Abstract
In metal-cutting processes, the interaction between the tool and workpiece is highly nonlinear and is very sensitive to small variations in the process parameters. This causes difficulties in controlling and predicting the resulting surface finish quality of the machined surface. In this work, vibration signals along the major cutting force direction in the turning process are measured at different combinations of cutting speeds, feeds, and depths of cut using a piezoelectric accelerometer. The signals are processed to extract features in the time and frequency domains. These include statistical quantities, Fast Fourier spectral signatures, and various wavelet analysis extracts. Various feature selection methods are applied to the extracted features for dimensionality reduction, followed by applying several outlier-resistant unsupervised clustering algorithms on the reduced feature set. The objective is to ascertain if partitions created by the clustering algorithms correspond to experimentally obtained surface roughness data for specific combinations of cutting conditions. We find 75% accuracy in predicting surface finish from the Noise Clustering Fuzzy C-Means (NC-FCM) and the Density-Based Spatial Clustering Applications with Noise (DBSCAN) algorithms, and upwards of 80% accuracy in identifying outliers. In general, wrapper methods used for feature selection had better partitioning efficacy than filter methods for feature selection. These results are useful when considering real-time steel turning process monitoring systems.
Highlights
IntroductionSurface finish is one of the most important quality measures that affect the product cost and its functionality
In a related work [14], the effect of transformation, feature scaling with mean normalization, and normalization were estimated
A framework to predict the level of surface roughness using data clustering based on features extracted from vibration signals measured during the turning of steel is presented here
Summary
Surface finish is one of the most important quality measures that affect the product cost and its functionality. Examples of functionality characteristics include tribological properties, corrosion resistance, sliding surface friction, light reflection fatigue life, and fit of critical mating surfaces for assembly. It is normally specified for a certain application in order to achieve the desired level during machining. Factors that may affect the surface finish in machining such as the machining parameters, hardness of workpiece material, selection of cutting tool and tool geometry, must be carefully selected to obtain desired product quality. A review on the effective and accurate prediction of surface roughness in machining is presented in [1]
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