CN220519506U - Automatic chartered plane that turns over of toughened glass - Google Patents

Abstract

The utility model relates to an automatic toughened glass turning machine, which belongs to the technical field of toughened glass quality inspection and comprises a sucker type stacker, wherein an upper sheet lifting platform is arranged on the grabbing side of the sucker type stacker, a stacking lifting platform is arranged on the releasing side of the sucker type stacker, and the sucker type stacker turns the toughened glass on the upper sheet lifting platform sheet by sheet and places the toughened glass on the stacking lifting platform sheet by sheet so as to re-pack broken toughened glass after cleaning.

Description

Automatic chartered plane that turns over of toughened glass

Technical Field

The utility model relates to the technical field of toughened glass quality inspection, in particular to an automatic toughened glass ladle overturning machine.

Background

The photovoltaic industry is evolving increasingly, and the size of the glass sheets increases as the size of the cells increases. Because of the large plate glass tempering production process, the original sheet and other reasons, the self-explosion phenomenon occurs in the production of the stacked glass in a glass warehouse with huge base numbers. In addition, there are other reasons that the package needs to be turned over, and the defective products are selected. The existing bag turning method is to manually turn over bags by two workers to pick out unqualified products, so that the labor capacity is increased for workshop staff, the glass plate surface is scratched by manual bag turning, and certain potential safety hazards are brought to operators.

The patent with publication number CN 109081077A discloses a glass turnover production line, which comprises a front conveyor belt, a turnover mechanism and a rear conveyor belt, wherein the turnover mechanism comprises a rotating arm and a rotating shaft, the front conveyor belt is provided with a sliding structure or a telescopic structure, and the front end of the front conveyor belt can pass through a channel groove on the rotating shaft to be in butt joint with the rear conveyor belt. The above patent, although realizing the turning of the glass, fails to solve the technical problem presented in the present application because the stacked glass cannot be turned piece by piece.

Disclosure of Invention

In order to solve the technical problems, the utility model provides the automatic toughened glass turning machine which can automatically turn the stacked glass piece by piece to a packing position without manual operation, thereby improving the working efficiency, reducing the workload of staff, avoiding the scratch of the glass plate surface caused by manual turning and reducing the cost loss.

In order to achieve the above purpose, the technical scheme adopted by the utility model for solving the technical problems is as follows: the automatic toughened glass bagging machine comprises a sucker type stacker, wherein an upper sheet lifting platform is arranged on the grabbing side of the sucker type stacker, a stacking lifting platform is arranged on the releasing side of the sucker type stacker, and the sucker type stacker is used for overturning and placing toughened glass on the upper sheet lifting platform sheet by sheet on the stacking lifting platform so as to repackage broken toughened glass after cleaning.

The sucking disc formula stacker includes the frame and rotates the roll-over stand of connection on it, the top of roll-over stand rotates and is connected with the sucking disc frame that is used for absorbing toughened glass.

The turnover frame comprises a driving shaft which is horizontally and rotatably connected to the frame, one end of the driving shaft extends out of the frame and then is connected with a driving motor I, two swing arms which are perpendicular to the driving shaft and are parallel to the driving shaft are respectively fixed at the positions, extending out of the frame, of the driving shaft, and the sucker frame is connected between the two swing arms.

The sucker frame comprises a rotating shaft and a plurality of groups of oppositely arranged connecting rods, wherein the rotating shaft is connected between two swing arms in a rotating mode, the connecting rods are fixedly connected with the rotating shaft, one end of each rotating shaft stretches out of the corresponding swing arm and then is connected with a driving motor II, and an electric sucker is arranged at the end portion of each connecting rod.

The upper sheet lifting platform and the stacking lifting platform have the same structure and comprise a supporting platform, and a bevel gear screw rod lifter I, a bevel gear screw rod lifter II, a bevel gear screw rod lifter III and a bevel gear screw rod lifter IV which are respectively arranged at four corners of the supporting platform and are synchronously linked;

the four rotating screw rods of the bevel gear screw rod lifter I, the bevel gear screw rod lifter II, the bevel gear screw rod lifter III and the bevel gear screw rod lifter IV penetrate through the supporting platform, screw rod nuts are connected to the four rotating screw rods in a threaded mode, and the four screw rod nuts are fixedly connected with the supporting platform.

The bevel gear screw rod lifter I comprises a base I fixed on the ground, a rotating screw rod I is connected to the base I in a threaded mode, a first bevel gear I is fixed to the rotating screw rod I along the axial direction, a second bevel gear I and a third bevel gear I are connected to the first bevel gear I along the circumferential direction in a meshed mode, central axes of the second bevel gear I and the third bevel gear I are mutually perpendicular, the second bevel gear I is connected with a driving motor III through an input shaft, and the third bevel gear I is connected with the bevel gear screw rod lifter II through a synchronous shaft I.

The bevel gear screw rod lifter II and the bevel gear screw rod lifter III have the same structure and comprise a base II fixed on the ground, a rotating screw rod II is connected to the base II in a threaded manner, a first bevel gear II is axially fixed to the rotating screw rod II, a second bevel gear II and a third bevel gear II are connected to the first bevel gear II in a circumferential meshing manner, and central axes of the second bevel gear II and the third bevel gear II are mutually perpendicular;

the bevel gear screw rod lifter II is opposite to two second bevel gears II on the bevel gear screw rod lifter III and is connected with the bevel gear screw rod lifter through a synchronizing shaft II, a third bevel gear II of the bevel gear screw rod lifter II is connected with the bevel gear screw rod lifter I through a synchronizing shaft I, and a third bevel gear II of the bevel gear screw rod lifter III is connected with the bevel gear screw rod lifter IV through a synchronizing shaft III.

The bevel gear screw rod lifter IV comprises a base III fixed on the ground, a rotating screw rod III is connected to the base III in a threaded mode, a first bevel gear III is axially fixed to the rotating screw rod III, the first bevel gear III is meshed with a second bevel gear III, and the second bevel gear III is connected with the bevel gear screw rod lifter III through a synchronous shaft III.

The automatic bag turning machine further comprises a control screen and a PLC (programmable logic controller) connected with the control screen in a communication manner, wherein the control screen is connected with the suction disc type stacker, the upper sheet lifting platform and the stacking lifting platform through the PLC so as to control the times of the bag turning action of the suction disc type stacker and control the lifting platform to ascend and set the same height and simultaneously descend the stacking lifting platform.

The beneficial effects of the utility model are as follows:

according to the utility model, the upper sheet lifting platform and the stacking lifting platform are respectively arranged on the grabbing side and the releasing side of the suction disc type stacker, the stacked glass is placed on the upper sheet lifting platform, the suction disc type stacker overturns the toughened glass on the upper sheet lifting platform one by one on the stacking lifting platform until the toughened glass which breaks the sheet is exposed and stops overturning, in the process of overturning the sheet, the upper sheet lifting platform rises to a set height so as to enable the suction disc type stacker to smoothly suck the sheet, and the stacking lifting platform descends to the same height so as to enable the suction disc type stacker to smoothly place the sheet, the stacked glass can be overturned one by one to a packing position automatically without manual operation, the working efficiency is improved, the workload of staff is lightened, the scratch of the glass panel caused by manual overturning is avoided, and the cost loss is reduced.

Drawings

The contents of the drawings and the marks in the drawings of the present specification are briefly described as follows:

FIG. 1 is a schematic structural view of an automatic bag turning machine for tempered glass;

FIG. 2 is a schematic view of the suction stacker of FIG. 1 with the frame removed;

FIG. 3 is a top view of the upper sheet lift platform or stacking lift platform of FIG. 1 with the support platform removed;

the labels in the above figures are: 1. the stacker comprises a suction cup type stacker body, a frame, 12, a roll-over stand, 121, a drive shaft, 122, a swing arm, 13, a suction cup holder, 131, a rotary shaft, 132, a connecting rod, 133, an electric suction cup, 14, a drive motor I, 15, a drive motor II, 2, an upper plate lifting platform, 21, a support platform, 22, a bevel gear screw lifter I, 221, a base I, 222, a rotary screw I, 223, a first bevel gear I, 224, a second bevel gear I, 225, a third bevel gear I, 226, an input shaft, 227, a screw nut I, 23, a bevel gear screw lifter II, 231, a base II, 232, a rotary screw II, 233, a first bevel gear II, 234, a second bevel gear II, 235, a third bevel gear II, 236, a screw nut II, 24, a screw lifter III, 25, a bevel gear screw lifter IV, 251, a base III, 252, a rotary screw III, 253, a first bevel gear III, 254, a second bevel gear III, 255, a screw nut III, 26, a drive motor III, 27, a synchronous shaft II, 28, a synchronous shaft III, and a stacking platform 3.

Detailed Description

For the purpose of making the objects, technical solutions and advantages of the embodiments of the present utility model more apparent, the technical solutions in the embodiments will be clearly and completely described with reference to the accompanying drawings in the embodiments of the present utility model, and the following embodiments are used to illustrate the present utility model, but are not intended to limit the scope of the present utility model.

In the description of the present utility model, it should be noted that the directions or positional relationships indicated by the terms "upper", "lower", "front", "rear", "left", "right", "vertical", "inner", "outer", etc. are based on the directions or positional relationships shown in the drawings, are merely for convenience of describing the present utility model and simplifying the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present utility model.

In the description of the present utility model, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium. The specific meaning of the above terms in the present utility model will be understood in specific cases by those of ordinary skill in the art.

The specific embodiments of the utility model are as follows: as shown in fig. 1 to 3, the utility model provides an automatic toughened glass bagging machine, which comprises a suction disc type stacker 1, wherein an upper sheet lifting platform 2 is arranged on the grabbing side of the suction disc type stacker 1, a stacking lifting platform 3 is arranged on the releasing side of the suction disc type stacker 1, and toughened glass on the upper sheet lifting platform 2 is placed on the stacking lifting platform 3 in a piece-by-piece and overturning manner by the suction disc type stacker 1 so as to be cleaned and repacketed. The stacked glass is placed on the upper sheet lifting platform 2, the suction disc type stacker 1 turns the toughened glass on the upper sheet lifting platform 2 sheet by sheet and places the toughened glass on the stacking lifting platform 3 until the toughened glass which is broken sheets is exposed, the turning is stopped, the upper sheet lifting platform 2 rises to a set height so that the suction disc type stacker 1 can suck sheets smoothly in the process of turning sheets, the stacking lifting platform 3 falls to the same height so that the suction disc type stacker 1 can place sheets smoothly, the stacked glass can be automatically turned sheet by sheet to a packing position, manual operation is not needed, the work efficiency is improved, the workload of staff is reduced, the scratch of a glass plate surface caused by manual turning is avoided, and the cost loss is reduced.

Specifically, the sucker type stacker 1 comprises a frame 11 and a roll-over stand 12 rotatably connected with the frame, wherein a sucker frame 13 for sucking toughened glass is rotatably connected with the top of the roll-over stand 12.

The roll-over stand 12 comprises a driving shaft 121 which is horizontally and rotatably connected to the stand 11, one end of the driving shaft 121 extends out of the stand 11 and is connected with a driving motor I14, two swing arms 122 which are perpendicular to the driving shaft 121 and are parallel to each other are respectively fixed at positions, extending out of the stand 11, of the driving shaft 121, and a sucker frame 13 is connected between the two swing arms 122. The driving motor I14 acts to drive the driving shaft 121 to rotate so as to drive the two parallel swing arms 122 to rotate, so that the position of the sucker frame 13 can be adjusted to perform the work of sucking and discharging sheets.

The sucker frame 13 comprises a rotating shaft 131 rotatably connected between two swing arms 122 and a plurality of groups of oppositely arranged connecting rods 132 fixedly connected with the rotating shaft, one end of the rotating shaft 131 extends out of the corresponding swing arm 122 and then is connected with a driving motor II 15, and an electric sucker 133 is arranged at the end part of each connecting rod 132. The driving motor II 15 can drive the rotating shaft 131 to rotate, so that the angles of a plurality of electric suckers 133 on the connecting rod 132 can be adjusted, and the suction stability of toughened glass is ensured.

Specifically, the upper sheet lifting platform 2 and the stacking lifting platform 3 have the same structure, and each upper sheet lifting platform comprises a supporting platform 21, and a bevel gear screw rod lifter I22, a bevel gear screw rod lifter II 23, a bevel gear screw rod lifter III 24 and a bevel gear screw rod lifter IV 25 which are respectively arranged at four corners of the supporting platform and are synchronously linked. Four rotating screw rods of the bevel gear screw rod lifter I22, the bevel gear screw rod lifter II 23, the bevel gear screw rod lifter III 24 and the bevel gear screw rod lifter IV 25 penetrate through the supporting platform 21, screw nuts are connected to the four rotating screw rods in a threaded mode, and the four screw nuts are fixedly connected with the supporting platform 21.

The bevel gear screw rod lifter I22 comprises a base I221 fixed on the ground, a rotating screw rod I222 is connected to the base I221 in a threaded mode, a first bevel gear I223 is fixed to the rotating screw rod I222 along the axial direction, a second bevel gear I224 and a third bevel gear I225 are connected to the first bevel gear I223 along the circumferential direction in a meshed mode, central axes of the second bevel gear I224 and the third bevel gear I225 are perpendicular to each other, the second bevel gear I224 is connected with a driving motor III 26 through an input shaft 226, and the third bevel gear I225 is connected with the bevel gear screw rod lifter II 23 through a synchronous shaft I27.

The bevel gear screw rod lifter II 23 and the bevel gear screw rod lifter III 24 have the same structure and comprise a base II 231 fixed on the ground, a rotating screw rod II 232 is connected to the base II 231 in a threaded mode, a first bevel gear II 233 is fixed to the rotating screw rod II 232 along the axial direction, a second bevel gear II 234 and a third bevel gear II 235 are connected to the first bevel gear II 233 along the circumferential direction in a meshed mode, and central axes of the second bevel gear II 234 and the third bevel gear II 235 are perpendicular to each other.

The bevel gear screw rod lifter II 23 is opposite to two second bevel gears II 234 on the bevel gear screw rod lifter III 24 and is connected with the bevel gear screw rod lifter I22 through a synchronizing shaft II 28, a third bevel gear II 235 of the bevel gear screw rod lifter II 23 is connected with the bevel gear screw rod lifter I22 through a synchronizing shaft I27, and a third bevel gear II 235 of the bevel gear screw rod lifter III 24 is connected with the bevel gear screw rod lifter IV 25 through a synchronizing shaft III 29.

The bevel gear screw rod lifter IV 25 comprises a base III 251 fixed on the ground, a rotary screw rod III 252 is connected to the base III 251 in a threaded mode, a first bevel gear III 253 is axially fixed to the rotary screw rod III 252, the first bevel gear III 253 is meshed with a second bevel gear III 254, and the second bevel gear III 254 is connected with the bevel gear screw rod lifter III 24 through a synchronous shaft III 29.

The driving motor III 26 acts, and the second bevel gear I224 drives the rotating screw rod I222 and the first bevel gear I223 to synchronously rotate, so that a screw rod nut I227 on the rotating screw rod I222 moves along the axial direction; simultaneously, the first bevel gear I223 drives the third bevel gear I225 to synchronously rotate, and the driving force is transmitted to the third bevel gear I225 of the bevel gear screw rod lifter II 23 through the synchronous shaft I27, so that the first bevel gear II 233 and the rotating screw rod II 232 are driven to synchronously rotate, and the screw rod nut II 236 on the rotating screw rod II 232 moves along the axial direction; simultaneously, the first bevel gear II 233 drives the second bevel gear II 234 to synchronously rotate, and the driving force is transmitted to the second bevel gear II 234 of the bevel gear screw rod lifter III 24 through the synchronous shaft II 28, so that the first bevel gear II 233 and the rotating screw rod II 232 of the bevel gear screw rod lifter III 24 are driven to synchronously rotate, and the screw rod nut II 236 on the rotating screw rod II 232 of the bevel gear screw rod lifter III 24 moves along the axial direction; simultaneously, the first bevel gear II 233 drives the third bevel gear II 235 to synchronously rotate, and the driving force is transmitted to the second bevel gear III 254 of the bevel gear screw rod lifter IV 25 through the synchronizing shaft III 29, so that the first bevel gear III 253 and the rotating screw rod III 252 are driven to synchronously rotate, and the screw rod nut III 255 on the rotating screw rod III 252 moves along the axial direction. Because the driving motor III 26 acts, four screw nuts on four rotating screw rods can be simultaneously driven to synchronously rotate in the same direction, so that the supporting platform 21 fixedly connected with the four screw nuts can stably lift, and the two driving motors III 26 on the upper sheet lifting platform 2 and the stacking lifting platform 3 are opposite in rotation direction, so that the ascending sheet lifting of the upper sheet lifting platform 2 and the descending sheet lifting of the stacking lifting platform 3 can be completed.

In addition, the automatic bag turning machine further comprises a control screen and a PLC (programmable logic controller) which is communicated with the control screen, wherein the control screen is connected with the suction disc type stacker 1, the upper sheet lifting platform 2 and the stacking lifting platform 3 through the PLC, and controls the times of the bag turning action of the suction disc type stacker 1 and the lifting setting height of the upper sheet lifting platform 2 through the control screen, and meanwhile the stacking lifting platform 3 descends by the same height.

The using method of the automatic toughened glass ladle overturning machine comprises the following steps:

step 1: placing the stacked glass to be turned over on an upper sheet lifting platform 2 of an automatic turning over machine by using a forklift, wherein the stacked glass is in an unpacked state;

step 2: calculating the number of glass sheets above the self-explosion glass of the uppermost layer from the starting number of the uppermost layer of the stacked glass, and inputting the number of glass sheets above the self-explosion glass on the control screen;

step 3: starting the upper sheet lifting platform 2, the stacking lifting platform 3 and the suction disc type stacker 1, wherein the suction disc type stacker 1 can automatically suck glass from the upper sheet lifting platform 2 to the stacking lifting platform 3 on the other side, and the glass is reciprocated in this way until the glass is automatically stopped after a set number of sheets are transported;

step 4: after the broken pieces are cleaned manually, inputting the number of the glass pieces above the self-explosion glass on the uppermost layer again on the control screen;

step 5: and (3) operating according to the methods in the step (3) and the step (4) until the self-explosion glass is not contained, inputting the number of the glass sheets which are missing in the package, and then placing the package on a shelf for packaging.

In conclusion, the utility model can automatically turn the stacked glass piece by piece to the packing position without manual operation, thereby improving the working efficiency, reducing the workload of staff, avoiding the scratch of the glass plate surface caused by manual turning and reducing the cost loss.

The foregoing is provided by way of illustration of the principles of the present utility model, and is not intended to be limited to the specific constructions and applications illustrated herein, but rather to all modifications and equivalents which may be utilized as fall within the scope of the utility model as defined in the claims.

Claims (9)

1. The utility model provides an automatic chartered plane that turns over of toughened glass, its characterized in that includes sucking disc formula stacker, the side of snatching of sucking disc formula stacker sets up the piece lift platform, the release side of sucking disc formula stacker sets up the stack lift platform, the sucking disc formula stacker will toughened glass turns over one by one on the lift platform of going up and places on the stack lift platform so as to repackage after the toughened glass clearance to the broken piece.

2. The automatic bag turner for tempered glass as claimed in claim 1, wherein: the sucking disc formula stacker includes the frame and rotates the roll-over stand of connection on it, the top of roll-over stand rotates and is connected with the sucking disc frame that is used for absorbing toughened glass.

3. The automatic bag turner for tempered glass as claimed in claim 2, wherein: the turnover frame comprises a driving shaft which is horizontally and rotatably connected to the frame, one end of the driving shaft extends out of the frame and then is connected with a driving motor I, two swing arms which are perpendicular to the driving shaft and are parallel to the driving shaft are respectively fixed at the positions, extending out of the frame, of the driving shaft, and the sucker frame is connected between the two swing arms.

4. The automatic bag turner for tempered glass as claimed in claim 3, wherein: the sucker frame comprises a rotating shaft and a plurality of groups of oppositely arranged connecting rods, wherein the rotating shaft is connected between two swing arms in a rotating mode, the connecting rods are fixedly connected with the rotating shaft, one end of each rotating shaft stretches out of the corresponding swing arm and then is connected with a driving motor II, and an electric sucker is arranged at the end portion of each connecting rod.

5. The automatic bag turner for tempered glass as claimed in claim 1, wherein: the upper sheet lifting platform and the stacking lifting platform have the same structure and comprise a supporting platform, and a bevel gear screw rod lifter I, a bevel gear screw rod lifter II, a bevel gear screw rod lifter III and a bevel gear screw rod lifter IV which are respectively arranged at four corners of the supporting platform and are synchronously linked;

the four rotating screw rods of the bevel gear screw rod lifter I, the bevel gear screw rod lifter II, the bevel gear screw rod lifter III and the bevel gear screw rod lifter IV penetrate through the supporting platform, screw rod nuts are connected to the four rotating screw rods in a threaded mode, and the four screw rod nuts are fixedly connected with the supporting platform.

6. The automatic bag turner for tempered glass as in claim 5 wherein: the bevel gear screw rod lifter I comprises a base I fixed on the ground, a rotating screw rod I is connected to the base I in a threaded mode, a first bevel gear I is fixed to the rotating screw rod I along the axial direction, a second bevel gear I and a third bevel gear I are connected to the first bevel gear I along the circumferential direction in a meshed mode, central axes of the second bevel gear I and the third bevel gear I are mutually perpendicular, the second bevel gear I is connected with a driving motor III through an input shaft, and the third bevel gear I is connected with the bevel gear screw rod lifter II through a synchronous shaft I.

7. The automatic bag turner for tempered glass as in claim 5 wherein: the bevel gear screw rod lifter II and the bevel gear screw rod lifter III have the same structure and comprise a base II fixed on the ground, a rotating screw rod II is connected to the base II in a threaded manner, a first bevel gear II is axially fixed to the rotating screw rod II, a second bevel gear II and a third bevel gear II are connected to the first bevel gear II in a circumferential meshing manner, and central axes of the second bevel gear II and the third bevel gear II are mutually perpendicular;

the bevel gear screw rod lifter II is opposite to two second bevel gears II on the bevel gear screw rod lifter III and is connected with the bevel gear screw rod lifter through a synchronizing shaft II, a third bevel gear II of the bevel gear screw rod lifter II is connected with the bevel gear screw rod lifter I through a synchronizing shaft I, and a third bevel gear II of the bevel gear screw rod lifter III is connected with the bevel gear screw rod lifter IV through a synchronizing shaft III.

8. The automatic bag turner for tempered glass as in claim 5 wherein: the bevel gear screw rod lifter IV comprises a base III fixed on the ground, a rotating screw rod III is connected to the base III in a threaded mode, a first bevel gear III is axially fixed to the rotating screw rod III, the first bevel gear III is meshed with a second bevel gear III, and the second bevel gear III is connected with the bevel gear screw rod lifter III through a synchronous shaft III.

9. The automatic bag turner for tempered glass as claimed in claim 1, wherein: the automatic bag turning machine further comprises a control screen and a PLC (programmable logic controller) connected with the control screen in a communication manner, wherein the control screen is connected with the suction disc type stacker, the upper sheet lifting platform and the stacking lifting platform through the PLC so as to control the times of the bag turning action of the suction disc type stacker and control the lifting platform to ascend and set the same height and simultaneously descend the stacking lifting platform.