CN215559867U - Multi-head numerical control glass cutting device - Google Patents

Abstract

The utility model discloses a multi-head numerical control glass cutting device, and relates to the technical field of numerical control; comprises a workbench, a Y-axis motion module, an X-axis motion module and a Z-axis motion module; the Y-axis motion module comprises a Y-axis motor, a Y-axis lead screw, a lead screw sleeve connecting frame, a Y-axis dragging plate and a Y-axis sliding rail; two ends of the X-axis motion module are respectively and fixedly arranged on the Y-axis slide block and are driven by the Y-axis motor to perform reciprocating translation on the Y-axis slide rail; the Z-axis motion module is arranged on the X-axis motion module and is driven by the X-axis motion module to perform reciprocating translation in the X-axis direction; the Z-axis movement module comprises a processing tool bit for processing glass; the utility model has the beneficial effects that: the operation of simultaneously processing a plurality of glass workpieces can be realized, and the working efficiency is improved; meanwhile, the labor and the cost are saved.

Description

Multi-head numerical control glass cutting device

Technical Field

The utility model relates to the technical field of numerical control, in particular to a multi-head numerical control glass cutting device.

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 multi-head numerical control glass cutting device which can simultaneously machine a plurality of glass workpieces.

The technical scheme adopted by the utility model for solving the technical problems is as follows: the improvement of the multi-head numerical control glass cutting device is that the device comprises a workbench, a Y-axis motion module, an X-axis motion module and a Z-axis motion module;

the Y-axis motion module comprises a Y-axis motor, a Y-axis lead screw, a lead screw sleeve connecting frame, a Y-axis dragging plate and a Y-axis sliding rail; the Y-axis motor is fixedly arranged below the workbench, one end of a Y-axis lead screw is connected with the Y-axis motor, a lead screw nut is arranged on the Y-axis lead screw, the middle part of the lead screw sleeve connecting frame is fixed on the lead screw nut, and two ends of the lead screw sleeve connecting frame extend out of the lower part of the workbench and are respectively connected with the bottom ends of the two Y-axis dragging plates; the two Y-axis sliding rails are fixed at two opposite ends of the workbench in parallel, each Y-axis sliding rail is provided with a Y-axis sliding block in a sliding manner, and the top end of the Y-axis dragging plate is fixedly connected with the Y-axis sliding block;

two ends of the X-axis motion module are respectively and fixedly arranged on the Y-axis slide block and are driven by the Y-axis motor to perform reciprocating translation on the Y-axis slide rail; the Z-axis motion module is arranged on the X-axis motion module and is driven by the X-axis motion module to perform reciprocating translation in the X-axis direction; the Z-axis movement module comprises a machining tool bit for machining glass.

In the above structure, the Y-axis motion module further includes a Y-axis support, the Y-axis support is fixedly mounted on the lower surface of the worktable, and the other end of the Y-axis lead screw is rotatably mounted inside the Y-axis support.

In the structure, notches are arranged at two opposite ends of the workbench, so that steps are formed on the workbench, and the Y-axis guide rail is fixed at the steps.

In the structure, the multi-head numerical control glass cutting device further comprises a main frame, and the workbench is fixedly arranged on the main frame.

In the above structure, one side of the main frame is provided with a column, and the top end of the column is provided with a system control box.

In the structure, the X-axis motion module comprises a cross beam, an X-axis motor, an X-axis guide rail, an X-axis lead screw and an X-axis sliding plate;

two ends of the cross beam are respectively and fixedly arranged on the Y-axis sliding block;

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.

In the above structure, the X-axis sliding plate is provided with an adjusting guide rail, and the Z-axis motion module comprises a Z1-axis motion module slidably mounted on the adjusting guide rail and a Z2-axis motion module fixedly mounted on the X-axis sliding plate;

and the X-axis sliding plate is provided with an adjusting assembly for adjusting the relative position of the Z1 axis motion module and the Z2 axis motion module.

In the above structure, the adjusting assembly includes an adjusting motor, an adjusting screw rod and an adjusting screw rod nut;

the adjusting screw rod is connected with a motor shaft of the adjusting motor, and the adjusting screw rod nut is arranged on the adjusting screw rod;

the Z1 axle motion module include Z axle slide, adjust feed screw nut and Z axle slide fixed connection, through the drive of adjusting motor, make Z axle slide translation on adjusting the guide rail.

The utility model has the beneficial effects that: the integral structure is more attractive in appearance, the space at the bottom of the workbench is reasonably utilized, the size of the integral equipment in the height direction is reduced, the integral volume of the equipment is smaller, and the space for placing products is reduced; the operation of simultaneously processing a plurality of glass workpieces can be realized, and the working efficiency is improved; meanwhile, the labor and the cost are saved.

Drawings

FIG. 1 is a schematic view of a first three-dimensional structure of a multi-head numerical control glass cutting device according to the present invention.

FIG. 2 is a second perspective view of a multi-head NC glass cutting apparatus according to the present invention.

FIG. 3 is an exploded view of a multi-head NC glass cutting apparatus according to the present invention.

FIG. 4 is a schematic structural diagram of a Z-axis motion module of the multi-head numerical control glass cutting device according to the present invention.

Detailed Description

The utility model is further illustrated with reference to the following figures 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. It is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all embodiments, and those skilled in the art can obtain other embodiments without inventive effort based on the embodiments of the present invention, and all embodiments are within 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. All technical characteristics in the utility model can be interactively combined on the premise of not conflicting with each other.

Referring to fig. 1 to 3, the present invention discloses a multi-head numerical control glass cutting device, which comprises a worktable 10, a Y-axis movement module 20, an X-axis movement module 30 and a Z-axis movement module 40; referring to fig. 3, for the Y-axis driving module, a specific embodiment of the present invention is provided, in which the Y-axis moving module 20 includes a Y-axis motor 201, a Y-axis screw 202, a screw sleeve connecting frame 203, a Y-axis dragging plate 204, and a Y-axis sliding rail 205; the Y-axis motor 201 is fixedly arranged below the workbench 10, one end of a Y-axis lead screw 202 is connected with the Y-axis motor 201, a lead screw nut is arranged on the Y-axis lead screw 202, the middle part of the lead screw sleeve connecting frame 203 is fixed on the lead screw nut, and two ends of the lead screw sleeve connecting frame 203 extend out of the lower part of the workbench 10 and are respectively connected with the bottom ends of two Y-axis dragging plates 204; two Y-axis slide rails 205 are fixed in parallel at two opposite ends of the workbench 10, each Y-axis slide rail 205 is slidably mounted with a Y-axis slide block 206, and the top end of the Y-axis dragging plate 204 is fixedly connected with the Y-axis slide block 206. In addition, the Y-axis motion module 20 further includes a Y-axis support 207, the Y-axis support 207 is fixedly mounted on the lower surface of the table 10, and the other end of the Y-axis screw is rotatably mounted inside the Y-axis support 207.

As shown in fig. 1 and fig. 2, two ends of the X-axis motion module 30 are respectively and fixedly mounted on a Y-axis slider 206, and are driven by a Y-axis motor 201 to reciprocate on a Y-axis slide rail 205; the Z-axis motion module 40 is arranged on the X-axis motion module 30 and is driven by the X-axis motion module to perform reciprocating translation in the X-axis direction; the Z-axis motion module 40 includes a machining tool bit 401 for machining glass.

In the above embodiment, the multi-head numerical control glass cutting device further includes a main frame 50, the workbench 10 is fixedly mounted on the main frame 50, an upright 501 is mounted on one side of the main frame 50, and a system control box 502 is disposed at the top end of the upright 501. With reference to fig. 1 and 2, a gap for extending the screw sleeve connection frame 203 is reserved between the main frame 50 and the workbench 10, in this way, most of the structure of the Y-axis driving module is disposed below the workbench 10, wherein the Y-axis motor 201 and the Y-axis support 207 are directly fixed on the lower surface of the workbench 10, the structure of the Y-axis motor 201, the Y-axis screw 202 and the Y-axis support 207 cannot be seen in normal use, and the overall structure is designed in a hidden manner, so that the overall structure is more beautiful; and reasonable the space of having utilized workstation 10 bottom, compare in the structure with Y axle motion module 20 setting on workstation 10, reduced whole equipment size on the direction of height for the holistic volume of equipment is less, has reduced area. In addition, because the worktable 10 is thick and heavy, deformation is not easy to occur, the installation accuracy of the Y-axis motor 201 and the Y-axis support 207 is improved, and the situation of large error does not occur even after long-time use, thereby improving the processing accuracy of products.

In the above embodiment, notches are provided at opposite ends of the table 10, so that a step is formed on the table 10, and the Y-axis guide rail is fixed at the step. This kind of structural design makes X axle motion module 30 be close to more in the upper surface of workstation 10 in Z axle direction, reduces the height of equipment as far as possible under the circumstances that satisfies the processing requirement, and the demand of processing also can be satisfied to workstation 10 simultaneously.

As for the X-axis movement module 30, as shown in fig. 1 and fig. 2, the X-axis movement module 30 includes a cross beam 301, an X-axis motor 302, an X-axis guide rail 303, an X-axis lead screw 304, and an X-axis slide plate 305; two ends of the beam 301 are respectively and fixedly arranged on the Y-axis sliding block 206; the X-axis guide rail 303 and the X-axis lead screw 304 are fixed on the same side wall of the cross beam 301 in parallel, one end of the X-axis lead screw 304 is connected with a motor shaft of the X-axis motor 302, the X-axis sliding plate 305 is slidably mounted on the X-axis guide rail 303, and a lead screw nut is fixed on the X-axis sliding plate 305 and mounted on the X-axis lead screw 304; the X-axis screw 304 is driven to rotate by the X-axis motor 302, and the X-axis sliding plate 305 reciprocates on the X-axis guide rail 303 through the matching of a screw nut.

Further, referring to fig. 4, the X-axis sliding plate 305 is provided with an adjusting guide rail 403, and for the Z-axis moving module 40, a specific embodiment of the present invention is provided, in which the Z-axis moving module 40 includes a Z1-axis moving module 406 slidably mounted on the adjusting guide rail and a Z2-axis moving module 407 fixedly mounted on the X-axis sliding plate 305; in this embodiment, the Z1 axis motion module 406 and the Z2 axis motion module 407 have the same structure, and only differ in the installation position. The X-axis sliding plate 305 is provided with an adjusting component for adjusting the relative positions of the Z1 axis moving module 406 and the Z2 axis moving module 407. In the scheme, the adjusting assembly comprises an adjusting motor 404, an adjusting screw rod 405 and an adjusting screw rod nut, the adjusting screw rod 405 is connected with a motor shaft of the adjusting motor 404, the adjusting screw rod nut is arranged on the adjusting screw rod 405, the Z1 shaft motion module 406 comprises a Z shaft sliding plate 402, the adjusting screw rod nut is fixedly connected with the Z shaft sliding plate 402, and the Z shaft sliding plate 402 is driven by the adjusting motor 404 to translate on the adjusting guide rail 403.

In this embodiment, referring to fig. 4, the Z2 axis motion module 407 and the Z1 axis motion module 406 located at two sides of the Z2 axis motion module 407 are included, the Z2 axis motion module 407 is fixedly mounted on the X-axis sliding plate 305, the Z1 axis motion modules 406 at two sides are respectively mounted on the adjusting guide rail 403, and the distance between the Z1 axis motion module 406 and the Z2 axis motion module 407 can be adjusted by driving the adjusting motor 404; therefore, the cutting device can be suitable for cutting processing of glass workpieces with different sizes, and has wider adaptability; the plurality of Z-axis movement modules 40 can realize the operation of simultaneously processing a plurality of glass workpieces, so that the working efficiency is improved; meanwhile, the labor and the cost are saved. The cutting machine can replace the traditional engraving and milling machine and the traditional cutting machine, and the process which can be realized by the two original devices is integrated into one device for processing.

While the preferred embodiments of the present invention have been illustrated and described, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the utility model as defined by the appended claims.

Claims (8)

1. A multi-head numerical control glass cutting device is characterized by comprising a workbench, a Y-axis movement module, an X-axis movement module and a Z-axis movement module;

the Y-axis motion module comprises a Y-axis motor, a Y-axis lead screw, a lead screw sleeve connecting frame, a Y-axis dragging plate and a Y-axis sliding rail; the Y-axis motor is fixedly arranged below the workbench, one end of a Y-axis lead screw is connected with the Y-axis motor, a lead screw nut is arranged on the Y-axis lead screw, the middle part of the lead screw sleeve connecting frame is fixed on the lead screw nut, and two ends of the lead screw sleeve connecting frame extend out of the lower part of the workbench and are respectively connected with the bottom ends of the two Y-axis dragging plates; the two Y-axis sliding rails are fixed at two opposite ends of the workbench in parallel, each Y-axis sliding rail is provided with a Y-axis sliding block in a sliding manner, and the top end of the Y-axis dragging plate is fixedly connected with the Y-axis sliding block;

two ends of the X-axis motion module are respectively and fixedly arranged on the Y-axis slide block and are driven by the Y-axis motor to perform reciprocating translation on the Y-axis slide rail; the Z-axis motion module is arranged on the X-axis motion module and is driven by the X-axis motion module to perform reciprocating translation in the X-axis direction; the Z-axis movement module comprises a machining tool bit for machining glass.

2. The multi-headed numerical control glass cutting device according to claim 1, wherein the Y-axis motion module further comprises a Y-axis support fixedly mounted on the lower surface of the table, and the other end of the Y-axis lead screw is rotatably mounted inside the Y-axis support.

3. The multi-headed numerical control glass cutting device according to claim 1, wherein notches are provided at opposite ends of the worktable so as to form steps on the worktable, and the Y-axis guide rails are fixed at the steps.

4. The multi-headed digitally controlled glass cutting device according to claim 1 further comprising a main frame, said table being fixedly mounted to said main frame.

5. The multi-head numerical control glass cutting device according to claim 4, wherein a column is installed on one side of the main frame, and a system control box is arranged at the top end of the column.

6. The multi-head numerical control glass cutting device according to claim 1, wherein the X-axis motion module comprises a cross beam, an X-axis motor, an X-axis guide rail, an X-axis lead screw and an X-axis slide plate;

two ends of the cross beam are respectively and fixedly arranged on the Y-axis sliding block;

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.

7. The multi-head numerical control glass cutting device according to claim 6, wherein the X-axis sliding plate is provided with an adjusting guide rail, and the Z-axis motion module comprises a Z1-axis motion module which is slidably arranged on the adjusting guide rail and a Z2-axis motion module which is fixedly arranged on the X-axis sliding plate;

and the X-axis sliding plate is provided with an adjusting assembly for adjusting the relative position of the Z1 axis motion module and the Z2 axis motion module.

8. The multi-head numerical control glass cutting device according to claim 7, wherein the adjusting assembly comprises an adjusting motor, an adjusting screw and an adjusting screw nut;

the adjusting screw rod is connected with a motor shaft of the adjusting motor, and the adjusting screw rod nut is arranged on the adjusting screw rod;

the Z1 axle motion module include Z axle slide, adjust feed screw nut and Z axle slide fixed connection, through the drive of adjusting motor, make Z axle slide translation on adjusting the guide rail.

Images