Abstract
In current precision and ultraprecision machining practice, the positioning and control of actuation systems, such as slideways and spindles, are heavily dependent on the use of linear or rotary encoders. However, positioning control is passive because of the lack of direct monitoring and control of the tool and workpiece positions in the dynamic machining process and also because it is assumed that the machining system is rigid and the cutting dynamics are stable. In ultraprecision machining of freeform surfaces using slow tool servo mode in particular, however, account must be taken of the machining dynamics and dynamic synchronization of the cutting tool and workpiece positioning. The important question also arises as to how ultraprecision machining systems can be designed and developed to work better in this application scenario. In this paper, an innovative dynamics-oriented engineering approach is presented for ultraprecision machining of freeform surfaces using slow tool servo mode. The approach is focused on seamless integration of multibody dynamics, cutting forces, and machining dynamics, while targeting the positioning and control of the tool–workpiece loop in the machining system. The positioning and motion control between the cutting tool and workpiece surface are further studied in the presence of interfacial interactions at the tool tip and workpiece surface. The interfacial cutting physics and dynamics are likely to be at the core of in-process monitoring applicable to ultraprecision machining systems. The approach is illustrated using a virtual machining system developed and supported with simulations and experimental trials. Furthermore, the paper provides further explorations and discussion on implementation perspectives of the approach, in combination with case studies, as well as discussing its fundamental and industrial implications.
Highlights
Ultraprecision machining of freeform surfaces through diamond turning in slow tool servo (STS) machining mode is becoming one of the most useful machining processes, since it can deliver high accuracy and efficiency by integrating distinct precision engineering techniques
Numerical simulations on a typical ultraprecision machining system are performed using algorithms for multibody dynamics implemented in the ADAMS/Solver environment
An innovative precision engineering approach for ultraprecision machining of freeform surfaces has been presented based on modeling and analysis of dynamics
Summary
Ultraprecision machining of freeform surfaces through diamond turning in slow tool servo (STS) machining mode is becoming one of the most useful machining processes, since it can deliver high accuracy and efficiency by integrating distinct precision engineering techniques. Scitation.org/journal/npe function of the spindle rotation and translation of the machine slide This method differs from the use of tool servos to generate the tool motion.. To fulfill the increasing requirements for high precision and productivity in ultraprecision machining of freeform surfaces, it is essential to have a scientific understanding of the underlying dynamics, ideally linked to the materials, mechanical stiffness, friction, tooling, servo system, and their collective effects, together with the precision engineering perspectives for the machining system. The research presented in this paper is focused on a dynamicsoriented engineering approach for ultraprecision machining of freeform surfaces based on a scientific understanding of the underlying dynamics, the modeling of these dynamics, and the development of algorithms for implementation of the approach in precision engineering practice. The paper attempts in a holistic manner to bridge the gaps between engineering science fundamentals, precision engineering, and ultraprecision machining systems for high-precision machining of complex components and surfaces
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