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dc.contributor.authorDeshpande, Amit Anand
dc.contributor.authorMadhavan, Viswanathan
dc.date.accessioned2012-04-27T20:11:10Z
dc.date.available2012-04-27T20:11:10Z
dc.date.issued2012-06
dc.identifier.citationDeshpande, Amit Anand & Viswanathan, Madhavan. 2012. “A novel approach to accelerate attainment of thermal steady state in coupled thermomechanical analysis of machining”. International Journal of Heat and Mass Transfer, Volume 55, Issues 13–14, June 2012, Pages 3869–3884en_US
dc.identifier.issn0017-9310
dc.identifier.urihttp://hdl.handle.net/10057/5089
dc.identifier.urihttp://dx.doi.org/10.1016/j.ijheatmasstransfer.2012.02.066
dc.descriptionClick on the DOI link below to access the article (may not be free).en_US
dc.description.abstractA novel approach for obtaining the steady state temperature distribution of cutting tools involves reducing the specific heat capacity of the cutting tool by a scale factor and carrying out a short duration single step thermomechanical analysis. Reduction of the specific heat causes the thermal time constant of the tool to be reduced by the same scale factor, making it closer to the mechanical time constant required for stabilization of the chip geometry, and enables rapid attainment of mechanical and thermal steady state conditions. As expected, FEA results show that the steady state temperature distribution achieved by the reduced specific heat approach is exact. Results obtained from a single step simulation of the first 1200 μs of cutting, using this approach, are found to be more accurate than those obtained using the time consuming multistep analysis approach used to date. Rapid attainment of an accurate steady state temperature distribution permits tool wear rate to be calculated accurately using tool wear models. This enables tracking of changes in tool geometry due to wear over time, and resulting changes in the machining process and part quality produced. It is also shown that this approach is essential for accurate simulation of processes such as saw-tooth chip formation, where the ‘steady state’ involves local periodic thermomechanical changes, and leads to accurate thermomechanical results so long as the specific heat of the local region experiencing significant thermal oscillations is not scaled. An estimate for the size of this boundary layer, related to the wavelength of the thermal waves, is also given. The reduced specific heat approach can be used in many other applications involving a range of phenomena coupled with temperature, where the thermal changes are the most sluggish and take the most time to reach steady state.en_US
dc.language.isoen_USen_US
dc.publisherElsevieren_US
dc.relation.ispartofseriesInternational Journal of Heat and Mass Transfer;2012, v.55, issues 13-14
dc.subjectFinite elementsen_US
dc.subjectCoupled thermomechanical analysisen_US
dc.subjectMachiningen_US
dc.subjectSteady stateen_US
dc.subjectSpecific heaten_US
dc.subjectThermal Inertiaen_US
dc.subjectTool wearen_US
dc.subjectThermal wavesen_US
dc.titleA novel approach to accelerate attainment of thermal steady state in coupled thermomechanical analysis of machiningen_US
dc.typeArticleen_US
dc.description.versionPeer reviewed
dc.rights.holderCopyright © 2012, Elsevier


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