CN112122068A

CN112122068A - Production method of building glass

Info

Publication number: CN112122068A
Application number: CN202011013770.1A
Authority: CN
Inventors: 梁桂清
Original assignee: Individual
Current assignee: Jiangsu Xinyu Building Materials Technology Co.,Ltd.
Priority date: 2020-09-24
Filing date: 2020-09-24
Publication date: 2020-12-25
Anticipated expiration: 2040-09-24
Also published as: CN112122068B

Abstract

The invention discloses a production method of building glass in the technical field of building material processing, which comprises a bottom plate, wherein a driving mechanism is arranged at the top of the bottom plate, a glue applying device is arranged at the top of the bottom plate and comprises a first rotating shaft fixedly connected with the center of the top of the bottom plate, the top of the first rotating shaft is fixedly connected with a first rotating disc, a first sliding groove is formed in the outer wall of the first rotating disc, and a rotating ring is rotatably connected to the outer wall of the first rotating shaft; according to the invention, through the arrangement of the glue applying device, glue can be accurately injected to the inner side edge of the two glass stacks, and the glue is prevented from dripping due to the unsatisfactory position of the sprayed glue, so that the waste of the glue is reduced, the pollution to a workbench is reduced, the glue applying is more accurate, the problem that two pieces of glass cannot be bonded due to inaccurate glue applying is avoided, the processing quality is improved, the processing of glass plates with different shapes can be realized, and the practicability of the device can be greatly improved.

Description

Production method of building glass

Technical Field

The invention relates to the technical field of building material processing, in particular to a production method of building glass.

Background

Glass is the most common material used in doors and windows, and because people basically select heating or air conditioning indoors in winter, the temperature difference between the front surface and the rear surface of the traditional single-layer glass is large, and the glass is easy to break. In order to solve the problem, double-layer glass appears in the prior art, the double-layer glass is formed by bonding two pieces of glass through glass cement, and the condition that a single piece of glass is broken due to uneven heating of two sides is effectively avoided due to the sealed space between the two glass plates.

The prior art discloses an invention patent in the technical field of part of building material processing, and an invention patent with the application number of CN201910877765.6, and discloses a production process of high-performance building glass.

According to the invention, when a gluing device is used for gluing two pieces of superposed glass, glue is applied to the side edge of the superposed position of the two pieces of glass, the glue cannot be accurately injected to the inner side edge of the two pieces of glass, and can drip downwards if the glue is not solidified in time, so that glue is easily wasted and a workbench is easily polluted, the two pieces of glass cannot be adhered due to inaccurate gluing, the processing quality is influenced, and the device can only be used for glass with one shape, and the practicability of the device can be greatly limited.

Based on the above, the invention designs a production method of building glass to solve the problems.

Disclosure of Invention

The invention aims to provide a production method of building glass, and aims to solve the problems that when a gluing device is used for gluing two pieces of superposed glass in the prior art, glue is applied to the side edge of the superposed position of the two pieces of glass, the glue cannot be accurately injected to the inner side edge of the two pieces of glass, and can drip downwards if the glue is not solidified in time, so that the glue is easily wasted and pollutes a workbench, the two pieces of glass can not be adhered due to inaccurate gluing, the processing quality is influenced, and the practicability of the device can be greatly limited because the device can only be used for glass with one shape.

In order to achieve the purpose, the invention provides the following technical scheme: the production method of the building glass comprises a bottom plate, wherein a driving mechanism is arranged at the top of the bottom plate, and a gluing device is arranged at the top of the bottom plate;

the gluing device comprises a first rotating shaft fixedly connected with the center of the top of a bottom plate, the top of the first rotating shaft is fixedly connected with a first rotating disc, the outer wall of the first rotating disc is provided with a first chute, the outer wall of the first rotating shaft is rotatably connected with a rotating ring, a driving mechanism is used for driving the rotating ring to rotate, the outer wall of the rotating ring is fixedly connected with a first rotating rod, the first rotating rod is slidably connected with the inner wall of the first chute, the center of the top of the first rotating disc is fixedly connected with a first electric telescopic rod, the top end of the first electric telescopic rod is connected with a bearing plate through a bolt and a screw thread, the top of the bearing plate is fixedly connected with four first suckers distributed in a circumferential array manner, the tops of the four first suckers are jointly sucked with a first glass plate, the shape of the bearing plate is the same as that of the first glass plate, and the left and right side walls of, the second rotating rod is connected with the outer wall of the bearing plate in a sliding manner, a first reset spring is sleeved on the second rotating rod, the first reset spring is positioned at the right end of the first rotating rod, the left end of the first reset spring is fixedly connected with the right wall of the first rotating rod, the right end of the first reset spring is fixedly connected with the limiting end on the right side of the second rotating rod, a second sliding groove is formed in the top of the second rotating rod, a glue spraying gun head is connected in the second sliding groove in a sliding manner, an upper rubber tube is fixedly connected to the bottom of the glue spraying gun head, a rubber barrel is connected to the top of the first rotating disk in a sliding manner, the rubber barrel is fixedly connected with the left side wall of the first rotating rod, the upper rubber tube is inserted into the rubber barrel, a connecting rod is fixedly connected to the outer wall of the bottom plate, a fixing plate is fixedly connected to the right side wall of the top of the connecting, the bottom of the second rotary table is fixedly connected with four second suckers distributed in a circumferential array, the bottom of each second sucker is fixedly connected with a second glass plate, the shape of each second glass plate is the same as that of the corresponding first glass plate, each second glass plate is positioned right above the corresponding first glass plate, a third sliding groove is formed in the top of each second rotary table, a sliding block is connected in the corresponding third sliding groove in a sliding mode, the top of each second rotary table is connected with a third rotating rod in a sliding mode, a fourth sliding groove is formed in each third rotating rod, each sliding block is positioned in each fourth sliding groove and is connected with the corresponding fourth sliding groove in a sliding mode, a second reset spring is fixedly connected to the left side of the inner wall of each fourth sliding groove, the right end of each second reset spring is fixedly connected with the outer wall of each sliding block, a fourth rotating rod is rotatably connected to the right side wall of each third rotating rod, and the bottom end;

the production method of the architectural glass comprises the following steps:

step 1: installing the center position of a bearing plate on the top of a first electric telescopic rod, then overlapping a first glass plate and a second glass plate together and placing the first glass plate and the second glass plate on the top of a first suction disc, enabling the positions of the first glass plate and the second glass plate to be overlapped with the bearing plate in the vertical direction, enabling the first suction disc to firmly suck the first glass plate, then starting the first electric telescopic rod to enable the first electric telescopic rod to drive the bearing plate, the first glass plate and the second glass plate to move upwards, and enabling the second suction disc to firmly suck the second glass plate under the pushing of the first electric telescopic rod when the second glass plate is in contact with the second suction disc;

step 2: starting a second electric telescopic rod to drive a second rotary table and a second glass plate to move upwards, driving a third rotary rod to move upwards synchronously while the second rotary table moves upwards, driving a fourth rotary rod to move upwards while rotating on the right side wall of the third rotary rod, driving a gluing gun head to slide in a second chute by the fourth rotary rod, closing the second electric telescopic rod when the gluing gun head moves to be attached to the left side wall of the second chute, and moving the second glass plate to a certain height to move the gluing gun head to the right side edge of the top of the first glass plate;

and step 3: the driving mechanism is started, the driving mechanism drives the rotating ring to rotate, the rotating ring can drive the first rotating rod to rotate around the first rotating shaft in the first sliding groove, the first rotating rod can drive the second rotating rod to slide on the outer wall of the bearing plate, when the second rotating rod slides along the outer wall of the bearing plate, the second rotating rod can receive force from the outer wall of the bearing plate, the acting force can enable the second rotating rod to slide on the first rotating rod and stretch the reset spring, the second rotating rod can always be attached to the outer wall of the bearing plate under the elastic force of the reset spring, the glue spraying gun head can be static relative to the second rotating rod, and the glue spraying gun head can uniformly glue the top edge of the first glass plate while the first rotating rod rotates;

and 4, step 4: when the gluing gun head rotates for one circle, and after one circle of gluing is finished on the top edge of the first glass plate, the driving mechanism is closed, the second disc type motor is started to drive the second rotary disc and the second glass plate to move downwards, the second rotary disc can drive the gluing gun head to slide rightwards in the second sliding chute through the fourth rotating rod, when the second glass plate is in contact with glue on the first glass plate, the gluing gun head moves to the outer part of the right side wall of the first glass plate, at the moment, the second electric telescopic rod continues to drive the second glass plate to move downwards, so that the second glass plate is fully attached to the glue, and the first glass plate and the second glass plate are adhered together under the action of the glue;

and 5: starting a second electric telescopic rod to drive a second rotary table and a second sucker to move upwards, simultaneously taking down a second glass plate from the second sucker by a worker to separate the second glass plate from the second sucker, then starting a first electric telescopic rod to drive a bearing plate, a first sucker and a well-adhered first glass plate and second glass plate to move downwards, and then taking down the well-adhered glass plate from the first sucker by the worker;

when the gluing device is used for gluing two pieces of superposed glass, the side edge of the superposed position of the two pieces of glass is glued by the gluing device in the prior art, glue cannot be accurately injected to the inner side edge of the two pieces of glass, and the glue can drip downwards if the glue is not solidified in time, so that the waste of the glue and the pollution to a workbench are easily caused, the two pieces of glass cannot be bonded due to inaccurate gluing, the processing quality is influenced, and the gluing device can only be used for glass with one shape, so that the practicability of the gluing device is greatly limited; the production method of the architectural glass comprises the steps that the bearing plate is not arranged at the top end of the first electric extension rod, the first electric telescopic rod is in a contraction state, when the glass plate needs to be bonded, the center of the bearing plate is arranged at the top of the first electric telescopic rod, then the first glass plate and the second glass plate are overlapped together and placed at the top of the first suction disc, the first glass plate and the second glass plate are overlapped with the bearing plate in the vertical direction, the first suction disc is firmly sucked on the first glass plate, then the first electric telescopic rod is started to drive the bearing plate, the first glass plate and the second glass plate to move upwards, when the second glass plate is contacted with the second suction disc, the second suction disc is firmly sucked on the second glass plate under the pushing of the first electric telescopic rod, the second electric telescopic rod is started to drive the second rotary disc and the second glass plate to move upwards, the second rotating disc moves upwards and simultaneously drives the third rotating rod to move upwards synchronously, the third rotating rod drives the fourth rotating rod to move upwards and simultaneously rotate on the right side wall of the third rotating rod, the fourth rotating rod drives the glue spraying gun head to slide in the second chute, when the glue spraying gun head moves to be attached to the left side wall of the second chute, the second electric telescopic rod is closed, the second glass plate moves to a certain height, the glue spraying gun head moves to the right side edge of the top of the first glass plate, the driving mechanism is started to drive the rotating ring to rotate, the rotating ring drives the first rotating rod to rotate around the first rotating shaft in the first chute, the first rotating rod drives the second rotating rod to slide on the outer wall of the bearing plate, when the second rotating rod slides along the outer wall of the bearing plate, the second rotating rod is subjected to the force from the outer wall of the bearing plate, the acting force can enable the second rotating rod to slide on the first rotating rod and simultaneously stretch the return spring, the second rotating rod can be always attached to the outer wall of the bearing plate under the action of the elastic force of the return spring, the gluing gun head can be static relative to the second rotating rod, the gluing gun head can evenly glue the top edge of the first glass plate when the first rotating rod rotates, when the gluing gun head rotates for one circle, and after one circle of gluing is finished on the top edge of the first glass plate, the driving mechanism is closed, the second disc type motor is started to drive the second rotating disc and the second glass plate to move downwards, the second rotating disc can drive the gluing gun head to slide rightwards in the second sliding chute through the fourth rotating rod, when the second glass plate is contacted with the glue on the first glass plate, the gluing gun head moves to the outer part of the right side wall of the first glass plate, at the moment, the second motor continues to drive the second glass plate to move downwards, so that the second glass plate is fully attached to the glue, and the first glass plate and the second glass plate can be adhered together under the action of the glue, starting a second electric telescopic rod to drive a second rotary table and a second sucker to move upwards, simultaneously taking down a second glass plate from the second sucker by a worker to separate the second glass plate from the second sucker, starting a first electric telescopic rod to drive a bearing plate, a first sucker, a first glass plate and a second glass plate which are well adhered to each other to move downwards, taking down the well adhered glass plate from the first sucker by the worker, when the glass plates with different shapes need to be machined, only manufacturing the bearing plate with the same shape as the glass plate, wherein the bearing plate can be manufactured into another shape as shown in the schematic diagram of figure 8 to meet the gluing of circular glass, then installing the center position of the bearing plate at the top of the first electric telescopic rod, firmly sucking the glass plate at the top of the first sucker, and enabling the center position of the glass plate to be coincided with the center position of the bearing plate, the second bull stick can realize sliding on the outer wall of different shapes bearing plate, can realize the processing to the glass board without the shape, through the setting of above structure, can be accurate will glue the inboard border department of injecting two glass stacks, avoid spraying the unsatisfactory and drip that causes glue in position of glue, thereby reduce the waste of glue, reduce the pollution to the workstation, make to beat and glue more accurate, thereby avoid because beat glue inaccurate and cause the unable adhesive problem of two glass, the processingquality is improved, and can realize the processing to the glass board of different shapes, can improve the device's practicality greatly.

As a further scheme of the invention, a fixed block capable of sliding left and right is connected to the front wall of the second rotating rod in a sliding manner, a scraping plate is connected to the top of the fixed block in a sliding manner in the vertical direction, a third return spring is fixedly connected to the right side wall of the fixed block, and the right end of the third return spring is fixedly connected with the front side wall of the second rotating rod; during operation, when considering that the second glass plate moves downwards and is bonded with the first glass plate, glue can be pressed to cause the glue to overflow from the first glass plate and can be bonded on the side wall of the first glass plate, and the glue can be caused to solidify and is difficult to clean after a long time.

As a further scheme of the invention, a material receiving disc capable of sliding up and down is connected to the left side wall of the fixed block in a sliding manner, the material receiving disc is positioned below the scraping plate, an inclined plane is arranged on the left side of the material receiving disc, and the material receiving disc is positioned between the first glass plate and the bearing plate; during operation, if glue cleaned by the scraper blade is not collected, the glue can drip on the device, and the device can be damaged due to long-term accumulation, so that the device can not work normally.

As a further scheme of the invention, a rotating wheel is rotatably connected to the left side wall of the second rotating rod; during operation, through the setting of rotating wheel, the frictional force that receives when can reducing the second bull stick and slide on the bearing plate outer wall can make the gliding more smooth and easy on the bearing plate outer wall of second bull stick.

As a further scheme of the invention, the driving mechanism comprises a first gear fixedly connected to the outer wall of the rotating ring, the top of the bottom plate is fixedly connected with a disc motor, an output shaft of the disc motor is fixedly connected with a second gear, and the second gear and the outer wall of the first gear are jointly in transmission connection with a belt; when in work; the disc type motor drives the second gear to rotate, the second gear drives the first gear to rotate through the belt, the first gear rotates to drive the rotating ring to rotate, and the effect of driving the gluing device is achieved.

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

1. according to the invention, through the arrangement of the glue applying device, glue can be accurately injected to the inner side edge of the two glass stacks, and the glue is prevented from dripping due to the unsatisfactory position of the sprayed glue, so that the waste of the glue is reduced, the pollution to a workbench is reduced, the glue applying is more accurate, the problem that two pieces of glass cannot be bonded due to inaccurate glue applying is avoided, the processing quality is improved, the processing of glass plates with different shapes can be realized, and the practicability of the device can be greatly improved.

2. According to the invention, through the arrangement of the fixing block and the scraper, the glue overflowing from the side edge of the first glass plate can be scraped and cleaned, and the problem that the glue overflowing from the side edge of the first glass plate is solidified on the side edge of the first glass plate to cause difficulty in cleaning when two pieces of glass are pressed can be avoided.

3. According to the invention, through the arrangement of the receiving disc, the glue scraped by the scraper can be collected, so that the glue cannot fall onto the gluing device, and the problem that the device is possibly damaged due to long-term accumulation is avoided.

Drawings

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

FIG. 1 is a flow chart of a production method of the present invention;

FIG. 2 is a schematic view of a first overall structure of the gluing device of the present invention;

FIG. 3 is a schematic view of part A of FIG. 2;

FIG. 4 is a second general construction of the gluing device of the present invention;

FIG. 5 is a partial enlarged view of portion B of FIG. 4;

FIG. 6 is a side view of the gluing device of the present invention;

FIG. 7 is a partial schematic view of the driving mechanism of the present invention;

fig. 8 is another embodiment of the load bearing plate of the present invention.

In the drawings, the components represented by the respective reference numerals are listed below:

the automatic glue applying machine comprises a base plate 1, a first rotating shaft 2, a first rotating disc 3, a first sliding chute 4, a rotating ring 5, a first rotating rod 6, a first electric telescopic rod 7, a bearing plate 8, a first suction disc 9, a first glass plate 10, a second rotating rod 11, a first return spring 12, a second sliding chute 13, a glue applying gun head 14, a glue applying pipe 15, a glue barrel 16, a connecting rod 17, a fixing plate 18, a second electric telescopic rod 19, a second rotating disc 20, a second suction disc 21, a second glass plate 22, a third sliding chute 23, a sliding block 24, a third rotating rod 25, a fourth sliding chute 26, a second return spring 27, a fourth rotating rod 28, a fixing block 29, a scraping plate 30, a third return spring 31, a material receiving disc 32, a rotating wheel 33, a first gear 34, a disc type motor 35, a second gear 36 and a belt 37.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying 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. Based on the embodiments of the present invention, other embodiments obtained by persons of ordinary skill in the art without any creative effort are within the protection scope of the present invention.

Referring to fig. 1-8, the present invention provides a technical solution: a production method of building glass is provided, and gluing equipment suitable for the production method comprises a bottom plate 1, wherein the bottom plate 1 comprises a bottom plate 1, a driving mechanism is arranged at the top of the bottom plate 1, and a gluing device is arranged at the top of the bottom plate 1;

the gluing device comprises a first rotating shaft 2 fixedly connected with the top center of a bottom plate 1, a first rotating disc 3 is fixedly connected with the top of the first rotating shaft 2, a first chute 4 is arranged on the outer wall of the first rotating disc 3, a rotating ring 5 is rotatably connected with the outer wall of the first rotating shaft 2, a driving mechanism is used for driving the rotating ring 5 to rotate, a first rotating rod 6 is fixedly connected with the outer wall of the rotating ring 5, the first rotating rod 6 is slidably connected with the inner wall of the first chute 4, a first electric telescopic rod 7 is fixedly connected with the top center of the top of the first rotating disc 3, a bearing plate 8 is connected with the top end of the first electric telescopic rod 7 through bolt threads, four first absorbing discs 9 distributed in a circumferential array are fixedly connected with the top of the bearing plate 8, a first glass plate 10 is jointly absorbed at the top of the four first absorbing discs 9, the shape of the bearing plate 8 is the same as that of the first glass plate 10, and, the second rotating rod 11 is connected with the outer wall of the bearing plate 8 in a sliding way, a first return spring 12 is sleeved on the second rotating rod 11, the first return spring 12 is positioned at the right end of the first rotating rod 6, the left end of the first return spring 12 is fixedly connected with the right wall of the first rotating rod 6, the right end of the first return spring 12 is fixedly connected with the right outer wall of the second rotating rod 11, a second sliding chute 13 is arranged at the top of the second rotating rod 11, a glue spraying gun head 14 is connected in the second sliding chute 13 in a sliding way, an upper rubber tube 15 is fixedly connected at the bottom of the glue spraying gun head 14, a rubber barrel 16 is connected at the top of the first rotating disk 3 in a sliding way, the rubber barrel 16 is fixedly connected with the left wall of the first rotating rod 6, the upper rubber tube 15 is inserted into the rubber barrel 16, a connecting rod 17 is fixedly connected on the outer wall of the bottom plate 1, a fixing plate 18 is fixedly connected on the right side wall at, the bottom of the second rotary table 20 is fixedly connected with four second suction cups 21 distributed in a circumferential array, the bottom of each second suction cup 21 is fixedly connected with a second glass plate 22, the second glass plate 22 is identical to the first glass plate 10 in shape, the second glass plate 22 is positioned right above the first glass plate 10, the top of the second rotary table 20 is provided with a third sliding chute 23, the third sliding chute 23 is connected with a sliding block 24 in a sliding manner, the top of the second rotary table 20 is connected with a third rotating rod 25 in a sliding manner, the third rotating rod 25 is provided with a fourth sliding chute 26, the sliding block 24 is positioned in the fourth sliding chute 26 and is connected with the fourth sliding chute 26 in a sliding manner, the left side of the inner wall of the fourth sliding chute 26 is fixedly connected with a second return spring 27, the right end of the second return spring 27 is fixedly connected with the outer wall of the sliding block 24, the right side wall of the third rotating rod 25 is connected with a fourth rotating rod 28 in a rotating;

the production method of the architectural glass comprises the following steps:

step 1: installing the center position of a bearing plate 8 on the top of a first electric telescopic rod 7, then overlapping a first glass plate 10 and a second glass plate 22 together and placing the first glass plate 10 and the second glass plate 22 on the top of a first suction cup 9, enabling the positions of the first glass plate 10 and the second glass plate 22 to be overlapped with the bearing plate 8 in the vertical direction, enabling the first suction cup 9 to firmly suck the first glass plate 10, then starting the first electric telescopic rod 7 to enable the first electric telescopic rod 7 to drive the bearing plate 8, the first glass plate 10 and the second glass plate 22 to move upwards, and enabling the second suction cup 21 to firmly suck the second glass plate 22 under the pushing of the first electric telescopic rod 7 when the second glass plate 22 is in contact with the second suction cup 21;

step 2: starting a second electric telescopic rod 19 to drive a second rotary table 20 and a second glass plate 22 to move upwards, wherein the second rotary table 20 can drive a third rotary rod 25 to move upwards synchronously while moving upwards, the third rotary rod 25 can drive a fourth rotary rod 28 to move upwards while rotating on the right side wall of the third rotary rod 25, the fourth rotary rod 28 can drive a glue spraying gun head 14 to slide in a second sliding chute 13, when the glue spraying gun head 14 moves to be attached to the left side wall of the second sliding chute 13, the second electric telescopic rod 19 is closed, the second glass plate 22 moves to a certain height at the moment, and the glue spraying gun head 14 moves to the right side edge of the top of the first glass plate 10;

and step 3: starting a driving mechanism, enabling the driving mechanism to drive a rotating ring 5 to rotate, enabling the rotating ring 5 to drive a first rotating rod 6 to rotate around a first rotating shaft 2 in a first sliding chute 4, enabling the first rotating rod 6 to drive a second rotating rod 11 to slide on the outer wall of a bearing plate 8, enabling the second rotating rod 11 to receive force from the outer wall of the bearing plate 8 when the second rotating rod 11 slides along the outer wall of the bearing plate 8, enabling the second rotating rod 11 to slide on the first rotating rod 6 and stretch a return spring under the action of the force, enabling the second rotating rod 11 to be always attached to the outer wall of the bearing plate 8 under the action of the elastic force of the return spring, enabling a gluing gun head 14 to be static relative to the second rotating rod 11, and enabling the gluing gun head 14 to evenly glue the top edge of a first glass plate 10 when the first rotating rod 6 rotates;

and 4, step 4: when the gluing gun head 14 rotates for one circle, and after one circle of gluing is finished on the top edge of the first glass plate 10, the driving mechanism is closed, the second disc type motor 35 is started to drive the second rotary disc 20 and the second glass plate 22 to move downwards, the second rotary disc 20 drives the gluing gun head 14 to slide rightwards in the second sliding chute 13 through the fourth rotary rod 28, when the second glass plate 22 is in contact with glue on the first glass plate 10, the gluing gun head 14 moves to the outer part of the right side wall of the first glass plate 10, at the moment, the second electric telescopic rod 19 continues to drive the second glass plate 22 to move downwards, so that the second glass plate 22 is fully attached to the glue, and the first glass plate 10 and the second glass plate 22 are bonded together under the action of the glue;

and 5: starting a second electric telescopic rod 19 to drive a second rotary table 20 and a second suction cup 21 to move upwards, simultaneously taking down a second glass plate 22 from the second suction cup 21 by a worker to separate the second glass plate 22 from the second suction cup 21, then starting a first electric telescopic rod 7 to drive a bearing plate 8, a first suction cup 9 and a first glass plate 10 and a second glass plate 22 which are well bonded to move downwards, and then taking down the well bonded glass plate from the first suction cup 9 by the worker;

when the gluing device is used for gluing two pieces of superposed glass, the side edge of the superposed position of the two pieces of glass is glued by the gluing device in the prior art, glue cannot be accurately injected to the inner side edge of the two pieces of glass, and the glue can drip downwards if the glue is not solidified in time, so that the waste of the glue and the pollution to a workbench are easily caused, the two pieces of glass cannot be bonded due to inaccurate gluing, the processing quality is influenced, and the gluing device can only be used for glass with one shape, so that the practicability of the gluing device is greatly limited; in the above method for producing architectural glass, the initial state of the device is that the top end of the first electric telescopic rod is not provided with the bearing plate 8, the first electric telescopic rod 7 is in a contracted state, when glass plates need to be bonded, firstly, the center of the bearing plate 8 is arranged at the top of the first electric telescopic rod 7, then, the first glass plate 10 and the second glass plate 22 are overlapped together and placed at the top of the first suction cup 9, the positions of the first glass plate 10 and the second glass plate 22 are overlapped with the bearing plate 8 in the up-down direction, so that the first suction cup 9 absorbs the first glass plate 10, then, the first electric telescopic rod 7 is started to drive the bearing plate 8, the first glass plate 10 and the second glass plate 22 to move upwards, when the second glass plate 22 is contacted with the second suction cup 21, the second suction cup 21 is driven by the first electric telescopic rod 7 to firmly absorb the second glass plate 22, the second electric telescopic rod 19 is started to drive the second rotary table 20 and the second glass plate 22 to move upwards, the second rotary table 20 can drive the third rotary rod 25 to move upwards synchronously while moving upwards, the third rotary rod 25 can drive the fourth rotary rod 28 to move upwards while rotating on the right side wall of the third rotary rod 25, the fourth rotary rod 28 can drive the gluing gun head 14 to slide in the second chute 13, when the gluing gun head 14 moves to be attached to the left side wall of the second chute 13, the second electric telescopic rod 19 is closed, the second glass plate 22 moves to a certain height at the moment, the gluing gun head 14 moves to the right side edge of the top of the first glass plate 10, the driving mechanism is started to drive the rotary ring 5 to rotate, the rotary ring 5 can drive the first rotary rod 6 to rotate around the first rotary shaft 2 in the first chute 4, the first rotary rod 6 can drive the second rotary rod 11 to slide on the outer wall of the bearing plate 8, when the second rotating rod 11 slides along the outer wall of the bearing plate 8, the second rotating rod 11 is subjected to a force from the outer wall of the bearing plate 8, the acting force can enable the second rotating rod 11 to slide on the first rotating rod 6 and simultaneously stretch the return spring, the second rotating rod 11 can be always attached to the outer wall of the bearing plate 8 under the elastic force of the return spring, the gluing gun head 14 can be stationary relative to the second rotating rod 11, the gluing gun head 14 can evenly glue the top edge of the first glass plate 10 when the first rotating rod 6 rotates, when the gluing gun head 14 rotates for one circle, the driving mechanism is closed after one circle of gluing is finished on the top edge of the first glass plate 10, the second disc type motor 35 is started to drive the second rotating disc 20 and the second glass plate 22 to move downwards, the second rotating disc 20 can drive the gluing gun head 14 to slide rightwards in the second chute 13 through the fourth rotating rod 28, and when the second glass plate 22 is in contact with glue on the first glass plate 10, the glue spraying gun head 14 moves to the outside of the right side wall of the first glass plate 10, at the moment, the second electric telescopic rod 19 continues to drive the second glass plate 22 to move downwards, so that the second glass plate 22 is fully attached to glue, the first glass plate 10 and the second glass plate 22 are bonded together under the action of the glue, the second electric telescopic rod 19 is started to drive the second rotary disc 20 and the second suction disc 21 to move upwards, meanwhile, a worker takes the second glass plate 22 off the second suction disc 21, so that the second glass plate 22 is separated from the second suction disc 21, then the first electric telescopic rod 7 is started to drive the bearing plate 8, the first suction disc 9 and the bonded first glass plate 10 and second glass plate 22 to move downwards, then the worker takes the bonded glass plate off the first suction disc 9, when glass plates with different shapes need to be processed, only one bearing plate 8 with the same shape as the glass plate is manufactured first, as shown in the schematic diagram of fig. 8, another shape that the bearing plate 8 can implement is used for gluing circular glass, then the center position of the bearing plate 8 is installed at the top of the first electric telescopic rod 7, the glass plate is installed at the top of the first suction cup 9 and is firmly sucked, the center position of the glass plate must coincide with the center position of the bearing plate 8, the second rotating rod 11 can slide on the outer walls of the bearing plates 8 with different shapes, so that the processing of the glass plate with different shapes can be realized, through the arrangement of the structure, glue can be accurately injected to the inner side edge of the two glass stacks, the phenomenon that the position of the sprayed glue is not ideal and the glue drops is avoided, thereby the waste of the glue is reduced, the pollution to the workbench is reduced, the gluing is more accurate, the problem that the two pieces of glass cannot be glued due to inaccurate gluing is avoided, and the processing quality is improved, and the processing of glass plates with different shapes can be realized, and the practicability of the device can be greatly improved.

As a further scheme of the present invention, a fixed block 29 capable of sliding left and right is slidably connected to the front wall of the second rotating rod 11, a scraper 30 is slidably connected to the top of the fixed block 29 in the vertical direction, a third return spring 31 is fixedly connected to the right side wall of the fixed block 29, and the right end of the third return spring 31 is fixedly connected to the front side wall of the second rotating rod 11; in operation, considering that when the second glass plate 22 moves downwards to be bonded with the first glass plate 10, the glue may be pressed to overflow from the first glass plate 10 and be bonded on the side wall of the first glass plate 10, and the glue may be solidified and not easy to clean after a long time, after the gluing is finished, the glue barrel 16 is closed to enable the gluing gun head 14 not to work, the driving mechanism drives the rotating ring 5 to rotate, the rotating ring 5 drives the first rotating rod 6 and the second rotating rod 11 to rotate, the second rotating rod 11 drives the fixed block 29 and the scraper 30 to synchronously rotate, the third air spring can play a buffering role on the scraper 30, the scraper 30 can be always attached to the side wall of the first glass plate 10, and the scraper 30 can scrape and clean glue overflowing from the side edge of the first glass plate 10, the problem that the glue overflowing out is solidified at the side edge of the first glass plate 10 to cause difficulty in cleaning can be avoided.

As a further scheme of the present invention, a material receiving tray 32 capable of sliding up and down is slidably connected to the left side wall of the fixed block 29, the material receiving tray 32 is located below the scraper 30, an inclined surface is arranged on the left side of the material receiving tray 32, and the material receiving tray 32 is located between the first glass plate 10 and the bearing plate 8; in the process of working, if the glue cleaned by the scraper 30 is not collected, the glue can drip on the device, and the device can be damaged due to long-term accumulation, so that the device can not work normally, in the production method of the architectural glass, the fixed block 29 can drive the material receiving disc 32 to move synchronously while moving, the material receiving disc 32 is positioned under the scraper 30, the glue scraped by the scraper 30 can flow into the material receiving disc 32 along the outer wall of the scraper 30, so that the glue can not fall on the gluing device, and the problem that the device can be damaged due to long-term accumulation is avoided.

As a further scheme of the invention, a rotating wheel 33 is rotatably connected to the left side wall of the second rotating rod 11; during operation, through the setting of swivel 33, can reduce the frictional force that receives when second bull stick 11 slides on bearing plate 8 outer wall, can make second bull stick 11 gliding more smooth and easy on bearing plate 8 outer wall.

As a further scheme of the invention, the driving mechanism comprises a first gear 34 fixedly connected on the outer wall of the rotating ring 5, the top of the bottom plate 1 is fixedly connected with a disc type motor 35, an output shaft of the disc type motor 35 is fixedly connected with a second gear 36, and the second gear 36 and the outer wall of the first gear 34 are jointly in transmission connection with a belt 37; when in work; the disc motor 35 drives the second gear 36 to rotate, the second gear 36 drives the first gear 34 to rotate through the belt 37, and the first gear 34 rotates to drive the rotating ring 5 to rotate, so that the effect of driving the gluing device is achieved.

The working principle is as follows: when the gluing device is used for gluing two pieces of superposed glass, the side edge of the superposed position of the two pieces of glass is glued, if glue on the side edge of the glass is not solidified in time in the gluing process, the glue can drip downwards, so that the two pieces of glass can not be adhered, and the gluing device can only be used for glass with one shape, so that the practicability of the gluing device is greatly limited; in the above method for producing architectural glass, the initial state of the device is that the top end of the first electric telescopic rod is not provided with the bearing plate 8, the first electric telescopic rod 7 is in a contracted state, when glass plates need to be bonded, firstly, the center of the bearing plate 8 is arranged at the top of the first electric telescopic rod 7, then, the first glass plate 10 and the second glass plate 22 are overlapped together and placed at the top of the first suction cup 9, the positions of the first glass plate 10 and the second glass plate 22 are overlapped with the bearing plate 8 in the up-down direction, so that the first suction cup 9 absorbs the first glass plate 10, then, the first electric telescopic rod 7 is started to drive the bearing plate 8, the first glass plate 10 and the second glass plate 22 to move upwards, when the second glass plate 22 is contacted with the second suction cup 21, the second suction cup 21 is driven by the first electric telescopic rod 7 to firmly absorb the second glass plate 22, the second electric telescopic rod 19 is started to drive the second rotary table 20 and the second glass plate 22 to move upwards, the second rotary table 20 can drive the third rotary rod 25 to move upwards synchronously while moving upwards, the third rotary rod 25 can drive the fourth rotary rod 28 to move upwards while rotating on the right side wall of the third rotary rod 25, the fourth rotary rod 28 can drive the gluing gun head 14 to slide in the second chute 13, when the gluing gun head 14 moves to be attached to the left side wall of the second chute 13, the second electric telescopic rod 19 is closed, the second glass plate 22 moves to a certain height at the moment, the gluing gun head 14 moves to the right side edge of the top of the first glass plate 10, the driving mechanism is started to drive the rotary ring 5 to rotate, the rotary ring 5 can drive the first rotary rod 6 to rotate around the first rotary shaft 2 in the first chute 4, the first rotary rod 6 can drive the second rotary rod 11 to slide on the outer wall of the bearing plate 8, when the second rotating rod 11 slides along the outer wall of the bearing plate 8, the second rotating rod 11 is subjected to a force from the outer wall of the bearing plate 8, the acting force can enable the second rotating rod 11 to slide on the first rotating rod 6 and simultaneously stretch the return spring, the second rotating rod 11 can be always attached to the outer wall of the bearing plate 8 under the elastic force of the return spring, the gluing gun head 14 can be stationary relative to the second rotating rod 11, the gluing gun head 14 can evenly glue the top edge of the first glass plate 10 when the first rotating rod 6 rotates, when the gluing gun head 14 rotates for one circle, the driving mechanism is closed after one circle of gluing is finished on the top edge of the first glass plate 10, the second disc type motor 35 is started to drive the second rotating disc 20 and the second glass plate 22 to move downwards, the second rotating disc 20 can drive the gluing gun head 14 to slide rightwards in the second chute 13 through the fourth rotating rod 28, and when the second glass plate 22 is in contact with glue on the first glass plate 10, the glue spraying gun head 14 moves to the outside of the right side wall of the first glass plate 10, at the moment, the second electric telescopic rod 19 continues to drive the second glass plate 22 to move downwards, so that the second glass plate 22 is fully attached to glue, the first glass plate 10 and the second glass plate 22 are bonded together under the action of the glue, the second electric telescopic rod 19 is started to drive the second rotary disc 20 and the second suction disc 21 to move upwards, meanwhile, a worker takes the second glass plate 22 off the second suction disc 21, so that the second glass plate 22 is separated from the second suction disc 21, then the first electric telescopic rod 7 is started to drive the bearing plate 8, the first suction disc 9 and the bonded first glass plate 10 and second glass plate 22 to move downwards, then the worker takes the bonded glass plate off the first suction disc 9, when glass plates with different shapes need to be processed, only one bearing plate 8 with the same shape as the glass plate is manufactured first, as shown in the schematic diagram of fig. 8, another shape that the bearing plate can implement is used for gluing circular glass, then the center position of the bearing plate 8 is installed at the top of the first electric telescopic rod 7, the glass plate is installed at the top of the first suction disc 9 and is firmly sucked, the center position of the glass plate must coincide with the center position of the bearing plate 8, the second rotating rod 11 can slide on the outer walls of the bearing plates 8 with different shapes, so that the processing of the glass plate with different shapes can be realized, through the arrangement of the structure, glue can be accurately injected to the inner side edge of the two glass stacks, the phenomenon that the position of the sprayed glue is not ideal and the glue drops is avoided, thereby the waste of the glue is reduced, the pollution to the workbench is reduced, the gluing is more accurate, the problem that the two pieces of glass cannot be glued due to inaccurate gluing is avoided, and the processing quality is improved, and the processing of glass plates with different shapes can be realized, and the practicability of the device can be greatly improved.

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

The preferred embodiments of the invention disclosed above are intended merely to assist in the explanation of the invention. The preferred embodiments are not exhaustive and do not limit the invention to the precise embodiments disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the invention and the practical application, to thereby enable others skilled in the art to best utilize the invention. The invention is limited only by the claims and their full scope and equivalents.

Claims

1. A production method of building glass, a gluing device suitable for the production method comprises a bottom plate (1), a driving mechanism is arranged on the top of the bottom plate (1), and the production method is characterized in that: the top of the bottom plate (1) is provided with a gluing device;

the gluing device comprises a first rotating shaft (2) fixedly connected with the top center of a bottom plate (1), a first rotating disc (3) is fixedly connected with the top of the first rotating shaft (2), a first sliding groove (4) is formed in the outer wall of the first rotating disc (3), a rotating ring (5) is rotatably connected to the outer wall of the first rotating shaft (2), a driving mechanism is used for driving the rotating ring (5) to rotate, a first rotating rod (6) is fixedly connected to the outer wall of the rotating ring (5), the first rotating rod (6) is in sliding connection with the inner wall of the first sliding groove (4), a first electric telescopic rod (7) is fixedly connected to the top center of the first rotating disc (3), the top end of the first electric telescopic rod (7) is connected with a bearing plate (8) through bolt threads, and four first suckers (9) distributed in a circumferential array are fixedly connected to the top of the bearing plate (8), the four first suckers (9) are connected with a first glass plate (10) in a sucking mode at the tops, the shape of the bearing plate (8) is the same as that of the first glass plate (10), the left side wall and the right side wall of the first rotating rod (6) are connected with a second rotating rod (11) in a sliding mode, the second rotating rod (11) is connected with the outer wall of the bearing plate (8) in a sliding mode, a first reset spring (12) is sleeved on the second rotating rod (11), the first reset spring (12) is located at the right end of the first rotating rod (6), the left end of the first reset spring (12) is fixedly connected with the right wall of the first rotating rod (6), the right end of the first reset spring (12) is fixedly connected with a limiting end on the right side of the second rotating rod (11), a second sliding groove (13) is formed in the top of the second rotating rod (11), a glue spraying gun head (14) is connected in the second sliding groove (13), and an upper rubber tube (15) is fixedly connected to the bottom of the glue spraying, the glue barrel (16) is connected to the top of the first rotary table (3) in a sliding manner, the glue barrel (16) is fixedly connected with the left side wall of the first rotary rod (6), the glue feeding pipe (15) is inserted into the glue barrel (16), the outer wall of the bottom plate (1) is fixedly connected with a connecting rod (17), the right side wall of the top of the connecting rod (17) is fixedly connected with a fixing plate (18), the bottom of the fixing plate (18) is fixedly connected with a second electric telescopic rod (19), the telescopic end of the second electric telescopic rod (19) is fixedly connected with a second rotary table (20), the bottom of the second rotary table (20) is fixedly connected with four second suction cups (21) distributed in a circumferential array manner, the bottom of each second suction cup (21) is fixedly connected with a second glass plate (22), the second glass plate (22) is the same as the first glass plate (10) in shape, and the second glass plate (22) is positioned right above the first glass plate, a third sliding groove (23) is formed in the top of the second rotating disc (20), a sliding block (24) is connected in the third sliding groove (23) in a sliding manner, a third rotating rod (25) is connected in the top of the second rotating disc (20) in a sliding manner, a fourth sliding groove (26) is formed in the third rotating rod (25), the sliding block (24) is located in the fourth sliding groove (26) and is connected with the fourth sliding groove (26) in a sliding manner, a second reset spring (27) is fixedly connected to the left side of the inner wall of the fourth sliding groove (26), the right end of the second reset spring (27) is fixedly connected with the outer wall of the sliding block (24), a fourth rotating rod (28) is rotatably connected to the right side wall of the third rotating rod (25), and the bottom end of the fourth rotating rod (28) is rotatably connected with the top of the glue spraying gun head;

the production method of the architectural glass comprises the following steps:

step 1: installing the center position of a bearing plate (8) on the top of a first electric telescopic rod (7), then overlapping a first glass plate (10) and a second glass plate (22) together and placing the first glass plate and the second glass plate on the top of a first sucker (9), enabling the positions of the first glass plate (10) and the second glass plate (22) to be overlapped with the bearing plate (8) in the vertical direction, enabling the first sucker (9) to firmly suck the first glass plate (10), then starting the first electric telescopic rod (7) to enable the first electric telescopic rod (7) to drive the bearing plate (8), the first glass plate (10) and the second glass plate (22) to move upwards, and enabling the second sucker (21) to firmly suck the second glass plate (22) under the pushing of the first electric telescopic rod (7) when the second glass plate (22) is in contact with the second sucker (21);

step 2: starting a second electric telescopic rod (19) to drive a second rotary table (20) and a second glass plate (22) to move upwards, wherein the second rotary table (20) can drive a third rotating rod (25) to move upwards synchronously, the third rotating rod (25) can drive a fourth rotating rod (28) to move upwards and rotate on the right side wall of the third rotating rod (25), the fourth rotating rod (28) can drive a gluing gun head (14) to slide in a second sliding chute (13), when the gluing gun head (14) moves to be attached to the left side wall of the second sliding chute (13), the second electric telescopic rod (19) is closed, at the moment, the second glass plate (22) moves to a certain height, and the gluing gun head (14) moves to the right side edge of the top of the first glass plate (10);

and step 3: starting the driving mechanism to drive the rotating ring (5) to rotate, the rotating ring (5) can drive the first rotating rod (6) to rotate around the first rotating shaft (2) in the first sliding chute (4), the first rotating rod (6) can drive the second rotating rod (11) to slide on the outer wall of the bearing plate (8), when the second rotating rod (11) slides along the outer wall of the bearing plate (8), the second rotary rod (11) is subjected to a force from the outer wall of the bearing plate (8), and the force causes the second rotary rod (11) to slide on the first rotary rod (6) and simultaneously stretch the return spring, the second rotating rod (11) can be always attached to the outer wall of the bearing plate (8) under the action of the elastic force of the return spring, the gluing gun head (14) can be in a static state relative to the second rotating rod (11), when the first rotating rod (6) rotates, the gluing gun head (14) can glue the top edge of the first glass plate (10) uniformly;

and 4, step 4: when the gluing gun head (14) rotates for one circle, and after one circle of gluing is finished on the top edge of the first glass plate (10), the driving mechanism is closed, the second disc type motor (35) is started to drive the second rotary disc (20) and the second glass plate (22) to move downwards, the second rotary disc (20) can drive the gluing gun head (14) to slide rightwards in the second sliding chute (13) through the fourth rotary rod (28), when the second glass plate (22) is contacted with glue on the first glass plate (10), the gluing gun head (14) moves to the outer part of the right side wall of the first glass plate (10), at the moment, the second electric telescopic rod (19) continues to drive the second glass plate (22) to move downwards, so that the second glass plate (22) is fully attached to the glue, and the first glass plate (10) and the second glass plate (22) are adhered together under the action of the glue;

and 5: start second electric telescopic handle (19) and make it drive second carousel (20) and second sucking disc (21) upward movement, the staff takes off second glass board (22) from second sucking disc (21) simultaneously, make second glass board (22) break away from down second sucking disc (21), then start first electric telescopic handle (7) and make it drive bearing plate (8), first sucking disc (9) and the first glass board (10) and the second glass board (22) downstream that have bonded, then the staff takes off the glass board that has bonded from first sucking disc (9).

2. The method for producing an architectural glass according to claim 1, wherein: but sliding connection has fixed block (29) of horizontal slip on second bull stick (11) antetheca, sliding connection has scraper blade (30) on the upper and lower direction at fixed block (29) top, fixedly connected with third reset spring (31) on fixed block (29) right side wall, lateral wall fixed connection before third reset spring (31) right-hand member and second bull stick (11).

3. The method for producing an architectural glass according to claim 2, wherein: the utility model discloses a glass plate, including fixed block (29), connecting plate (32), scraper blade (30), the connecting plate (32) that have slidable from top to bottom on the wall of fixed block (29) left side, connecting plate (32) left side is provided with inclined plane and connecting plate (32) and is located between first glass board (10) and bearing plate (8).

4. The method for producing an architectural glass according to claim 1, wherein: and a rotating wheel (33) is rotatably connected to the left side wall of the second rotating rod (11).

5. The method for producing an architectural glass according to claim 1, wherein: the driving mechanism comprises a first gear (34) fixedly connected to the outer wall of the rotating ring (5), a disc motor (35) is fixedly connected to the top of the bottom plate (1), a second gear (36) is fixedly connected to an output shaft of the disc motor (35), and a belt (37) is connected to the outer walls of the second gear (36) and the first gear (34) in a transmission mode.