixing member 260 is respectively embedded in a spliced portion of both the first fixing frame 220 and the second fixing frame 230, so as to ensure that the first fixing frame 220 and the second fixing frame 230 are fastened and connected to each other.

Meanwhile, in order to facilitate installation and material selection, the fixing member 260 is a fixing screw or a rivet.

Referring to fig. 2, the intelligent glass 200 of the present embodiment further includes four first limiting blocks 270, two of the first limiting blocks 270 are respectively disposed at two sides of one of the first fixing frames 220, and the other two first limiting blocks 270 are respectively disposed at two sides of the other first fixing frame 220, so as to limit the sliding of the mirror surface hollow glass assembly 210 on the first fixing frame 220, and therefore, by means of the first limiting blocks 270, the smooth connection and matching between the mirror surface hollow glass assembly 210 and the first fixing frame 220 can be ensured, and the mirror surface hollow glass assembly 210 and the first fixing frame 220 cannot be loosened at will.

Preferably, the smart glass 200 of the embodiment further includes four second limit blocks 280, two of the second limit blocks 280 are respectively disposed at two side ends of one of the second fixing frames 230, and the other two second limit blocks 280 are respectively disposed at two side ends of the other second fixing frame 230 for limiting the sliding of the mirror surface hollow glass assembly 210 on the second fixing frame 230, so that the smooth connection and matching between the mirror surface hollow glass assembly 210 and the second fixing frame 230 can be ensured, and the mirror surface hollow glass assembly 210 and the second fixing frame 230 can not be loosened freely by the arrangement of the second limit blocks 280.

Example two:

referring to fig. 3, and with reference to fig. 1 and fig. 2, the present embodiment relates to an intelligent production line 100 for intelligent glass, which is applied to the intelligent glass 200 of the first embodiment, and includes a feeding mechanism 10, a feeding mechanism 20, a bonding mechanism 30, a coating mechanism 40, an assembling mechanism 50, and a control box 60, and the following describes the parts of the intelligent production line 100 for intelligent glass further:

the feeding mechanism 10 is used to feed the hollow glass placed at the placing position to a specified position.

The feeding mechanism 20 is used for receiving the hollow glass fed by the feeding mechanism and feeding the hollow glass to a specified position; the feeding mechanism is adjacently arranged on the feeding mechanism 10;

the attaching mechanism 30 is used for receiving the hollow glass fed by the feeding mechanism 20, attaching the received hollow glass to each other, and then sending the attached hollow glass to a specified position; the attaching mechanism 30 is arranged adjacent to the feeding mechanism 20;

the coating mechanism 40 is used for receiving the laminated hollow glass sent by the laminating mechanism 30, performing coating operation on the laminated hollow glass to form a mirror-surface hollow glass assembly 210, and then sending the mirror-surface hollow glass assembly 210 to a specified position; the coating mechanism 40 is arranged adjacent to the attaching mechanism 30;

the assembling mechanism 50 is used for receiving the mirror surface hollow glass assembly 210 sent by the coating mechanism 40, and assembling the mirror surface hollow glass assembly 210 with the prepared first fixing frame 220, second fixing frame 230, LED lamp 240, inductive touch switch 250 and graphene film battery to form the required intelligent glass 200; the assembling mechanism 50 is arranged adjacent to the film coating mechanism 40;

the control box 60 is used for controlling the feeding mechanism 10, the feeding mechanism 20, the attaching mechanism 30, the film coating mechanism 40 and the assembling mechanism 50 to work; the control box 60 is disposed at the side end of the feeding mechanism 20 and is electrically connected to the feeding mechanism 10, the feeding mechanism 20, the attaching mechanism 30, the coating mechanism 40, and the assembling mechanism 50, respectively.

When the intelligent glass production line 100 of the intelligent glass in the embodiment is required to produce the intelligent glass 200, the machine is started through the control box 60, and at this time, the feeding mechanism 10 feeds the hollow glass placed at the placing position to the feeding mechanism 20; then, the feeding mechanism 20 feeds the hollow glass to the attaching mechanism 30; the attaching mechanism 30 attaches the hollow glasses to each other and then sends them to the coating mechanism 40; the coating mechanism 40 will perform a coating operation on the attached hollow glass to form a mirror-surface hollow glass assembly 210, and then send it to the assembling mechanism 50; then, the assembling mechanism 50 assembles the mirror-surface hollow glass assembly with the prepared first fixing frame, second fixing frame, LED lamp, inductive touch switch, and graphene thin film battery to form the required smart glass 200. The intelligent glass production line 100 in the embodiment is simple in structure and intelligent in production, and the whole intelligent glass 200 is simply and quickly produced.

Referring to fig. 4, the feeding mechanism 10 in the present embodiment preferably includes a mounting base plate 11, a steering driving source 12, a steering rod 13, a first joint 14, a first connecting rod 15, an up-down telescopic driving source 16, a second connecting rod 17, and an adsorption assembly 18, and the following further describes each part of the feeding mechanism 10:

the steering drive source 12 is provided on the mounting base plate 11; preferably, the steering driving source 12 is a forward and reverse rotation motor or a rotary cylinder, so as to facilitate material taking and installation;

the steering rod 13 is connected to an output end of the steering drive source 12 so as to be driven to rotate by the steering drive source 12;

the bottom end of the first joint 14 is connected to the top end of the steering rod 13;

one end of the first connecting rod 15 is connected to the side end of the first connecting head 14 and is arranged perpendicular to the steering rod 13;

a vertical telescopic driving source 16 is connected to the other end of the first connecting rod 15; preferably, the up-down telescopic driving source 16 is a telescopic cylinder for easy material drawing and installation;

the second connecting rod 17 is arranged at the bottom end of the upper and lower telescopic driving source 16 and is connected to the output end of the upper and lower telescopic driving source 16, and the second connecting rod 17 is perpendicular to the first connecting rod 15 and is parallel to the steering rod 13;

the adsorption assembly 18 is connected to the bottom end of the second connection rod 17.

When the loading operation is required, firstly, the steering driving source 12 is started to enable the steering driving source 12 to rotate the steering rod 13 to a required position; then, the up-down telescopic driving source 16 is started, so that the adsorption component 18 is moved downwards to a specified position by starting the up-down telescopic driving source 16; then, the adsorption component 18 is started to adsorb the hollow glass placed at the designated position; when the adsorption component 18 adsorbs the hollow glass, the up-down telescopic driving source 16 moves the adsorption component 18 up to a designated position; then, the steering driving source 12 rotates the steering rod 13 to a desired position, and then the up-down telescopic driving source 16 moves the adsorption assembly 18 down to a specified position; and finally, the hollow glass is loosened by the adsorption component 18, so that the hollow glass is fed to the target position, the whole operation is simple and convenient, and the hollow glass can be quickly and smoothly fed to the target position.

Preferably, the adsorption assembly 18 includes an adsorption fixing plate 181, a connection pipe frame 182, a first connection pipe 183, a second connection pipe 184, a first adsorption module 185, and a second adsorption module 186;

the adsorption fixing plate 181 is connected to the bottom end of the second connecting rod 17;

the connection pipe frame 182 is connected to the bottom end of the adsorption fixing plate 181;

a plurality of first connecting pipes 183 are provided, and the plurality of first connecting pipes 183 are respectively arranged at two sides of the connecting pipe frame 182;

a plurality of second connecting pipes 184 are provided, the plurality of second connecting pipes 184 are respectively provided at the other two sides of the connecting pipe frame 182, and the plurality of second connecting pipes 184 and the plurality of first connecting pipes 183 are vertically provided;

the number of the first adsorption modules 185 is the same as the number of the first connection pipes 183; any one of the first adsorption modules 185 includes a first suction pad 1851 and a first vacuum pump 1852, the first suction pad 1851 is disposed at the bottom end of the corresponding first connection pipe 183, and the first vacuum pump 1852 is disposed at the side end of the corresponding first connection pipe 183 and is communicated with the corresponding first suction pad 1851;

a plurality of second adsorption modules 186 are provided, and the number of the second adsorption modules 186 is the same as that of the second connection pipes 184; any one of the second suction modules 186 includes a second suction pad 1861 and a second vacuum pump 1862, the second suction pad 1861 is disposed at the bottom end of the corresponding second connection pipe 184, and the second vacuum pump 1862 is disposed at the side end of the corresponding second connection pipe 184 and is communicated with the corresponding second suction pad 1861.

Accordingly, when the adsorption module 18 adsorbs the hollow glass, the first vacuum pumps 1852 and the second vacuum pumps 1862 are simultaneously activated, wherein any one of the first vacuum pumps 1852 is continuously pumped out of air around the corresponding first suction pad 1851 after being activated to generate a negative pressure around the corresponding first suction pad 1851, and simultaneously any one of the second vacuum pumps 1862 is also continuously pumped out of air around the corresponding second suction pad 1861 to generate a negative pressure around the corresponding second suction pad 1861, so that the hollow glass can be adsorbed when the first suction pads 1851 and the second suction pads 1861 contact the hollow glass.

When it is required to release the hollow glass from the adsorption module 18, the hollow glass can be released from the adsorption module 18 only by stopping the plurality of first vacuum pumps 1852 and the plurality of second vacuum pumps 1862 at the same time since negative pressure is not generated around the plurality of first suction pads 1851 and the plurality of second suction pads 1861.

In addition, the connecting pipe frame 182, the first connecting pipe 183, the second connecting pipe 184, the first adsorption module 185 and the second adsorption module 186 are disposed to ensure that the adsorption component 18 can tightly hold the hollow glass when adsorbing the hollow glass, and ensure that the hollow glass is not damaged when adsorbing the hollow glass, and can quickly adsorb and release the hollow glass.

In order to ensure that hollow glass with various sizes can be adsorbed, preferably, any one of the second connecting pipes 184 is telescopically arranged on the connecting pipe frame 182, and a plurality of positioning holes 1841 arranged at intervals are arranged on any one of the second connecting pipes 184;

the connecting pipe frame 182 is provided with a positioning piece 1821 correspondingly matched with any positioning hole 1841 of the second connecting pipe 184;

when the positioning member 1821 is engaged with one of the positioning holes 1841 of the corresponding second connecting tube 184, the second connecting tube 184 is fixed on the connecting tube frame 182, and when the positioning member 1821 is released from the one of the positioning holes 1841 of the corresponding second connecting tube 184, the second connecting tube 184 is telescopically and movably disposed on the connecting tube frame 182.

Meanwhile, in order to facilitate material taking and installation, the positioning member 1821 is a screw, and the positioning hole 1841 is a screw hole.

Referring to fig. 5, the feeding mechanism 20 of the present embodiment preferably includes a feeding mounting frame 21, a feeding transmission shaft 22, a feeding transmission wheel 23, a feeding driving wheel 24, a feeding transmission belt 25, a feeding driving source 26, an electrostatic-removing ion bar 27, and a fan 28, and the following further describes each part of the feeding mechanism 20:

the feeding mounting frame 21 is arranged adjacent to the feeding mechanism 10;

a plurality of feeding transmission shafts 22 are arranged, the feeding transmission shafts 22 can be rotatably arranged on the feeding mounting frame 21 along the same linear direction, and two adjacent feeding transmission shafts 22 are arranged at intervals;

a plurality of feeding driving wheels 23 are arranged, and the plurality of feeding driving wheels 23 are uniformly sleeved on the plurality of feeding transmission shafts 22 at intervals;

a plurality of feeding driving wheels 24 are arranged, the number of the feeding driving wheels 24 corresponds to the number of the feeding transmission shafts 22, and each feeding driving wheel 24 is sleeved at one end, protruding out of the feeding mounting frame 21, of the corresponding feeding transmission shaft 22;

the feeding transmission belt 25 is sleeved on the plurality of feeding driving wheels 24;

the feeding driving source 26 is arranged on the side end of the feeding mounting frame 21, and the output end of the feeding driving source 26 is connected to one of the feeding driving wheels 24;

the static-removing ion bar 27 is arranged on the feeding mounting frame 21 and is positioned below the feeding transmission shaft 22;

the fan 28 is arranged on the feeding mounting frame 21 and close to the static-removing ion bar 27, the fan 28 is positioned below the feeding transmission shaft 22, and the air outlet end of the fan 28 faces the feeding transmission wheel 24.

When the feeding mechanism 20 performs feeding operation, the feeding driving source 26, the static-removing ion bar 27 and the fan 28 are respectively started, after the feeding driving source 26 is started, one of the connected feeding driving wheels 24 is driven to rotate, and after the feeding driving wheels 24 rotate, the other feeding driving wheels 24 are driven to rotate through the feeding driving belt 25, meanwhile, as the feeding driving wheels 24 rotate, the feeding driving wheels 24 drive the feeding transmission shafts 22 to rotate, and the feeding transmission wheels 23 arranged on the feeding transmission shafts 22 rotate along with the feeding transmission shafts 22, so that the hollow glass arranged on the feeding transmission wheels 23 can be sent to a specified position. In addition, because the static-removing ion bar 27 can generate a large amount of ions when working, and the fan 28 can blow the ions to the surface of the conveyed hollow glass, the static electricity on the surface of the hollow glass is eliminated, fine dust impurities in the air are effectively prevented from being attached to the surface of the hollow glass, and the integral appearance of the product is ensured.

For convenience of material selection and installation, the feeding driving source 26 is preferably a motor. Meanwhile, in order to facilitate mounting of the feeding drive source 26, the feeding drive source 26 is provided on the side end of the feeding mount 21 through a fixing plate 29.

In addition, in order to more effectively prevent fine dust impurities in the air from attaching to the surface of the conveyed hollow glass and affecting the overall appearance of the product, preferably, two static-removing ion bars 27 are provided, and the two static-removing ion bars 27 are symmetrically arranged at two ends of the feeding mounting rack 21;

two fans 28 are arranged, and the two fans 28 are symmetrically arranged at two ends of the feeding mounting frame 21.

Referring to fig. 6 and 7, the attaching mechanism 30 of the present embodiment preferably includes an attaching mounting frame 31, an attaching transmission shaft 32, an attaching transmission wheel 33, a blocking member 34, a blocking telescopic driving source 35, a clamping assembly 36, and a clamping driving source 37, and the following describes each part of the attaching mechanism 30 further:

the attaching installation frame 31 is arranged adjacent to the feeding mechanism 20;

a plurality of attaching transmission shafts 32 are arranged, the attaching transmission shafts 32 can be rotatably arranged on the attaching installation frame 31 along the same linear direction, and two adjacent attaching transmission shafts are arranged at intervals;

a plurality of the attaching transmission wheels 33 are arranged, and the attaching transmission wheels 33 are uniformly sleeved on the attaching transmission shafts 32 at intervals;

the intercepting piece 34 is arranged between any two adjacent joint transmission shafts 32 in a vertically telescopic mode, so that the conveyed hollow glass can be intercepted when the intercepting piece 34 extends out of the space between the two adjacent joint transmission shafts 32, and the conveyed hollow glass can be released when the intercepting piece 34 is retracted into the space between the two adjacent joint transmission shafts 32;

the intercepting telescopic driving source 35 is arranged on the attaching installation frame 31, and the output end of the intercepting telescopic driving source 35 is connected to the intercepting part 34;

the clamping assembly 36 comprises a first clamping piece 361 and a second clamping piece 362, the first clamping piece 361 and the second clamping piece 362 are arranged between any two adjacent abutting transmission shafts 32 in a relatively sliding manner, and the first clamping piece 361 and the second clamping piece 362 are adjacent to the intercepting piece 34;

the clamping driving source 37 is disposed on the attaching frame 31, and connected to the clamping assembly 36 through a clamping transmission assembly 38, and is used for controlling the first clamping member 364 and the second clamping member 362 to slide close to clamp the hollow glass, and controlling the first clamping member 361 and the second clamping member 362 to slide apart to release the hollow glass.

When the conveyed hollow glass needs to be attached, because the hollow glass is fed by the feeding mechanism 20, acting force moving forwards is applied, and accordingly, the hollow glass can move forwards on the plurality of attaching transmission wheels 33 by the acting force moving forwards; when the hollow glass moves to a designated position, the intercepting telescopic driving source 35 can be started, after the intercepting telescopic driving source 35 is started, the intercepting piece 34 can be driven to extend out between the two adjacent attaching transmission shafts 32, the transmitted hollow glass can be intercepted by the intercepting piece 34, and at the moment, the hollow glass can be collected and placed at the designated position; then, according to the above operation, when another piece of hollow glass is intercepted by the intercepting member 34, the clamping driving source 37 is started, and after the clamping driving source 37 is started, the clamping driving source is transmitted to the first clamping member 361 and the second clamping member 362 through the clamping transmission assembly 38, and the first clamping member 361 and the second clamping member 362 slide relatively and approach to each other, so as to clamp the hollow glass; after the hollow glass is clamped, the hollow glass can be attached, specifically, glue can be smeared on the clamped hollow glass through manual operation, and then the collected hollow glass is attached to the clamped hollow glass so as to finish the attaching operation of the hollow glass; thereafter, the clamping driving source 37 is controlled to slide the first and second clamping members 361 and 362 apart to release the hollow glass.

Preferably, the clamping driving assembly 38 includes a clamping driving screw 381, one end of the clamping driving screw 381 penetrates through the first clamping member 361 and is in forward threaded connection with the first clamping member 361, the other end of the clamping driving screw 381 penetrates through the second clamping member 362 and is in reverse threaded connection with the second clamping member 362, and one end of the clamping driving screw 381 is connected with the output end of the clamping driving source 37.

Therefore, after the clamping driving source 37 is started, the sliding approaching of the first clamping piece 361 and the second clamping piece 362 and the sliding separation of the first clamping piece 361 and the second clamping piece 362 can be controlled directly through the clamping transmission screw 381, and the device is simple and convenient and is low in cost.

In order to ensure that the hollow glass is well clamped, two groups of clamping assemblies 36 are preferably arranged, and the two groups of clamping assemblies 36 are arranged between two adjacent attached transmission shafts 32 at intervals;

meanwhile, correspondingly, in order to enable the clamping driving source 37 to control the sliding operation of the first clamping member 361 and the second clamping member 362 of the two sets of clamping assemblies 36 more smoothly and reliably through the clamping transmission assembly 38, the clamping transmission assembly 38 further includes two clamping transmission wheels 382, two clamping transmission belts 383 and a driving connecting wheel 384, and the two clamping transmission screw rods 381 are respectively arranged on the two sets of clamping assemblies 36; two clamping transmission wheels 382 are arranged, and the two clamping transmission wheels 382 are respectively arranged at the side ends of the two clamping transmission screw rods 381; the clamping transmission belt 383 is sleeved on the two clamping transmission wheels 382; the driving connecting wheel 384 is sleeved on the output end of the clamping driving source 37 and is connected with the clamping driving belt 383 in a matching way, and the driving connecting wheel 384 is positioned between the two clamping driving wheels 382.

Meanwhile, in order to facilitate the material taking and installation, the clamping driving source 37 is a forward and reverse motor.

In addition, in order to better intercept the hollow glass, two intercepting pieces 34 are arranged, and the two intercepting pieces 34 are respectively arranged at two sides of the attaching installation frame 31;

the two intercepting telescopic driving sources 35 are arranged, and the two intercepting telescopic driving sources 35 are respectively arranged at two sides of the fitting installation frame 31 and are respectively connected to the two intercepting parts 34.

Moreover, in order to facilitate material collection and installation, the intercepting telescopic driving source 35 is a telescopic cylinder.

Referring to fig. 8, in order to ensure that the hollow glass can move forward on the plurality of bonding transmission wheels 33 and avoid the need for manual movement, the bonding mechanism 30 further includes a bonding driving wheel 391, a bonding transmission belt 392 and a bonding driving source 393;

a plurality of bonding driving wheels 391 are arranged, the number of the bonding driving wheels 391 corresponds to the number of the bonding transmission shafts 32, and each bonding driving wheel 391 is sleeved at one end, protruding out of the bonding mounting frame 31, of the corresponding bonding transmission shaft 32;

the bonding transmission belt 392 is sleeved on the bonding driving wheels 391;

the attaching driving source 393 is disposed at a side end of the attaching mounting frame 31, and an output end of the attaching driving source 393 is connected to one of the attaching driving wheels 391.

In view of the above, start laminating driving source 393, and laminating driving wheel 391 rotation work that can drive one of them connection after laminating driving source 393 starts, and can drive other laminating driving wheel 391 rotation work through laminating drive belt 392 after this laminating driving wheel 391 rotates, simultaneously, because a plurality of laminating driving wheels 391 rotate, this a plurality of laminating driving wheels 391 can drive a plurality of laminating transmission shafts 32 and rotate, and locate a plurality of laminating transmission wheels 33 on a plurality of laminating transmission shafts 32 and also can follow a plurality of laminating transmission shafts 32 and rotate, therefore, alright guarantee better that the cavity glass who arranges in on the laminating transmission wheel 33 is sent to assigned position department.

Preferably, the attaching mechanism 30 further includes an attaching sensor 394, the attaching sensor 394 is disposed on the attaching mounting frame 31, and is used for sensing whether the hollow glass is conveyed to the designated position, and if the hollow glass is conveyed to the designated position, a relevant signal is sent to the control box 60, so that the control box 60 controls the operation of the intercepting telescopic driving source 35 to drive the intercepting member 34 to intercept the hollow glass, and if the hollow glass is not conveyed to the designated position, no relevant signal is sent to the control box 60.

In addition, in order to reduce the labor cost and remove the operation of manually attaching the hollow glass, the attaching mechanism 30 further includes an attaching manipulator (not shown), and the attaching manipulator is adjacent to the attaching installation frame 31 and is used for attaching the hollow glass.

Referring to fig. 9, the assembly mechanism 50 of the present embodiment preferably includes an assembly cabinet 51, an assembly table 52, a first assembly member 53 and a second assembly member 54, and the following describes the parts of the assembly mechanism 50 further:

the assembly cabinet body 51 is arranged adjacent to the film coating mechanism 40;

the assembling table 52 is arranged on the assembling cabinet body 51 and is used for placing the mirror surface hollow glass assembly 210, the two first fixing frames 220 combined with the LED lamp 240 and the inductive touch switch 250, and the two second fixing frames 230 combined with the LED lamp 240, the inductive touch switch 250 and the graphene film battery;

two first assembling members 53 are provided, and the two first assembling members 53 are provided at the left and right sides of the assembling cabinet body 52, and are used for respectively providing the two first fixing frames 220 combined with the LED lamp 240 and the inductive touch switch 250 at the left and right sides of the mirror surface hollow glass assembly 210;

the two second assembling members 54 are provided, and the two second assembling members 54 are provided at the front and rear sides of the assembling cabinet body 51, and are used for separately providing the two second fixing frames 230 combined with the LED lamp 240, the inductive touch switch 250, and the graphene thin-film battery at the front and rear sides of the mirror-surface hollow glass assembly 210.

When the intelligent glass 200 needs to be assembled, firstly, the mirror surface hollow glass assembly 210 sent by the coating mechanism 40 is ensured to be placed on the assembling table 52, and meanwhile, the two first fixing frames 220 combined with the LED lamp 240 and the inductive touch switch 250, and the two second fixing frames 230 combined with the LED lamp 240, the inductive touch switch 250 and the graphene film battery are also placed on the assembling table 52 in a stop way; then, the first assembling member 53 and the second assembling member 54 are activated, wherein after the first assembling member 53 is activated, the two first fixing frames 220 combined with the LED lamp 240 and the inductive touch switch 250 are respectively disposed at the left and right sides of the mirror-surface hollow glass assembly 210, and after the second assembling member 54 is activated, the two second fixing frames 230 combined with the LED lamp 240, the inductive touch switch 250 and the graphene thin film battery are respectively disposed at the front and rear sides of the mirror-surface hollow glass assembly 210, thereby the assembly of the smart glass 200 can be simply and rapidly realized.

Wherein the first assembling member 53 includes a first push plate 531 and a first moving drive source 532;

the first push plate 531 is movably disposed between the inside of the assembly cabinet 51 and the side end of the assembly table 52;

the first mobile driving source 532 is disposed on the outer side of the assembly cabinet 51, an output end of the first mobile driving source 532 penetrates through the side wall of the assembly cabinet 51 and extends into the assembly cabinet 51, and an output end of the first mobile driving source 532 is connected to the first push plate 531.

Therefore, as long as the first moving driving source 532 is started, and the first moving driving source 532 drives the first push plate 531 to move towards the left side or the right side of the mirror surface hollow glass assembly 210 arranged on the assembling table 52 after being started, at this time, the first fixed frame 220 combined with the LED lamp 240 and the inductive touch switch 250 can be arranged on the left side or the right side of the mirror surface hollow glass assembly 210 by the first push plate 531, and the whole operation is simple and convenient.

In order to facilitate the installation of the first driving source 532, the first driving source 532 is preferably installed on the outer side of the assembled cabinet 51 through a first fixing plate 533. Meanwhile, the first mobile driving source 532 is preferably a telescopic cylinder to facilitate material drawing and installation.

In addition, the second assembling member 54 includes a second push plate 541 and a second moving drive source 542;

the second pushing plate 541 is movably arranged between the inside of the assembly cabinet 51 and the side end of the assembly table 52;

the second driving source 542 is disposed on the outer side of the assembly cabinet 51, an output end of the second driving source 542 penetrates through a sidewall of the assembly cabinet 51 and extends into the assembly cabinet 51, and an output end of the second driving source 542 is connected to the second pushing plate 541.

Therefore, as long as the second moving driving source 542 is started, and the second moving driving source 542 is started to drive the second pushing plate 541 to move towards the front side or the rear side of the mirror surface hollow glass assembly 210 placed on the assembly table 52, at this time, the second pushing plate 541 can locate the second fixing frame 230 combined with the LED lamp 240, the inductive touch switch 250 and the graphene thin film battery at the front side or the rear side of the mirror surface hollow glass assembly 210, and the whole operation is simple and convenient.

In order to facilitate the installation of the second driving source 542, the second driving source 542 is preferably installed on the outer side of the assembly cabinet 51 through a second fixing plate. Meanwhile, the second driving source 542 is preferably a telescopic cylinder for easy material collection and installation.

In addition, the coating mechanism 40 of the present embodiment may adopt an existing coating mechanism, and the structure of the coating mechanism 40 may be approximate, where the coating mechanism 40 includes a machine platform and a vacuum chamber arranged on the machine platform, the upper portion of the vacuum chamber is provided with at least twenty cathode targets, the vacuum chamber is connected with an exhaust tube in the form of a bellows, the other end of the exhaust tube is connected with a molecular pump, and the molecular pump is connected with a roots pump through a connecting tube in the form of a bellows; a sample table is rotatably arranged at the center of the bottom of the vacuum chamber, and a heating source is arranged at the lower part of the sample table; at least three vapor deposition film collecting plates are fixedly connected to the vacuum chamber bottom plate, and heating clapboards are fixedly connected to the vapor deposition film collecting plates.

The operation of the coating mechanism 40 is as follows: firstly, turning on a roots pump, starting air extraction timing, starting a molecular pump after ten minutes, starting background vacuum extraction when the vacuum degree of a vacuum chamber reaches an initial vacuum numerical range (such as 3Pa), and finishing background vacuum when the vacuum degree of the vacuum chamber reaches a target vacuum numerical range (such as 6.0 multiplied by 10 < -4 > Pa); or after 30 minutes, the vacuum degree of the vacuum chamber fails to reach the target vacuum numerical range, the system considers that the vacuum chamber has a leakage point, and the system is shut down to eliminate faults. Then adjusting the stop valve, controlling the mass flowmeter to fill a certain amount of process gas, and stabilizing the vacuum degree of the vacuum chamber at a set value. Starting a heat source according to the process setting, starting a power supply to perform pre-sputtering when the temperature reaches a set value and the sputtering condition is met, rotating a sample table for a period of pre-sputtering (the time can be set), automatically closing the system after the sputtering reaches the set time, and finishing the whole sputtering process. After the evaporation is finished, the evaporation film layer material deposited on the evaporation film collecting plate can be scraped off and then appropriately treated (the evaporation film layer material is delivered to an evaporation film target preparation company for impurity removal, and the target material can be reused after reaching the target material use purity).

The above description is only exemplary of the present invention, and the structure is not limited to the above-mentioned shapes, and any modification, equivalent replacement, and improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims

1. A smart glass, characterized in that: the LED lamp comprises a mirror surface hollow glass assembly, a first fixing frame, a second fixing frame, an LED lamp, an induction touch switch and a graphene film battery;

2. The smart glass of claim 1, wherein: still include the mounting, the mounting imbeds respectively in first fixed frame with the fixed frame both of second.

3. The smart glass of claim 2, wherein: the fixing piece is a fixing screw or a rivet.

4. The smart glass of claim 1, wherein: still include first stopper, first stopper is equipped with four, wherein two one of them is located to first stopper branch the both sides end of first fixed frame, two in addition first stopper branch is located another one the both sides end of first fixed frame is used for injecing the mirror surface cavity glass assembly is in slip on the first fixed frame.

5. The smart glass of claim 1, wherein: still include the second stopper, the second stopper is equipped with four, two of them the second stopper branch is located one of them both sides end of the fixed frame of second, two of the other the second stopper branch is located another one both sides end of the fixed frame of second is used for injecing the mirror surface cavity glass assembly is in the slip on the fixed frame of second.

6. An intelligent production line of intelligent glass, which is applied to the intelligent glass of any one of claims 1-5, and is characterized in that: the method comprises the following steps:

7. The intelligent production line of intelligent glass of claim 6, characterized in that: the feeding mechanism comprises an installation bottom plate, a steering driving source, a steering rod, a first connecting joint, a first connecting rod, an up-down telescopic driving source, a second connecting rod and an adsorption assembly;

the steering driving source is arranged on the mounting bottom plate;

the steering rod is connected to the output end of the steering driving source so as to be driven to rotate by the steering driving source;

the bottom end of the first connecting joint is connected to the top end of the steering rod;

one end of the first connecting rod is connected to the side end of the first connecting head and is perpendicular to the steering rod;

the up-down telescopic driving source is connected to the other end of the first connecting rod;

the second connecting rod is arranged at the bottom end of the upper and lower telescopic driving source and is connected to the output end of the upper and lower telescopic driving source, and the second connecting rod is perpendicular to the first connecting rod and is parallel to the steering rod;

the adsorption component is connected to the bottom end of the second connecting rod.

8. The intelligent production line of intelligent glass of claim 6, characterized in that: the feeding mechanism comprises:

the feeding mounting frame is adjacently arranged on the feeding mechanism;

the feeding transmission shafts are arranged in a plurality and can be rotatably arranged on the feeding mounting frame along the same linear direction, and two adjacent feeding transmission shafts are arranged at intervals;

a plurality of feeding driving wheels are arranged and are uniformly sleeved on the plurality of feeding transmission shafts at intervals;

the feeding driving wheels are arranged in a plurality, the number of the feeding driving wheels corresponds to that of the feeding transmission shafts, and each feeding driving wheel is sleeved at one end, protruding out of the feeding mounting frame, of the corresponding feeding transmission shaft;

the feeding driving belt is sleeved on the feeding driving wheels;

the feeding driving source is arranged on the side end of the feeding mounting frame, and the output end of the feeding driving source is connected to one of the feeding driving wheels;

the static-removing ion bar is arranged on the feeding mounting frame and is positioned below the feeding transmission shaft;

the fan is arranged on the feeding mounting frame and close to the static-removing ion bar, the fan is located below the feeding transmission shaft, and the air outlet end of the fan faces towards the feeding transmission wheel.

9. The intelligent production line of intelligent glass of claim 6, characterized in that: the laminating mechanism includes:

the laminating mounting frame is adjacently arranged on the feeding mechanism;

the laminating transmission shafts are arranged in a plurality and can be rotatably arranged on the laminating mounting frame along the same linear direction, and two adjacent laminating transmission shafts are arranged at intervals;

a plurality of laminating transmission wheels are arranged and are uniformly sleeved on the plurality of laminating transmission shafts at intervals;

the intercepting piece is arranged between any two adjacent joint transmission shafts in a vertically telescopic mode, so that the conveyed hollow glass can be intercepted when the intercepting piece extends out of the space between the two adjacent joint transmission shafts, and the conveyed hollow glass can be released when the intercepting piece retracts into the space between the two adjacent joint transmission shafts;

the intercepting telescopic driving source is arranged on the attaching installation frame, and the output end of the intercepting telescopic driving source is connected to the intercepting piece;

the clamping assembly comprises a first clamping piece and a second clamping piece, the first clamping piece and the second clamping piece are arranged between any two adjacent fit transmission shafts in a relatively sliding mode, and the first clamping piece and the second clamping piece are adjacent to the intercepting piece;

the centre gripping driving source, the centre gripping driving source is located on the laminating mounting bracket, and through a centre gripping drive assembly with the centre gripping subassembly is connected, be used for control first holder with the second holder slides and is close to with the centre gripping cavity glass, and control first holder with the separation of second holder sliding is in order to release cavity glass.

10. The intelligent production line of intelligent glass of claim 6, characterized in that: the assembly mechanism includes:

the assembling cabinet body is adjacently arranged on the film coating mechanism;

the assembling table is arranged on the assembling cabinet body and used for placing the mirror surface hollow glass assembly, the two first fixing frames combined with the LED lamp and the induction touch switch and the two second fixing frames combined with the LED lamp, the induction touch switch and the graphene film battery in a stop way;

the two first assembly components are arranged on the left side and the right side of the assembly cabinet body and used for arranging the two first fixed frames combined with the LED lamps and the induction touch switches on the left side and the right side of the mirror surface hollow glass assembly;

and the two second assembly components are arranged on the front side and the rear side of the assembly cabinet body and used for arranging the two second fixing frames combined with the LED lamp, the induction touch switch and the graphene film battery on the front side and the rear side of the mirror surface hollow glass assembly.