Cutting equipment is used in cavity glass production
Technical Field
The utility model relates to the technical field of cutting equipment, in particular to cutting equipment for hollow glass production.
Background
The hollow glass is high-efficiency sound-insulation heat-insulation glass which is prepared by bonding two (or three) glass sheets with an aluminum alloy frame containing a drying agent by using a high-strength high-air-tightness composite adhesive, and has various performances superior to that of common double-layer glass, and patent numbers are found through patent search: CN217535835U: the utility model discloses a cutting equipment is used in cavity glass production and processing can realize rack removal through T type installation pole removal, can realize gear rotation through rack removal, can realize two racks and reverse removal simultaneously through gear rotation, can realize I shape slider removal through T type installation pole removal, can adjust the interval between two cutting heads through two I shape slider removal, can solve the cutting equipment among the prior art only has a cutting assembly for glass cutting inefficiency's problem.
The existing hollow glass cutting device is used for cutting hollow glass, the glass is still connected after the hollow glass is cut, and pressure is applied to the hollow glass at two sides of a cutting position, so that the hollow glass can be separated, the cutting efficiency of the hollow glass is reduced by manual separation, operators are injured by glass breakage during manual separation, safety during use is reduced, and the cutting device for hollow glass production is provided for solving the problems.
Disclosure of Invention
Object of the utility model
In order to solve the technical problems in the background art, the utility model provides cutting equipment for hollow glass production, the bottom of a telescopic rod is firstly contacted with the surface of the hollow glass through a rubber pressing seat, the telescopic rod can be fixed at two sides of a cutting part of the hollow glass, the end part of a pressing rod can be abutted against the cutting part after a supporting spring in the telescopic rod is compressed, the cutting part is extruded through the pressing rod, the quick separation of the hollow glass can be realized, the cutting efficiency is improved, and the safety during operation is also improved.
(II) technical scheme
In order to solve the technical problems, the utility model provides cutting equipment for hollow glass production, which comprises an operating platform, a portal frame and a transverse moving frame, wherein the portal frame is movably connected to the side wall of the operating platform, and the transverse moving frame is movably arranged on the portal frame;
the lower surface of the transverse moving frame is rotatably provided with a rotary disk, the center of the lower surface of the rotary disk is provided with a cutter holder, and the inner cavity of the cutter holder is movably inserted with a glass cutter;
the utility model discloses a rotary disk, including rotary disk, electric putter, connecting frame, telescopic link, rubber press seat, two adjacent groups are equipped with the depression bar between the telescopic link, the mounting groove has been seted up to rotary disk lower surface symmetry, electric putter is all installed to the mounting groove inner chamber, electric putter's stroke pipe end connection has the link, the link both ends all are connected with the telescopic link, the telescopic link bottom is connected with rubber press seat.
Preferably, the fluted disc is arranged on the top surface of the rotary disc.
Preferably, a servo motor is embedded in the side wall of the transverse moving frame, a driving gear is connected with the power output end of the servo motor, and the driving gear is meshed with the fluted disc.
Preferably, the end part of the pressure rod is of a trapezoid structure.
Preferably, dust collection nozzles are symmetrically arranged on the lower surface of the rotary disk, and the dust collection nozzles and the telescopic rods are arranged in a staggered mode.
Preferably, a dust collector is arranged on the top surface of the transverse moving frame, and the dust collector is connected with the dust collection nozzle through a dust collection pipe.
Preferably, the inner cavity of the telescopic rod is provided with a supporting spring, and the bottom of the telescopic rod is lower than the bottom of the compression rod in height.
The technical scheme of the utility model has the following beneficial technical effects:
according to the utility model, the bottom of the telescopic rod is firstly contacted with the surface of the hollow glass through the rubber pressing seat, the telescopic rod can be fixed at two sides of the cutting position of the hollow glass, the end part of the pressing rod can be abutted to the cutting position after the supporting spring in the telescopic rod is compressed, the cutting position is extruded through the pressing rod, the quick separation of the hollow glass can be realized, the cutting efficiency is improved, and the safety during operation is also improved.
According to the utility model, tiny glass scraps can be generated in the cutting process, and the glass scraps can be sucked away at the cutting position of the glass knife through the mutual matching of the dust collector and the dust collection nozzle, so that the splashing of the glass scraps can be reduced.
Drawings
FIG. 1 is a schematic diagram of the overall structure of the present utility model;
FIG. 2 is a schematic view of a glass cutter mounting structure according to the present utility model;
FIG. 3 is a schematic diagram of a rotary disk drive according to the present utility model;
fig. 4 is a schematic cross-sectional view of the telescopic rod according to the present utility model.
Reference numerals:
1. an operation table; 2. a portal frame; 3. a transverse moving frame; 4. a rotating disc; 5. a tool apron; 6. a glass cutter; 7. fluted disc; 8. a servo motor; 9. a drive gear; 10. an electric push rod; 11. a connecting frame; 12. a telescopic rod; 13. a rubber pressing seat; 14. a compression bar; 15. a dust collector; 16. a dust suction nozzle.
Detailed Description
The objects, technical solutions and advantages of the present utility model will become more apparent by the following detailed description of the present utility model with reference to the accompanying drawings. It should be understood that the description is only illustrative and is not intended to limit the scope of the utility model. In addition, in the following description, descriptions of well-known structures and techniques are omitted so as not to unnecessarily obscure the present utility model.
As shown in fig. 1-4, the cutting equipment for hollow glass production provided by the utility model comprises an operating platform 1, a portal frame 2 and a transverse moving frame 3, wherein the portal frame 2 is movably connected to the side wall of the operating platform 1, and the transverse moving frame 3 is movably arranged on the portal frame 2;
the lower surface of the transverse moving frame 3 is rotatably provided with a rotary disk 4, the center of the lower surface of the rotary disk 4 is provided with a cutter holder 5, and a glass cutter 6 is movably inserted into the inner cavity of the cutter holder 5;
the utility model discloses a rotary disk, including rotary disk 4, electric putter 10, connecting frame 11, telescopic link 12 bottom is connected with rubber and presses seat 13, two adjacent groups be equipped with depression bar 14 between the telescopic link 12, telescopic link 12 inner chamber is equipped with supporting spring, telescopic link 12 bottom is less than depression bar 14 bottom height, the depression bar 14 tip is trapezium structure.
It should be noted that, the hollow glass is placed on the surface of the operation table 1, and the horizontal moving frame 3 moves along the operation table through the portal frame 2, and meanwhile, the glass knife 6 can be driven to flexibly move on the surface of the operation table 1;
after cutting, the electric push rod 10 is controlled to extend, the electric push rod 10 pushes the pressure rod 14 and the telescopic rod 12 to be pressed downwards through the stroke pipe, the bottom of the telescopic rod 12 is lower than the height of the pressure rod 14, so that the bottom of the telescopic rod 12 is firstly contacted with the surface of hollow glass through the rubber pressing seat 13, the two sides of the cutting part of the hollow glass can be fixed, the end part of the pressure rod 14 can be abutted to the cutting part after the supporting spring in the telescopic rod 12 is compressed, the cutting part is extruded through the pressure rod 14, and the quick separation of the hollow glass can be realized.
As shown in fig. 1, a fluted disc 7 is arranged on the top surface of the rotary disc 4, a servo motor 8 is embedded in the side wall of the transverse moving frame 3, a driving gear 9 is connected to the power output end of the servo motor 8, and the driving gear 9 is meshed with the fluted disc 7.
It should be noted that, when changing the cutting direction, the cutter head of the glass cutter 6 is of a wheel type structure, and the driving gear 9 is driven by the control servo motor 8, the driving gear 9 drives the fluted disc 7 to rotate, so that the glass cutter 6 can be driven to rotate by the fluted disc 7, the angle of the cutter head can be changed, and the cutting quality of the hollow glass can be improved.
As shown in fig. 1 and 3, the lower surface of the rotating disc 4 is symmetrically provided with dust collection nozzles 16, the dust collection nozzles 16 and the telescopic rods 12 are arranged in a staggered mode, the top surface of the transverse moving frame 3 is provided with a dust collector 15, and the dust collector 15 is connected with the dust collection nozzles 16 through dust collection pipes.
In addition, tiny glass scraps can be generated in the cutting process, and the glass scraps can be sucked away at the cutting position of the glass knife 6 through the mutual matching of the dust collector 15 and the dust collection nozzle 16, so that the splashing of the glass scraps can be reduced.
The working principle and the using flow of the utility model are as follows: placing hollow glass on the surface of an operating platform 1, moving along the operating platform through a portal frame 2, moving along the portal frame 2 through a transverse moving frame 3, driving a glass cutter 6 to flexibly move on the surface of the operating platform 1, cutting the hollow glass through the glass cutter 6, generating tiny glass scraps in the cutting process, sucking away the glass scraps at the cutting position of the glass cutter 6 through the mutual cooperation of a dust collector 15 and a dust suction nozzle 16, reducing splashing of the glass scraps, driving a driving gear 9 through controlling a servo motor 8 when changing the cutting direction, driving a fluted disc 7 to rotate through controlling a servo motor 9, driving the glass cutter 6 to rotate through the fluted disc 7, changing the angle of the cutting bit, improving the cutting quality of the hollow glass, extending through controlling an electric push rod 10 after cutting, pushing a compression rod 14 and a telescopic rod 12 through a stroke pipe, enabling the bottom of the telescopic rod 12 to be lower than the height of the compression rod 14, enabling the bottom of the telescopic rod 12 to be in contact with the surface of the hollow glass at first, fixing two sides of the cutting position of the hollow glass, fixing the telescopic rod 12 at two sides, supporting the telescopic rod 12 and then compressing the compression rod 14, and enabling the end of the hollow glass to be in contact with the compression rod 14 to be quickly pressed, so that the hollow glass can be cut and separated.
It is to be understood that the above-described embodiments of the present utility model are merely illustrative of or explanation of the principles of the present utility model and are in no way limiting of the utility model. Accordingly, any modification, equivalent replacement, improvement, etc. made without departing from the spirit and scope of the present utility model should be included in the scope of the present utility model. Furthermore, the appended claims are intended to cover all such changes and modifications that fall within the scope and boundary of the appended claims, or equivalents of such scope and boundary.