Development of family of artificial neural networks for the prediction of cutting tool condition

Recently, besides regression analysis, artificial neural networks (ANNs) are increasingly used to predict the state of tools. Nevertheless, simulations trained by cutting modes, material type and the method of sharpening twist drills (TD) and the drilling length from sharp to blunt as input paramete...

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Veröffentlicht in:	Advances in production engineering & management 2020-06, Vol.15 (2), p.164-178
Hauptverfasser:	Spaic, O., Krivokapic, Z., Kramar, D.
Format:	Artikel
Sprache:	eng
Schlagworte:	Acoustics Artificial neural networks Axial forces Axial stress Back propagation Computer simulation Cutting tools Drill bits Drilling Galvanized steel Machine learning Neural networks Parameters Powder metallurgy Regression analysis Sharpening Software Titanium alloys Torque Twist drills Vibration
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creator	Spaic, O. Krivokapic, Z. Kramar, D.
description	Recently, besides regression analysis, artificial neural networks (ANNs) are increasingly used to predict the state of tools. Nevertheless, simulations trained by cutting modes, material type and the method of sharpening twist drills (TD) and the drilling length from sharp to blunt as input parameters and axial drilling force and torque as output ANN parameters did not achieve the expected results. Therefore, in this paper a family of artificial neural networks (FANN) was developed to predict the axial force and drilling torque as a function of a number of influencing factors. The formation of the FANN took place in three phases, in each phase the neural networks formed were trained by drilling lengths until the drill bit was worn out and by a variable parameter, while the combinations of the other influencing parameters were taken as constant values. The results of the prediction obtained by applying the FANN were compared with the results obtained by regression analysis at the points of experimental results. The comparison confirmed that the FANN can be used as a very reliable method for predicting tool condition.
doi_str_mv	10.14743/apem2020.2.356
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Nevertheless, simulations trained by cutting modes, material type and the method of sharpening twist drills (TD) and the drilling length from sharp to blunt as input parameters and axial drilling force and torque as output ANN parameters did not achieve the expected results. Therefore, in this paper a family of artificial neural networks (FANN) was developed to predict the axial force and drilling torque as a function of a number of influencing factors. The formation of the FANN took place in three phases, in each phase the neural networks formed were trained by drilling lengths until the drill bit was worn out and by a variable parameter, while the combinations of the other influencing parameters were taken as constant values. The results of the prediction obtained by applying the FANN were compared with the results obtained by regression analysis at the points of experimental results. 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Nevertheless, simulations trained by cutting modes, material type and the method of sharpening twist drills (TD) and the drilling length from sharp to blunt as input parameters and axial drilling force and torque as output ANN parameters did not achieve the expected results. Therefore, in this paper a family of artificial neural networks (FANN) was developed to predict the axial force and drilling torque as a function of a number of influencing factors. The formation of the FANN took place in three phases, in each phase the neural networks formed were trained by drilling lengths until the drill bit was worn out and by a variable parameter, while the combinations of the other influencing parameters were taken as constant values. The results of the prediction obtained by applying the FANN were compared with the results obtained by regression analysis at the points of experimental results. 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subjects	Acoustics Artificial neural networks Axial forces Axial stress Back propagation Computer simulation Cutting tools Drill bits Drilling Galvanized steel Machine learning Neural networks Parameters Powder metallurgy Regression analysis Sharpening Software Titanium alloys Torque Twist drills Vibration
title	Development of family of artificial neural networks for the prediction of cutting tool condition
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