Predictive modeling of turning operations under different cooling/lubricating conditions for sustainable manufacturing with machine learning techniques
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Davorin Kramar | Branislav Sredanovic | Djordje Cica | Sasa Tesic | D. Cica | D. Kramar | S. Tešić | B. Sredanović | Saša Tešić
[1] Vishal S. Sharma,et al. Estimation of cutting forces and surface roughness for hard turning using neural networks , 2008, J. Intell. Manuf..
[2] Davorin Kramar,et al. Modeling of the Cutting Forces in Turning Process Using Various Methods of Cooling and Lubricating: An Artificial Intelligence Approach , 2013 .
[3] Jose Vicente Abellan-Nebot,et al. A review of machining monitoring systems based on artificial intelligence process models , 2010 .
[4] Mozammel Mia,et al. Response surface and neural network based predictive models of cutting temperature in hard turning , 2016, Journal of advanced research.
[5] Sudarsan Ghosh,et al. Application of sustainable techniques in metal cutting for enhanced machinability: a review , 2015 .
[6] N. R. Dhar,et al. Effect of time-controlled MQL pulsing on surface roughness in hard turning by statistical analysis and artificial neural network , 2017 .
[7] J. Paulo Davim,et al. Performance comparison of conventional and wiper ceramic inserts in hard turning through artificial neural network modeling , 2011 .
[8] Jasmine Siu Lee Lam,et al. Process characterisation of 3D-printed FDM components using improved evolutionary computational approach , 2015 .
[9] Carl E. Rasmussen,et al. In Advances in Neural Information Processing Systems , 2011 .
[10] Anupam Agrawal,et al. Prediction of surface roughness during hard turning of AISI 4340 steel (69 HRC) , 2015, Appl. Soft Comput..
[11] Geoffrey E. Hinton,et al. Bayesian Learning for Neural Networks , 1995 .
[12] Mozammel Mia,et al. Prediction and optimization by using SVR, RSM and GA in hard turning of tempered AISI 1060 steel under effective cooling condition , 2017, Neural Computing and Applications.
[13] Danil Yu. Pimenov,et al. An approach to cleaner production for machining hardened steel using different cooling-lubrication conditions , 2018, Journal of Cleaner Production.
[14] Davorin Kramar,et al. Modelling of tool life and surface roughness in hard turning using soft computing techniques: a comparative study , 2015 .
[15] Mozammel Mia,et al. Prediction and optimization of surface roughness in minimum quantity coolant lubrication applied turning of high hardness steel , 2018 .
[16] Ahmet Özdemir,et al. Analyzing the performance of artificial neural network (ANN)-, fuzzy logic (FL)-, and least square (LS)-based models for online tool condition monitoring , 2016, The International Journal of Advanced Manufacturing Technology.
[17] N. R. Dhar,et al. Modeling of chip–tool interface temperature using response surface methodology and artificial neural network in HPC-assisted turning and tool life investigation , 2017 .
[18] Salim Belhadi,et al. Investigation of the performance of the MQL, dry, and wet turning by response surface methodology (RSM) and artificial neural network (ANN) , 2017 .
[19] Ramón Quiza,et al. Comparing statistical models and artificial neural networks on predicting the tool wear in hard machining D2 AISI steel , 2008 .
[20] Jing Li,et al. Energy consumption model and energy efficiency of machine tools: a comprehensive literature review , 2016 .
[21] Ravinder Kumar,et al. Study on surface roughness measurement for turning of Al 7075/10/SiCp and Al 7075 hybrid composites by using response surface methodology (RSM) and artificial neural networking (ANN) , 2015 .
[22] Sylvie Castagne,et al. Sustainable manufacturing models for mass finishing process , 2016 .
[23] Sharath Chandra Guntuku,et al. Optimisation of turning parameters by integrating genetic algorithm with support vector regression and artificial neural networks , 2014, The International Journal of Advanced Manufacturing Technology.
[24] Ihsan Korkut,et al. Application of regression and artificial neural network analysis in modelling of tool-chip interface temperature in machining , 2011, Expert Syst. Appl..
[25] Pedro Paulo Balestrassi,et al. Robust multiple criteria decision making applied to optimization of AISI H13 hardened steel turning with PCBN wiper tool , 2017 .
[26] Mozammel Mia,et al. Sustainability assessment associated with surface roughness and power consumption characteristics in nanofluid MQL-assisted turning of AISI 1045 steel , 2019, The International Journal of Advanced Manufacturing Technology.
[27] Kalipada Maity,et al. A Comprehensive GRNN Model for the Prediction of Cutting Force, Surface Roughness and Tool Wear During Turning of CP-Ti Grade 2 , 2018, Silicon.
[28] David A. Freedman,et al. Statistical Models: Theory and Practice: References , 2005 .
[29] M. Elbah,et al. Machinability investigation in hard turning of AISI D3 cold work steel with ceramic tool using response surface methodology , 2014 .
[30] Mozammel Mia,et al. Prediction of surface roughness in hard turning under high pressure coolant using Artificial Neural Network , 2016 .
[31] Adem Çiçek,et al. Prediction of cutting temperature in orthogonal machining of AISI 316L using artificial neural network , 2016, Appl. Soft Comput..
[32] Tarek Mabrouki,et al. Modeling and multi-objective optimization for minimizing surface roughness, cutting force, and power, and maximizing productivity for tempered stainless steel AISI 420 in turning operations , 2018, The International Journal of Advanced Manufacturing Technology.
[33] J. K. Watson,et al. A decision-support model for selecting additive manufacturing versus subtractive manufacturing based on energy consumption. , 2018, Journal of cleaner production.
[34] Salim Belhadi,et al. Investigation, modeling, and optimization of cutting parameters in turning of gray cast iron using coated and uncoated silicon nitride ceramic tools. Based on ANN, RSM, and GA optimization , 2018, The International Journal of Advanced Manufacturing Technology.
[35] Anupam Yadav,et al. A dynamic metaheuristic optimization model inspired by biological nervous systems: Neural network algorithm , 2018, Appl. Soft Comput..
[36] Mozammel Mia,et al. Performance prediction of high-pressure coolant assisted turning of Ti-6Al-4V , 2017 .
[37] John W. Sutherland,et al. Dry Machining and Minimum Quantity Lubrication , 2004 .
[38] Carl E. Rasmussen,et al. Gaussian processes for machine learning , 2005, Adaptive computation and machine learning.
[39] Vladimir Vapnik,et al. Statistical learning theory , 1998 .
[40] M. Elbah,et al. Prediction of surface roughness and cutting forces using RSM, ANN, and NSGA-II in finish turning of AISI 4140 hardened steel with mixed ceramic tool , 2018 .