CN216946717U - Glass product production system - Google Patents

Abstract

The utility model discloses a glass product production system, which aims to solve the technical problems that a mold locking mechanism of the existing glass bubble blowing mechanism is difficult to separate and is inconvenient to replace. The glass product production system comprises a driving belt, a U-shaped workbench, a bubble blowing mechanism, a first vertical oil cylinder and a rotating motor, wherein the driving belt is intermittently conveyed from left to right, the U-shaped workbench is horizontally arranged on the rear side of the driving belt, the bubble blowing mechanism is installed at the upper end of the workbench, and the first vertical oil cylinder and the rotating motor are installed at the lower end of the workbench. This glassware production system adopts vertical elevating system control mould locking in the workstation, has the effect of accurate butt joint simultaneously for the bubbling mechanism, can be with the ejecting workstation of mould, and the gyration push pedal can be used as the change of mould when having the fashioned glassware of propelling movement, accomplishes the variety of equipment function, and automatic mould change does not need artifical the participation, shortens the equipment because of the working gap who changes the mould and produce, reduces the probability that the incident takes place.

Description

Glass product production system

Technical Field

The utility model belongs to the field of glass production equipment, and particularly relates to a glass product production system.

Background

The glass product is an industrial commodity with low price, economy and practicality, is an inorganic non-metallic material with wider application range, can be applied to the fields of buildings, daily use, art, instruments and the like, has abundant types, and is particularly widely used in household life.

The glass product is produced through a series of processes such as stirring and mixing of raw materials, high-temperature melting in a furnace, shaping in a bubble machine, and cooling and annealing. Therefore, different processing equipment is required to be equipped in a glass manufacturing factory according to various procedures to form a complete industrial production chain, glass is matched with a corresponding mould in the process of blowing bubble molding, the mould is required to be accurately installed relative to a bubble blowing machine, a locking mechanism of the mould is difficult to separate, and the mould is difficult to replace

Therefore, aiming at the condition that the bubble blowing mould of the glass production system is not easy to replace, a mould mounting structure is developed, and the plane turnover mechanism of the glass product is matched with the mounting mechanism of the mould, so that the equipment can be freely started and stopped in the process of moving the glass, and the mould is replaced.

SUMMERY OF THE UTILITY MODEL

(1) Technical problem to be solved

Aiming at the defects of the prior art, the utility model aims to provide a glassware production system, which aims to solve the technical problems that the mold locking mechanism of the existing glass bubbling mechanism is difficult to disengage and inconvenient to replace.

(2) Technical scheme

In order to solve the technical problems, the utility model provides a glass product production system which comprises a transmission belt intermittently conveyed from left to right, a U-shaped workbench horizontally arranged at the rear side of the transmission belt, a bubble blowing mechanism arranged at the upper end of the workbench, a vertical oil cylinder and a rotating motor, wherein the vertical oil cylinder and the rotating motor are arranged at the lower end of the workbench, the upper end of the vertical oil cylinder is vertically and annularly movably connected with a lifting rod, a cylindrical hollow mold for shaping glass products is arranged at the upper end of the lifting rod, the mold is arranged below the bubble blowing mechanism, the rotating motor is arranged at the right side of the vertical oil cylinder, the upper end of the rotating motor is movably connected with a balance table, the upper end of the balance table is provided with a rotating shaft, and the outer side of the rotating shaft is horizontally connected with a rotating push plate for moving the mold and forming glass products, the mould is characterized in that the rotary push plate is arranged on the upper side of the transmission belt, a horizontal oil cylinder is arranged on the right side of the front end of the transmission belt, a push-pull rod is movably connected to the rear end of the horizontal oil cylinder, a hook connecting plate used for horizontally taking out the mould is transversely connected to the top end of the push-pull rod, and the left end of the hook connecting plate is arranged above the rotary push plate.

When the glass product production system adopting the technical scheme is used, a user starts a vertical oil cylinder to eject a mold from a lifting port to a position above a workbench, then starts a horizontal oil cylinder, enables a hooking plate to move to the upper part of the rear end of a transmission belt, then starts a rotating motor, utilizes a rotary push plate to horizontally move the mold onto the transmission belt, enables the horizontal oil cylinder to drive the hooking plate to move backwards, enables the mold to be hooked and moved and separated from the upper side of the transmission belt, places another mold on the rear side of the hooking plate to be ejected onto the transmission belt, then drives the rotary push plate to reversely rotate through the rotating motor to move the mold to the upper part of the lifting port, drives the mold to descend and lock the mold, and utilizes a bubble blowing mechanism to match the mold to blow glass products.

Preferably, a second horizontal oil cylinder is arranged on the left side of the front end of the transmission belt, a second push-pull rod is movably connected to the rear end of the second horizontal oil cylinder, a feeding push plate is fixedly connected to the top end of the second push-pull rod, and the feeding push plate is arranged on the upper side of the transmission belt. A second horizontal oil cylinder controls a feeding push plate to push scattered glass raw materials to a stirring mechanism, and a driving belt has the function of conveying the raw materials and glass finished products.

Preferably, the left side of the upper end of the workbench is provided with a material mixing mechanism, a material sliding groove is arranged between the material mixing mechanism and the transmission belt, and the feeding push plate is arranged above the material sliding groove. The material sliding groove is directly communicated with a feeding hole of the material mixing mechanism and is of an inclined plane structure, and raw materials automatically slide into the material mixing mechanism to be mixed through built-in motor equipment.

Preferably, a limiting baffle is arranged between the second horizontal oil cylinder and the upper part of the workbench, the limiting baffle is arranged on the right side of the feeding push plate, and the lower end of the limiting baffle is attached to the surface of the transmission belt. The spacing breast board is held back scattered raw materials in the left side of drive belt, prevents to carry along the drive belt continuously right.

Preferably, a furnace melting mechanism is installed at the upper end of the workbench, the furnace melting mechanism is arranged on the right side of the material mixing mechanism, a pumping mechanism is arranged between the furnace melting mechanism and the material mixing mechanism, a material conveying pipeline is connected between the material mixing mechanism and the pumping mechanism, and the other material conveying pipeline is connected between the furnace melting mechanism and the bubbling mechanism. The pumping mechanism sucks the mixed materials in the stirring mechanism into a furnace melting mechanism for heating and melting, and then introduces the molten glass into the bubble blowing mechanism through a material conveying pipeline to prepare for blowing glass products.

Preferably, a lifting port is formed in the upper end of the workbench, the mold is arranged on the inner side of the lifting port, a second vertical oil cylinder is installed at the upper end of the first vertical oil cylinder, an ejector rod is movably connected to the upper end of the second vertical oil cylinder, a bearing platform is fixedly connected to the upper end of the ejector rod, and the bearing platform is arranged on the inner side of the mold. When the mold descends into the lifting port, the lifting port is locked by being attached to the outer wall of the mold to prevent movement, the second vertical oil cylinder controls the bearing platform to seal the pore channel at the lower end of the mold, and molded glass can be ejected out of the mold.

Preferably, the right end of the transmission belt is provided with a transition plate, and the right end of the transition plate is provided with a blanking table. The formed glass product is moved to a transmission belt by a rotary push plate, then conveyed to the right to a transition plate, and enters a collection system or annealing equipment along a blanking table for cooling operation.

(3) Advantageous effects

Compared with the prior art, the utility model has the beneficial effects that: the glass product production system provided by the utility model has the advantages that the vertical lifting mechanism is adopted to control the mold to be locked in the workbench, the mold can be ejected out of the workbench to be used as the preparation work of the mold replacing mechanism while the mold is accurately butted against the bubbling mechanism, the rotary push plate can be used for replacing the mold while pushing the formed glass product, the function diversity of equipment is realized, the automatic mold replacement does not need manual participation, the working gap of the equipment caused by mold replacement is shortened, the direct contact with the equipment is reduced, and the probability of safety accidents is reduced.

Drawings

FIG. 1 is a schematic view of an assembly configuration of an embodiment of a glassware production system of the present invention;

FIG. 2 is a schematic view of another state assembly configuration of an embodiment of a glassware production system of the present invention;

FIG. 3 is a schematic structural view of a mold control mechanism in accordance with one embodiment of the glassware production system of the present invention;

fig. 4 is a schematic structural diagram of a mold changing mechanism according to an embodiment of the present invention.

The symbols in the drawings are: 1. a transmission belt; 2. a work table; 3. a bubble blowing mechanism; 4. a first vertical oil cylinder; 5. a lifting rod; 6. a mold; 7. a rotating electric machine; 8. a balancing table; 9. a rotating shaft; 10. a rotary push plate; 11. a first horizontal oil cylinder; 12. a first push-pull rod; 13. hooking the connecting plate; 14. a second horizontal oil cylinder; 15. a second push-pull rod; 16. a feeding push plate; 17. a material mixing mechanism; 18. a chute; 19. a limit sideboard; 20. a furnace melting mechanism; 21. a pumping mechanism; 22. a delivery pipeline; 23. a lifting port; 24. a second vertical oil cylinder; 25. ejecting the rod; 26. a support platform; 27. a transition plate; 28. a blanking table.

Detailed Description

The specific embodiment is used for a glass product production system, the assembly structure schematic diagram of which is shown in fig. 1, the assembly structure schematic diagram of which is shown in fig. 2, the control mechanism schematic diagram of a mold 6 is shown in fig. 3, and the replacement mechanism schematic diagram of the mold 6 is shown in fig. 4, the glass product production system comprises a transmission belt 1 which is intermittently conveyed from left to right, a U-shaped worktable 2 which is horizontally arranged at the rear side of the transmission belt 1, a bubble blowing mechanism 3 which is arranged at the upper end of the worktable 2, a vertical oil cylinder 4 which is arranged at the lower end of the worktable 2 and a rotating motor 7, wherein a lifting rod 5 is movably connected at the upper end of the vertical oil cylinder 4 in a vertical annular manner, a cylindrical hollow mold 6 which is used for shaping glass products is arranged at the upper end of the lifting rod 5, the mold 6 is arranged below the bubble blowing mechanism 3, the rotating motor 7 is arranged at the right side of the vertical oil cylinder 4, a balancing table 8 is movably connected at the upper end of the rotating motor 7, a rotary shaft 9 is installed at the upper end of the balance table 8, a rotary push plate 10 used for moving the mold 6 and the formed glass product is horizontally connected to the outer side of the rotary shaft 9, the rotary push plate 10 is arranged on the upper side of the driving belt 1, a horizontal oil cylinder 11 is arranged on the right side of the front end of the driving belt 1, a push-pull rod 12 is movably connected to the rear end of the horizontal oil cylinder 11, a hooking plate 13 used for horizontally taking out the mold 6 is transversely connected to the top end of the push-pull rod 12, and the left end of the hooking plate 13 is arranged above the rotary push plate 10.

To this embodiment, the rotating electrical machine 7 drives the rotating push plate 10 to rotate counterclockwise from the workbench 2 to move the mold 6 to the transmission belt 1, after the hooking plate 13 takes the mold 6 out of the transmission belt 1, the rotating electrical machine 7 makes the hooking plate 13 rotate counterclockwise again by a certain angle, and when the new mold 6 is sent into the transmission belt 1, the rotating electrical machine 7 drives the rotating push plate 10 to rotate clockwise to move the new mold 6 to the lower side of the bubbling mechanism 3.

Wherein, drive belt 1 front end left side is provided with horizontal cylinder 14 No. two, No. two 14 rear end swing joints of horizontal cylinder have push-and-pull rod 15 No. two, 15 top fixedly connected with pay-off push pedal 16 of push-and-pull rod, pay-off push pedal 16 sets up in drive belt 1 upside, 2 upper end left sides of workstation are installed and are mixed material mechanism 17, it is provided with smooth silo 18 to mix between material mechanism 17 and the drive belt 1, pay-off push pedal 16 sets up in smooth silo 18 top, install spacing breast board 19 between No. two horizontal cylinder 14 and the 2 tops of workstation, spacing breast board 19 sets up in pay-off push pedal 16 right side, the laminating of 19 lower extremes of spacing breast board is in drive belt 1 surface. Horizontal cylinder 14 control pay-off push pedal 16 will be scattered glass raw materials to mixing the propelling movement of material mechanism 17, drive belt 1 has the function of carrying raw materials and glass finished product simultaneously, smooth silo 18 directly lets in the feed inlet of mixing material mechanism 17, and be the inclined plane structure, the raw materials automatic sliding is mixed material mechanism 17 and is carried out the mixture of material through built-in electrical equipment, spacing breast board 19 is detained scattered raw materials in the left side of drive belt 1, prevent to continue to carry right along drive belt 1.

Meanwhile, a furnace melting mechanism 20 is installed at the upper end of the workbench 2, the furnace melting mechanism 20 is arranged on the right side of the material mixing mechanism 17, a pumping mechanism 21 is arranged between the furnace melting mechanism 20 and the material mixing mechanism 17, a material conveying pipeline 22 is connected between the material mixing mechanism 17 and the pumping mechanism 21, and the other material conveying pipeline 22 is connected between the furnace melting mechanism 20 and the bubble blowing mechanism 3. The pumping mechanism 21 sucks the mixed materials in the mixing mechanism 17 into the furnace melting mechanism 20 for heating and melting, and then introduces the molten glass into the bubbling mechanism 3 through the delivery pipeline 22 to prepare for blowing glass products.

In addition, a lifting port 23 is formed in the upper end of the workbench 2, the die 6 is arranged on the inner side of the lifting port 23, a second vertical oil cylinder 24 is installed at the upper end of the first vertical oil cylinder 4, an ejector rod 25 is movably connected to the upper end of the second vertical oil cylinder 24, a bearing platform 26 is fixedly connected to the upper end of the ejector rod 25, the bearing platform 26 is arranged on the inner side of the die 6, a transition plate 27 is arranged at the right end of the transmission belt 1, and a blanking platform 28 is arranged at the right end of the transition plate 27. When the mold 6 descends into the lifting port 23, the lifting port 23 is locked by the fit of the outer wall of the mold 6, the movement is prevented, the second vertical oil cylinder 24 controls the supporting platform 26 to close the pore channel at the lower end of the mold 6 and can eject the formed glass out of the mold 6, the formed glass product is moved onto the transmission belt 1 by the rotary push plate 10, then is conveyed to the right on the transition plate 27, and enters a collection system or annealing equipment along the blanking platform 28 for cooling operation.

When the glass product production system of the technical scheme is used, a user puts scattered glass raw materials on the left side of a transmission belt 1, the second horizontal oil cylinder 14 drives a feeding push plate 16 to push the materials into a chute 18 and finally enter a stirring mechanism 17 while the glass raw materials are conveyed rightwards, after the materials are stirred, a pumping mechanism 21 sucks the materials into a furnace melting mechanism 20 for high-temperature melting, then the molten glass is guided into a bubble blowing mechanism 3 and matched with a lower mold 6 for processing glass products, after the glass products are molded, the second vertical oil cylinder 24 is started, the glass products are ejected out of the mold 6 through a supporting platform 26, then a rotating motor 7 is started, the glass products are moved to the transmission belt 1 through the rotating push plate 10 and conveyed rightwards to a transition plate 27 to enter a rear annealing program, then the rotating motor 7 resets the rotating push plate 10, when the mold 6 needs to be replaced, starting a first vertical oil cylinder 4 to eject a mold 6 to a position above a workbench 2 from a lifting port 23, then starting a first horizontal oil cylinder 11 to enable a hooking plate 13 to move to the upper part of the rear end of a transmission belt 1, then starting a rotating motor 7, horizontally moving the mold 6 to the transmission belt 1 by utilizing a rotary push plate 10, enabling the first horizontal oil cylinder 11 to drive the hooking plate 13 to move back, enabling the mold 6 to be hooked and moved and separated from the upper side of the transmission belt 1, placing another mold 6 at the rear side of the hooking plate 13 to be ejected onto the transmission belt 1, then driving the rotary push plate 10 to reversely rotate through the rotating motor 7 to move the new mold 6 to the upper part of the lifting port 23, driving the new mold 6 to descend and lock the new mold 6 by the first vertical oil cylinder 4, and carrying out blowing on glass products again by matching with the new mold 6 by the bubble blowing mechanism 3 according to the processing method.

Claims (7)

1. The utility model provides a glassware production system, this glassware production system include intermittent type nature from left right conveying's drive belt, level set up in the U type workstation of drive belt rear side, install in the bubbling mechanism of workstation upper end, install in a perpendicular hydro-cylinder and rotating electrical machines of workstation lower extreme, its characterized in that: a vertical annular swing joint in perpendicular hydro-cylinder upper end has the lifter, the lifter upper end is provided with and is used for the fashioned cylindrical hollow mould of glassware, the mould set up in bubbling mechanism below, the rotating electrical machines set up in perpendicular hydro-cylinder right side, rotating electrical machines upper end swing joint has the balancing stand, the revolving axle is installed to the balancing stand upper end, revolving axle outside horizontally connected with is used for removing the gyration push pedal of mould and shaping glassware, the gyration push pedal set up in the drive belt upside, drive belt front end right side is provided with horizontal cylinder No. one, horizontal cylinder rear end swing joint has a push-and-pull rod No. one, push-and-pull rod top transverse connection has and is used for the level to take out collude the tie plate of mould, collude the tie plate left end set up in gyration push pedal top.

2. The glassware production system of claim 1, wherein a second horizontal cylinder is disposed on a left side of a front end of the transmission belt, a second push-pull rod is movably connected to a rear end of the second horizontal cylinder, a feeding push plate is fixedly connected to a top end of the second push-pull rod, and the feeding push plate is disposed on an upper side of the transmission belt.

3. The glassware production system of claim 2, wherein a material mixing mechanism is mounted to the left side of the upper end of the work table, a material sliding groove is disposed between the material mixing mechanism and the drive belt, and the feeding push plate is disposed above the material sliding groove.

4. The glassware production system of claim 2, wherein a limit fence is installed between the second horizontal cylinder and the upper side of the workbench, the limit fence is arranged on the right side of the feeding push plate, and the lower end of the limit fence is attached to the surface of the transmission belt.

5. The system for producing glass products as claimed in claim 3, wherein a furnace melting mechanism is installed at the upper end of the workbench, the furnace melting mechanism is disposed at the right side of the stirring mechanism, a pumping mechanism is disposed between the furnace melting mechanism and the stirring mechanism, a material conveying pipeline is connected between the stirring mechanism and the pumping mechanism, and the other material conveying pipeline is connected between the furnace melting mechanism and the bubbling mechanism.

6. The glassware production system of claim 1, wherein a lifting opening is formed in an upper end of the workbench, the mold is disposed inside the lifting opening, a second vertical oil cylinder is mounted at an upper end of the first vertical oil cylinder, an ejector rod is movably connected to an upper end of the second vertical oil cylinder, a supporting table is fixedly connected to an upper end of the ejector rod, and the supporting table is disposed inside the mold.

7. A glassware producing system, as set forth in claim 1, wherein a transition plate is provided at the right end of the drive belt, and a blanking station is provided at the right end of the transition plate.

Images