CN112158601A - Glass burst system - Google Patents

Abstract

The invention provides a glass slicing system, and belongs to the field of glass slicing processing. The system comprises a sheet feeding unit, a sheet separating unit, at least one output unit, at least one storage unit, a first negative pressure sucker unit, a second negative pressure sucker unit, at least one third proximity switch and a control unit. The automatic glass sheet separating and storing device can perform automatic continuous conveying, sheet separating and storing operations, and greatly improves the efficiency of the sheet separating link in glass processing.

Description

Glass burst system

Technical Field

The invention belongs to the field of glass slicing processing, and particularly relates to a glass slicing system.

Background

The development of the glass industry is connected with a plurality of industries of national economy, and the glass industry plays a positive role in promoting the development of the whole national economy. The common flat glass and the float glass are both flat glass, but the production process and the quality are different. Float glass is widely applied and is divided into colored glass, float silver mirror, automobile windshield float glass, scanner float glass, coating float glass, mirror-making float glass and the like.

In a float glass production line, glass needs to be sliced, and the period of conveying glass sheets by a main line and a branch line is comprehensively considered so as to meet the production takt time. Therefore, how to process the glass sheet transportation is an important technology of a float glass production line.

Disclosure of Invention

The invention aims to provide an automatic and efficient glass slicing system.

In order to achieve the above object, the present invention adopts a technical solution of a glass sheet separation system, comprising:

the sheet feeding unit is used for conveying large sheets of glass to be subjected to sheet separation;

the slicing unit is used for cutting a large piece of glass into small pieces of glass finished products with different specifications;

the at least one output unit is used for transmitting the small glass products output by the slicing unit to the next process;

at least one storage unit for temporarily storing small glass products, including a removable multiple layer glass storage device;

the first negative pressure sucker unit is arranged between the upper sheet unit and the sheet separating unit and is used for taking and placing the large sheets of glass conveyed by the upper sheet unit to the sheet separating unit;

the second negative pressure sucker unit is arranged between the slicing unit and the output unit and is used for taking and placing the small glass products output by the slicing unit to the output unit of different branches;

the third negative pressure sucker unit is arranged between the output unit and the storage unit of the same branch and is used for picking and placing the small glass products conveyed by the branch output unit into the corresponding storage unit;

and the third proximity switch is correspondingly arranged at the outlet of the output unit.

In one implementation technical scheme of the invention, the upper sheet unit comprises an upper sheet conveying roller way, a first proximity switch arranged at a position close to an outlet of the upper sheet conveying roller way and a first rotating motor correspondingly connected with the upper sheet conveying roller way, and the first rotating motor drives the upper sheet conveying roller way to convey large sheets of glass.

In one embodiment of the invention, the slicing unit comprises a glass slicing machine and a second proximity switch, and the second proximity switch is arranged at a position close to an outlet of the glass slicing machine.

In one implementation technical scheme of the invention, each output unit comprises an output roller way, a third proximity switch arranged at a proximity outlet of the output roller way and a second rotating motor correspondingly connected with the output roller way, and the second rotating motor drives the corresponding output roller way to convey small glass products.

In one embodiment of the invention, the first negative pressure suction cup unit comprises a first negative pressure suction cup, a first transverse motor, a first longitudinal motor, a first vertical motor and a first air pump, wherein the first transverse motor, the first longitudinal motor, the first vertical motor and the first air pump are used for controlling the first negative pressure suction cup to move transversely, longitudinally and vertically, and the first air pump is communicated with the first negative pressure suction cup through a hose.

In one embodiment of the invention, the second negative pressure sucker unit comprises a second negative pressure sucker, a second transverse motor, a second longitudinal motor, a second vertical motor and a second air pump, wherein the second transverse motor, the second longitudinal motor, the second vertical motor and the second air pump are used for controlling the second negative pressure sucker to move transversely, longitudinally and vertically; the third negative pressure sucker unit comprises a third negative pressure sucker, a third transverse motor, a third longitudinal motor, a third vertical motor and a third air pump, wherein the third transverse motor, the third longitudinal motor, the third vertical motor and the third air pump are used for controlling the third negative pressure sucker to move transversely, longitudinally and vertically, and the third air pump is communicated with the third negative pressure sucker through a hose.

In one embodiment of the invention, the glass sheet separation system further comprises a control unit, wherein the control unit comprises a main control module, a first sub-control module and at least one second sub-control module, the first sub-control module and the second sub-control module are respectively electrically connected with the main control module, a first rotating motor, a first transverse motor, a first longitudinal motor, a first vertical motor, a first air pump, a second rotating motor, a second transverse motor, a second longitudinal motor, a second vertical motor, a second air pump, a first proximity switch and a second proximity switch are respectively electrically connected with the first sub-control module, and a third rotating motor, a third transverse motor, a third longitudinal motor, a third vertical motor, a third air pump and a third proximity switch of the same branch are respectively electrically connected with the second sub-control module of the corresponding branch.

In one implementation technical scheme of the invention, the multilayer glass storage device comprises a base, a cuboid frame and a lifting driving mechanism, wherein the cuboid frame is installed on the base, rotating supports for placing glass are symmetrically sleeved on two rear vertical rods of the frame, the rotating supports are arranged from top to bottom in a layered mode and can horizontally rotate, the driving mechanism is used for driving the rotating supports to horizontally rotate, an outer gear ring bearing is fixed on each rotating support, the outer gear ring bearings are fixedly sleeved on the rear vertical rods of the frame, and the driving mechanism drives the rotating supports to horizontally rotate by driving the outer gear ring bearings to rotate.

Furthermore, the driving mechanism comprises a vertical plate, a third rotating motor, an electric push rod, a supporting plate, a fourth rotating motor, a sliding plate, a rotating shaft, a lead screw and a gear; the vertical plate is fixed on the base and positioned behind the frame, parallel guide rails are arranged on the front side surface of the vertical plate, the supporting plate is horizontally arranged, parallel sliding grooves are formed in the top surface of the vertical plate, strip-shaped holes are formed among the sliding grooves, screw holes are further formed in the rear sides of the strip-shaped holes, guide blocks matched with the guide rails are arranged on the rear sides of the guide grooves, a third rotating motor is coaxially connected with the upper ends of vertically arranged screw rods, the lower ends of the screw rods penetrate through the screw holes and then are rotatably connected with the base, the screw holes are matched with the screw rods, electric push rods are fixed on the top surface of the supporting plate and fixedly connected with the rear side surface of the sliding plate, sliding blocks matched with the sliding grooves are arranged on the bottom surface of the sliding plate, a fourth rotating motor is installed on the top surface of the sliding; a vertical baffle is also arranged between the vertical plate and the frame; the guide rail is of a T-shaped structure, and the guide block matched with the guide rail is also of a T-shaped structure; the riser trailing flank is equipped with and pushes away the handle, and the base bottom surface is equipped with 4 gyro wheels.

Furthermore, the third rotating motor, the electric push rod and the fourth rotating motor are respectively and electrically connected with the second sub-control modules of the corresponding branches.

In summary, due to the adoption of the technical scheme, the invention has the beneficial effects that: the automatic glass sheet separating and storing device can perform automatic continuous conveying, sheet separating and storing operations, and greatly improves the efficiency of the sheet separating link in glass processing.

Drawings

FIG. 1 is a block diagram of a schematic flow diagram of a glass slicing system according to the present invention;

FIG. 2 is a left side view of a multiple layer glass storage device in a glass sheet separation system according to the invention;

FIG. 3 is a top view of a support plate of the multiple layer glass storage device of FIG. 2;

FIG. 4 is a front view of a multiple layer glass storage device in a glass sheet separation system according to the present invention;

FIG. 5 is a top view of the rotating support of the multiple layer glass storage device of FIG. 4;

reference numerals: 1-a vertical plate, 2-a third rotating motor, 3-an electric push rod, 4-a support plate, 5-a fourth rotating motor, 6-a sliding plate, 7-a rotating shaft, 8-a baffle, 9-a frame, 10-a pushing handle, 11-a screw rod, 12-a gear, 13-a base, 14-an external gear ring bearing, 15-a rotating support, 16-a guide block, 17-a screw hole, 18-a sliding groove, 19-a strip-shaped hole, 20-a guide rail and 21-a roller.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below with reference to preferred embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

Example 1

Referring to FIG. 1, a glass sheet separation system according to the present invention includes:

the sheet feeding unit is used for conveying large sheets of glass to be subjected to sheet separation; the upper piece unit comprises an upper piece conveying roller way, a first proximity switch arranged at a position, close to an outlet, of the upper piece conveying roller way and a first rotating motor correspondingly connected with the upper piece conveying roller way, and the first rotating motor drives the upper piece conveying roller way to convey large pieces of glass;

the slicing unit is used for cutting a large piece of glass into small pieces of glass finished products with different specifications; the slicing unit comprises a glass slicing machine and a second proximity switch, and the second proximity switch is arranged at a position close to an outlet of the glass slicing machine;

the at least one output unit is used for transmitting the small glass products output by the slicing unit to the next process; each output unit comprises an output roller way, a third proximity switch arranged at a position, close to an outlet, of the output roller way, and a second rotating motor correspondingly connected with the output roller way, and the second rotating motor drives the corresponding output roller way to convey small glass products;

at least one storage unit for temporarily storing small glass products, including a removable multiple layer glass storage device;

the first negative pressure sucker unit is arranged between the upper sheet unit and the sheet separating unit and is used for taking and placing the large sheets of glass conveyed by the upper sheet unit to the sheet separating unit; the first negative pressure sucker unit comprises a first negative pressure sucker, a first transverse motor, a first longitudinal motor, a first vertical motor and a first air pump, wherein the first transverse motor, the first longitudinal motor, the first vertical motor and the first air pump are used for controlling the first negative pressure sucker to move transversely, longitudinally and vertically;

the second negative pressure sucker unit is arranged between the slicing unit and the output unit and is used for taking and placing the small glass products output by the slicing unit to the output unit of different branches; the second negative pressure sucker unit comprises a second negative pressure sucker, a second transverse motor, a second longitudinal motor, a second vertical motor and a second air pump, wherein the second transverse motor, the second longitudinal motor, the second vertical motor and the second air pump are used for controlling the second negative pressure sucker to move transversely, longitudinally and vertically;

the third negative pressure sucker unit is arranged between the output unit and the storage unit of the same branch and is used for picking and placing the small glass products conveyed by the branch output unit into the corresponding storage unit; the third negative pressure sucker unit comprises a third negative pressure sucker, a third transverse motor, a third longitudinal motor, a third vertical motor and a third air pump, wherein the third transverse motor, the third longitudinal motor, the third vertical motor and the third air pump are used for controlling the third negative pressure sucker to move transversely, longitudinally and vertically;

and the third proximity switch is correspondingly arranged at the outlet of the output unit.

The glass sheet separating system further comprises a control unit, wherein the control unit comprises a main control module, a first sub-control module and at least one second sub-control module, the first sub-control module and the second sub-control module are respectively electrically connected with the main control module, a first rotating motor, a first transverse motor, a first longitudinal motor, a first vertical motor, a first air pump, a second rotating motor, a second transverse motor, a second longitudinal motor, a second vertical motor, a second air pump, a first proximity switch and a second proximity switch are respectively electrically connected with the first sub-control module, and a third rotating motor, a third transverse motor, a third longitudinal motor, a third vertical motor, a third air pump and a third proximity switch of the same branch are respectively electrically connected with the second sub-control modules of the corresponding branches.

Preferably, the electrical control component of the glass wafer separator is electrically connected with the first sub-control module.

In this embodiment, a large glass is conveyed to a sheet by the sheet feeding unit, the large glass is conveyed to a position close to the end of the sheet feeding unit, the first proximity switch sends an electric signal, the first negative pressure sucker unit sucks and lifts the large glass from the end of the sheet feeding unit to the sheet separating unit for sheet separation processing, the sheet separating unit outputs small glass finished products of different specifications, the small glass finished products are conveyed to the end of the sheet separating unit, the second proximity switch sends the electric signal, the second negative pressure sucker unit sucks and lifts the small glass finished products to output units of different branches, the small glass finished products are conveyed to the end of the output unit, the third proximity switch sends the electric signal, and the third negative pressure sucker unit sucks and lifts the small glass finished products from the end of the output unit of the corresponding branch.

Example 2

Referring to the attached drawings 2-5, on the basis of embodiment 1, the multilayer glass storage device adopted in the glass slicing system of the present invention includes a base 13, a rectangular frame 9 mounted on the base 13, and a lifting driving mechanism, wherein two rear vertical rods of the frame 9 are symmetrically sleeved with rotating supports 15 for placing glass, the rotating supports 15 are layered from top to bottom and can rotate horizontally, the driving mechanism is used for driving the rotating supports 15 to rotate horizontally, each rotating support 15 is fixed with an outer gear ring bearing 14, the outer gear ring bearing 14 is fixedly sleeved on the rear vertical rod of the frame 9, and the driving mechanism drives the outer gear ring bearing 14 to rotate so as to drive the rotating supports 15 to rotate horizontally.

The driving mechanism comprises a vertical plate 1, a third rotating motor 2, an electric push rod 3, a supporting plate 4, a fourth rotating motor 5, a sliding plate 6, a rotating shaft 7, a lead screw 11 and a gear 12; the vertical plate 1 is fixed on a base 13 and positioned behind a frame 9, the front side surface of the vertical plate is provided with parallel guide rails 20, a support plate 4 is horizontally arranged, the top surface of the support plate is provided with parallel sliding grooves 18, strip-shaped holes 19 are formed between the sliding grooves 18, screw holes 17 are also arranged behind the strip-shaped holes 19, the rear side surface of the support plate is provided with guide blocks 16 matched with the guide rails 20, a third rotating motor 2 is coaxially connected with the upper ends of vertically arranged lead screws 11, the lower ends of the lead screws 11 penetrate through the screw holes 17 and then are rotatably connected with the base 13, the screw holes 17 are matched with the lead screws, an electric push rod 3 is fixed on the top surface of the support plate 4, the push rod of the electric push rod is fixedly connected with the rear side surface of a sliding plate 6, the bottom surface of the sliding plate 6 is provided with sliding blocks matched with the sliding grooves 18, the top surface of the sliding plate 6 is, and is fixedly connected with the gear 12; a vertical baffle 8 is arranged between the vertical plate 1 and the frame 9; the guide rail 20 is of a T-shaped structure, and the guide block 16 matched with the guide rail is also of a T-shaped structure; the rear side surface of the vertical plate 1 is provided with a push handle 10, and the bottom surface of the base 13 is provided with 4 rollers 21.

And the third rotating motor 2, the electric push rod 3 and the fourth rotating motor 5 are respectively and electrically connected with the second sub-control modules of the corresponding branches.

In this embodiment, the rotating bracket 15 includes a connecting rod and a plurality of supporting pieces perpendicular to the connecting rod, the rear end of the connecting rod is sleeved on the rear vertical rod of the frame 9, the rotating bracket 15 horizontally rotates around the rear vertical rod of the frame 9, so that the rotating bracket 15 is opened from two sides of the frame 9 or is inserted into the frame 9, and the driving mechanism is used for driving the rotating bracket 15 to horizontally rotate; the guide rail 20 is of a T-shaped structure, and the guide block 16 matched with the guide rail is also of a T-shaped structure.

In this embodiment, the third rotating motor 2 drives the screw rod 11 to rotate, so as to realize the lifting of the support plate 4, the electric push rod 3 drives the sliding plate 6 to advance or retreat, so as to realize the meshing and separation of the gear 12 and the external teeth of the external gear ring bearing 14, the fourth rotating motor 5 drives the rotating shaft 7 to rotate, so as to drive the gear 12 to rotate, when the external teeth of the external gear ring bearing 14 are meshed with the gear 12, the rotating gear 12 drives the external gear ring bearing 14 to rotate, and the rotating bracket 15 rotates along with the external gear ring bearing 14.

In the present embodiment, all the rotating brackets 15 are previously opened from both sides of the frame 9 before the multiple glass storage apparatus stores glass; when the glass is stored, the driving mechanism is controlled to drive the rotating bracket 15 to be combined into the frame 9 layer by layer from bottom to top; after the glass storage is finished, the multi-layer glass storage device is pushed away, and another multi-layer glass storage device is replaced for continuous storage.

The above description is only a preferred embodiment of the present invention, and it is intended to explain the technical solutions of the present invention, and those skilled in the art can make routine modifications, equivalent substitutions, improvements, and the like within the spirit and principle of the present invention.

Claims (10)

1. A glass sheet separation system, comprising:

the sheet feeding unit is used for conveying large sheets of glass to be subjected to sheet separation;

the slicing unit is used for cutting a large piece of glass into small pieces of glass finished products with different specifications;

the at least one output unit is used for transmitting the small glass products output by the slicing unit to the next process;

at least one storage unit for temporarily storing small glass products, including a removable multiple layer glass storage device;

the first negative pressure sucker unit is arranged between the upper sheet unit and the sheet separating unit and is used for taking and placing the large sheets of glass conveyed by the upper sheet unit to the sheet separating unit;

the second negative pressure sucker unit is arranged between the slicing unit and the output unit and is used for taking and placing the small glass products output by the slicing unit to the output unit of different branches;

the third negative pressure sucker unit is arranged between the output unit and the storage unit of the same branch and is used for picking and placing the small glass products conveyed by the branch output unit into the corresponding storage unit;

and the third proximity switch is correspondingly arranged at the outlet of the output unit.

2. The glass sheet system of claim 1, wherein: the upper piece unit comprises an upper piece conveying roller way, a first proximity switch arranged at an outlet of the upper piece conveying roller way, and a first rotating motor correspondingly connected with the upper piece conveying roller way, and the first rotating motor drives the upper piece conveying roller way to convey large pieces of glass.

3. The glass sheet system of claim 1, wherein: the slicing unit comprises a glass slicing machine and a second proximity switch, and the second proximity switch is arranged at a position, close to the outlet, of the glass slicing machine.

4. The glass sheet system of claim 1, wherein: each output unit comprises an output roller way, a third proximity switch arranged at a position, close to an outlet, of the output roller way, and a second rotating motor correspondingly connected with the output roller way, and the second rotating motor drives the corresponding output roller way to convey the small glass finished product.

5. The glass sheet system of claim 1, wherein: the first negative pressure sucker unit comprises a first negative pressure sucker, a first transverse motor, a first longitudinal motor, a first vertical motor and a first air pump, wherein the first transverse motor, the first longitudinal motor, the first vertical motor and the first air pump are used for controlling the first negative pressure sucker to move transversely, longitudinally and vertically, and the first air pump is communicated with the first negative pressure sucker through a hose.

6. The glass sheet system of claim 1, wherein: the second negative pressure sucker unit comprises a second negative pressure sucker, a second transverse motor, a second longitudinal motor, a second vertical motor and a second air pump, wherein the second transverse motor, the second longitudinal motor, the second vertical motor and the second air pump are used for controlling the second negative pressure sucker to move transversely, longitudinally and vertically; the third negative pressure sucker unit comprises a third negative pressure sucker, a third transverse motor, a third longitudinal motor, a third vertical motor and a third air pump, wherein the third transverse motor, the third longitudinal motor, the third vertical motor and the third air pump are used for controlling the third negative pressure sucker to move transversely, longitudinally and vertically, and the third air pump is communicated with the third negative pressure sucker through a hose.

7. The glass sheet system of claim 1, wherein: the glass sheet separating system further comprises a control unit, wherein the control unit comprises a main control module, a first sub-control module and at least one second sub-control module, the first sub-control module and the second sub-control module are respectively electrically connected with the main control module, a first rotating motor, a first transverse motor, a first longitudinal motor, a first vertical motor, a first air pump, a second rotating motor, a second transverse motor, a second longitudinal motor, a second vertical motor, a second air pump, a first proximity switch and a second proximity switch are respectively electrically connected with the first sub-control module, and a third rotating motor, a third transverse motor, a third longitudinal motor, a third vertical motor, a third air pump and a third proximity switch of the same branch are respectively electrically connected with the second sub-control modules of the corresponding branches.

8. The glass sheet system of claim 1, wherein: multilayer formula glass storage device includes the base, installs cuboid frame and liftable actuating mechanism on the base, and the symmetrical cover is equipped with the rotation support that is used for placing glass on two rear montants of frame, rotates support top-down layering setting, but and the horizontal rotation, actuating mechanism is used for driving to rotate support horizontal rotation, every all be fixed with an outer gear ring bearing on rotating the support, the fixed cover of outer gear ring bearing is established on the rear montant of frame, thereby actuating mechanism rotates through driving outer gear ring bearing and drives and rotate support horizontal rotation.

9. The glass sheet system of claim 8, wherein: the driving mechanism comprises a vertical plate, a third rotating motor, an electric push rod, a supporting plate, a fourth rotating motor, a sliding plate, a rotating shaft, a lead screw and a gear; the vertical plate is fixed on the base and positioned behind the frame, parallel guide rails are arranged on the front side surface of the vertical plate, the supporting plate is horizontally arranged, parallel sliding grooves are formed in the top surface of the vertical plate, strip-shaped holes are formed among the sliding grooves, screw holes are further formed in the rear sides of the strip-shaped holes, guide blocks matched with the guide rails are arranged on the rear sides of the guide grooves, a third rotating motor is coaxially connected with the upper ends of vertically arranged screw rods, the lower ends of the screw rods penetrate through the screw holes and then are rotatably connected with the base, the screw holes are matched with the screw rods, electric push rods are fixed on the top surface of the supporting plate and fixedly connected with the rear side surface of the sliding plate, sliding blocks matched with the sliding grooves are arranged on the bottom surface of the sliding plate, a fourth rotating motor is installed on the top surface of the sliding; a vertical baffle is also arranged between the vertical plate and the frame; the guide rail is of a T-shaped structure, and the guide block matched with the guide rail is also of a T-shaped structure; the riser trailing flank is equipped with and pushes away the handle, and the base bottom surface is equipped with 4 gyro wheels.

10. The glass sheet system of claim 9, wherein: and the third rotating motor, the electric push rod and the fourth rotating motor are respectively and electrically connected with the second sub-control modules of the corresponding branches.

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