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Real-Time Acoustic Measurement System for Cutting-Tool Analysis During Stainless Steel Machining

Tom Salm, Kourosh Tatar, José Chilo

2024Machines13 citationsDOIOpen Access PDF

Abstract

This study presents a sound-based tool-wear monitoring system designed to overcome the limitations of conventional methods that focus solely on gradual and predictable wear patterns. The proposed system employs low-cost, high-frequency microphones and advanced signal processing—featuring analog/digital filtering, oversampling, signal conditioning, PLL-based synchronization, and feature extraction (ZCR, RMS)—to capture acoustic emissions during machining. Key innovations include optimized microphone placement, a custom PCB, and real-time data transfer via WiFi to MATLAB for analysis. Using the TreeBagger machine-learning algorithm, the system accurately predicts tool wear, detecting both gradual and abrupt wear patterns. Tested on EN 1.4307 (AISI/ASTM 304L) stainless steel, the system demonstrated robust performance in real-time tool-condition assessment. Its scalable and cost-effective design allows for the integration of additional sensors and features, providing a non-invasive and adaptive solution to enhance machining efficiency and reduce operational costs.

Topics & Concepts

MicrophoneMachiningTool wearSynchronization (alternating current)SIGNAL (programming language)Focus (optics)ScalabilitySignal processingComputer scienceEngineeringDigital signal processingElectronic engineeringMechanical engineeringTelecommunicationsComputer networkChannel (broadcasting)PhysicsDatabaseSound pressureOpticsProgramming languageAdvanced machining processes and optimizationAdvanced Machining and Optimization TechniquesAdvanced Sensor Technologies Research
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