CN214781491U - Three-head numerical control glass cutting machine - Google Patents
Three-head numerical control glass cutting machine Download PDFInfo
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- CN214781491U CN214781491U CN202120594868.4U CN202120594868U CN214781491U CN 214781491 U CN214781491 U CN 214781491U CN 202120594868 U CN202120594868 U CN 202120594868U CN 214781491 U CN214781491 U CN 214781491U
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Abstract
The utility model discloses a three-head numerical control glass cutting machine, relating to the technical field of glass cutting equipment; comprises a working platform, an X-axis motion module, a Y-axis motion module and a Z-axis motion module; the Y-axis motion module comprises two parallel Y-axis guide rails, the Y-axis guide rails are fixed on two sides of the working platform, and the X-axis motion module is slidably mounted on the two Y-axis guide rails so as to be positioned right above the working platform; the X-axis movement module comprises an X-axis mounting plate, and a plurality of Z-axis movement modules are arranged on the X-axis mounting plate in a sliding mode side by side; the Z-axis movement module comprises a Z-axis motor and a cutter head which moves up and down under the driving of the Z-axis motor, and the glass is cut by the cutter head; the utility model has the advantages that: the processing of a plurality of glass work pieces can be realized simultaneously, and the processing efficiency of the equipment is improved.
Description
Technical Field
The utility model relates to a glass-cutting equipment technical field, more specifically the utility model relates to a three numerical control glass-cutting machine that says so.
Background
At present, the demand for glass products such as tablet computers, mobile phone cover plates and LED display screens in the market is continuously increased, blank blanking is carried out by adopting a common glass cutting machine aiming at the traditional processing mode of the products, and finished products are processed by a numerical control engraving and milling machine.
The common glass cutting machine is low in machining precision, generally adopts single-spindle cutting machining, is low in machining efficiency, adopts PLC control, can only do linear motion to machine rectangular glass, and increases equipment, so that equipment cost and site cost are improved.
SUMMERY OF THE UTILITY MODEL
In order to overcome the defects of the prior art, the utility model provides a three-head numerical control glass cutting machine which can simultaneously realize the processing of a plurality of glass workpieces and the processing efficiency of the improved equipment.
The utility model provides a technical scheme that its technical problem adopted is: the improvement of the three-head numerical control glass cutting machine is that the three-head numerical control glass cutting machine comprises a working platform, an X-axis motion module, a Y-axis motion module and a Z-axis motion module;
the Y-axis motion module comprises two parallel Y-axis guide rails, the Y-axis guide rails are fixed on two sides of the working platform, and the X-axis motion module is slidably mounted on the two Y-axis guide rails so as to be positioned right above the working platform;
the X-axis movement module comprises an X-axis mounting plate, and a plurality of Z-axis movement modules are arranged on the X-axis mounting plate in a sliding mode side by side; the Z-axis movement module comprises a Z-axis motor and a cutter head which moves up and down through the driving of the Z-axis motor, and the cutting of the glass is realized through the cutter head.
In the above structure, the Y-axis motion module includes a Y-axis motor, a driving synchronizing wheel, a driven synchronizing wheel and a Y-axis lead screw;
the Y-axis guide rail and the Y-axis screw rod are fixed on the working platform side by side, a Y-axis screw rod sleeve is arranged on the Y-axis screw rod, and two ends of the X-axis movement module are respectively connected with the two Y-axis screw rod sleeves;
the Y-axis motor is fixed below the working platform, the driving synchronizing wheel is connected to the top end of a motor shaft of the Y-axis motor, the driven synchronizing wheel is connected to one end of the Y-axis screw rod, and the driving synchronizing wheel and the driven synchronizing wheel are sleeved with a transmission belt.
In the structure, the X-axis movement module comprises a cross beam, a cross beam left support plate and a cross beam right support plate;
the beam left supporting plate and the beam right supporting plate are respectively fixed on a Y-axis screw rod sleeve, and two ends of the beam are respectively fixed at the top end of the beam left supporting plate and the top end of the beam right supporting plate.
In the structure, the X-axis motion module further comprises an X-axis motor, an X-axis guide rail, an X-axis lead screw and an X-axis sliding plate;
the X-axis guide rail and the X-axis screw rod are fixed on the same side wall of the cross beam in parallel, one end of the X-axis screw rod is connected with a motor shaft of an X-axis motor, the X-axis sliding plate is slidably mounted on the X-axis guide rail, a screw rod nut is fixed on the X-axis sliding plate, and the screw rod nut is mounted on the X-axis screw rod; the X-axis sliding plate is fixed with the X-axis mounting plate.
In the above structure, the Z-axis motion module further includes a Z-axis mounting plate, a Z-axis guide rail, a Z-axis sliding plate, and a Z-axis slider;
the Z-axis guide rail is fixed on one side of the Z-axis mounting plate, the Z-axis sliding block is mounted on the Z-axis guide rail, and the Z-axis sliding plate is fixedly connected with the Z-axis sliding block;
the Z-axis motor is fixed at the top end of the Z-axis mounting plate, the top end of a motor shaft of the Z-axis motor is connected with a Z-axis lead screw, a Z-axis lead screw sleeve is arranged on the Z-axis sliding plate, the Z-axis lead screw penetrates through the Z-axis lead screw sleeve, and the Z-axis sliding plate is driven to slide on the Z-axis guide rail through the drive of the Z-axis motor.
In the above structure, the Z-axis motion module further includes a backing plate, an adjusting cylinder, a floating guide rail, a C-axis support and a C-axis motor;
the C-shaft support is slidably mounted on the floating guide rail, and the C-shaft support is connected with a cylinder rod of the adjusting cylinder;
the C-axis motor is fixed on the C-axis support, and the cutter head is connected with a motor shaft of the C-axis motor and driven by the C-axis motor to rotate.
In the above structure, the cylinder rod of the adjusting cylinder is sleeved with a balance spring, and two ends of the balance spring are respectively pressed on the adjusting cylinder and the C-axis support.
In the structure, a coupler is arranged in the C-axis support, a speed reducer is connected to the C-axis motor, and the coupler is used for connecting the speed reducer and the cutter head.
The utility model has the advantages that: install a plurality of Z axle motion modules side by side on X axle mounting panel, consequently can realize carrying out the operation of processing to a plurality of glass work pieces simultaneously, improve work efficiency, also practiced thrift manpower and cost simultaneously.
Drawings
Fig. 1 is a schematic view of a first three-dimensional structure of a three-head numerical control glass cutting machine according to the present invention.
Fig. 2 is a schematic diagram of a second three-dimensional structure of the three-head numerical control glass cutting machine of the present invention.
Fig. 3 is a schematic structural diagram of a Y-axis movement module of the three-head numerical control glass cutting machine of the present invention.
Fig. 4 is a schematic structural diagram of a Z-axis movement module of the three-head numerical control glass cutting machine of the present invention.
Detailed Description
The present invention will be further explained with reference to the drawings and examples.
The conception, the specific structure, and the technical effects produced by the present invention will be clearly and completely described below in conjunction with the embodiments and the accompanying drawings to fully understand the objects, the features, and the effects of the present invention. Obviously, the described embodiments are only a part of the embodiments of the present invention, and not all embodiments, and other embodiments obtained by those skilled in the art without inventive labor based on the embodiments of the present invention all belong to the protection scope of the present invention. In addition, all the connection/connection relations referred to in the patent do not mean that the components are directly connected, but mean that a better connection structure can be formed by adding or reducing connection auxiliary components according to specific implementation conditions. The utility model discloses each technical feature in the creation can the interactive combination under the prerequisite that does not contradict conflict each other.
Referring to fig. 1 and fig. 2, the utility model discloses a three-head numerical control glass cutting machine, it is concrete, including work platform 40, X axle motion module 10, Y axle motion module 20 and Z axle motion module 30, work platform 40 sets up in frame 50, realizes supporting work platform 40 through frame 50, as shown in fig. 2, the inside vacuum pump 501 that is provided with of frame 50, make work platform 40 produce vacuum suction through vacuum pump 501, the realization is treated the absorption of processing work piece, still be provided with a numerical control on work platform 40 and control platform 401. The Y-axis motion module 20 comprises two parallel Y-axis guide rails 201, the Y-axis guide rails 201 are fixed on two sides of the working platform 40, and the X-axis motion module 10 is slidably mounted on the two Y-axis guide rails 201, so that the X-axis motion module 10 is positioned right above the working platform 40; the X-axis movement module 10 comprises an X-axis mounting plate, and a plurality of Z-axis movement modules 30 are slidably mounted on the X-axis mounting plate side by side; the Z-axis movement module 30 includes a Z-axis motor 301 and a cutter head 302 driven by the Z-axis motor 301 to move up and down, and the cutting of the glass is realized by the cutter head 302.
As shown in fig. 2, the X-axis mounting plate is provided with a spacing adjustment module 60, and the spacing adjustment module 60 adjusts the spacing between adjacent Z-axis movement modules 30, so as to implement processing of glass workpieces of different specifications.
Under the drive of the Z-axis motor 301, the cutter head 302 can reciprocate in the Z-axis direction, and through the cooperation of the Y-axis motion module 20 and the X-axis motion module 10, the Z-axis motion module 30 can move above the working platform 40 along the X-axis direction and the Y-axis direction, so that the glass can be cut. In this embodiment, because install a plurality of Z axle motion modules 30 side by side on X axle mounting panel, consequently can realize carrying out the operation of processing to a plurality of glass work pieces simultaneously, improve work efficiency, also practiced thrift manpower and cost simultaneously.
Referring to fig. 3, for the Y-axis motion module 20, the present invention provides a specific embodiment, the Y-axis motion module 20 includes a Y-axis motor 202, a driving synchronizing wheel 203, a driven synchronizing wheel 204, and a Y-axis lead screw 205; the Y-axis guide rail 201 and the Y-axis lead screw 205 are fixed on the working platform 40 side by side, a Y-axis lead screw sleeve 206 is arranged on the Y-axis lead screw 205, and two ends of the X-axis motion module 10 are respectively connected with the two Y-axis lead screw sleeves 206; the Y-axis motor 202 is fixed below the working platform 40, the driving synchronizing wheel 203 is connected to the top end of a motor shaft of the Y-axis motor 202, the driven synchronizing wheel 204 is connected to one end of a Y-axis screw rod 205, and a transmission belt (not marked in the figure) is sleeved on the driving synchronizing wheel 203 and the driven synchronizing wheel 204. Therefore, under the driving of the Y-axis motor 202, the two Y-axis screws 205 can be rotated simultaneously by the driving of the driving belt, and the Y-axis screw sleeve 206 is driven to translate on the Y-axis screws 205.
Referring to fig. 3, the X-axis motion module 10 includes a beam 102, a beam left support plate 103, and a beam right support plate 104; the beam left support plate 103 and the beam right support plate 104 are respectively fixed on a Y-axis screw rod sleeve 206, and two ends of the beam 102 are respectively fixed at the top end of the beam left support plate 103 and the top end of the beam right support plate 104. Furthermore, the X-axis motion module 10 further includes an X-axis motor 105, an X-axis guide rail 106, an X-axis lead screw 107, and an X-axis slide 108; the X-axis guide rail 106 and the X-axis screw 107 are fixed on the same side wall of the cross beam 102 in parallel, one end of the X-axis screw is connected with a motor shaft of an X-axis motor 105, the X-axis sliding plate 108 is slidably mounted on the X-axis guide rail 106, and a screw nut is fixed on the X-axis sliding plate 108 and mounted on the X-axis screw; the X-axis sliding plate 108 is fixed with the X-axis mounting plate.
Referring to fig. 4, the Z-axis motion module 30 further includes a Z-axis mounting plate 303, a Z-axis guide 304, a Z-axis sliding plate 305, and a Z-axis sliding block 306; the Z-axis guide rail 304 is fixed on one side of the Z-axis mounting plate 303, the Z-axis slider 306 is mounted on the Z-axis guide rail 304, and the Z-axis sliding plate 305 is fixedly connected with the Z-axis slider 306; the Z-axis motor 301 is fixed at the top end of the Z-axis mounting plate 303, the top end of a motor shaft of the Z-axis motor 301 is connected with a Z-axis lead screw, a Z-axis lead screw sleeve is arranged on the Z-axis sliding plate 305, the Z-axis lead screw penetrates through the Z-axis lead screw sleeve, and the Z-axis sliding plate 305 is driven by the Z-axis motor 301 to slide on the Z-axis guide rail 304.
Further, the Z-axis movement module 30 further includes a backing plate 307, an adjusting cylinder 308, a floating guide rail (not labeled), a C-axis support 309, and a C-axis motor 310; the backing plate 307 is fixed on the Z-axis sliding plate 305, the adjusting cylinder 308 and the floating guide rail are both fixed on the backing plate 307, the C-axis support is slidably mounted on the floating guide rail, and the C-axis support 309 is connected with a cylinder rod of the adjusting cylinder 308; the C-axis motor 310 is fixed on the C-axis support 309, and the cutter head 302 is connected with a motor shaft of the C-axis motor 310 and is driven by the C-axis motor 310 to rotate. In addition, a balance spring 311 is sleeved on the cylinder rod of the adjusting cylinder 308, and both ends of the balance spring 311 are respectively pressed on the adjusting cylinder 308 and the C-axis support 309. As shown in fig. 4, a coupling 312 is disposed inside the C-axis support 309, a speed reducer 313 is connected to the C-axis motor 310, and the coupling 312 is used for connecting the speed reducer 313 and the cutter head 302.
The Z-axis sliding plate 305 can translate up and down by the driving of the Z-axis motor 301, so that the cutter head 302 can move up and down; in the process, the adjusting cylinder 308 can drive the C-axis support 309 to move up and down, and the position of the cutter head 302 is finely adjusted, so that the movement precision of the cutter head 302 is improved, and fine cutting is realized; in this process, a damping action is achieved by the compensating spring 311. In addition, through the drive of C axle motor 310, rethread speed reducer and the transmission of shaft coupling 312, can make cutter head 302 realize the rotation of arbitrary angle in the horizontal direction to satisfy multiple different cutting angle demands.
While the preferred embodiments of the present invention have been described, the present invention is not limited to the above embodiments, and those skilled in the art can make various equivalent modifications or substitutions without departing from the spirit of the present invention, and such equivalent modifications or substitutions are intended to be included within the scope of the present invention as defined by the appended claims.
Claims (8)
1. A three-head numerical control glass cutting machine is characterized by comprising a working platform, an X-axis motion module, a Y-axis motion module and a Z-axis motion module;
the Y-axis motion module comprises two parallel Y-axis guide rails, the Y-axis guide rails are fixed on two sides of the working platform, and the X-axis motion module is slidably mounted on the two Y-axis guide rails so as to be positioned right above the working platform;
the X-axis movement module comprises an X-axis mounting plate, and a plurality of Z-axis movement modules are arranged on the X-axis mounting plate in a sliding mode side by side; the Z-axis movement module comprises a Z-axis motor and a cutter head which moves up and down through the driving of the Z-axis motor, and the cutting of the glass is realized through the cutter head.
2. The numerical control glass cutting machine with three heads according to claim 1, wherein the Y-axis motion module comprises a Y-axis motor, a driving synchronizing wheel, a driven synchronizing wheel and a Y-axis screw rod;
the Y-axis guide rail and the Y-axis screw rod are fixed on the working platform side by side, a Y-axis screw rod sleeve is arranged on the Y-axis screw rod, and two ends of the X-axis movement module are respectively connected with the two Y-axis screw rod sleeves;
the Y-axis motor is fixed below the working platform, the driving synchronizing wheel is connected to the top end of a motor shaft of the Y-axis motor, the driven synchronizing wheel is connected to one end of the Y-axis screw rod, and the driving synchronizing wheel and the driven synchronizing wheel are sleeved with a transmission belt.
3. The numerical control glass cutting machine with three heads as claimed in claim 2, wherein the X-axis motion module comprises a beam, a left beam support plate and a right beam support plate;
the beam left supporting plate and the beam right supporting plate are respectively fixed on a Y-axis screw rod sleeve, and two ends of the beam are respectively fixed at the top end of the beam left supporting plate and the top end of the beam right supporting plate.
4. The numerical control glass cutting machine with three heads according to claim 3, wherein the X-axis motion module further comprises an X-axis motor, an X-axis guide rail, an X-axis lead screw and an X-axis slide plate;
the X-axis guide rail and the X-axis screw rod are fixed on the same side wall of the cross beam in parallel, one end of the X-axis screw rod is connected with a motor shaft of an X-axis motor, the X-axis sliding plate is slidably mounted on the X-axis guide rail, a screw rod nut is fixed on the X-axis sliding plate, and the screw rod nut is mounted on the X-axis screw rod; the X-axis sliding plate is fixed with the X-axis mounting plate.
5. The numerical control glass cutting machine with three heads according to claim 1, wherein the Z-axis motion module further comprises a Z-axis mounting plate, a Z-axis guide rail, a Z-axis sliding plate and a Z-axis sliding block;
the Z-axis guide rail is fixed on one side of the Z-axis mounting plate, the Z-axis sliding block is mounted on the Z-axis guide rail, and the Z-axis sliding plate is fixedly connected with the Z-axis sliding block;
the Z-axis motor is fixed at the top end of the Z-axis mounting plate, the top end of a motor shaft of the Z-axis motor is connected with a Z-axis lead screw, a Z-axis lead screw sleeve is arranged on the Z-axis sliding plate, the Z-axis lead screw penetrates through the Z-axis lead screw sleeve, and the Z-axis sliding plate is driven to slide on the Z-axis guide rail through the drive of the Z-axis motor.
6. The numerical control glass cutting machine with three heads according to claim 5, wherein the Z-axis movement module further comprises a backing plate, a regulating cylinder, a floating guide rail, a C-axis support and a C-axis motor;
the C-shaft support is slidably mounted on the floating guide rail, and the C-shaft support is connected with a cylinder rod of the adjusting cylinder;
the C-axis motor is fixed on the C-axis support, and the cutter head is connected with a motor shaft of the C-axis motor and driven by the C-axis motor to rotate.
7. The numerical control glass cutting machine with three heads as claimed in claim 6, wherein the cylinder rod of the adjusting cylinder is sleeved with a balance spring, and two ends of the balance spring are respectively pressed against the adjusting cylinder and the C-axis support.
8. The numerical control glass cutting machine with three heads as claimed in claim 6, wherein a coupling is arranged inside the C-axis support, a speed reducer is connected to the C-axis motor, and the coupling is used for connecting the speed reducer and the cutter head.
Priority Applications (1)
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CN202120594868.4U CN214781491U (en) | 2021-03-24 | 2021-03-24 | Three-head numerical control glass cutting machine |
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CN202120594868.4U CN214781491U (en) | 2021-03-24 | 2021-03-24 | Three-head numerical control glass cutting machine |
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CN214781491U true CN214781491U (en) | 2021-11-19 |
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- 2021-03-24 CN CN202120594868.4U patent/CN214781491U/en active Active
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