CN119407271A - Gear ring rotation processing method and equipment - Google Patents

Abstract

The invention provides a gear ring rotary separation processing method and equipment, comprising a workbench, a workpiece sliding table, a tool sliding table, a workpiece spindle assembly and a tool spindle assembly, wherein the workpiece sliding table and the tool sliding table are mounted on the workbench, the workpiece sliding table can realize transverse movement, the tool sliding table can realize longitudinal movement, the workpiece spindle assembly is mounted on the workpiece sliding table, the tool spindle assembly is mounted on the tool sliding table, the workpiece spindle assembly is used for being mounted on a workpiece body, and the tool spindle assembly is used for being mounted on the tool body. The invention improves the machining precision, does not damage the structural organization of the workpiece, and has simple and convenient machining of the workpiece, easy replacement of the blade, strong stability and high machining efficiency.

Description

Gear ring rotary separation processing method and equipment

Technical Field

The invention belongs to the field of machining, and particularly relates to a method and equipment for rotary separation machining of a gear ring.

Background

The extrusion wheel and tooth sleeve meshing extrusion method (only roughly controlled by a time relay) is common in the processing technology of the back taper, the depth of backlog on a circle of teeth at the extruded position is difficult to be consistent, the precision of the extruded internal spline is lower, the accumulation of the circle section is larger, the requirement of the M value cross bar moment after extrusion is increased at the extruded back taper position for preventing gear dropping after gear shift, the manufacturing difficulty is further increased, the stress of the processed tooth sleeve is generated due to extrusion processing, the stress is released in the processes of heat treatment carburization, quenching and tempering, the precision of the internal spline is damaged, and the back taper is processed in a cutting mode at present, so that the influence on the precision factor can be eliminated. The special extrusion gear is needed in the back taper processing, and the variety of the special extrusion gear is increased along with the different internal spline parameters of the tooth sleeve, so that the extrusion gears with different moduli, pressure angles, deflection coefficients, tooth top circles, tooth root circles, tooth groove widths (tooth thicknesses), back taper angles and back taper lengths are needed to be prepared, the extrusion gear has higher precision and higher manufacturing cost.

Disclosure of Invention

In view of the above, the invention aims to provide a method and equipment for rotary separation processing of a gear ring, which can improve the processing precision, does not damage the structural organization of a workpiece, and has the advantages of simple and convenient processing of the workpiece, easy replacement of a blade, strong stability and high processing efficiency.

In order to achieve the above purpose, the technical scheme of the invention is realized as follows:

the gear ring rotary separation processing device comprises a workbench, a workpiece sliding table, a tool sliding table, a workpiece spindle assembly and a tool spindle assembly;

the workpiece sliding table and the tool sliding table are mounted on the workbench, the workpiece sliding table can realize transverse movement, and the tool sliding table can realize longitudinal movement;

The workpiece spindle assembly is mounted on the workpiece sliding table, and the tool spindle assembly is mounted on the tool sliding table;

The workpiece spindle assembly is for mounting to a workpiece body and the tool spindle assembly is for mounting a tool body.

Further, the workpiece sliding table comprises a first sliding table seat, a first lead screw and a first motor;

The first lead screw and the first motor are mounted on the first sliding table seat, and the first lead screw is connected to an output section of the first motor;

the workpiece spindle assembly comprises a workpiece base, a workpiece rotating shaft and a workpiece chuck, wherein the workpiece base is connected to a first screw rod in a threaded manner, the workpiece rotating shaft is mounted on the workpiece base, and the workpiece chuck is connected to the output end of the workpiece rotating shaft;

the workpiece chuck is used for clamping the workpiece body.

The cutter sliding table comprises a second sliding table seat, a second lead screw and a second motor, wherein the second lead screw and the second motor are mounted on the second sliding table seat, and the second lead screw is connected to an output section of the second motor;

the tool spindle assembly comprises a tool base, a tool rotating shaft and a tool chuck, wherein the tool base is connected to a second screw rod in a threaded mode, the tool rotating shaft is mounted on the tool base, the tool chuck is connected to the output end of the tool rotating shaft, and the tool chuck is used for clamping the tool body.

A gear ring rotary separation processing method comprises the following steps:

s1, preheating a machine tool,

S2, starting equipment and preparing a workpiece;

s3, quick positioning and detection;

S4, cutting;

S5, finishing processing and resetting;

S6, confirming the machining shape and the interpolation position;

In the step S1, the machine tool is preheated in an automatic operation mode, the operation time is 10-20 minutes, the main shaft is 1000-2000 rpm, the workpiece sliding table and the tool sliding table move on the maximum stroke, but the speed is not the maximum;

in the step S2, after the hydraulic clamping system is started, the toothed sleeve workpiece is accurately placed in the all-external-holding fixture, so that the workpiece is ensured to be stable, and the workpiece is locked through the hydraulic device so as to prevent displacement or loosening in the subsequent processing process.

Further, in step S3, the start key is pressed, the tool main shaft sliding table starts to rapidly move, the feeding speed is set to be 200mm/min, the tool main shaft sliding table rapidly reaches the set position, meanwhile, the workpiece main shaft sliding table also rapidly moves to the tooth detection position at the same feeding speed, the tooth detection switch is used for detecting, the machining position of a workpiece is accurately found, at the moment, if the position of the workpiece is detected to be abnormal, the system automatically alarms and stops running, and after the position detection is completed, the workpiece main shaft sliding table rapidly returns to the safe position, and the accuracy of subsequent machining is ensured.

Further, in step S4, the tool spindle sliding table is rapidly moved to the cutting position of the tooth sleeve and is accurately positioned at the position determined by the tooth detection switch, at the moment, the workpiece spindle starts to rotate positively at the speed of 2000rpm, the tool spindle rotates reversely at the speed of 5500rpm, the two spindles synchronously rotate, high-efficiency cutting is achieved, the cutting process adopts reverse taper cutting, the required taper machining effect is achieved, the tool spindle sliding table is subjected to continuous feeding cutting at the stage, and the machining uniformity and precision are ensured so as to meet the design requirement of the workpiece.

Further, in step S5, after the machining is completed, the main shaft of the equipment stops running to ensure that all moving parts are in a static state, then the workpiece main shaft and the cutter main shaft are quickly returned to the initial positions, the hydraulically locked workpiece is fully released to ensure that the workpiece can be safely taken out after the machining is completed to avoid damage or deformation, and the system displays the state of the machining completion to prompt an operator to replace or machine the workpiece of the next round.

In addition, the machined tooth sleeve workpiece is subjected to surface treatment, so that the smoothness and the wear resistance of the machined tooth sleeve workpiece are ensured, and the service life and the working efficiency of the whole product are improved.

Compared with the prior art, the method and the device for rotationally separating the gear ring have the following advantages:

(1) The cutting machining mode is beneficial to the recovery of deformation generated in the machining process of a machine tool process system, is beneficial to the recovery of rigid deformation of a workpiece, and improves the surface quality of a machined curved surface.

(2) The gear ring rotary separation processing method and equipment provided by the invention have the advantages that the cutter and the workpiece are operated simultaneously, and the synchronous operation can ensure accurate control in the processing process, so that the processing precision is improved, and the vibration and noise caused by gear transmission can be reduced.

(3) The method and the device for rotary parting processing of the gear ring are characterized in that the cutting heat generated in the contact area of the cutter and the workpiece is not easy to release in the cutting process, and the thermal deformation of the processed workpiece and the machine tool is easy to cause.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the invention. In the drawings:

fig. 1 is a schematic view of an apparatus for rotary separation processing of a ring gear according to an embodiment of the present invention.

Reference numerals illustrate:

1. a work table; 2, a workpiece sliding table, 3, a tool sliding table, 4, a workpiece spindle assembly and 5, a tool spindle assembly.

Detailed Description

It should be noted that, without conflict, the embodiments of the present invention and features of the embodiments may be combined with each other.

In the description of the present invention, it should be understood that the terms "center", "longitudinal", "lateral", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are merely for convenience in describing the present invention and simplifying the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and thus should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first", "a second", etc. may explicitly or implicitly include one or more such feature. In the description of the present invention, unless otherwise indicated, the meaning of "a plurality" is two or more.

In the description of the present invention, unless explicitly stated or limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected, mechanically connected, electrically connected, directly connected, indirectly connected via an intervening medium, or in communication between two elements. The specific meaning of the above terms in the present invention can be understood by those of ordinary skill in the art in a specific case.

The invention will be described in detail below with reference to the drawings in connection with embodiments.

The gear ring rotary separation processing device comprises a workbench 1, a workpiece sliding table 2, a tool sliding table 3, a workpiece spindle assembly 4 and a tool spindle assembly 5;

The workpiece sliding table 2 and the tool sliding table 3 are mounted on the workbench 1, the workpiece sliding table 2 can realize transverse movement, and the tool sliding table 3 can realize longitudinal movement;

the workpiece spindle assembly 4 is mounted to the workpiece sliding table 2, and the tool spindle assembly 5 is mounted to the tool sliding table 3;

The workpiece spindle assembly 4 is for mounting to a workpiece body and the tool spindle assembly 5 is for mounting a tool body.

Preferably, the workpiece sliding table 2 comprises a first sliding table seat, a first lead screw and a first motor;

The first lead screw and the first motor are mounted on the first sliding table seat, and the first lead screw is connected to an output section of the first motor;

The workpiece spindle assembly 4 comprises a workpiece base, a workpiece rotating shaft and a workpiece chuck, wherein the workpiece base is connected to a first screw rod in a threaded manner, the workpiece rotating shaft is mounted on the workpiece base, and the workpiece chuck is connected to the output end of the workpiece rotating shaft;

the workpiece chuck is used for clamping the workpiece body.

Preferably, the tool sliding table 3 comprises a second sliding table seat, a second lead screw and a second motor, wherein the second lead screw and the second motor are mounted on the second sliding table seat, and the second lead screw is connected to an output section of the second motor;

The tool spindle assembly 5 comprises a tool base, a tool rotating shaft and a tool chuck, wherein the tool base is connected to the second screw rod in a threaded mode, the tool rotating shaft is mounted on the tool base, the tool chuck is connected to the output end of the tool rotating shaft, and the tool chuck is used for clamping the tool body.

A gear ring rotary separation processing method comprises the following steps:

s1, preheating a machine tool,

S2, starting equipment and preparing a workpiece;

s3, quick positioning and detection;

S4, cutting;

S5, finishing processing and resetting;

S6, confirming the machining shape and the interpolation position;

Preferably, in the step S1, the machine tool is preheated in an automatic operation mode, the operation time is 10-20 minutes, the main shaft is 1000-2000 rpm, the workpiece sliding table 2 and the tool sliding table 3 move on the maximum stroke, but the speed is not the maximum;

in the step S2, after the hydraulic clamping system is started, the toothed sleeve workpiece is accurately placed in the all-external-holding fixture, so that the workpiece is ensured to be stable, and the workpiece is locked through the hydraulic device so as to prevent displacement or loosening in the subsequent processing process.

In the step S3, the start key is pressed, the tool main shaft sliding table starts to rapidly move, the feeding speed is set to be 200mm/min, the tool main shaft sliding table rapidly reaches the set position, meanwhile, the workpiece main shaft sliding table also rapidly moves to the tooth detection position at the same feeding speed, the tooth detection switch is used for detecting, the machining position of a workpiece is accurately found, at the moment, if the position of the workpiece is detected to be abnormal, the system automatically alarms and stops running, and after the position detection is completed, the workpiece main shaft sliding table rapidly returns to the safe position, so that the accuracy of subsequent machining is ensured.

Preferably, in step S4, the tool spindle slipway moves rapidly to the cutting position of the tooth sleeve and is accurately positioned at the position determined by the tooth detection switch, at the moment, the workpiece spindle starts to rotate positively at the speed of 2000rpm, the tool spindle rotates reversely at the speed of 5500rpm, the two spindles synchronously run to realize efficient cutting, the cutting process adopts reverse taper cutting to realize the required taper machining effect, and the tool spindle slipway carries out continuous feed cutting at the stage to ensure the uniformity and precision of machining so as to meet the design requirement of the workpiece.

The high speed of the tool spindle increases the cutting frequency when the tool contacts the workpiece, can cut more rapidly, improves the cutting amount in unit time, removes waste more effectively, and improves the machining efficiency at the same time;

By setting the rotation speeds of the workpiece and the cutter spindle to different ratios, the distribution of shearing force can be optimized, so that the crushing and deformation of materials in the cutting process are more uniform, the roughness of the processed surface is reduced, and the finish of the final workpiece is improved;

Higher tool spindle speeds can reduce the time of contact with the workpiece, which also means that the tool has less friction and heat generation during cutting, thereby reducing tool wear. The reverse taper machining has higher requirements on surface quality, and the higher cutter rotating speed is beneficial to generating smoother and uniform taper, which is important for assembly precision and subsequent treatment.

The examples were described using two different sets of process parameters:

Combination A (Low speed cutter)

2000Rpm for workpiece spindle, 3000rpm for tool spindle, 0.5mm for cutting depth, 2cm3/min for cutting per minute, and Ra1.5 μm for surface roughness

The service life of the cutter is 50;

Combination B (optimized combination)

Workpiece spindle 2000rpm, tool spindle 5500rpm, cutting depth 0.5mm, cutting power 4cm3/min per minute, surface roughness Ra0.8μm

The service life of the cutter is 70 pieces;

From the above, it can be seen from the comparison that, in the case of using the combination B (2000 rpm for the workpiece spindle and 5500rpm for the tool spindle), the cutting depth was the same, but the cutting amount per minute was greatly increased and the surface roughness was reduced by increasing the rotation speed of the tool. In addition, the service life of the cutter is also obviously prolonged. Such comparative data is sufficient to demonstrate that selecting an appropriate rotational speed can provide significant processing advantages.

Preferably, in step S5, after the machining is completed, the main shaft of the equipment stops running to ensure that all moving parts are in a static state, then the workpiece main shaft and the cutter main shaft are quickly returned to the initial positions, the hydraulically locked workpiece is fully released to ensure that the workpiece can be safely taken out after the machining is completed to avoid damage or deformation, and the system displays the state of the machining completion to prompt an operator to replace or machine the workpiece of the next round.

In addition, the machined tooth sleeve workpiece is subjected to surface treatment to ensure the smoothness and the wear resistance, so that the service life and the working efficiency of the whole product are improved.

In back taper machining, reasonable matching of the speeds of the workpiece spindle and the cutter spindle can improve production efficiency, improve machining quality and prolong the service life of the cutter. The design considers the material characteristics, cutting force and process requirements, and ensures the efficient and high-quality processing process.

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, alternatives, and improvements that fall within the spirit and scope of the invention.

Claims (9)

1. The gear ring rotary separation processing device is characterized by comprising a workbench, a workpiece sliding table, a tool sliding table, a workpiece spindle assembly and a tool spindle assembly;

the workpiece sliding table and the tool sliding table are mounted on the workbench, the workpiece sliding table can realize transverse movement, and the tool sliding table can realize longitudinal movement;

The workpiece spindle assembly is mounted on the workpiece sliding table, and the tool spindle assembly is mounted on the tool sliding table;

The workpiece spindle assembly is for mounting to a workpiece body and the tool spindle assembly is for mounting a tool body.

2. The gear ring rotary separation processing device according to claim 1, wherein the workpiece sliding table comprises a first sliding table seat, a first lead screw and a first motor;

The first lead screw and the first motor are mounted on the first sliding table seat, and the first lead screw is connected to an output section of the first motor;

the workpiece spindle assembly comprises a workpiece base, a workpiece rotating shaft and a workpiece chuck, wherein the workpiece base is connected to a first screw rod in a threaded manner, the workpiece rotating shaft is mounted on the workpiece base, and the workpiece chuck is connected to the output end of the workpiece rotating shaft;

the workpiece chuck is used for clamping the workpiece body.

3. The gear ring rotary separation processing device according to claim 1, wherein the tool sliding table comprises a second sliding table seat, a second lead screw and a second motor, wherein the second lead screw and the second motor are mounted on the second sliding table seat, and the second lead screw is connected to an output section of the second motor;

the tool spindle assembly comprises a tool base, a tool rotating shaft and a tool chuck, wherein the tool base is connected to a second screw rod in a threaded mode, the tool rotating shaft is mounted on the tool base, the tool chuck is connected to the output end of the tool rotating shaft, and the tool chuck is used for clamping the tool body.

4. A gear ring rotation dividing processing method, which uses the gear ring rotation dividing processing device according to any one of claims 1-3, and is characterized by comprising the following steps:

s1, preheating a machine tool,

S2, starting equipment and preparing a workpiece;

s3, quick positioning and detection;

S4, cutting;

S5, finishing processing and resetting;

S6, confirming the machining shape and the interpolation position.

5. The gear ring rotary separation processing method is characterized in that in the step S1, a machine tool is preheated in an automatic operation mode, the operation time is 10-20 minutes, the main shaft is 1000-2000 rpm, the workpiece sliding table and the tool sliding table move on the maximum stroke, but the speed is not the maximum;

in the step S2, after the hydraulic clamping system is started, the toothed sleeve workpiece is accurately placed in the all-external-holding fixture, so that the workpiece is ensured to be stable, and the workpiece is locked through the hydraulic device so as to prevent displacement or loosening in the subsequent processing process.

6. A gear ring rotary separation machining method according to claim 4 is characterized in that in the step S3, a start key is pressed, a tool main shaft sliding table starts to move rapidly, the feeding speed is set to be 200mm/min, the tool main shaft sliding table rapidly reaches a set position, meanwhile, a workpiece main shaft sliding table also moves rapidly to a tooth detection position at the same feeding speed, the workpiece main shaft sliding table is detected through a tooth detection switch, the machining position of a workpiece is accurately found, at the moment, if the workpiece position is detected to be abnormal, the system automatically alarms and stops running, and after the position detection is completed, the workpiece main shaft sliding table rapidly returns to a safe position, so that the accuracy of subsequent machining is ensured.

7. The gear ring rotary separation machining method according to claim 4 is characterized in that in the step S4, a tool spindle sliding table moves quickly to a cutting position of a gear sleeve and is accurately positioned at a position determined by a gear detection switch, at the moment, a workpiece spindle starts to rotate positively at a speed of 2000rpm, the tool spindle rotates reversely at a speed of 5500rpm, the two spindles synchronously run, efficient cutting is achieved, the cutting process adopts inverted cone cutting, the required cone machining effect is achieved, the tool spindle sliding table carries out continuous feeding cutting at the stage, and machining uniformity and machining precision are guaranteed to meet workpiece design requirements.

8. The gear ring rotary separation machining method according to claim 4, wherein in the step S5, after machining is completed, a main shaft of the equipment stops to ensure that all moving parts are in a static state, then the main shaft of the workpiece and the main shaft of the cutter quickly retract to an initial position, the hydraulically locked workpiece is fully released to ensure that the workpiece can be safely taken out after machining is completed to avoid damage or deformation, and the system displays the state of the machined workpiece to prompt an operator to replace or machine the workpiece of the next round.

9. The gear ring rotary separation machining method according to claim 4, wherein in the step S6, the machining shape is secondarily confirmed through a three-coordinate measuring instrument, the sizes and tolerance indexes are guaranteed to meet the standards, in addition, the machined tooth sleeve workpiece is subjected to surface treatment, the smoothness and the wear resistance of the machined tooth sleeve workpiece are guaranteed, and therefore the service life and the working efficiency of the whole product are improved.