CN222269506U - High precision milling and grinding machine - Google Patents

Abstract

The high-precision milling and grinding integrated machine comprises a workbench arranged on a base, wherein the workbench is arranged on the base through a parallel rail assembly, a portal frame is arranged above the base, a Y-axis module is arranged on the portal frame, a first Z-axis module and a second Z-axis module are arranged on the same side of the Y-axis module side by side, a chip milling assembly is arranged on the side edge of the first Z-axis module, and a grinding assembly is arranged on the side edge of the second Z-axis module. The utility model realizes two different processing procedures of milling scraps and polishing a metal workpiece on one piece of equipment, avoids the trouble of lifting the metal workpiece in the switching procedure between the milling machine and the grinding machine, can reduce the purchase cost of the processing equipment, can improve the processing efficiency, and improves the processing precision of the metal workpiece by designing the structure of the parallel rail assembly so as to solve the problem that the processing precision of the metal workpiece is influenced by the easy shaking of a workbench due to the easy deformation of the parallel rail structure of the milling machine and the grinding machine at present.

Description

High-precision milling and grinding integrated machine

Technical Field

The utility model relates to the field of milling equipment, in particular to a high-precision milling and grinding integrated machine.

Background

With the development of industrialization, in the processing of large-scale equipment accessories, the surface of a relatively large metal piece is often required to be milled and polished, and the existing milling machine or grinding machine can only perform a single process, or milling is performed by adopting the milling machine or grinding is performed by adopting the grinding machine. When a metal piece is required to be milled and ground, the milling machine and the grinding machine are required to be used respectively, and the milling machine and the grinding machine are divided into two working procedures, so that the metal piece is required to be hoisted between the milling machine and the grinding machine when the working procedures of the milling machine and the grinding are replaced, and finally the metal piece has the defects of low production efficiency, high working strength and high production cost. In addition, the workbench and the base in the traditional milling machine or grinding machine are generally only provided with a conventional single set of sliding rails and sliding blocks as sliding components, and the sliding components with the structure are only suitable for being used for a relatively light workbench and a relatively light metal workpiece, and if the relatively heavy workbench and the metal workpiece are encountered, the problems of unstable sliding and poor sliding precision are generally caused. In addition, because the workbench works for a long time and can lead to the deformation of the workbench and the heating of the sliding component, the deformed workbench and the deformed sliding component are easy to shake in the processing and sliding process, so that the accuracy of milling and polishing the metal workpiece is affected, and the problem of low processing accuracy is caused.

Disclosure of Invention

The utility model aims to solve the technical problems of providing a high-precision milling and grinding integrated machine, the whole structure of the milling and grinding integrated machine can finish two different processing procedures of milling scraps and grinding a metal workpiece on one piece of equipment, the milling and grinding integrated machine has the advantages of high processing precision, high processing efficiency and capability of reducing the cost of purchasing a machine, the problems that the existing milling machine or grinding machine can only perform a single procedure to cause that the metal workpiece can be lifted between the milling machine and the grinding machine to switch different processing procedures, so that the processing efficiency is low and the processing cost is high are solved, and the problems that a workbench and a base in the existing milling machine or grinding machine generally adopt a conventional single-group sliding rail as a sliding component, the workbench and the sliding component are easy to deform due to friction heating after long-time working and the phenomenon of shaking occurs during processing and sliding, so that the sliding is unstable, the sliding precision is poor, and the processing precision of the metal workpiece is low are solved. The utility model is realized by the following technical scheme:

The high-precision milling and grinding integrated machine comprises a base, a first Z-axis module and a second Z-axis module, wherein a workbench is arranged on the base, a portal frame is arranged above the base, two lower ends of the portal frame are respectively arranged on two sides of the base through portal frame installation seats, and the first Z-axis module and the second Z-axis module are adjacently arranged;

the milling chip assembly is arranged on the side edge of the first Z-axis module and is used for milling chips on the metal workpiece transferred below the milling chip assembly;

The grinding component is arranged on the side edge of the second Z-axis module and is used for grinding the metal workpiece transferred below the second Z-axis module;

The Y-axis module is arranged on the portal frame and used for driving the first Z-axis module and the second Z-axis module to synchronously reciprocate in the Y-axis direction to realize linear displacement, so that the milling chip component and the grinding component can be respectively and accurately positioned to the position to be processed in the workpiece;

The workbench is arranged on the base through the parallel rail assembly, and can carry out X-axis reciprocating linear displacement on the base along the parallel rail assembly through the X-axis module.

Through adopting foretell technical scheme, mill bits subassembly and can go up and down to remove through first Z axle module, make it not only be fit for processing the metal work piece of not co-altitude, it still makes and mills bits subassembly and can accurately descend to the surface of metal work piece under the drive of first Z axle module and mill bits processing. Similarly, the grinding component can be lifted and moved through the second Z-axis module, so that the grinding component is not only suitable for grinding metal workpieces with different heights, but also can be precisely lowered to a position, which is required to be ground, in the metal workpieces for grinding under the driving of the second Z-axis module. The first Z-axis module and the second Z-axis module can move in the Y-axis direction through the Y-axis module, so that the chip milling assembly can move up and down and can move in the Y-axis direction under the common driving of the first Z-axis module and the Y-axis module, and similarly, the grinding assembly can move up and down and can move in the Y-axis direction under the common driving of the second Z-axis module and the Y-axis module, and the chip milling assembly and the grinding assembly can be accurately positioned to the position of a metal workpiece to be processed for processing, so that the processing precision of the chip milling assembly and the grinding assembly is high.

Preferably, the parallel rail assembly comprises two V-shaped sliding rails respectively arranged at two ends of the base, the bottom surface of the workbench is provided with Y-shaped guide bars which are matched with each V-shaped sliding rail for use so as to improve the sliding stability, rigidity and machining precision of the workbench, and the V-shaped sliding rails are arranged opposite to the Y-shaped guide bars.

Preferably, the parallel rail assembly further comprises parallel sliding rails arranged on the side edges of each V-shaped sliding rail, the bottom surface of the workbench is further provided with sliding blocks matched with each parallel sliding rail, and each sliding block is in sliding connection with each parallel sliding rail.

According to the technical scheme, the workbench can move along the X-axis direction along the parallel rail assembly under the drive of the X-axis module, so that a metal workpiece placed on the workbench can be accurately transferred to the lower part of the grinding assembly and the milling assembly for processing, the V-shaped sliding rail is arranged on the side edge of each parallel sliding rail, the Y-shaped guide bar is matched with the V-shaped sliding rail to be used on the side edge of each sliding block on the bottom surface of the workbench, the sliding block and the parallel sliding rail form a group of sliding assemblies, the Y-shaped guide bar and the V-shaped sliding rail form another group of sliding assemblies, the dual sliding assembly functions are realized, the sliding rigidity and the sliding stability of the workbench and the sliding accuracy of the parallel sliding rail on the base can be improved, the bearing of the workbench and the metal workpiece on the workbench can be effectively dispersed, the conventional single-group sliding rail is generally adopted as the sliding assembly for the workbench and the base in the milling machine or the grinding machine, the phenomenon that the workbench is easy to deform due to friction heating and the sliding in the sliding process of the sliding assembly is easy to occur in a long time, the phenomenon that the workbench slides due to deformation and the sliding phenomenon is poor in the process of the sliding assembly, the deformation accuracy and the workpiece is poor in volume and the precision is stable, the metal workpiece can be realized, the heavy and the workpiece is suitable for further processing, and the heavy precision is suitable for the heavy processing precision.

Preferably, the grinding assembly comprises a grinding motor, a grinding shaft is arranged below the grinding motor, a grinding head is arranged at one end of the grinding shaft, and the other end of the grinding shaft is connected with the grinding motor through a synchronous wheel assembly. The synchronizing wheel assembly mainly comprises two synchronizing wheels and a synchronous belt connected with the two synchronizing wheels, and the working principle of the synchronizing wheel assembly is common knowledge and is not explained in detail here. The grinding head refers to a tool for grinding a metal workpiece.

Through adopting foretell technical scheme, can drive the synchronous rotation of grinding axle through synchronizing wheel subassembly when grinding the motor and rotate, and can drive the synchronous rotation of bistrique when grinding the axle and rotate, can polish the processing to the metal workpiece that contacts with it when the bistrique rotates.

Preferably, the milling chip assembly comprises a milling chip motor, and a milling head is arranged on an output shaft of the milling chip motor.

By adopting the technical scheme, the milling head can be driven to synchronously rotate when the milling chip motor rotates so as to mill the metal workpiece contacted with the milling head.

Preferably, the top surface of the workbench is recessed downwards and provided with a plurality of T-shaped grooves in equidistant distribution, and two adjacent T-shaped grooves are arranged in parallel.

Preferably, an electric permanent magnet disc is arranged on the top surface of the workbench, a first screw hole is arranged on the electric permanent magnet disc, a T-shaped block is arranged in the T-shaped groove, and the electric permanent magnet disc is connected with the T-shaped block by a screw through the first screw hole on the electric permanent magnet disc so as to realize the fixed installation of the electric permanent magnet disc on the workbench.

According to the technical scheme, the T-shaped grooves are distributed at equal intervals, so that the workbench is suitable for being provided with electric permanent magnetic disks with different widths, the purpose of strong universality is achieved, and the electric permanent magnetic disks can be fixedly arranged on the workbench when an installer installs screws in the T-shaped grooves through first screw holes in the electric permanent magnetic disks and the T-shaped blocks.

In another embodiment, the two end portions and the middle portion of the workbench are provided with second screw holes.

By adopting the technical scheme, the clamping structure (such as the clamp) except the permanent magnet disk can be arranged on the second screw hole by screws according to the production requirement to fix the metal workpiece.

Preferably, the first Z-axis module, the second Z-axis module, the Y-axis module, the X-axis module, the milling assembly, the grinding assembly and other assemblies are respectively connected with a controller or a PLC control system in a signal mode, the controller is a PLC programmable logic controller, and the PLC programmable logic controller can adopt a programmable logic controller with Shenzhen production area and XDS-40T-D model, but is not limited to the programmable logic controller.

It should be noted that the first Z-axis module, the second Z-axis module, the Y-axis module and the X-axis module each include a nut fixing seat, and a ball screw is disposed at a center of the nut fixing seat, wherein one end of the ball screw in the first Z-axis module and one end of the ball screw in the second Z-axis module are connected with a lifting motor, and a rotating motor is disposed on a side edge of one end of the ball screw in the Y-axis module and one side edge of one end of the ball screw in the X-axis module, and the rotating motor in the Y-axis module and one end of the ball screw in the X-axis module are connected through a belt pulley assembly. The belt pulley assembly mainly comprises two belt pulleys, wherein one belt pulley is installed on an output shaft of the rotating motor, the other belt pulley is installed on one end of the ball screw, and the two belt pulleys are connected with a belt. The working principle of the pulley assembly is well known and will not be explained in detail here. In other embodiments, the first Z-axis module, the second Z-axis module, the X-axis module, and the Y-axis module may further adopt a structure capable of outputting a reciprocating motion, such as a belt linear module and a rack-and-pinion module, and the structure capable of realizing a reciprocating motion may be selected and used in an attempt, which is not particularly limited herein. The gantry mounting and the parallel slide rail are functional descriptions of the mounting and slide rail, respectively. Both the grinding motor and the chip milling motor are functional descriptions of the motor.

The utility model has the beneficial effects that 1, the structure of the parallel rail assembly is designed, the inner side of each parallel rail is provided with the V-shaped rail, the parallel rail is opposite to the sliding block, the V-shaped rail is opposite to the Y-shaped guide bar, the workbench can stably slide on the base through the opposite parallel rail and the sliding block and the opposite V-shaped rail and Y-shaped guide bar, the design of the V-shaped rail and the Y-shaped guide bar can effectively disperse the bearing of the parallel rail on the workbench and the metal workpiece on the workbench, and improve the rigidity, the sliding stability and the sliding precision of the whole parallel rail assembly.

2. The grinding component and the milling chip component are integrated on the same equipment, the grinding component and the milling chip component can be driven by the Y-axis module to grind or mill chip processing at different positions in the Y-axis direction on a workpiece, the grinding component and the milling chip component can be accurately reduced to the position, which is needed to grind or mill chip, in the metal workpiece respectively under the driving of the Z-axis module connected with the grinding component and the milling chip component, so that a plurality of equipment with different procedures are not needed to be purchased, the cost of purchasing machines and the production cost are reduced, and the problems that the existing milling machine or grinding machine can only perform a single procedure, so that different processing procedures can be switched only by lifting metal pieces between the milling machine and the grinding machine, and the processing efficiency is low and the processing cost is high are effectively solved.

Drawings

For ease of illustration, the utility model is described in detail by the following preferred embodiments and the accompanying drawings.

Fig. 1 is a perspective view of a high precision milling and grinding integrated machine of the present utility model.

Fig. 2 is an assembled rear view of the base, the workbench, the electric permanent magnet disc and the gantry mounting base of the high-precision milling and grinding integrated machine.

Fig. 3 is an assembled front view of the base, the workbench, the electric permanent magnet disc and the gantry mounting base of the high-precision milling and grinding integrated machine.

Fig. 4 is an assembled perspective view of the base, the table and the gantry mounting base of the high-precision milling and grinding integrated machine of the utility model.

Fig. 5 is an assembled perspective view of a chip milling assembly and a grinding assembly of the high precision milling and grinding integrated machine of the present utility model.

Detailed Description

In order that the utility model may be readily understood, a more complete description of the utility model will be rendered by reference to the appended drawings. The drawings illustrate preferred embodiments of the utility model. This utility model may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this utility model belongs. The terminology used herein in the description of the utility model is for the purpose of describing particular embodiments only and is not intended to be limiting of the utility model.

In this embodiment, referring to fig. 1 to 5, the high-precision milling and grinding integrated machine of the utility model comprises a base 1, a workbench 2 arranged on the base 1, a portal frame 3 arranged above the base 1, a first Z-axis module 51 and a second Z-axis module 52 arranged adjacently to the first Z-axis module 51 and the second Z-axis module 52, a chip milling assembly 6 arranged on the side edge of the first Z-axis module 51 and used for milling chips on a workpiece placed on the workbench 2, a grinding assembly 7 arranged on the side edge of the second Z-axis module 52 and used for grinding the workpiece placed on the workbench 2, and a Y-axis module 8 arranged on the portal frame 3 and used for driving the first Z-axis module 51 and the second Z-axis module 52 to reciprocate linearly along the Y-axis direction synchronously, so that the chip milling assembly 6 and the grinding assembly 7 can be precisely positioned at a position required to be processed in the workpiece, respectively, and the workbench 2 can reciprocate linearly along the X-axis direction of the workbench 10 and the X-axis module 9 arranged on the base 1 through a parallel rail assembly 9.

In one embodiment, the parallel rail assembly 9 includes two V-shaped slide rails 91 respectively mounted on two ends of the base 1, the bottom surface of the workbench 2 is provided with a Y-shaped guide bar 92 that cooperates with each V-shaped slide rail 91 to improve the sliding stability, rigidity and processing precision of the workbench 2, and the V-shaped slide rails 91 are disposed opposite to the Y-shaped guide bar 92.

In one embodiment, the parallel rail assembly 9 further includes parallel sliding rails 93 disposed on the side edges of each V-shaped sliding rail 91, a sliding block 94 matched with each parallel sliding rail 93 is further mounted on the bottom surface of the workbench 2, and each sliding block 94 is slidably connected with each parallel sliding rail 93.

In one embodiment, the V-shaped rail 91, the Y-shaped guide bar 92, the parallel rail 93 and the slider 94 are provided with more than one pair respectively.

In one embodiment, the grinding assembly 7 comprises a grinding motor 71, a grinding shaft 72 is arranged below the grinding motor 71, a grinding head 73 is installed at one end of the grinding shaft 72, and the other end of the grinding shaft 72 is connected with the grinding motor 71 through a synchronous wheel assembly 74.

In one embodiment, the chip milling assembly 6 includes a chip milling motor 61, and a milling head 62 is mounted on an output shaft of the chip milling motor 61.

In one embodiment, the top surface of the workbench 2 is recessed downwards, and a plurality of T-shaped grooves 21 are distributed at equal intervals, and two adjacent T-shaped grooves 21 are arranged in parallel.

In one embodiment, an electro-permanent magnet disc 20 is installed on the top surface of the workbench 2, a T-shaped block is installed in the T-shaped groove 21, and the electro-permanent magnet disc 20 is installed and connected with the T-shaped block through a first screw hole on which a screw passes, so that the electro-permanent magnet disc 20 can be fixedly installed on the workbench 2.

In one embodiment, the second screw holes 22 are formed in both end portions and the middle portion of the table 2.

In another embodiment, the milling chip assembly 6 and the grinding assembly 7 can be provided with a Y-axis module 8 on the side of each Z-axis module according to the production requirement, so that the two Z-axis modules can be respectively driven by the Y-axis module 8 connected with the two Z-axis modules to be close to or far away from each other, thereby realizing that the distance between the milling chip assembly 6 and the grinding assembly 7 can be adjusted, and the processing operation of the metal workpiece is more flexible.

In one embodiment, the working principle of the high-precision milling and grinding integrated machine is that whether the electric permanent magnet disc 20 is installed on the workbench 2 or not can be selected according to the use requirement, T-shaped grooves 21 are formed in the top surface of the workbench 2, T-shaped blocks are installed in each T-shaped groove 21, when the electric permanent magnet disc 20 is placed on the workbench 2, the electric permanent magnet disc 20 passes through first screw holes in the electric permanent magnet disc 20 to be connected with the T-shaped blocks in a mounting mode, the electric permanent magnet disc 20 can be fixedly locked on the workbench 2, when a metal workpiece is placed on the electric permanent magnet disc 20, the electric permanent magnet disc 20 can absorb the metal workpiece on the electric permanent magnet disc 20 by utilizing magnetic force, so that the metal workpiece is fixed, displacement of the metal workpiece in the sliding process along with the workbench 2 and the machining process of the milling chip assembly 6 and the grinding assembly 7 respectively is avoided, and the machining precision of the metal workpiece is high. When the metal workpiece is placed on the electro-permanent magnet disc 20, the metal workpiece can slide to the position right below the portal frame 3 along the parallel rail assembly 9 along with the workbench 2 and driven by the X-axis module 10. The structure of the parallel rail assembly 9 is designed, so that the side edge of each parallel rail 93 in the parallel rail assembly 9 is provided with a V-shaped sliding rail 91 opposite to a Y-shaped guide bar 92 on the lower surface of the workbench 2, when the V-shaped sliding rail 91 and the Y-shaped guide bar 92 are matched for use, the workbench 2 and a metal workpiece positioned on the workbench 2 can be effectively dispersed to bear the weight of the parallel rail 93, and the problem that the workbench 2 and the parallel rail 93 are easy to deform after long-time working friction heating of the workbench 2 is avoided, so that the deformed workbench 2 is easy to shake in the sliding process of the deformed parallel rail 93 and the milling assembly 6 and the grinding assembly 7 are easy to process the metal workpiece respectively, and the processing precision of the metal workpiece is easy to be affected.

When the metal workpiece slides to the position right below the portal frame 3 along the parallel rail assembly 9 under the driving of the X-axis module 10 along with the workbench 2, the first Z-axis module 51 and the second Z-axis module 52 can reciprocate linearly along the Y-axis under the driving of the Y-axis module 8, so that the chip milling assembly 6 can precisely move to the position right above the metal workpiece along with the first Z-axis module 51 under the driving of the Y-axis module 8, then the chip milling assembly 6 can descend to the processing surface of the metal workpiece under the driving of the first Z-axis module 51, and when the chip milling motor 61 of the chip milling assembly 6 drives the milling head 62 to rotate, chip milling processing can be performed on the processing surface of the metal workpiece.

When the metal workpiece is subjected to chip milling, the first Z-axis module 51 drives the chip milling module 6 to reset and ascend, then the grinding module 7 can precisely move to each processing surface of the metal workpiece to be ground after being driven by the Y-axis module 8 and the second Z-axis module 52 to move in the Y-axis direction and descend, and when the grinding motor 71 of the grinding module 7 drives the grinding head 73 to rotate, the metal workpiece can be ground. After the metal workpiece is polished, the polishing assembly 7 is reset and lifted under the driving of the second Z-axis module 52, and finally, the metal workpiece is reset and retreated (i.e. moved in a direction away from the portal frame 3) along the parallel rail assembly 9 along with the workbench 2 and under the driving of the X-axis module 10, so as to conveniently perform blanking on the processed metal workpiece and conveniently perform feeding on the next metal workpiece to be processed.

The whole structure of the milling machine realizes two different processing procedures of milling scraps and polishing a metal workpiece on one piece of equipment, avoids the trouble of lifting the metal workpiece when the procedures are switched between two different processing equipment of a milling machine and a grinding machine, reduces the purchase cost of the processing equipment, reduces the production cost, improves the processing efficiency, and improves the rigidity, the sliding stability and the sliding precision of the parallel rail assembly 9 by designing the structure of the parallel rail assembly 9, so that the processing precision of the metal workpiece can be further improved, and the problem that the processing precision of the metal workpiece is influenced by the easy shaking of the workbench 2 due to easy deformation of the structure of the parallel rail 93 of the milling machine and the grinding machine at present is effectively solved.

The above embodiment is only an example of the present utility model and is not intended to limit the scope of the present utility model, and all technical solutions identical or equivalent to those described in the claims should be included in the scope of the present utility model.

Claims (7)

1. The high-precision milling and grinding integrated machine comprises a base, wherein a workbench is arranged on the base, a portal frame is arranged above the base, and two lower ends of the portal frame are respectively arranged on two sides of the base through portal frame installation seats;

The milling chip assembly is arranged on the side edge of the first Z-axis module and is used for milling chips on a workpiece placed on the workbench;

The grinding component is arranged on the side edge of the second Z-axis module and is used for grinding a workpiece placed on the workbench;

The Y-axis module is arranged on the portal frame and used for driving the first Z-axis module and the second Z-axis module to synchronously reciprocate in the Y-axis direction to realize linear displacement, so that the milling chip component and the grinding component can be respectively and accurately positioned to the position to be processed in the workpiece;

the workbench is arranged on the base through the parallel rail assembly, and can perform X-axis reciprocating linear displacement on the base along the parallel rail assembly through the X-axis module;

The parallel rail assembly comprises two V-shaped sliding rails which are respectively arranged at two ends of the base, the bottom surface of the workbench is provided with Y-shaped guide bars which are matched with each V-shaped sliding rail for use so as to improve the sliding stability, rigidity and machining precision of the workbench, and the V-shaped sliding rails are arranged opposite to the Y-shaped guide bars.

2. The high-precision milling and grinding integrated machine of claim 1, wherein the parallel rail assembly further comprises parallel sliding rails arranged on the side edges of each V-shaped sliding rail, a sliding block matched with each parallel sliding rail is further arranged on the bottom surface of the workbench, and each sliding block is in sliding connection with each parallel sliding rail.

3. The high-precision milling and grinding integrated machine of claim 1, wherein the grinding assembly comprises a grinding motor, a grinding shaft is arranged below the grinding motor, a grinding head is arranged at one end of the grinding shaft, and the other end of the grinding shaft is connected with the grinding motor through a synchronous wheel assembly.

4. The high-precision milling and grinding integrated machine of claim 1, wherein the milling chip assembly comprises a milling chip motor, and a milling head is arranged on an output shaft of the milling chip motor.

5. The high-precision milling and grinding integrated machine of claim 1, wherein the top surface of the workbench is recessed downwards, a plurality of T-shaped grooves are distributed at equal intervals, and two adjacent T-shaped grooves are arranged in parallel.

6. The high-precision milling and grinding integrated machine of claim 5, wherein the electric permanent magnet disc is arranged on the top surface of the workbench, the T-shaped block is arranged in the T-shaped groove, and the electric permanent magnet disc is connected with the T-shaped block in a mounting manner through a screw penetrating through a first screw hole on the electric permanent magnet disc so as to realize the fixed installation of the electric permanent magnet disc on the workbench.

7. The high-precision milling and grinding integrated machine according to any one of claims 1 and 6, wherein the two end parts and the middle part of the workbench are provided with second screw holes.