CN109227318A

CN109227318A - Double-station numerical control lathe

Info

Publication number: CN109227318A
Application number: CN201811312319.2A
Authority: CN
Inventors: 夏军; 罗育银; 田献印; 袁志刚; 周作权
Original assignee: Shenzhen Create Century Machinery Co Ltd
Current assignee: Shenzhen Create Century Machinery Co Ltd
Priority date: 2018-11-06
Filing date: 2018-11-06
Publication date: 2019-01-18

Abstract

The present invention discloses a kind of double-station numerical control lathe, including pedestal, workbench, column, crossbeam, the first saddle, grinding nose assembly and the second saddle and carving and milling machine head assembly, wherein workbench is mounted on the base, and is used for bearing glass workpiece；Column is two, and two columns are installed on pedestal, and are oppositely arranged；Crossbeam is fixedly installed in column far from pedestal one end；First saddle is slidably mounted on crossbeam；Grinding nose assembly is slidably mounted on the first saddle, for carrying out grinding to the glass pieces for being placed in workbench；Second saddle is slidably mounted on crossbeam, and is arranged with the first saddle interval；Carving and milling machine head assembly is slidably mounted on the second saddle, and the glass pieces for completing the process to grinding carry out carving Milling Machining.Grinding nose assembly is integrated with carving and milling machine head assembly, so that grinding, which may be implemented, in a numerically-controlled machine tool mills two different procedure for processing with carving, effectively improves processing efficiency by technical solution of the present invention.

Description

Double-station numerical control machine tool

Technical Field

The invention relates to the technical field of glass processing, in particular to a double-station numerical control machine tool.

Background

In recent years, the use of glass workpieces is currently being pursued due to the particularly rapid updating of the appearance of mobile phones.

The processing of glass workpieces generally comprises: grinding and engraving and milling. The existing method for processing the glass workpiece is generally as follows: firstly, the glass workpiece is positioned and installed on a grinding machine tool so as to realize the grinding processing of the glass workpiece. And then, the glass workpiece after grinding is processed by a grinding machine tool and is positioned and arranged on a carving and milling machine tool so as to realize carving and milling of the glass workpiece.

Therefore, in the existing processing process, at least two numerical control machines (a grinding machine tool and a carving and milling machine tool) are needed, and the equipment cost is high; and the glass workpiece needs to be disassembled and assembled for many times, the time consumption is relatively long, and the processing efficiency is low.

Disclosure of Invention

The invention mainly aims to provide a double-station numerical control machine tool, aiming at effectively improving the processing efficiency of glass and reducing the processing cost.

In order to achieve the purpose, the invention provides a double-station numerical control machine tool, which comprises a base, a workbench, a stand column, a cross beam, a first saddle, a grinding machine head component, a second saddle and an engraving and milling machine head component, wherein,

the workbench is arranged on the base and used for bearing a glass workpiece;

the number of the upright columns is two, and the two upright columns are arranged on the base and are opposite to each other;

the cross beam is fixedly arranged at one end of the upright post, which is far away from the base;

the first saddle is slidably mounted on the cross beam;

the grinding machine head assembly is slidably mounted on the first saddle and is used for grinding the glass workpiece placed on the workbench;

the second saddle is slidably mounted on the cross beam and is arranged at an interval with the first saddle;

and the engraving and milling head assembly is slidably arranged on the second saddle and is used for engraving and milling the glass workpiece after the grinding processing is finished.

Optionally, the workbench is slidably mounted on the base; the upright post is fixedly arranged on the base.

Optionally, the workbench is fixedly mounted on the base; the upright post is slidably mounted on the base.

Optionally, the double-station numerical control machine further comprises a Y-axis driving assembly; the Y-axis driving component is fixedly arranged on the base and used for driving the workbench or the upright post to move in the Y-axis direction.

Optionally, the double-station numerical control machine further comprises an X-axis driving assembly; the X-axis driving assembly is fixedly mounted on the cross beam and used for driving the first sliding saddle and the second sliding saddle to move in the X-axis direction.

Optionally, the X-axis driving assembly includes a driving motor, a lead screw in transmission connection with the driving motor, and a first nut and a second nut in transmission connection with the lead screw; the first saddle is fixedly connected with the first nut; the second saddle is fixedly connected with the second nut.

Optionally, the grinder head assembly comprises a first Z-axis sliding plate, a grinding rod mounted on the first Z-axis sliding plate, and a grinding driving assembly mounted on the first Z-axis sliding plate; the first Z-axis sliding plate is connected with the first saddle in a sliding manner; the grinding driving assembly is fixedly arranged on the first Z-axis sliding plate and used for driving the grinding rod to rotate.

Optionally, the double-station numerical control machine further comprises a first Z-axis driving assembly, wherein the first Z-axis driving assembly is fixedly mounted on the first saddle and used for driving the grinding machine head assembly to move in the Z-axis direction.

Optionally, the engraving and milling head assembly comprises a second Z-axis sliding plate, a milling cutter mounted on the second Z-axis sliding plate, and an engraving and milling driving assembly mounted on the second Z-axis sliding plate; the second Z-axis sliding plate is connected with the second saddle in a sliding manner; and the engraving and milling driving component is fixedly arranged on the second Z-axis sliding plate and used for driving the milling cutter to rotate.

Optionally, the double-station numerical control machine further comprises a second Z-axis driving assembly, and the second Z-axis driving assembly is fixedly mounted on the second sliding saddle and used for driving the engraving and milling head assembly to move in the Z-axis direction.

According to the technical scheme, the grinding machine head assembly and the engraving and milling machine head assembly are integrated, so that two different machining processes of grinding and engraving and milling can be realized by one numerical control machine tool, the machining efficiency is effectively improved, and the machining cost is reduced; the double-station numerical control machine tool is simple in structure and relatively low in cost.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the structures shown in the drawings without creative efforts.

Fig. 1 is a schematic perspective view of a double-station numerical control machine tool according to an embodiment of the invention.

The implementation, functional features and advantages of the objects of the present invention will be further explained with reference to the accompanying drawings.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

This implementation provides a duplex position digit control machine tool.

As shown in fig. 1, fig. 1 is a schematic perspective view of a double-station numerical control machine tool according to an embodiment of the present invention.

The double-station numerical control machine tool of the embodiment comprises a base 110, a workbench 120, a Y-axis driving assembly 130, a column 140, a beam 150, a first saddle 210, a second saddle 310, an X-axis driving assembly 160, a grinding machine head assembly 220, a first Z-axis driving assembly 230, a carving and milling machine head assembly 320 and a second Z-axis driving assembly 330. Wherein,

the stage 120 is mounted on the base 110 for carrying a glass workpiece 400.

Specifically, in the present embodiment, the worktable 120 is slidably mounted on the base 110, and is used for carrying, positioning and fixing a jig (not labeled) containing the glass workpiece 400. Preferably, the worktable 120 and the base 110 are slidably connected through a Y-axis guide assembly (not shown). The Y-axis guide assembly comprises a Y-axis slide rail and a Y-axis slide block. Preferably, the Y-axis slide rail is fixedly mounted on the base 110; one end of the Y-axis sliding block is connected with the Y-axis in a sliding manner, and the other end of the Y-axis sliding block is fixedly connected with the workbench 120; the Y-axis slider slides on the Y-axis slide rail, thereby achieving the sliding connection between the worktable 120 and the base 110. Meanwhile, the Y-axis guiding assembly is further used for guiding the movement of the workbench 120 in the Y-axis direction, so as to ensure the smoothness and smoothness of the movement of the workbench 120 in the Y-axis direction, and further ensure the machining precision.

It should be noted that the positions of the Y-axis slide rail and the Y-axis slider can be interchanged, that is, the Y-axis slide rail is fixedly mounted on the worktable 120, and the Y-axis slider is fixedly connected to the base 110, which can also achieve the above technical effects.

The Y-axis driving assembly 130 is fixedly mounted on the base 110, and is used for driving the worktable 120 or the column 140 to move in the Y-axis direction.

Specifically, in this embodiment, the Y-axis driving assembly 130 is a driving cylinder, a cylinder body of the driving cylinder is fixedly mounted on the base 110, and a push rod is in transmission connection with the worktable 120. The Y-axis driving assembly 130 is used for driving the movement of the table 120 in the Y-axis direction.

It should be noted that the Y-axis driving assembly 130 is not limited to a driving cylinder, and other driving devices, such as a linear motor, or a combination of a servo motor and a lead screw assembly, may also be used to drive the movement of the table 120 in the Y-axis direction.

The number of the upright posts 140 is two, and the two upright posts 140 are mounted on the base 110 and are oppositely disposed. The cross member 150 is fixedly mounted on an end of the upright 140 away from the base 110.

Specifically, in the present embodiment, the two columns 140 and the cross beam 150 form a gantry structure. The two upright posts 140 are respectively and fixedly mounted at two sides of the tail end of the base 110. The cross member 150 may be integrally formed with the pillar 140, or may be separately formed and then fixedly connected together.

The first saddle 210 and the second saddle 310 are both slidably mounted on the beam 150, and the first saddle 210 and the second saddle 310 are spaced apart.

Specifically, in the present embodiment, the first saddle 210 and the second saddle 310 are slidably connected to the cross beam 150 through an X-axis guide assembly (not shown). The X-axis guide assembly comprises an X-axis slide rail, a first X-axis slide block and a second X-axis slide block. Wherein the X-axis slide rail is fixedly mounted to the cross beam 150. One end of the first X-axis slider is slidably connected to the X-axis slide rail, and the other end of the first X-axis slider is slidably connected to the first saddle 210; the first X-axis slider slides on the X-axis slide rail, thereby achieving the sliding connection between the first saddle 210 and the cross beam 150. One end of the second X-axis sliding block is connected with the X-axis sliding rail in a sliding manner, and the other end of the second X-axis sliding block is connected with the second saddle 310 in a sliding manner; the second X-axis slider slides on the X-axis slide rail, thereby achieving the sliding connection between the second saddle 310 and the cross beam 150.

It should be noted that, the guide assemblies may be disposed corresponding to the first saddle 210 and the second saddle 310, respectively, and the above technical effects may also be achieved.

The X-axis driving assembly 160 is fixedly mounted on the cross beam 150, and is used for driving the first saddle 210 and the second saddle 310 to move in the X-axis direction.

Specifically, in the present embodiment, the X-axis driving assembly 160 includes a driving motor (not shown), a lead screw (not shown) in transmission connection with an output shaft of the driving motor, and a first nut (not shown) and a second nut (not shown) in transmission connection with the lead screw. The first screw nut and the second screw nut are arranged at intervals. The first saddle 210 is fixedly connected with the first nut; the second saddle 310 is fixedly connected with the second nut. The drive motor is preferably a servo motor. The output shaft of the driving motor rotates to drive the screw rod to rotate, and the screw rod rotates and drives the first screw nut and the second screw nut to do linear motion along the X-axis direction, so that the linear motion of the first saddle 210 and the second saddle 310 along the X-axis direction is realized.

It should be noted that, X-axis driving components 160 may be further disposed corresponding to the first saddle 210 and the second saddle 310, respectively, so as to realize the driving control of the first saddle 210 and the second saddle 310, respectively, and also achieve the above technical effects.

The grinder head assembly 220 is slidably mounted on the first saddle 210, and is used for grinding the glass workpiece 400 placed on the worktable 120.

In this embodiment, the grinder head assembly 220 is of a horizontal grinding type, and includes a first Z-axis slide 222, a grinding bar 224 mounted on the first Z-axis slide 222, and a grinding drive assembly 226 mounted on the first Z-axis slide 222. Wherein,

the first Z-axis slide plate 222 is slidably coupled to the first saddle 210 via a first Z-axis guide assembly (not shown). Specifically, the first Z-axis guiding assembly includes a first Z-axis sliding rail and a first Z-axis sliding block. The first Z-axis slide rail is fixedly mounted on the first saddle 210, one end of the first Z-axis slider is slidably connected to the first Z-axis slide rail, and the other end of the first Z-axis slider is fixedly connected to the first Z-axis slide plate 222. The first Z-axis slider slides on the first Z-axis slide rail, so that the sliding connection between the first Z-axis slide plate 222 and the first saddle 210 is realized.

The grinding drive assembly 226 is fixedly mounted to the first Z-axis slide 222 for driving the grinding bar 224 in rotation. In particular, the grinding drive assembly 226 is preferably a servo motor.

The first Z-axis drive assembly 230 is fixedly mounted to the first saddle 210 for driving the movement of the grinder head assembly 220 in the Z-axis direction.

Specifically, in this embodiment, the first Z-axis driving assembly 230 is a driving cylinder or a linear motor, and is fixedly mounted on the first saddle 210 for driving the first Z-axis sliding plate 222 to move in the Z-axis direction, so as to drive the grinder head assembly 220.

The engraving and milling head assembly 320 is slidably mounted on the second saddle 310, and is used for engraving and milling the glass workpiece 400 after the grinding process is completed.

In this embodiment, the engraving and milling head assembly 320 includes a second Z-axis slide 322, a milling cutter 324 mounted on the second Z-axis slide 322, and an engraving and milling drive assembly 326 mounted on the second Z-axis slide 322. Wherein,

the second Z-axis sled 322 is slidably coupled to the second saddle 310 via a second Z-axis guide assembly (not shown). Specifically, the second Z-axis guiding assembly includes a second Z-axis sliding rail and a second Z-axis sliding block. The second Z-axis slide rail is fixedly mounted on the second saddle 310, one end of the second Z-axis slide block is slidably connected to the second Z-axis slide rail, and the other end of the second Z-axis slide block is fixedly connected to the second Z-axis slide plate 322. The second Z-axis slider slides on the second Z-axis slide rail, so that the sliding connection between the second Z-axis slide plate 322 and the second saddle 310 is realized.

The engraving and milling driving assembly 326 is fixedly mounted on the second Z-axis sliding plate 322, and is used for driving the milling cutter 324 to rotate. In particular, the router drive assembly 326 is preferably a combination of a servo motor and a gear box.

The second Z-axis drive assembly 330 is fixedly mounted to the second saddle 310 for driving the milling drive assembly 326 to move in the Z-axis direction.

Specifically, in this embodiment, the second Z-axis driving assembly 330 is a driving cylinder or a linear motor, and is fixedly mounted on the second saddle 310, and is configured to drive the second Z-axis sliding plate 322 to move in the Z-axis direction, so as to drive the engraving and milling head assembly 320.

When the double-station numerical control machine tool works, the jig containing the glass workpiece 400 is placed on the workbench 120 and is positioned and fixed. After the fixing is completed, the Y-axis driving assembly 130 drives the worktable 120 to move, and simultaneously, the X-axis driving assembly 160 drives the grinder head assembly 220 to move until the grinding rod 224 of the grinder head assembly 220 is positioned right above the glass workpiece 400 (at this time, the grinder head assembly 220 is positioned in the middle of the cross beam 150, and the engraving and milling head assembly 320 is positioned at one end of the cross beam 150). The grinder head assembly 220 moves toward the glass workpiece 400 under the driving of the first Z-axis driving assembly 230, and after the grinder head assembly is in position, the grinding driving assembly 226 drives the grinding rod 224 to grind the glass workpiece 400. After the grinding process is completed, the grinder head assembly 220 is driven by the first Z-axis driving assembly 230 to move in a direction away from the glass workpiece 400, and at the same time, the X-axis driving assembly 160 drives the engraving and milling head assembly 320 to move in a direction close to the glass workpiece 400, so that the milling cutter 324 of the engraving and milling head assembly 320 is located right above the glass workpiece 400 (at this time, the engraving and milling head assembly 320 is located in the middle of the cross beam 150, and the grinder head assembly 220 is located at the other end of the cross beam 150). The engraving and milling head assembly 320 moves towards the direction close to the glass workpiece 400 under the driving of the second Z-axis driving assembly 330, and after the engraving and milling head assembly is in place, the engraving and milling driving assembly 326 drives the milling cutter 324 to engrave and mill the glass workpiece 400.

According to the technical scheme of the embodiment, the grinding head assembly 220 and the engraving and milling head assembly 320 are integrated, so that two different machining processes of grinding and engraving and milling can be realized by one numerical control machine, the machining efficiency is effectively improved, and the machining cost is reduced; and the double-station numerical control machine tool of the embodiment has simple structure and relatively low cost.

The invention also provides another embodiment of the double-station numerical control machine tool.

Based on the above embodiments, the present embodiment is different from the above embodiments only in that, in the present embodiment, the upright 140 is slidably connected to the base 110, and the worktable 120 is fixedly connected to the base 110. The Y-axis driving assembly 130 is used for driving the column 140 to move in the Y-axis direction.

The present embodiment can achieve the same technical effects as the above embodiments, and details are not described herein.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the scope of the present invention, and all modifications and equivalents of the present invention, which are made by the contents of the present specification and the accompanying drawings, or directly/indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims

1. A double-station numerical control machine tool is characterized by comprising a base, a workbench, a stand column, a cross beam, a first saddle, a grinding machine head assembly, a second saddle and a carving and milling machine head assembly, wherein,

the workbench is arranged on the base and used for bearing a glass workpiece;

the first saddle is slidably mounted on the cross beam;

2. The double-station numerically-controlled machine tool according to claim 1, wherein the worktable is slidably mounted to the base; the upright post is fixedly arranged on the base.

3. The double-station numerical control machine tool according to claim 1, wherein the worktable is fixedly installed at the base; the upright post is slidably mounted on the base.

4. The double-station numerical control machine tool according to claim 2 or 3, further comprising a Y-axis drive assembly; the Y-axis driving component is fixedly arranged on the base and used for driving the workbench or the upright post to move in the Y-axis direction.

5. The double-station numerically-controlled machine tool of claim 1, further comprising an X-axis drive assembly; the X-axis driving assembly is fixedly mounted on the cross beam and used for driving the first sliding saddle and the second sliding saddle to move in the X-axis direction.

6. The double-station numerical control machine tool according to claim 5, wherein the X-axis driving assembly comprises a driving motor, a screw rod in transmission connection with the driving motor, and a first screw nut and a second screw nut in transmission connection with the screw rod; the first saddle is fixedly connected with the first nut; the second saddle is fixedly connected with the second nut.

7. The double-station numerical control machine tool of claim 1, wherein the grinder head assembly comprises a first Z-axis slide plate, a grinding bar mounted on the first Z-axis slide plate, and a grinding drive assembly mounted on the first Z-axis slide plate; the first Z-axis sliding plate is connected with the first saddle in a sliding manner; the grinding driving assembly is fixedly arranged on the first Z-axis sliding plate and used for driving the grinding rod to rotate.

8. The double-station numerical control machine tool of claim 7 further comprising a first Z-axis drive assembly fixedly mounted to the first saddle for driving movement of the grinding drive assembly in the Z-axis direction.

9. The double-station numerical control machine tool according to claim 1, wherein the engraving and milling head assembly comprises a second Z-axis sliding plate, a milling cutter mounted on the second Z-axis sliding plate, and an engraving and milling driving assembly mounted on the second Z-axis sliding plate; the second Z-axis sliding plate is connected with the second saddle in a sliding manner; and the engraving and milling driving component is fixedly arranged on the second Z-axis sliding plate and used for driving the milling cutter to rotate.

10. The double-station numerically-controlled machine tool of claim 9, further comprising a second Z-axis drive assembly fixedly mounted to the second saddle for driving movement of the engraving and milling head assembly in the Z-axis direction.