CN117226442B - Numerical control equipment for workpiece correction - Google Patents

Abstract

The invention relates to the technical field of workpiece correction, and discloses numerical control equipment for workpiece correction. The hydraulic cylinder a is arranged to adjust lifting operation of the cutter, the steering motor is arranged to adjust rotating operation of the cutter, the hydraulic cylinder c is arranged to adjust large-stroke transverse transmission operation of the cutter, the guide assembly is arranged to adjust small-stroke transverse transmission operation of the cutter, the cutting assembly is arranged to install the cutter and drive the cutter to rotate, automatic operation can be realized by utilizing PLC programming in cooperation with the positioning probe, the work piece is subjected to chamfering orthopedic operation, manual operation is not needed, the work piece machining yield and machining efficiency are greatly improved, and the practicability is strong.

Description

Numerical control equipment for workpiece correction

Technical Field

The invention relates to the technical field of workpiece correction, in particular to numerical control equipment for workpiece correction.

Background

Workpiece correction refers to shape correction or correction of a machined workpiece to achieve predetermined requirements and dimensional accuracy, often by chamfering the workpiece; in the chamfering process, burrs are generated on the surface of the workpiece, the burrs bring different degrees of harm to the processing and assembly of the subsequent workpiece, and the quality of the workpiece can be directly influenced, so that deburring is often required after the workpiece is chamfered.

Work pieces needing to be chamfered and deburred at a plurality of different positions at present mainly adopt the manual work to accomplish chamfer and deburr, but manual chamfering and deburr work efficiency is lower, and especially when work piece volume is big, the orthopedic quality of work piece can't be ensured to when adopting the manual work to chamfer, because operating personnel's application of force is inhomogeneous, the chamfer on the work piece can appear the cockscomb structure, influences work piece quality.

Disclosure of Invention

The invention aims to provide a device for solving the problem that the orthopedic quality of the existing large-batch artificial workpieces cannot be guaranteed.

The invention is realized in such a way that the numerical control equipment for workpiece correction comprises the numerical control equipment and a control device, wherein a working platform is arranged in the numerical control equipment and is used for fixing a workpiece, an correction frame is arranged right above the working platform by the numerical control equipment, and an correction component for correcting the workpiece is arranged at the bottom of the correction frame in a lifting driving way;

The orthopedic assembly comprises a base plate, a carrying plate, a mounting seat, a guide assembly and a cutting assembly, wherein the guide assembly and the cutting assembly are arranged on the mounting seat, and a cutter for orthopedic operation is arranged on the cutting assembly;

The orthopedic frame comprises a frame body, wherein a hydraulic cylinder a is arranged in an inner mounting head of the frame body, and the telescopic end of the hydraulic cylinder a is connected with the top of the base plate and used for adjusting the lifting operation of the cutter;

A steering motor is arranged in the base plate, and an output shaft of the steering motor is connected with the top of the carrier plate and used for adjusting the rotation operation of the cutter;

a hydraulic cylinder c is transversely arranged on the surface of the carrying disc, and the telescopic end of the hydraulic cylinder c is connected with the mounting seat and used for adjusting the large-stroke transverse transmission operation of the cutter;

The guide assembly drives the cutting assembly to transversely guide and is used for adjusting small-stroke transverse transmission operation of the cutter;

and, the cutting assembly includes a drum for mounting the cutter and driving a rotation operation of the cutter.

Preferably, the automatic cutting machine further comprises a switching assembly arranged on the base plate, wherein the switching assembly comprises a switching motor and a rotating disc which is driven by the switching motor and is connected to the inside of the base plate through a bearing, and a plurality of cutter grooves for inserting cutters are axially formed in the rotating disc;

And an electromagnet is also embedded in the center of the turntable, and the electromagnet is electrified to generate magnetism for restraining the cutter.

Preferably, the cutter groove and the inner walls around the rotary drum are provided with clamping grooves, the cutter comprises a cutter body and a cutter head, ribs corresponding to the clamping grooves are arranged around the cutter body, and the cutter body is made of magnetic materials;

the cutter heads of the cutter are various and are one of milling cutters, blades, boring cutters or grinding tools.

Preferably, a hydraulic cylinder b is arranged on one side of the frame body, which is close to the switching assembly, an electromagnetic ring is arranged at the telescopic end part of the hydraulic cylinder b, and a magnetizer is arranged in the electromagnetic ring;

The end of the mounting seat is provided with an assembly hole, and the telescopic end of the hydraulic cylinder b enables the cutter to pass through the assembly Kong Dingru or suck out of the mounting seat through a magnetizer.

Preferably, the guide assembly comprises a guide motor arranged at the end part of the mounting seat and two guide rods which are arranged in parallel and are driven by the guide motor and connected to the inside of the mounting seat through bearings, the guide seat is connected to the outer threads of the guide rods, and the rotary drum bearings are connected to the inside of the guide seat.

Preferably, the cutting assembly comprises a cutting motor arranged at the end part of the mounting seat, a transmission rod penetrating through the guide seat is further connected to the inside of the mounting seat in a bearing manner, and the transmission rod is driven to rotate through the cutting motor and drives the rotary drum to rotate.

Preferably, the output shaft of the cutting motor is sleeved with a driving bevel gear, the outer side of the end part of the transmission rod is sleeved with a transmission bevel gear a meshed with the driving bevel gear, the outer part of the rotary drum is sleeved with a driven bevel gear, and the outer part of the transmission rod is also sleeved with a transmission bevel gear b meshed with the driven bevel gear;

the transmission bevel gear b is arranged in the guide seat and slides outside the transmission rod along with the transmission of the guide seat;

The surface of the transmission rod is provided with ribs, and the inner wall of the transmission bevel gear b is provided with rib grooves corresponding to the ribs.

Preferably, a plurality of positioning probes are uniformly distributed on the surface of the carrying disc.

The invention discloses numerical control equipment for workpiece correction, which has the beneficial effects that:

1. The hydraulic cylinder a is arranged to adjust lifting operation of the cutter, the steering motor is arranged to adjust rotating operation of the cutter, the hydraulic cylinder c is arranged to adjust large-stroke transverse transmission operation of the cutter, the guide assembly is arranged to adjust small-stroke transverse transmission operation of the cutter, the cutting assembly is arranged to install the cutter and drive the cutter to rotate, automatic operation can be realized by utilizing PLC programming in cooperation with the positioning probe, the work piece is subjected to chamfering orthopedic operation, manual operation is not needed, the work piece machining yield and machining efficiency are greatly improved, and the practicability is strong.

2. The setting switch assembly can install a plurality of types of cutters, when the cutter needs to be replaced, only needs to utilize the electromagnetic ring to electrify to enable the magnetizer to generate strong magnetism, and the cutter is adsorbed under the telescopic pushing of the hydraulic cylinder b, the assembly hole is formed in the end portion of the mounting seat, the telescopic end of the hydraulic cylinder b passes through the magnetizer to enable the cutter to pass through the assembly Kong Dingru or the rotary drum in the suction mounting seat, and quick replacement operation of the cutter is realized.

Drawings

FIG. 1 is a schematic diagram of a numerical control device for workpiece rectification according to an embodiment of the present invention;

FIG. 2 is a schematic view of a partial structure of a numerical control apparatus for workpiece rectification according to an embodiment of the present invention;

FIG. 3 is a schematic view of the exploded view of FIG. 2 of a numerical control apparatus for workpiece rectification in accordance with an embodiment of the present invention;

FIG. 4 is a schematic rear view of the numerical control device for workpiece correction according to the embodiment of the present invention in FIG. 2;

FIG. 5 is a schematic view of a cutting assembly and routing assembly of a numerical control apparatus for workpiece rectification in accordance with an embodiment of the present invention;

fig. 6 is a schematic diagram of a section structure of a drum of a numerical control device for workpiece correction according to an embodiment of the present invention.

Description of the drawings

1. Numerical control equipment; 2. an orthopedic frame; 3. an orthopedic assembly; 4. a control device;

11. A working platform;

21. A frame body; 22. a hydraulic cylinder a; 23. a hydraulic cylinder b; 24. an electromagnetic ring; 25. a magnetizer;

31. A base plate; 32. a hydraulic cylinder c; 33. a mounting base; 331. a fitting hole; 34. a switching assembly; 35. a steering motor; 36. a carrier plate; 37. a cutting assembly; 38. a guide assembly; 39. a cutter;

341. A turntable; 342. switching the motor; 343. a cutter groove; 344. an electromagnet;

361. Positioning a probe; 371. a cutting motor; 372. a transmission rod; 373. a driving helical gear; 374. driven helical gears; 375. a rotating drum; 376. a transmission bevel gear a; 377. a transmission bevel gear b;

381. A guide motor; 382. a guide rod; 383. a guide seat.

Detailed Description

The present invention will be described in further detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present invention more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the invention.

The same or similar reference numerals in the drawings of the present embodiment correspond to the same or similar components; in the description of the present invention, it should be understood that, if there is an azimuth or positional relationship indicated by terms such as "upper", "lower", "left", "right", etc., based on the azimuth or positional relationship shown in the drawings, it is only for convenience of describing the present invention and simplifying the description, but it is not indicated or implied that the apparatus or element referred to must have a specific azimuth, be constructed and operated in a specific azimuth, and thus terms describing the positional relationship in the drawings are merely illustrative and should not be construed as limitations of the present patent, and specific meanings of the terms described above may be understood by those skilled in the art according to specific circumstances.

The implementation of the present invention will be described in detail below with reference to specific embodiments.

In the present embodiment

Referring to fig. 1-2, a preferred embodiment of the present invention is provided.

The numerical control device for workpiece correction comprises a numerical control device 1 and a control device 4, wherein a working platform 11 is arranged in the numerical control device 1, the working platform 11 is used for fixing a workpiece, an orthopedic frame 2 is arranged right above the working platform 11 by the numerical control device 1, and an orthopedic component 3 for performing orthopedic treatment on the workpiece is arranged at the bottom of the orthopedic frame 2 in a lifting driving mode;

The orthopedic assembly 3 comprises a base plate 31, a carrier plate 36, a mounting seat 33, a guide assembly 38 and a cutting assembly 37 which are arranged on the mounting seat 33, wherein a cutter 39 for orthopedic operation is arranged on the cutting assembly 37;

The orthopedic frame 2 comprises a frame body 21, a hydraulic cylinder a22 is arranged on an inner mounting head of the frame body 21, a telescopic end of the hydraulic cylinder a22 is connected with the top of the base plate 31 and used for adjusting the lifting operation of the cutter 39, a steering motor 35 is arranged in the base plate 31, an output shaft of the steering motor 35 is connected with the top of the carrying plate 36 and used for adjusting the rotating operation of the cutter 39, a hydraulic cylinder c32 is transversely arranged on the surface of the carrying plate 36, a telescopic end of the hydraulic cylinder c32 is connected with the mounting seat 33 and used for adjusting the large-stroke transverse transmission operation of the cutter 39, the guide assembly 38 drives a cutting assembly 37 to transversely guide and used for adjusting the small-stroke transverse transmission operation of the cutter 39, and the cutting assembly 37 comprises a rotary drum 375, and the rotary drum 375 is used for mounting the cutter 39 and driving the rotating operation of the cutter 39;

the surface of the carrying disc 36 is also uniformly provided with a plurality of positioning probes 361 which are convenient for positioning the orthopedic position of the workpiece so as to drive all parts to cooperate by utilizing PLC programming to realize orthopedic operation.

As shown in fig. 3-4, the switching assembly 34 is further mounted on the base plate 31, the switching assembly 34 includes a switching motor 342 and a turntable 341 which is driven by the switching motor 342 and is connected to the inside of the base plate 31 by a bearing, a plurality of cutter grooves 343 for inserting cutters 39 are axially formed in the turntable 341, and the turntable 341 is driven by the switching motor 342 to rotate, so that the positions of the cutter grooves 343 are switched, and different cutters 39 in the cutter grooves 343 are installed in the rotary drum 375;

The cutter 39 has a plurality of cutter heads, which are one of milling cutters, blades, boring cutters or grinding tools, and can realize the switching of different orthopedic requirements of different positions of a workpiece.

And the center of carousel 341 still inlays and is equipped with electromagnet 344, electromagnet 344 circular telegram produces magnetism and is used for retraining cutter 39, cutter groove 343 and the draw-in groove has all been seted up to rotary drum 375's inner wall all around, cutter 39 includes blade and tool bit, and the blade is provided with the rib that corresponds with the draw-in groove all around to the blade is for the magnetism material of inhaling, utilizes electromagnet 344 circular telegram to adsorb fixed cutter 39, also conveniently installs cutter 39 in rotary drum 375 simultaneously.

It is noted that, the hydraulic cylinder b23 is installed on the side of the frame 21 near the switch assembly 34, the electromagnetic ring 24 is installed at the telescopic end of the hydraulic cylinder b23, the magnetizer 25 is installed inside the electromagnetic ring 24, when the cutter 39 needs to be replaced, the magnetizer 25 is only needed to generate strong magnetism by electrifying the electromagnetic ring 24, and the cutter 39 is adsorbed under the telescopic pushing of the hydraulic cylinder b23, the end of the mounting seat 33 is provided with the assembly hole 331, and the telescopic end of the hydraulic cylinder b23 pushes or sucks the cutter 39 into the rotary drum 375 in the mounting seat 33 through the assembly hole 331 by the magnetizer 25, so that the quick replacement operation of the cutter 39 is realized.

Further, referring to fig. 5, the guiding assembly 38 includes a guiding motor 381 disposed at an end of the mounting base 33, and two parallel guide rods 382 driven by the guiding motor 381 and bearing-connected to the inside of the mounting base 33, the outer screw thread of the guide rods 382 is connected to a guide base 383, the rotating drum 375 bearing-connected to the inside of the guide base 383, and the guiding motor 381 drives the guide rods 382 to rotate, so as to push the guide base 383 in the outer screw thread to drive the cutter 39 mounted in the rotating drum 375 to perform fine adjustment operation on the transverse position, thereby improving the precision of the cutter 39 in the process of correcting the workpiece.

Further, the cutting assembly 37 is including set up in the cutting motor 371 of mount pad 33 tip, the inside of mount pad 33 still bearing connection has and runs through the transfer line 372 of guide pad 383, transfer line 372 passes through cutting motor 371 drive rotation, and drive rotary drum 375 rotation, the output shaft of cutting motor 371 has cup jointed initiative helical gear 373, the tip outside of transfer line 372 cup jointed the transmission helical gear a376 with initiative helical gear 373 meshing, the outside of rotary drum 375 has cup jointed driven helical gear 374, and the outside of transfer line 372 still overlaps and is equipped with the transmission helical gear b377 with driven helical gear 374 meshing, transmission helical gear b377 is arranged in the inside of guide pad 383 to along with the transmission of guide pad 383 slides outside the transfer line 372, and when the transfer line 372 in the transmission helical gear 373 of transfer line 372 utilization initiative helical gear 373 drive transmission helical gear a376 rotates, can drive rotary drum 375 through transmission helical gear b377 that the outside cup jointed, and then realize the operation such as realize the rotary cutting or polishing of instrument, the surface of transfer line 372 is provided with helical gear b, the inner wall of transfer line flat is equipped with and has not influenced by the transmission helical gear 383 and can not carried out the motion of guide pad 383 along with the transmission of guide pad 383, and the motion of the inner wall and has reduced the motion of guide pad 383 along with the transmission of guide pad 39, and can not influence the volume along with the transmission of the motion of the guide pad 383, and can not have reduced the effect on the volume of the motion of the tool 383 along with the transmission of the guide 39.

The hydraulic cylinder a22 is arranged to adjust the lifting operation of the cutter 39, the steering motor 35 is arranged to adjust the rotating operation of the cutter 39, the hydraulic cylinder c32 is arranged to adjust the large-stroke transverse transmission operation of the cutter 39, the guide and delivery assembly 38 is arranged to adjust the small-stroke transverse transmission operation of the cutter 39, the cutting assembly 37 is arranged to mount the cutter 39 and drive the cutter 39 to rotate, the automatic operation can be realized by utilizing PLC programming in cooperation with the positioning probe 361, the chamfering orthopedic operation is carried out on a workpiece, manual operation is not needed, the workpiece processing yield and the processing efficiency are greatly improved, and the practicability is high.

When the cutter 39 is required to be replaced, the electromagnetic ring 24 is electrified to enable the magnetizer 25 to generate strong magnetism, the cutter 39 is adsorbed under the telescopic pushing of the hydraulic cylinder b23, the end part of the mounting seat 33 is provided with the assembly hole 331, and the telescopic end of the hydraulic cylinder b23 pushes or sucks the cutter 39 into the rotary drum 375 in the mounting seat 33 through the assembly hole 331 by the magnetizer 25, so that the quick replacement operation of the cutter 39 is realized.

The foregoing description of the preferred embodiments of the invention is not intended to be limiting, but rather is intended to cover all modifications, equivalents, and alternatives falling within the spirit and principles of the invention.

Claims (6)

1. The numerical control equipment for workpiece correction comprises numerical control equipment and a control device, wherein a working platform is arranged in the numerical control equipment and is used for fixing a workpiece;

The orthopedic assembly comprises a base plate, a carrying plate, a mounting seat, a guide assembly and a cutting assembly, wherein the guide assembly and the cutting assembly are arranged on the mounting seat, and a cutter for orthopedic operation is arranged on the cutting assembly;

The orthopedic frame comprises a frame body, wherein a hydraulic cylinder a is arranged in an inner mounting head of the frame body, and the telescopic end of the hydraulic cylinder a is connected with the top of the base plate and used for adjusting the lifting operation of the cutter;

A steering motor is arranged in the base plate, and an output shaft of the steering motor is connected with the top of the carrier plate and used for adjusting the rotation operation of the cutter;

a hydraulic cylinder c is transversely arranged on the surface of the carrying disc, and the telescopic end of the hydraulic cylinder c is connected with the mounting seat and used for adjusting the large-stroke transverse transmission operation of the cutter;

The guide assembly drives the cutting assembly to transversely guide and is used for adjusting small-stroke transverse transmission operation of the cutter;

And, the cutting assembly includes a drum for mounting the cutter and driving a rotation operation of the cutter;

the switching assembly comprises a switching motor and a rotating disc which is driven by the switching motor and is connected with the inside of the base disc through a bearing, and a plurality of cutter grooves for inserting cutters are axially formed in the rotating disc;

an electromagnet is also embedded in the center of the turntable, and the electromagnet is electrified to generate magnetism for restraining the cutter;

a hydraulic cylinder b is arranged on one side of the frame body, which is close to the switching assembly, an electromagnetic ring is arranged at the telescopic end part of the hydraulic cylinder b, and a magnetizer is arranged in the electromagnetic ring;

The end of the mounting seat is provided with an assembly hole, and the telescopic end of the hydraulic cylinder b enables the cutter to pass through the assembly Kong Dingru or suck out of the mounting seat through a magnetizer.

2. The numerical control device for workpiece correction according to claim 1, wherein the cutter groove and the inner wall of the periphery of the rotary drum are provided with clamping grooves, the cutter comprises a cutter body and a cutter head, ribs corresponding to the clamping grooves are arranged on the periphery of the cutter body, and the cutter body is made of magnetic materials;

the cutter heads of the cutter are various and are one of milling cutters, blades, boring cutters or grinding tools.

3. The numerical control device for workpiece correction according to claim 1, wherein the guide assembly comprises a guide motor arranged at the end of the mounting seat and two guide rods which are driven by the guide motor and are connected with the inside of the mounting seat in a bearing manner, the guide seats are connected with external threads of the guide rods, and the rotary drum bearings are connected with the inside of the guide seats.

4. A numerical control device for workpiece rectification as recited in claim 3, wherein said cutting assembly comprises a cutting motor disposed at an end of said mounting base, a transmission rod penetrating said guide base being further bearing-connected to an interior of said mounting base, said transmission rod being driven to rotate by said cutting motor and said drum.

5. The numerical control device for workpiece correction according to claim 4, wherein the output shaft of the cutting motor is sleeved with a driving bevel gear, the outer side of the end part of the driving rod is sleeved with a driving bevel gear a meshed with the driving bevel gear, the outer part of the rotating drum is sleeved with a driven bevel gear, and the outer part of the driving rod is also sleeved with a driving bevel gear b meshed with the driven bevel gear;

the transmission bevel gear b is arranged in the guide seat and slides outside the transmission rod along with the transmission of the guide seat;

The surface of the transmission rod is provided with ribs, and the inner wall of the transmission bevel gear b is provided with rib grooves corresponding to the ribs.

6. The numerical control device for workpiece correction according to claim 1, wherein a plurality of positioning probes are uniformly distributed on the surface of the carrying disc.