Machining Control of Surface Roughness by Measuring Cutting Forces

Eustaquio García Plaza; Pedro José Núñez; Francisco Mata; A. Sanz

doi:10.4028/www.scientific.net/AMR.498.157

Paper Titles

Image Based Analysis Evaluation of the Elements of Secondary Adhesion Wear in Dry Turning of Aluminum Alloys
p.133

Improvement of the Mechanical Properties of Formed Steel Cross Section Profile for Timber Upgrading
p.139

Influence of Cutting Conditions on Temperature Rise, Feed Force and Cutting Torque when Drilling Bone
p.145

Laser Tracker Based Volumetric Verification of Machine Tools
p.151

Machining Control of Surface Roughness by Measuring Cutting Forces
p.157

Mechanistic Model for High Speed Turning of Austempered Ductile Irons
p.163

Metrology - Base for Scientific Cognition and Technical Production
p.169

Milling Strategies for Thin-Walled Components
p.177

Modeling and Simulation of Vibration-Assisted Extrusion Tapping of Internal Thread with Finite Element Method (FEM)
p.183

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Machining Control of Surface Roughness by Measuring Cutting Forces

Abstract:

The primary aim of this study was to design and develop an on-line control system of finished surfaces in automated machining process by CNC turning. The control system consisted of two basic phases: during the first phase, surface roughness was monitored through cutting force signals; the second phase involved a closed-loop adaptive control system based on data obtained during the monitoring of the cutting process. The system ensures that surfaces roughness is maintained at optimum values by adjusting the feed rate through communication with the PLC of the CNC machine. A monitoring and adaptive control system has been developed that enables the real-time monitoring of surface roughness during CNC turning operations. The system detects and prevents faults in automated turning processes, and applies corrective measures during the cutting process that raise quality and reliability reducing the need for quality control.