Abstract
This work proposes a model for suggesting optimal process configuration in plunge centreless grinding operations. Seven different approaches were implemented and compared: first principles model, neural network model with one hidden layer, support vector regression model with polynomial kernel function, Gaussian process regression model and hybrid versions of those three models. The first approach is based on an enhancement of the well-known numerical process simulation of geometrical instability. The model takes into account raw workpiece profile and possible wheel-workpiece loss of contact, which introduces an inherent limitation on the resulting profile waviness. Physical models, because of epistemic errors due to neglected or oversimplified functional relationships, can be too approximated for being considered in industrial applications. Moreover, in deterministic models, uncertainties affecting the various parameters are not explicitly considered. Complexity in centreless grinding models arises from phenomena like contact length dependency on local compliance, contact force and grinding wheel roughness, unpredicted material properties of the grinding wheel and workpiece, precision of the manual setup done by the operator, wheel wear and nature of wheel wear. In order to improve the overall model prediction accuracy and allow automated continuous learning, several machine learning techniques have been investigated: a Bayesian regularized neural network, an SVR model and a GPR model. To exploit the a priori knowledge embedded in physical models, hybrid models are proposed, where neural network, SVR and GPR models are fed by the nominal process parameters enriched with the roundness predicted by the first principle model. Those hybrid models result in an improved prediction capability.
Highlights
1.1 Centreless grindingAs Dhavlikar et al [1] describe centreless grinding is a common manufacturing grinding process for round workpieces, thanks to its unique workpiece (WP) holding system
Lela et al [26] examined the influence of cutting speed, feed and depth of cut on surface roughness in face milling by three different modelling methodologies, namely, regression analysis (RA), support vector machines (SVM) and Bayesian neural network (BNN), and found out that, when the training dataset is small, both BNN and Support vector regression (SVR) modelling methodologies are comparable with RA methodology and, they can even offer better results
This paper presents results from attempting to combine first principle and machine learning techniques into hybrid models to forecast performance of a centreless grinding process in terms of workpiece final roundness
Summary
As Dhavlikar et al [1] describe centreless grinding is a common manufacturing grinding process for round workpieces, thanks to its unique workpiece (WP) holding system. Lizarralde [12] has applied similar approaches to guide setup and optimization of centreless plunge grinding processes, in order to reduce setup time and avoid geometric instabilities as a function of WP height and blade angle, taking into account machine-WP dynamic interaction. These techniques lead to models that quantitatively predict the evolution of profile error for each geometric configuration. We will focus on process characterization by artificial intelligence techniques
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