CN117444779A - Grinding device for building glass processing - Google Patents

Abstract

The invention discloses a polishing device for building glass processing, which comprises a base station, wherein a glass turnover device is arranged at the top of the base station, a glass taking and placing device is connected to the glass turnover mechanism, the glass taking and placing device comprises a movement control mechanism and a glass taking and placing mechanism, an adjustable placing platform is arranged in front of the glass taking and placing device, and a glass polishing device is arranged above the adjustable placing platform. The invention belongs to the field of glass processing, and particularly relates to a polishing device for building glass processing; the invention solves the problems that in the prior art, the building glass needs to be manually lifted to turn over, so that the glass is easy to be knocked and scratched and the worker is easy to scratch in the carrying process.

Description

Grinding device for building glass processing

Technical Field

The invention belongs to the technical field of glass processing, and particularly relates to a polishing device for building glass processing.

Background

With the development of building technology, the traditional tall buildings are reinforced concrete buildings, and the existing buildings are provided with building glass to obtain better lighting effect and viewing effect; but building glass produces burr and overlap easily when processing, and glass surface and corner need the later stage to polish processing, at present when carrying out turn-over polishing, often still need the manual work to lift building glass and turn over, not only easily collide with and damage glass, still make the workman fish tail in the handling easily, consequently need one kind can polish and turn over building glass voluntarily, and can adapt to multiple size glass's grinding device.

Disclosure of Invention

Aiming at the situation, in order to overcome the defects of the prior art, the invention provides the polishing device for the building glass processing, which solves the problems that the building glass needs to be manually lifted to turn over, the glass is easy to be scratched and the worker is easy to scratch in the carrying process in the prior art.

The technical scheme adopted by the invention is as follows: the invention provides a polishing device for building glass processing, which comprises a base station, wherein a glass turnover device is arranged at the top of the base station, a glass taking and placing device is connected to the glass turnover mechanism, the glass taking and placing device comprises a movement control mechanism and a glass taking and placing mechanism, an adjustable placing platform is arranged in front of the glass taking and placing device, a glass polishing device is arranged above the adjustable placing platform, convex sliding grooves I are symmetrically arranged on two sides of the base station, rectangular sliding grooves are arranged above the convex sliding grooves, and a moving sliding groove is further arranged at the top of the base station.

Further, glass turning device includes hollow rectangle post, movable block, U-shaped frame one, dog, triangular block, rotation post, fixed column, V-arrangement piece, rectangle piece, fixed handle, crank, spacing post, spring, backup pad, motor one, gear one, rack, C shape steel one and slider, the base top is located to hollow rectangle post, be equipped with rectangular opening on the hollow rectangle post, the movable block is located in the hollow rectangle post, U-shaped frame one is located on the movable block, dog symmetry locates U-shaped frame one top, the triangular block is located on the U-shaped frame one, C shape steel one is located behind the hollow rectangle post and is connected with the base, the slider is located in the C shape steel one, the rack is located on the C shape steel one, the side of slider is located to the rectangular block, the rectangle piece runs through rectangle piece and rectangular block joint rotation and is connected, the V-shaped piece is located on the rotation post, V shape piece and rotation post fixed connection, the fixed column symmetry is located on the hollow rectangle post, the U-shaped frame one is located on the crank fixed end, the crank is located at the bottom of the fixed connection of the fixed spring, one is located at the crank and the fixed support plate, the fixed spring one is located between the fixed support plate, the fixed support plate and the fixed support plate is located at the crank, the fixed support plate is located at the bottom of the crank.

Further, the mobile control mechanism comprises a stand column, a second convex sliding groove, a first convex block, a first screw rod, a second motor and a second U-shaped frame, wherein the stand column is fixedly arranged at the front end of the rotating column, the second convex sliding groove is arranged on the stand column, the second U-shaped frame is arranged on the end face of the stand column, the second motor is arranged on the second U-shaped frame, the first screw rod is arranged in the second convex sliding groove, one end of the first screw rod is rotationally connected with the stand column in a clamping manner, the other end of the first screw rod penetrates through the stand column and is fixedly connected with the driving end of the second motor, and the first screw rod is symmetrically arranged on the first screw rod.

Further, the glass placing and taking mechanism comprises a C-shaped steel II, a fixed plate, a U-shaped frame III, a rotating rod I, a bevel gear II, a screw rod II, a knob, a convex column, an L-shaped plate, a motor III, a belt clamping ring I, a belt clamping ring II, a conveying belt, a right angle plate, a gear II, a gear III, a rotating rod II, a rotating rod III, a placing plate, a reinforcing plate, a rectangular plate, a solid rectangular column, a vacuum chuck and a vacuum generator, wherein the C-shaped steel II is arranged on the convex block, the fixed plate is arranged at the bottom of the C-shaped steel II, the U-shaped frame III is arranged at the bottom of the fixed plate, the rotating rod I is arranged at one end of the rotating rod I and penetrates through the U-shaped frame III and is in rotary connection with the U-shaped frame III, the knob is arranged at the other end of the transmission rod, the convex column is arranged in the C-shaped steel II, a threaded hole is arranged in the convex column, the screw rod II penetrates through the fixed plate and is in threaded connection with the threaded hole, the bottom of the screw rod II is arranged at the reinforcing plate II is meshed with the bevel gear I, the L-shaped plate is symmetrically arranged on the convex column, the L-shaped plate is arranged on the rectangular plate, the solid plate is arranged on the end face, the reinforcing plate is arranged on the rectangular plate, the motor L-shaped plate is arranged on the rectangular plate, the triangular plate is arranged on the side and the three-shaped plate, the three-shaped clamping plates are arranged on the side, the three-shaped plate B, the three-shaped clamping plate is arranged and the side is symmetrically, the rotating plate III is arranged on the side and the rotating plate B, the T-shaped plate B is arranged, the T-shaped B side and the T square plate, the T square plate B has the T square plate and the T square plate. The vacuum sucker linear array is arranged on the solid rectangular column, and the vacuum generator is arranged on the solid rectangular column.

Further, adjustable place the platform and including vacuum adsorption platform, support column, sliding plate, lead screw III and commentaries on classics handle, the support column is located on the base station with removal spout as central symmetry, vacuum adsorption platform locates the support column top, the sliding plate locate in the removal spout with vacuum adsorption platform bottom fixed connection, lead screw III runs through the sliding plate locate between two support columns with the support column block rotate to be connected, it locates on the lead screw III to changeing the handle.

Further, glass grinding device includes portal frame, motor IV, motor V, places the platform, lead screw IV, electric putter, sliding block, motor V, runner, square and polishing piece, the portal frame sets up in the base station both sides, the portal frame top is equipped with long opening, the portal frame bottom symmetry is equipped with short opening, place the platform and locate the portal frame side, the motor V is located and is placed on the platform, lead screw IV locates in the long opening, lead screw IV one end and portal frame block rotation are connected, lead screw IV other end runs through the portal frame and is connected with motor V's driving end, the sliding block is located on the lead screw IV, electric putter locates the sliding block bottom, electric putter's expansion end is located to the motor V's driving end, motor V is located in the short opening, the runner is located in the convex spout I, the runner links to each other with motor V's driving end, square is located in the rectangle spout and is linked to each other with the portal frame.

Further, the screw threads on the first screw rod and the third screw rod are formed by two sections of screw threads with opposite directions, and the vacuum chuck is connected with the vacuum generator.

Further, the length and the width of the rectangular notch are slightly larger than the diameter of the second belt clamping ring.

Further, the first motor, the second motor, the third motor, the fourth motor and the fifth motor are reversible motors capable of changing the rotation direction, and the vacuum generator is of the model VK-M10K-D of BOHE.

The beneficial effects obtained by the invention by adopting the structure are as follows:

(1) The glass overturning device can automatically overturn glass, and can drive the glass on the glass taking and placing device to lift and overturn only by controlling the motor, so that the operation is simple and convenient, the manual overturning operation of the glass by workers is not needed, and the scratch caused by the workers in the process of overturning the glass is effectively avoided;

(2) The glass taking and placing device can adjust the position of the vacuum chuck according to the size of glass by controlling the movement control mechanism and the glass placing and placing mechanism, so that better stress absorption is carried out on the glass, and the applicable size of the device to the glass is increased;

(3) The adjustable placing platform can be adjusted according to the size of glass, so that the glass is better stressed and supported, the platform can be adjusted in position only by twisting the rotating handle, and meanwhile, the placed glass can be adsorbed and fixed by the vacuum adsorption platform, so that glass displacement and deviation in the polishing process are effectively prevented.

Drawings

FIG. 1 is a perspective view of a polishing device for processing architectural glass according to the present invention;

FIG. 2 is a perspective view of a glass turning device of the polishing device for building glass processing according to the present invention;

FIG. 3 is a rear view of a glass turning device of the polishing device for architectural glass processing according to the present invention;

FIG. 4 is a top perspective view of a glass turning device of a polishing device for architectural glass processing according to the present invention;

FIG. 5 is a cross-sectional view of a triangular block of a polishing apparatus for architectural glass processing according to the present invention;

FIG. 6 is a perspective view of a glass pick-and-place device of the polishing device for architectural glass processing according to the present invention;

FIG. 7 is a perspective view showing the internal structure of a glass taking mechanism of a polishing device for architectural glass processing according to the present invention;

FIG. 8 is a cross-sectional view of a male block of a glass handling device of a polishing device for architectural glass processing in accordance with the present invention;

FIG. 9 is a perspective view of a glass polishing device of the polishing device for architectural glass processing according to the present invention;

fig. 10 is a sectional view of a polishing device for architectural glass processing at a slider according to the present invention.

Wherein 1, a base, 2, a glass turning device, 3, a glass taking and placing device, 4, a moving control mechanism, 5, a glass taking and placing mechanism, 6, an adjustable placing platform, 7, a glass polishing device, 8, a first convex chute, 9, a rectangular chute, 10, a moving chute, 11, a hollow rectangular column, 12, a moving block, 13, a first U-shaped frame, 14, a stop block, 15, a triangular block, 16, a rotating column, 17, a fixed column, 18, a V-shaped block, 19, a rectangular block, 20, a fixed handle, 21, a crank, 22, a limit column, 23, a spring, 24, a support plate, 25, a first motor, 26, a first gear, 27, a rack, 28, a first C-shaped steel, 29, a slide block, 30, a column, 31, a second convex chute, 32, a convex block, 33, a lead screw, 34, a second motor, 35, a second U-shaped frame, 36, a second C-shaped steel, 37, a fixed plate, 38, a third U-shaped frame, 39, first rotating rod, 40, first bevel gear, 41, second bevel gear, 42, second screw rod, 43, knob, 44, male post, 45, L-shaped plate, 46, third motor, 47, first belt clip, 48, second belt clip, 49, conveyor belt, 50, right angle plate, 51, second gear, 52, third gear, 53, second rotating rod, 54, third rotating rod, 55, placement plate, 56, reinforcing plate, 57, threaded hole, 58, rectangular plate, 59, solid rectangular columns, 60, vacuum chucks, 61, a vacuum generator, 62, rectangular notches, 63, a vacuum adsorption platform, 64, support columns, 65, sliding plates, 66, screw rods III, 67, rotating handles, 68, a portal frame, 69, four motors 70, five motors 71, a placing table 72, four screw rods 73, electric push rods 74, sliding blocks 75, six motors 76, rotating wheels 77, square blocks 78, polishing sheets 79, long opening, 80, short opening.

The accompanying drawings are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate the invention and together with the embodiments of the invention, serve to explain the invention.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all embodiments of the invention; all other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

In the description of the present invention, it should be understood that the terms "upper," "lower," "front," "rear," "left," "right," "top," "bottom," "inner," "outer," and the like indicate orientation or positional relationships based on those shown in the drawings, merely to facilitate description of the invention and simplify the description, and do not indicate or imply that the devices or elements referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be construed as limiting the invention.

As shown in fig. 1, the polishing device for building glass processing provided by the invention comprises a base 1, wherein a glass turnover device 2 is arranged at the top of the base 1, a glass taking and placing device 3 is connected to the glass turnover mechanism, the glass taking and placing device 3 comprises a movement control mechanism 4 and a glass placing and placing mechanism 5, an adjustable placing platform 6 is arranged in front of the glass taking and placing device 3, a glass polishing device 7 is arranged above the adjustable placing platform 6, convex sliding grooves 8 are symmetrically arranged on two sides of the base 1, a rectangular sliding groove 9 is arranged above the convex sliding grooves, and a movable sliding groove 10 is also arranged at the top of the base 1.

As shown in fig. 1, fig. 2, fig. 3, fig. 4 and fig. 5, the glass turning device 2 comprises a hollow rectangular column 11, a moving block 12, a U-shaped frame one 13, a stop block 14, a triangular block 15, a rotating column 16, a fixed column 17, a V-shaped block 18, a rectangular block 19, a fixed handle 20, a crank 21, a limit column 22, a spring 23, a support plate 24, a motor one 25, a gear one 26, a rack 27, a C-shaped steel one 28 and a sliding block 29, wherein the hollow rectangular column 11 is arranged at the top of the base 1, a rectangular opening is arranged on the hollow rectangular column 11, the moving block 12 is arranged in the hollow rectangular column 11, the U-shaped frame one 13 is arranged on the moving block 12, the stop block 14 is symmetrically arranged at the top of the U-shaped frame one 13, the triangular block 15 is arranged on the U-shaped frame one 13, the C-shaped steel one 28 is arranged at the back of the hollow rectangular column 11 and is connected with the base 1, the sliding block 29 is arranged in the C-shaped steel one 28, the rack 27 is arranged on the C-shaped steel one 28, the rectangular block 19 is arranged on the side surface of the C-shaped steel one 29, the rectangular block 19 is arranged on the side of the sliding block 29, the rectangular block 16 is arranged on the crank 16, the crank 16 penetrates the rectangular block 19 and the crank 19, the crank 19 is arranged at the other end of the fixed handle 23 and is in the fixed support plate 23, the fixed handle 23 is in the fixed connection with the fixed support plate, the fixed support plate 23, the fixed support plate and the fixed support plate 23 is arranged at the fixed support plate, the fixed support plate and the fixed support plate 23 is arranged at the end.

As shown in fig. 1, 6 and 8, the movement control mechanism 4 includes a column 30, a second convex chute 31, a convex block 32, a first screw rod 33, a second motor 34 and a second U-shaped frame 35, the column 30 is fixedly arranged at the front end of the rotating column 16, the column 30 is provided with the second convex chute 31, the second U-shaped frame 35 is arranged on the end surface of the column 30, the second motor 34 is arranged on the second U-shaped frame 35, the first screw rod 33 is arranged in the second convex chute 31, one end of the first screw rod 33 is rotationally connected with the column 30 in a clamping manner, the other end of the first screw rod 33 penetrates through the driving end of the column 30 and the second motor 34 to be fixedly connected, and the convex block 32 is symmetrically arranged on the first screw rod 33.

As shown in fig. 1, 6, 7 and 8, the glass placing and taking mechanism 5 comprises a second C-shaped steel 36, a fixing plate 37, a third U-shaped frame 38, a first rotating rod 39, a first bevel gear 40, a second bevel gear 41, a second screw rod 42, a knob 43, a convex column 44, an L-shaped plate 45, a third motor 46, a first belt clamping ring 47, a second belt clamping ring 48, a conveying belt 49, a right angle plate 50, a second gear 51, a third gear 52, a second rotating rod 53, a third rotating rod 54, a placing plate 55, a reinforcing plate 56, a rectangular plate 58, a solid rectangular column 59, a vacuum chuck 60 and a vacuum generator 61, wherein the second C-shaped steel 36 is arranged on the convex block 32, the fixing plate 37 is arranged at the bottom of the second C-shaped steel 36, the third U-shaped frame 38 is arranged at the bottom of the fixing plate 37, the first rotating rod 39 penetrates through one side of the third U-shaped frame 38 to be in clamping and rotating connection with the third U-shaped frame 38, the first bevel gear 40 is arranged at one end of the first bevel gear 39, the knob 43 is arranged at the other end of the transmission rod, the convex column 44 is arranged in the C-shaped steel II 36, the convex column 44 is internally provided with a threaded hole 57, the screw rod II 42 penetrates through the fixing plate 37 and is in threaded connection with the threaded hole 57, the bevel gear II 41 is arranged at the bottom of the screw rod II 42 and is meshed with the bevel gear I40, the L-shaped plate 45 is symmetrically arranged on the convex column 44, the placing plate 55 is arranged on the end face of the L-shaped plate 45, the reinforcing plate 56 is obliquely arranged between the placing plate 55 and the convex column 44, the motor III 46 is arranged on the L-shaped plate 45, the belt clamping ring I47 is arranged on the transmission shaft of the motor III 46, the right angle plates 50 are symmetrically arranged at the top of the convex column 44, the rotating rod II 53 and the rotating rod III 54 are sequentially arranged between the two right angle plates 50, the gear II 51 is arranged on the rotating rod II 53, the belt clamping ring II 48 is symmetrically arranged on two sides of the gear II 51, the conveying belt 49 is sleeved on the first belt clamping ring 47 and the second belt clamping ring 48, the third gear 52 is arranged on the third rotating rod 54, the rectangular plates 58 are symmetrically arranged on two sides of the third gear 52, rectangular notches 62 are formed in the rectangular plates 58, the solid rectangular columns 59 are arranged on the end faces of the two rectangular plates 58, the linear array of the vacuum sucking discs 60 is arranged on the solid rectangular columns 59, and the vacuum generator 61 is arranged on the solid rectangular columns 59.

As shown in fig. 1, the adjustable placement platform 6 includes a vacuum adsorption platform 63, a support column 64, a sliding plate 65, a third screw 66 and a rotating handle 67, the support column 64 is symmetrically arranged on the base 1 by taking the movable chute 10 as a center, the vacuum adsorption platform 63 is arranged at the top of the support column 64, the sliding plate 65 is arranged in the movable chute 10 and fixedly connected with the bottom of the vacuum adsorption platform 63, the third screw 66 penetrates through the sliding plate 65 and is arranged between the two support columns 64 and is rotationally connected with the support column 64 in a clamping manner, and the rotating handle 67 is arranged on the third screw 66.

As shown in fig. 1, 9 and 10, the glass polishing device 7 includes a gantry 68, a motor four 69, a motor five 70, a placing table 71, a screw four 72, an electric push rod 73, a sliding block 74, a motor six 75, a rotating wheel 76, a square 77 and polishing sheets 78, wherein the gantry 68 is erected on two sides of the base table 1, a long opening 79 is formed in the top of the gantry 68, short openings 80 are symmetrically formed in the bottom of the gantry 68, the placing table 71 is arranged on the side surface of the gantry 68, the motor four 69 is arranged on the placing table 71, the screw four 72 is arranged in the long opening 79, one end of the screw four 72 is in clamping rotation connection with the gantry 68, the other end of the screw four 72 penetrates through the driving end of the gantry 68 and is connected with the motor four 69, the sliding block 74 is arranged on the screw four 72, the electric push rod 73 is arranged at the bottom of the sliding block 74, the motor five 70 is arranged at the driving end of the electric push rod 73, the polishing sheets 78 are arranged at the driving end of the motor five 70, the motor six is arranged in the short opening 80, the motor 76 is arranged in the square chute 8, the rotating wheel six ends are connected with the rotating wheel 77, and the driving end of the rotating wheel 75 is connected with the square 75, and the driving end is arranged in the rectangular chute 68.

When the glass polishing machine is specifically used, firstly, the position of the vacuum adsorption platform 63 is adjusted according to the size of glass, the rotating handle 67 is rotated, the rotating handle 67 drives the screw rod III 66 to rotate, the screw rod III 66 drives the sliding plates 65 on two sides to jointly move towards the middle, namely, the vacuum adsorption platform 63 is driven to move towards the middle, if the glass polishing machine needs to be reversely adjusted, the rotating handle 67 is only required to be reversely rotated, then the glass is placed on the vacuum adsorption platform 63, the edge of the glass is required to be completely placed on the vacuum adsorption platform 63, and then the vacuum adsorption platform 63 is started to fix the glass, so that polishing of the first surface of the glass can be performed; the transverse and longitudinal positions of the motor five 70 can be adjusted by controlling the motor six 75 and the motor four 69, namely, the transverse and longitudinal positions of the polishing sheet 78 are adjusted, the motor six 75 is started, the motor six 75 drives the rotating wheel 76 to rotate, the rotating wheel 76 drives the portal frame 68 to integrally move longitudinally, after the longitudinal position of the polishing sheet 78 is adjusted, the electric push rod 73 is started, the electric push rod 73 drives the motor five 70 and the polishing sheet 78 to move downwards until the polishing sheet 78 is attached to the glass surface, the motor four 69 and the motor five 70 are started again, the motor four 69 drives the screw four 72 to rotate, the screw four 72 drives the sliding block 74 to move, the sliding block 74 drives the electric push rod 73, the motor five 70 and the polishing sheet 78 to transversely move, the motor five 70 drives the polishing sheet 78 to rotate, the glass surface can be transversely polished, and after the first surface of the glass is polished, the glass turnover device 2 and the glass taking and placing device 3 are controlled to turn over the glass, and then the second surface is polished.

Firstly, temporarily closing a vacuum adsorption platform 63, adjusting the transverse and longitudinal positions of a vacuum chuck 60, rotating a knob 43 to adjust the longitudinal position of the vacuum chuck 60, driving a rotary rod one 39 to rotate by the knob 43, driving a bevel gear one 40 to rotate by the rotary rod one 39, driving a bevel gear two 41 and a screw rod two 42 to rotate by the bevel gear one 40, driving a convex column 44 to longitudinally move by the screw rod two 42, driving a solid rectangular column 59 and the vacuum chuck 60 to longitudinally adjust by the convex column 44 through a rectangular plate 58, starting a motor two 34 after the adjustment to a proper longitudinal position, adjusting the transverse position of the vacuum chuck 60, driving a screw rod one 33 to jointly move by the screw rod one 33, driving the two convex blocks 32 to move towards the middle by the whole glass releasing mechanism 5 to move towards the middle, namely adjusting the transverse position of the vacuum chuck 60, and taking care that the transverse positions of the two glass releasing mechanisms 5 need to be completely arranged between the two vacuum adsorption platforms 63, and grabbing and overturning glass after the adjustment; the third motor 46 is started, the third motor 46 drives the first belt clamping ring 47 to rotate, the first belt clamping ring 47 drives the second belt clamping ring 48 to rotate through the conveying belt 49, the second belt clamping ring 48 drives the second rotating rod 53 and the second gear 51 to rotate, the second gear 51 drives the third gear 52 and the third rotating rod 54 to rotate, the third rotating rod 54 drives the rectangular plate 58 to rotate until the rectangular plate 58 is horizontally arranged on the placing plate 55, the vacuum chuck 60 is vertically arranged above the glass, the first motor 25 is started again, the first motor 25 drives the first gear 26 to rotate, the first gear 26 drives the sliding block 29 and the rectangular block 19 to move downwards, the rectangular block 19 drives the whole glass picking and placing device 3 to move downwards through the rotating column 16 until the vacuum chuck 60 is attached to the glass surface, the third motor 46 is closed, the vacuum generator 61 is started, the vacuum chuck 60 is enabled to absorb the glass tightly, the third motor 46 is started again, the third motor 46 is enabled to rotate reversely, the first gear 26 drives the slide block 29 and the rectangular block 19 to move upwards, the rectangular block 19 drives the whole glass taking and placing device 3 to move upwards through the rotating column 16 until the fixed column 17 abuts against the stop block 14, the fixed column 17 drives the rotating column 16 to rotate clockwise under the potential energy of the continuous upward movement of the rectangular block 19, the rotating column 16 drives the V-shaped block 18 and the crank 21 to rotate, when the rotating angle of the crank 21 exceeds ninety degrees, the crank 21 rotates from the limit column 22 on the right side to the limit column 22 on the left side under the action of the tension of the spring 23, namely, the rotating column 16 is driven to rotate one hundred eighty degrees, namely, the whole glass taking and placing device 3 is driven to rotate one hundred eighty degrees to finish the overturning of glass, the first motor 25 is controlled to rotate reversely, the first gear 26 drives the slide block 29 and the rectangular block 19 to move downwards, the rectangular block 19 drives the whole glass taking and placing device 3 to move downwards through the rotating column 16, and (3) until the glass is placed on the vacuum adsorption platform 63, closing the vacuum generator 61, opening the vacuum adsorption platform 63, polishing the surface of the glass as described above, polishing the two sides of the glass, closing the vacuum adsorption platform 63 after polishing, taking down the glass, and resetting the device.

It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

The invention and its embodiments have been described above with no limitation, and the actual construction is not limited to the embodiments of the invention as shown in the drawings. In summary, if one of ordinary skill in the art is informed by this disclosure, a structural manner and an embodiment similar to the technical solution should not be creatively devised without departing from the gist of the present invention.

Claims (9)

1. Polishing device for building glass processing, including base station (1), its characterized in that: the top of base station (1) is equipped with glass turning device (2), be connected with glass on glass turning device (2) and get put device (3), glass gets put device (3) and gets mechanism (5) including removal control mechanism (4) and glass, the place ahead that glass got put device (3) is equipped with adjustable place table (6), the top of adjustable place table (6) is equipped with glass grinding device (7), the bilateral symmetry of base station (1) is equipped with convex spout one (8), the top of convex spout one (8) is equipped with rectangle spout (9), the top of base station (1) still is equipped with removal spout (10).

2. A polishing device for architectural glass processing according to claim 1, wherein: the glass turning device (2) comprises a hollow rectangular column (11), a moving block (12), a U-shaped frame I (13), a stop block (14), a triangular block (15), a rotating column (16), a fixed column (17), a V-shaped block (18), a rectangular block (19), a fixed handle (20), a crank (21), a limit column (22), a spring (23), a support plate (24), a motor I (25), a gear I (26), a rack (27), a C-shaped steel I (28) and a sliding block (29), wherein the hollow rectangular column (11) is arranged at the top of the base station (1), a rectangular opening is formed in the hollow rectangular column (11), the moving block (12) is arranged in the hollow rectangular column (11), the U-shaped frame I (13) is arranged on the moving block (12), the stop block (14) is symmetrically arranged at the top of the U-shaped frame I (13), the triangular block (15) is arranged on the U-shaped frame I (13), the C-shaped steel I (28) is arranged at the rear of the hollow rectangular column (11) and is connected with the base station (1), the C-shaped steel I (28) is arranged in the rectangular block (29) and is arranged on the side surface of the rectangular block (29), the utility model provides a rotary column (16) runs through rectangle piece (19) and rectangle piece (19) block rotation connection, on rotating column (16) is located to V-arrangement piece (18), V-arrangement piece (18) and rotation column (16) fixed connection, on V-arrangement piece (18) is located to fixed column (17) symmetry, the rear end of rotating column (16) is located to crank (21) is fixed, the bottom of rectangle piece (19) is located to fixed handle (20), between crank (21) and fixed handle (20) is located to spring (23), the one end and the fixed handle (20) rotation of spring (23) are connected, the other end and crank (21) fixed connection of spring (23), crank (21) both sides are located to spacing post (22) symmetry, rectangular piece (19) top is located to backup pad (24), the driving end and rack (27) meshing of motor one (25) are located to gear one (26).

3. A polishing device for architectural glass processing according to claim 2, wherein: the movable control mechanism (4) comprises a stand column (30), a convex block (32), a first screw rod (33), a second motor (34) and a second U-shaped frame (35), wherein the stand column (30) is fixedly arranged at the front end of the rotary column (16), a second convex chute (31) is arranged on the stand column (30), the second U-shaped frame (35) is arranged on the end face of the stand column (30), the second motor (34) is arranged on the second U-shaped frame (35), the first screw rod (33) is arranged in the second convex chute (31), one end of the first screw rod (33) is rotationally connected with the stand column (30) in a clamping mode, the other end of the first screw rod (33) penetrates through the stand column (30) and is fixedly connected with the transmission end of the second motor (34), and the first screw rod (33) is symmetrically arranged on the first screw rod (32).

4. A polishing apparatus for architectural glass processing according to claim 3, wherein: the glass placing and taking mechanism (5) comprises a C-shaped steel II (36), a fixed plate (37), a U-shaped frame III (38), a rotating rod I (39), a bevel gear I (40), a bevel gear II (41), a screw rod II (42), a knob (43), a convex column (44), an L-shaped plate (45), a motor III (46), a belt clamping ring I (47), a belt clamping ring II (48), a conveying belt (49), a right angle plate (50), a gear II (51), a gear III (52), a rotating rod II (53), a rotating rod III (54), a placing plate (55), a reinforcing plate (56), a rectangular plate (58), a solid rectangular column (59), a vacuum chuck (60) and a vacuum generator (61), wherein the C-shaped steel II (36) is arranged on a convex block (32), the fixed plate (37) is arranged at the bottom of the C-shaped steel II (36), the U-shaped frame III (38) is arranged at the bottom of the fixed plate (37), one side of the rotating rod I (39) penetrating through the U-shaped frame III (38) is in a clamping connection with the U-shaped frame III (38), the rotating rod I (40) is arranged at one end of the rotating rod II (43) and the other end of the rotating rod II (43) is arranged in the convex column, screw holes (57) are formed in the convex columns (44), the screw rod II (42) penetrates through the fixing plate (37) and is in threaded connection with the screw holes (57), the bevel gears II (41) are arranged at the bottoms of the screw rod II (42) and are meshed with the bevel gears I (40), the L-shaped plates (45) are symmetrically arranged on the convex columns (44), the placing plate (55) is arranged on the end faces of the L-shaped plates (45), the reinforcing plate (56) is obliquely arranged between the placing plate (55) and the convex columns (44), the motor III (46) is arranged on the L-shaped plates (45), the belt clamping ring I (47) is arranged on a transmission shaft of the motor III (46), the rectangular plates (50) are symmetrically arranged at the tops of the convex columns (44), the rotating rods II (53) and the rotating rods III (54) are sequentially arranged between the two rectangular plates (50), the gears II (51) are symmetrically arranged on the rotating rods II (53), the two sides of the gears II (51), the conveying belt (49) are sleeved on the belt II (47) and the rotating rods (48), the rectangular plates (52) are symmetrically arranged on the two sides of the rotating rods (52), the solid rectangular columns (59) are arranged on the end faces of the two rectangular plates (58), the vacuum chucks (60) are arranged on the solid rectangular columns (59) in a linear array mode, and the vacuum generators (61) are arranged on the solid rectangular columns (59).

5. The polishing device for architectural glass processing according to claim 4, wherein: the glass polishing device (7) comprises a portal frame (68), a motor IV (69), a motor V (70), a placing table (71), a screw rod IV (72), an electric push rod (73), a sliding block (74), a motor V (75), a rotating wheel (76), a square block (77) and polishing sheets (78), wherein the portal frame (68) is erected on two sides of a base table (1), a long opening (79) is formed in the top of the portal frame (68), short openings (80) are symmetrically formed in the bottom of the portal frame (68), the placing table (71) is arranged on the side surface of the portal frame (68), the motor IV (69) is arranged on the placing table (71), the screw rod IV (72) is arranged in the long opening (79), one end of the screw rod IV (72) is rotationally connected with the driving end of the portal frame (68), the other end of the screw rod IV (72) penetrates through the portal frame (68) to be connected with the driving end of the motor IV (69), the sliding block (74) is arranged on the screw rod IV (72), the electric push rod (73) is arranged at the bottom of the sliding block (74), the motor V (70) is arranged at the driving end of the motor V (70), the motor V (70) is arranged in the driving end of the motor V (78), the rotating wheel (76) is arranged in the first convex chute (8), the rotating wheel (76) is connected with the transmission end of the motor six (75), and the square block (77) is arranged in the rectangular chute (9) and connected with the portal frame (68).

6. The polishing device for architectural glass processing according to claim 5, wherein: the adjustable placing platform (6) comprises a vacuum adsorption platform (63), support columns (64), sliding plates (65), three screw rods (66) and a rotating handle (67), wherein the support columns (64) are symmetrically arranged on the base station (1) by taking a movable sliding chute (10) as a center, the vacuum adsorption platform (63) is arranged at the top of the support columns (64), the sliding plates (65) are arranged in the movable sliding chute (10) and fixedly connected with the bottom of the vacuum adsorption platform (63), the three screw rods (66) penetrate through the sliding plates (65) and are arranged between the two support columns (64) to be rotationally connected with the support columns (64) in a clamping mode, and the rotating handle (67) is arranged on the three screw rods (66).

7. The polishing device for architectural glass processing according to claim 6, wherein: the screw threads on the screw rod I (33) and the screw rod III (66) are formed by two sections of screw threads with opposite directions.

8. The polishing device for architectural glass processing according to claim 7, wherein: the vacuum chuck (60) is connected with a vacuum generator (61).

9. The polishing device for architectural glass processing according to claim 8, wherein: the length and width of the rectangular notch (62) are slightly larger than the diameter of the second belt clamping ring (48).