Xichun Luo scite author profile

Currently the underlying necessities for predictability, producibility and productivity remain big issues in ultraprecision machining of miniature/microproducts. The demand on rapid and economic fabrication of miniature/microproducts with complex shapes has also made new challenges for ultraprecision machine tool design. In this paper the design for an ultraprecision machine tool is introduced by describing its key machine elements and machine tool design procedures. The focus is on the review and assessment of the state-of-the-art ultraprecision machining tools. It also illustrates the application promise of miniature/microproducts. The trends on machine tool development, tooling, workpiece material and machining processes are pointed out.

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Improved Dynamic Cutting Force Model in Peripheral Milling. Part I: Theoretical Model and Simulation

Liu

Cheng

Webb

et al. 2002

The International Journal of Advanced Manufacturing Technology

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Modeling flank wear of carbide tool insert in metal cutting

Luo

Cheng

Holt

et al. 2005

Wear

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In this paper theoretical and experimental studies are carried out to investigate the intrinsic relationship between tool flank wear and operational conditions in metal cutting processes using carbide cutting inserts. A new flank wear rate model, which combines cutting mechanics simulation and an empirical model, is developed to predict tool flank wear land width. A set of tool wear cutting tests using hard metal coated carbide cutting inserts are performed under different operational conditions. The wear of the cutting inset is evaluated and recorded using Zygo New View 5000 microscope. The results of the experimental studies indicate that cutting speed has a more dramatic effect on tool life than feed rate. The wear constants in the proposed wear rate model are determined based on the machining data and simulation results. A good agreements between the predicted and measured tool flank wear land width show that the developed tool wear model can accurately predict tool flank wear to some extent.

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Prediction of cutting force distribution and its influence on dimensional accuracy in peripheral milling

Liu

Cheng

Webb

et al. 2002

International Journal of Machine Tools and Manufacture

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An investigation on the mechanics of nanometric cutting and the development of its test-bed

Luo

Cheng

Guo

et al. 2003

International Journal of Production Research

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The mechanics of machining at a very small depth of cut (100 nm or less) is not well understood. The chip formation physics, cutting forces generation, resulting temperatures and the size effects significantly affect the efficiency of the process and the surface quality of the workpiece. In this paper the cutting mechanics at nanometric scale is investigated in comparison with the conventional cutting principles. Molecular Dynamics (MD) is used to model and simulate the nanometric cutting processes. The models and simulated results are evaluated and validated by the cutting trials on an atomic force microscope (AFM). Furthermore, the conceptual design of a bench type ultraprecision machine tools is presented and the machine aims to be a facility for nanometric cutting of 3D MEMS devices. The paper concludes with a discussion on the potential and applications of nanometric cutting techniques/equipment for the predictabilty, producibility and productivity in manufacturing at the nanoscale.

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Xichun Luo

Design of ultraprecision machine tools with applications to manufacture of miniature and micro components

Improved Dynamic Cutting Force Model in Peripheral Milling. Part I: Theoretical Model and Simulation

Modeling flank wear of carbide tool insert in metal cutting

Prediction of cutting force distribution and its influence on dimensional accuracy in peripheral milling

An investigation on the mechanics of nanometric cutting and the development of its test-bed

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