CN111186993A

CN111186993A - Stable processing equipment of dysmorphism electronic glass

Info

Publication number: CN111186993A
Application number: CN202010088901.6A
Authority: CN
Inventors: 逯九利
Original assignee: Xian Aeronautical University
Current assignee: Pinghu Huarui Glass Co ltd
Priority date: 2020-02-12
Filing date: 2020-02-12
Publication date: 2020-05-22
Anticipated expiration: 2040-02-12
Also published as: CN111186993B

Abstract

The utility model provides a processing equipment is stabilized to dysmorphism electronic glass, the on-line screen storage device comprises a base, the rear side of two workstations that distribute about the middle part fixed connection of base front side, the front side of workstation is in the coplanar, the periphery of the left side of the workstation of upside and right side difference fixed connection annular slab, third helical gear and the cooperation of second helical gear meshing, fixed mounting suction head in the lower extreme of L type pipe respectively, the right side and the left side of base front side are equipped with respectively waits to process glass piece strorage device, the top side fixed mounting vertical axis drive arrangement of the workstation of upside, the preformed hole difference fixed connection fan's of fixed pipe periphery one side air intake. The glass sheet feeding device is simple in structure and ingenious in conception, adopts a pure mechanical structure, realizes automatic feeding and rotary discharging of glass sheets, can reduce the labor intensity of operators, reduces the manufacturing and using cost of equipment, is convenient to maintain, has high reliability, can meet market demands, and is suitable for popularization.

Description

Stable processing equipment of dysmorphism electronic glass

Technical Field

The invention belongs to the field of glass processing machinery, and particularly relates to stable processing equipment for special-shaped electronic glass.

Background

The shaped glass cutting machine is one of numerical control machine tools, and is named as: the glass engraving machine, the glass perforating machine, the glass edge grinding machine, the special-shaped glass cutting machine, the glass grooving machine and the precision glass forming machine are mainly applied to the fine processing and special-shaped cutting of various ultrathin glasses, and the technology is mature; because the development and the demand in future electronic consumer market, more digital electronic display screen have adopted glass to be display screen or touch-sensitive screen, the market of glass cnc engraving and milling machine is also more and more huge, current glass processing machinery generally adopts artificial mode to carry out material loading and unloading, waste time and energy, inefficiency, and there is the risk of being accidentally injured by the emery wheel, more advanced processing equipment is equipped with the multiaxis arm and goes up unloading, but multiaxis arm structure is complicated, manufacturing and use cost are higher, the multiaxis arm adopts a large amount of electronic control software, damaged, the reliability is poor, and cost of maintenance is higher, can't popularize, I invented a stable processing equipment of special-shaped electronic glass.

Disclosure of Invention

The invention provides a stable processing device for special-shaped electronic glass, which is used for overcoming the defects in the prior art.

The invention is realized by the following technical scheme:

the utility model provides a stable processing equipment of dysmorphism electronic glass, the on-line screen storage device comprises a base, the middle part fixed connection of base front side is the rear side of two workstations that distribute from top to bottom, the front side of workstation is in the coplanar, the left side of the workstation of upside and the periphery of right side difference fixed connection annular plate, the bottom side of annular plate difference fixed connection coaxial fixed tube's upper end, rotate the upper end of connecting the rotating tube periphery through sealed bearing respectively in the lower extreme of fixed tube, rotate through sealed bearing respectively in the annular plate and install the vertical axis, the lower extreme of vertical axis respectively with the bottom fixed connection of rotating tube, the left end of violently managing the periphery respectively fixed connection in the preformed hole on rotating tube right side, the interior horizontal tube rotates respectively and installs the cross axle, the lower extreme of vertical axis rear side is equipped with first semicircle helical gear respectively, the vertical axis front side is located the top of first semicircle helical gear and is equipped with the second, The second semicircular helical gears are respectively and fixedly connected with the annular plate, the axis of the circle of the first semicircular helical gear and the axis of the circle of the second semicircular helical gear are respectively collinear with the central line of the vertical shaft, the left ends of the transverse shafts are respectively and fixedly provided with the coaxial first helical gears, the first helical gears can be respectively meshed and matched with the corresponding first semicircular helical gears and the second semicircular helical gears, the right ends of the peripheries of the transverse pipes are respectively and fixedly connected with the reserved holes on the left side of the circular box, the right ends of the transverse shafts are respectively and fixedly arranged in the corresponding circular boxes, the inner walls of the lower ports of the circular boxes are respectively and rotatably connected with the peripheries of the upper ends of the L-shaped pipes through sealing bearings, the upper ends of the L-shaped pipes are respectively and fixedly connected with the bottoms of the L-shaped pipes, the upper ends of the fixed shafts are respectively and fixedly provided with the coaxial third helical gears, the third helical gears are meshed and matched with the second, the right side and the left side of base front side are equipped with respectively and treat processing glass piece strorage device, the top side fixed mounting vertical axis drive arrangement of the workstation of upside, the air intake of fixed connection fan is distinguished to the preformed hole of fixed pipe periphery one side.

The suction head comprises an inner tube, the inner periphery of the lower end of the L-shaped tube is fixedly connected with the outer periphery of the inner tube, two pistons are movably installed in the inner tube respectively, the outer peripheries of the pistons are in sliding contact fit with the inner periphery of the corresponding inner tube respectively, the left end of the inner piston is fixedly connected with the outer end of a spring rod, the inner end of the spring rod is fixedly connected with the inner wall of the L-shaped tube through a connecting rod, a rubber plate is fixedly installed in a reserved hole in the middle of the outer side of the outer piston, the outer side of the rubber plate protrudes out of the outer piston, a plurality of suction holes are uniformly formed in the outer side of the rubber plate, a gear is arranged between two adjacent pistons, the side surface of the gear is rotatably connected with the inner wall of the corresponding L-shaped tube through a bearing respectively, a bar-shaped rack is arranged on the upper side, and the bottom of the inner pipe is respectively provided with a gas distribution through hole penetrating through the L-shaped pipe.

According to the stable processing equipment for the special-shaped electronic glass, the driving device comprises the motor, the bottom side of the motor is fixedly connected with the top side of the upper workbench, the upper end of the rotating shaft of the motor is fixedly provided with the driving gear, the upper end of the vertical shaft is respectively and fixedly provided with the driven gear, and the driven gear is respectively meshed and matched with the driving gear.

The device for stably processing the special-shaped electronic glass comprises a box body with an opening at the front side, wherein the two box bodies are respectively positioned at the left side and the right side of the front side of a base, the inner side and the rear side of the box body are respectively provided with a through groove, the adjacent through grooves are communicated, the top side and the bottom side of the box body are respectively provided with a slot which is symmetrical up and down, two ends of the glass sheet to be processed are inserted into the corresponding slots, the upper part of the box body is respectively provided with a lead screw which is rotatably arranged at the front side of the base, the periphery of the lead screw is respectively matched with a screw in a threaded manner, the lower part of the box body is respectively provided with an optical axis which is fixedly connected with the base, the periphery of the optical axis is sleeved with a sleeve, the upper and lower adjacent sleeves are connected with the screw through a supporting plate, the rear side of the box body is respectively provided with a strip-shaped groove, and the inner ends of the screw rods are respectively and fixedly provided with a fifth coaxial helical gear, and the fourth helical gear is meshed and matched with the corresponding fifth helical gear.

As above, the front side of the workbench is respectively and fixedly provided with the electric telescopic rod, the moving end of the electric telescopic rod is respectively and fixedly connected with the middle of the outer side of the inverted L-shaped plate, the moving direction of the moving end of the electric telescopic rod and the horizontal plane form a forty-five degree included angle, and the vertical inner side of the inverted L-shaped plate is vertical to the horizontal plane, and the horizontal inner side of the inverted L-shaped plate is parallel to the horizontal plane.

According to the stable processing equipment for the special-shaped electronic glass, the bottom sides of the inner pipes are respectively provided with the strip-shaped sliding grooves, the sliding blocks are movably installed in the strip-shaped sliding grooves, the sliding blocks can only move left and right along the strip-shaped sliding grooves, and the sliding blocks are respectively and fixedly connected with the corresponding pistons on the outer sides.

The invention has the advantages that: the glass sheet feeding device is simple in structure and ingenious in conception, adopts a pure mechanical structure, realizes automatic feeding and rotary discharging of glass sheets, can reduce the labor intensity of operators, reduces the manufacturing and using cost of equipment, is convenient to maintain, has high reliability, can meet market demands, and is suitable for popularization. When the invention is used, firstly, the base is placed at a proper position, the front side of the workbench is placed upwards, when material loading is needed, the fan is electrified simultaneously, the fan generates suction force sequentially through the fixed pipe, the rotating pipe, the transverse pipe, the round box, the L-shaped pipe and the suction head, the suction head at the right side is in contact fit with the middle of the left side of the glass sheet to be processed on the glass sheet storage device to be processed, the glass sheet to be processed is adsorbed at the right end of the L-shaped pipe by the suction force generated by the suction head, the suction head at the left side is in contact fit with one side of the processed glass sheet facing the base, the processed glass sheet is adsorbed at the lower end of the L-shaped pipe by the suction force generated by the suction head, the glass sheet to be processed and the processed are grabbed, then the vertical shaft is driven to rotate by the driving device simultaneously, the vertical shaft drives the rotating pipe to rotate anticlockwise, the rotating pipe, the first bevel gear drives the cross shaft to roll along the corresponding second semicircular bevel gear, the cross shaft rotates, the cross shaft drives the fixed shaft to rotate through the second bevel gear and the third bevel gear, the fixed shaft drives the L-shaped pipe to rotate until the L-shaped pipe revolves anticlockwise along the vertical shaft for a half circle, the L-shaped pipe rotates clockwise for ninety degrees, a glass sheet to be processed and a processed glass sheet move along the corresponding L-shaped pipe, the outer side of a suction head in the lower end of the L-shaped pipe on the left side faces towards the left side, the outer side of the suction head in the lower end of the L-shaped pipe on the right side faces towards one side departing from the base and is in the same plane with one side of the workbench departing from the base, the fan is powered off at the moment, the suction force of the suction head disappears, the glass sheet is separated from the suction head, the processed glass sheet is placed on the glass sheet storage device to be processed on the, finishing the feeding of the glass sheet so as to carry out subsequent processing on the glass sheet to be processed; and the vertical shaft continues to rotate, the first helical gear is separated from the corresponding second semicircular helical gear, the first helical gear is meshed with the corresponding first semicircular helical gear respectively, the L-shaped pipe starts to rotate anticlockwise, and the L-shaped pipe is reset respectively until the vertical shaft rotates for a circle, so that the next blanking and loading of the glass sheet are facilitated.

Drawings

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

FIG. 1 is a schematic structural view of the present invention; FIG. 2 is an enlarged view of section I of FIG. 1; FIG. 3 is an enlarged view of a portion II of FIG. 1; FIG. 4 is an enlarged view of a portion III of FIG. 1; FIG. 5 is an enlarged view of a portion IV of FIG. 1; FIG. 6 is an enlarged view of part V of FIG. 3; fig. 7 is an enlarged view of the view from the direction a of fig. 2.

Detailed Description

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

A special-shaped electronic glass stable processing device comprises a base 1, wherein the middle part of the front side of the base 1 is fixedly connected with the rear sides of two workbenches 2 which are distributed up and down, the front sides of the workbenches 2 are in the same plane, the left side and the right side of the workbench 2 at the upper side are respectively fixedly connected with the periphery of a circular plate 3, the bottom side of the circular plate 3 is respectively fixedly connected with the upper end of a coaxial fixed pipe 4, the lower end of the fixed pipe 4 is respectively and rotatably connected with the upper end of the periphery of a rotating pipe 5 through a sealing bearing, the upper end opening and the lower end of the rotating pipe 5 are closed, a vertical shaft 6 is respectively and rotatably mounted in the circular plate 3 through a sealing bearing, the lower end of the vertical shaft 6 is respectively and fixedly connected with the bottom of the rotating pipe 5, the left end of the periphery of a transverse pipe 7 is respectively and fixedly connected in a reserved hole at the right, the periphery of the bearing is fixedly connected with the inner wall of the transverse pipe 7 through a connecting rod, the lower end of the rear side of the vertical shaft 6 is respectively provided with a first semicircular helical gear 9, the front side of the vertical shaft 6 is positioned above the first semicircular helical gear 9 and is provided with a second semicircular helical gear 10, the first semicircular helical gear 9 is centrosymmetric with the corresponding second semicircular helical gear 10, the first semicircular helical gear 9 and the second semicircular helical gear 10 are respectively fixedly connected with the annular plate 3, the axis of the circle where the first semicircular helical gear 9 is positioned and the axis of the circle where the second helical gear 10 is positioned are respectively collinear with the central line of the vertical shaft 6, the left end of the transverse shaft 8 is respectively fixedly provided with a coaxial first helical gear 11, the first helical gear 11 can be respectively meshed and matched with the corresponding first semicircular helical gear 9 and the second semicircular helical gear 10, the right end of the periphery of the transverse pipe 7 is respectively fixedly connected with a reserved hole on the left side of, the right end of the cross shaft 8 is respectively positioned in the corresponding round box 12 and fixedly provided with a second bevel gear 13, the inner wall of the lower port of the round box 12 is respectively connected with the periphery of the upper end of an L-shaped pipe 14 in a rotating mode through a sealing bearing, the lower end of the L-shaped pipe 14 on the left side faces forwards, the lower end of the L-shaped pipe 14 on the right side faces rightwards, a fixed shaft 15 is respectively arranged in the upper end of the L-shaped pipe 14, the lower end of the fixed shaft 15 is respectively fixedly connected with the bottom of the L-shaped pipe 14, the upper end of the fixed shaft 15 is respectively and fixedly provided with a coaxial third bevel gear 16, the third bevel gear 16 is meshed and matched with the second bevel gear 13, suction heads are respectively and fixedly arranged in the lower end of the L-shaped pipe 14, the right side and the left side of the front side of the base 1 are respectively provided with glass sheet storage devices to be. The glass sheet feeding device is simple in structure and ingenious in conception, adopts a pure mechanical structure, realizes automatic feeding and rotary discharging of glass sheets, can reduce the labor intensity of operators, reduces the manufacturing and using cost of equipment, is convenient to maintain, has high reliability, can meet market demands, and is suitable for popularization. When the glass sheet processing device is used, firstly, the base 1 is placed at a proper position, the front side of the workbench 2 is placed upwards, when the feeding is needed, the fan 17 is powered on at the same time, the fan 17 generates suction force through the fixed pipe 4, the rotating pipe 5, the transverse pipe 7, the round box 12, the L-shaped pipe 14 and the suction head in sequence, at the moment, the suction head on the right side is in contact fit with the middle of the left side of a glass sheet to be processed on the glass sheet storage device to be processed, the glass sheet to be processed is adsorbed at the right end of the L-shaped pipe 14 through the suction force generated by the suction head, the suction head on the left side is in contact fit with one side of the processed glass sheet facing the base 1, the processed glass sheet is adsorbed at the lower end of the L-shaped pipe 14 through the suction force generated by the suction head, the glass sheet to be processed and the processed are grabbed, then, the round box 12 and the L-shaped pipe 14 revolve, at the moment, the first bevel gear 11 is respectively engaged with the second semicircular bevel gear 10, the first bevel gear 11 drives the transverse shaft 8 and rolls along the corresponding second semicircular bevel gear 10, the transverse shaft 8 rotates, the transverse shaft 8 drives the fixed shaft 15 to rotate through the second bevel gear 13 and the third bevel gear 16, the fixed shaft 15 drives the L-shaped pipe 14 to rotate until the L-shaped pipe 14 rotates half-circle along with the vertical shaft 6 in an anticlockwise revolution manner, the L-shaped pipe 14 rotates ninety degrees clockwise, a glass sheet to be processed and processed moves along with the corresponding L-shaped pipe 4, at the moment, the outer side of a suction head in the lower end of the L-shaped pipe 14 on the left side faces towards the left side, at the same time, the outer side of the suction head in the lower end of the L-shaped pipe 14 on the right side faces towards one side departing from the base 1 and is in the same plane with one side of the workbench 2 departing from the base 1, at the, finishing the blanking of the glass sheet 100, placing the glass sheet to be processed on the glass sheet storage device to be processed on the right side on the workbench 2, finishing the feeding of the glass sheet 100 so as to carry out subsequent processing on the glass sheet to be processed; the vertical shaft 6 continues to rotate, the first bevel gears 11 are separated from the corresponding second semicircular bevel gears 10, then the first bevel gears 11 are respectively meshed with the corresponding first semicircular bevel gears 9, the L-shaped pipes 14 start to rotate anticlockwise, and when the vertical shaft 6 rotates for a circle, the L-shaped pipes 14 are respectively reset so as to facilitate the blanking and the loading of the next glass sheet.

Specifically, as shown in the figure, the suction head according to the embodiment includes an inner tube 20, an inner periphery of a lower end of the L-shaped tube 14 is fixedly connected to an outer periphery of the inner tube 20, two pistons 21 are movably installed in the inner tube 20, an outer periphery of each piston 21 is in sliding contact fit with an inner periphery of the corresponding inner tube 20, an outer end of a spring rod 22 is fixedly connected to a left end of the inner piston 21, an inner end of the spring rod 22 is fixedly connected to an inner wall of the L-shaped tube 14 through a connecting rod, a rubber plate 23 is fixedly installed in a reserved hole in the middle of an outer side of the outer piston 21, a plurality of suction holes 24 are uniformly formed in an outer side of the rubber plate 23, a gear 25 is respectively arranged between two adjacent pistons 21, a side surface of the gear 25 is rotatably connected to an inner wall of the corresponding L-shaped tube 14 through a bearing, an, the strip-shaped racks 26 are respectively fixedly connected with the corresponding pistons 21, and the bottom of the inner tube 20 is respectively provided with a gas distribution through hole 27 penetrating through the L-shaped tube 14. When the fan 17 is powered on to work, the upper end of the L-shaped pipe 14 generates suction force, which can suck the inner piston 21 out of the inner pipe 20, the corresponding spring rod 22 is compressed, the inner piston 21 drives the corresponding lower strip rack 26 to move inwards, the lower strip rack 26 drives the corresponding gear 25 to rotate, the gear 25 drives the corresponding upper strip rack 26 and the outer slide 21 to move outwards, the outer end of the outer piston 21 moves out of the inner pipe 20, the outer end of the inner piston 21 moves out of the inner pipe 20, the outer side of the rubber plate 23 contacts and matches with one side of the glass sheet to be processed, at this time, the external air can enter the inner pipe 20 and the L-shaped hanging pipe 14 through the air distribution through hole 27 and the suction hole 24, the air flow generated when the external air enters the L-shaped pipe 14 can generate inward thrust to the inner piston 21, so that the corresponding telescopic rod 22 is kept in a compressed state, because the outer end of the suction hole 24 is blocked by the glass sheet to be processed, the air flow entering the L-shaped pipe 14 can enable the right side of the piston 21 on the outer side to form negative pressure, so that the suction hole 24 generates suction force on the glass sheet to be processed, grabbing of the glass sheet to be processed is completed, when the fan 17 is powered off, the processes are carried out in a reverse order, and the piston 21 is reset and retracted into the inner pipe 20.

Specifically, as shown in the figure, the driving device according to the embodiment includes a motor 30, a bottom side of the motor 30 is fixedly connected to a top side of the upper working table 2, a driving gear 31 is fixedly mounted at an upper end of a rotating shaft of the motor 30, driven gears 32 are respectively fixedly mounted at upper ends of the vertical shafts 6, and the driven gears 32 are respectively engaged with the driving gear 31. When the motor 30 is powered on, the rotating shaft of the motor 30 drives the vertical shaft 6 to synchronously rotate in the same direction through the driving gear 31 and the driven gear 32.

Further, as shown in the figure, the storage device for glass sheets to be processed in this embodiment includes a box body 40 with an open front side, two box bodies 40 are respectively located on the left side and the right side of the front side of the base 1, the inner side and the rear side of the box body 40 are respectively provided with a through groove 41, the adjacent through grooves 41 are communicated, the top side and the bottom side of the box body 40 are respectively provided with a slot 42 which is symmetrical up and down, two ends of a glass sheet to be processed are inserted into the corresponding slots 42, the front and rear thickness of the box body 40 is not more than one third of the front and rear width of the glass sheet to be processed, a lead screw 43 rotatably mounted on the front side of the base 1 is respectively arranged above the box body 40, the lead screw 43 is rotatably connected with the base 1 through a bearing seat, the thread turning directions of the two lead screws 43 are opposite, the periphery of the lead screw 43 is respectively provided with a screw 44 in, the vertically adjacent sleeves 46 are connected with the screw nuts 44 through a support plate 47, the rear side of the box body 40 is respectively provided with a strip-shaped groove 48, strip-shaped blocks 49 fixedly connected with the support plate 47 are respectively arranged in the strip-shaped grooves 48, the peripheries of the vertical shafts 6 are respectively and fixedly provided with coaxial fourth bevel gears 50, the inner ends of the screw rods 43 are respectively and fixedly provided with coaxial fifth bevel gears 51, and the fourth bevel gears 50 are meshed with the corresponding fifth bevel gears 51. When the vertical shaft 6 rotates, the screw 43 can be driven to rotate by the fourth helical gear 50 and the fifth helical gear 51, the screw 44 drives the support plate 47, the strip-shaped block 49 and the sleeve 46 to move leftwards or rightwards, the support plate 47 drives the box body 40 to move leftwards and rightwards through the strip-shaped block 49 and the strip-shaped groove 48, the box body 40 moves leftwards or rightwards simultaneously, and when the vertical shaft 6 rotates for one circle, the box body 40 moves leftwards or rightwards for one thickness of a glass sheet to be processed and a distance between two adjacent glass sheets to be processed, so that the automatic feeding and positioning of the glass sheets to be processed are realized, the material position of the glass sheets to be processed is kept unchanged, the automatic blanking and sorting of the glass sheets to be processed are realized, the disordered stacking of the.

Furthermore, as shown in the figure, the electric telescopic rods 70 are respectively and fixedly installed at the front side of the workbench 2, the moving ends of the electric telescopic rods 70 are respectively and fixedly connected with the middle of the outer side of the inverted L-shaped plate 71, the moving direction of the moving ends of the electric telescopic rods 70 forms a forty-five degree included angle with the horizontal plane, and the vertical inner side of the inverted L-shaped plate 71 is perpendicular to the horizontal plane, and the horizontal inner side is parallel to the horizontal plane. Electrifying the electric telescopic rod 70, controlling the electric telescopic rod 70 to extend simultaneously, extending to the longest by the electric telescopic rod 70, and simultaneously contacting and matching the inner side of the inverted L-shaped plate 71 with the corresponding side surface of the glass sheet to be processed to position and clamp the glass sheet to be processed.

Furthermore, as shown in the figure, the bottom sides of the inner tubes 20 in this embodiment are respectively provided with a bar-shaped sliding groove 80, a sliding block 81 is movably installed in the bar-shaped sliding groove 80, the sliding block 81 can only move left and right along the bar-shaped sliding groove 80, and the sliding block 81 is respectively and fixedly connected with the corresponding outer side piston 21. The outer piston 21 can be guided, and the upper strip-shaped rack 26 and the gear 25 can be prevented from being separated due to the shaking of the outer piston 21 in the inner tube 20.

Finally, it should be noted that: the above examples are only intended to illustrate the technical solution of the present invention, but not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; and such modifications or substitutions do not depart from the spirit and scope of the corresponding technical solutions of the embodiments of the present invention.

Claims

1. The utility model provides a dysmorphism electronic glass stabilizes processing equipment which characterized in that: comprises a base (1), the middle part of the front side of the base (1) is fixedly connected with the rear sides of two working tables (2) which are distributed up and down, the front sides of the working tables (2) are in the same plane, the left side and the right side of the working table (2) at the upper side are respectively fixedly connected with the peripheries of annular plates (3), the bottom sides of the annular plates (3) are respectively fixedly connected with the upper ends of coaxial fixed tubes (4), the lower ends of the fixed tubes (4) are respectively and rotatably connected with the upper ends of the peripheries of rotating tubes (5) through sealing bearings, vertical shafts (6) are respectively and rotatably installed in the annular plates (3) through the sealing bearings, the lower ends of the vertical shafts (6) are respectively and fixedly connected with the bottoms of the rotating tubes (5), reserved holes at the right side of the rotating tubes (5) are respectively and fixedly connected with the left ends of the peripheries of transverse tubes (7), transverse shafts (8) are respectively and rotatably installed in the transverse tubes (7), the lower ends of, the front side of the vertical shaft (6) is provided with a second semicircular helical gear (10) above the first semicircular helical gear (9), the first semicircular helical gear (9) and the second semicircular helical gear (10) are respectively and fixedly connected with the annular plate (3), the axis of the circle of the first semicircular helical gear (9) and the axis of the circle of the second semicircular helical gear (10) are respectively collinear with the central line of the vertical shaft (6), the left end of the transverse shaft (8) is respectively and fixedly provided with a coaxial first helical gear (11), the first helical gear (11) can be respectively and correspondingly meshed with the first semicircular helical gear (9) and the second semicircular helical gear (10) to be matched, the right end of the periphery of the transverse pipe (7) is respectively and fixedly connected with a reserved hole on the left side of the circular box (12), the right end of the transverse shaft (8) is respectively and fixedly provided with a second helical gear (13) in the corresponding circular box (12), the inner wall of the lower end of the circular box (12) is respectively and rotatably connected with the periphery of an L, the upper end of the L-shaped pipe (14) is internally provided with a fixed shaft (15), the lower end of the fixed shaft (15) is fixedly connected with the bottom of the L-shaped pipe (14), the upper end of the fixed shaft (15) is fixedly provided with a coaxial third bevel gear (16), the third bevel gear (16) is meshed and matched with the second bevel gear (13), the lower end of the L-shaped pipe (14) is internally and fixedly provided with a suction head, the right side and the left side of the front side of the base (1) are respectively provided with a glass sheet storage device to be processed, the top side of the upper side of the workbench (2) is fixedly provided with a vertical shaft (6) driving device, and a preformed hole on one side of the periphery of the fixed pipe (4) is fixedly connected with an air inlet of a.

2. The shaped electronic glass stable processing equipment according to claim 1, characterized in that: the suction head comprises an inner pipe (20), the inner periphery of the lower end of an L-shaped pipe (14) is fixedly connected with the outer periphery of the inner pipe (20) respectively, two pistons (21) are movably mounted in the inner pipe (20) respectively, the outer peripheries of the pistons (21) are in sliding contact fit with the inner periphery of the corresponding inner pipe (20) respectively, the left end of the inner piston (21) is fixedly connected with the outer end of a spring rod (22), the inner end of the spring rod (22) is fixedly connected with the inner wall of the L-shaped pipe (14) through a connecting rod, a rubber plate (23) is fixedly mounted in a reserved hole in the middle of the outer side of the piston (21), the outer side of the rubber plate (23) protrudes out of the outer side of the piston (21), a plurality of suction holes (24) are uniformly formed in the outer side of the rubber plate (23), a gear (25) is arranged between two adjacent pistons (21) respectively, and the side, the upper side and the lower side of the gear (25) are respectively provided with a strip-shaped rack (26) in a meshing fit mode, the strip-shaped racks (26) are respectively fixedly connected with corresponding pistons (21), and the bottom of the inner pipe (20) is respectively provided with a gas distribution through hole (27) penetrating through the L-shaped pipe (14).

3. The shaped electronic glass stable processing equipment according to claim 1, characterized in that: the driving device comprises a motor (30), the bottom side of the motor (30) is fixedly connected with the top side of the upper workbench (2), a driving gear (31) is fixedly installed at the upper end of a rotating shaft of the motor (30), a driven gear (32) is fixedly installed at the upper end of a vertical shaft (6) respectively, and the driven gear (32) is meshed with the driving gear (31) respectively.

4. The shaped electronic glass stabilizing and processing device according to claim 3, wherein: the storage device for the glass sheets to be processed comprises box bodies (40) with openings at the front sides, wherein the two box bodies (40) are respectively positioned at the left side and the right side of the front side of a base (1), the inner side and the rear side of each box body (40) are respectively provided with a through groove (41), the adjacent through grooves (41) are communicated, the top side and the bottom side of each box body (40) are respectively provided with a slot (42) which is vertically symmetrical, two ends of each glass sheet to be processed are inserted into the corresponding slots (42), a lead screw (43) rotatably arranged at the front side of the base (1) is respectively arranged above each box body (40), the periphery of each lead screw (43) is respectively provided with a screw (44) in a threaded fit manner, an optical axis (45) fixedly connected with the base (1) is respectively arranged below each box body (40), a sleeve (46) is sleeved at the periphery of each optical axis (45), and the vertically adjacent sleeves (46, the rear side of the box body (40) is respectively provided with a strip-shaped groove (48), a strip-shaped block (49) fixedly connected with the supporting plate (47) is respectively arranged in the strip-shaped groove (48), the periphery of the vertical shaft (6) is respectively and fixedly provided with a coaxial fourth helical gear (50), the inner end of the screw rod (43) is respectively and fixedly provided with a coaxial fifth helical gear (51), and the fourth helical gear (50) is meshed with the corresponding fifth helical gear (51).

5. The shaped electronic glass stable processing equipment according to claim 1, characterized in that: the front side of workstation (2) respectively fixed mounting electric telescopic handle (70), the removal end of electric telescopic handle (70) is the centre in the outside of fixed connection falling L template (71) respectively, the moving direction and the horizontal plane that electric telescopic handle (70) removed the end become the contained angle of forty-five degrees, the vertical inboard and the horizontal plane of falling L template (71) are perpendicular, horizontal inboard is parallel with the horizontal plane.

6. The shaped electronic glass stable processing equipment according to claim 2, characterized in that: the bottom side of the inner pipe (20) is respectively provided with a strip-shaped sliding groove (80), a sliding block (81) is movably arranged in the strip-shaped sliding groove (80), the sliding block (81) can only move left and right along the strip-shaped sliding groove (80), and the sliding block (81) is respectively and fixedly connected with the corresponding piston (21) on the outer side.