Abstract

Processing certain kinds of micro-textures onto the surface of tools can improve their wear resistance, reduce the friction between them and machined surfaces, prolong their service life and improve their processing efficiency. When milling titanium alloy with ball-end milling cutters, the cutting force and the cutting heat causes plastic deformation and a concentration of stress on workpiece surfaces, damaging their surface integrity. In this paper, we report on a test involving the milling of titanium alloy, where a micro-texture was placed onto the front of a ball-end cutter and the surface roughness and work hardening of the machined surface were studied. The orthogonal experiment was designed around changes in the diameter of the micro-texture, its depth, the spacing between individual micro-pits, and its distance from the cutting edge. Data from the experiment was then used to assess the influence changes in the micro-texture parameters had upon the roughness and hardening of the surface. The data was processed and analyzed by using regression analysis and a prediction model for surface roughness and work hardening was established. The reliability of the model was then verified. The contents of this paper provide a theoretical basis for improving the cutting performance and the surface machining quality of cemented carbide tools.

Highlights

  • Titanium alloy has become one of the main structural materials used in the aerospace industry because of its outstanding characteristics, such as a high specific strength, and good corrosion resistance

  • The heat generated by the cutting process increases the temperature of the workpiece surface

  • When the temperature rises to a critical point, the strengthened metal returns to its normal state, and the physical and mechanical properties of the hardening are eliminated

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Summary

Introduction

Titanium alloy has become one of the main structural materials used in the aerospace industry because of its outstanding characteristics, such as a high specific strength, and good corrosion resistance. In the face of this, a large number of studies have found that adding a micro-texture to the tool’s surface can bring about good anti-friction and anti-adhesion effects, improve wear resistance, and improve the quality of the machined surface. This discovery provides a new research direction for the development of cutting tools [2]. This includes surface roughness, surface hardening, surface residual stress, and the surface metamorphic layer At present, it is attracting a great deal of research, and a number of studies have attempted to establish surface integrity analysis and evaluation models and to explore the surface formation process. TThhee FFaaccttoorrss AAffffeeccttiinngg TTiittaanniiuumm AAllllooyy SSuurrffaaccee QQuuaalliittyy WWhheenn MMiilllleedd bbyyaaMMiiccrroo-‐TTeexxttuurreedd Ball‐ BEnaldl-MEnidlliMngilClinugtteCrutter

The Machined Surface Formation Process
Factors Affecting the Surface Quality
Evaluation Criteria for the Work Hardening
Test Data and Orthogonal Analysis of Surface Roughness
Analysis of the Influence of Micro-Texture Parameters on Surface Roughness
Test Data and an Orthogonal Analysis of Work Hardening
Diameter 30 Depth
Prediction Model and the Test of its Significance
Test of the Significance of the Prediction Model
Conclusions

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