简介:Theauthorsinvestigateadisturbance-compensatingandenergy-savingcontrolmethodforairturbinespindlesequippedwitharotationcontrolsystemdesignedforuseinultra-precisionmilling.Thecontrollabilityandenergy-conservingcharacteristicsoftheproposedmethodusingtheproposedpneumaticregulatingdevice,calledahigh-precisionquick-responsepneumaticpressureregulator,weredemonstratedexperimentallypreviously.Herein,theproposedrotation-controlledairturbinespindleisfirstsummarised.Subsequently,theproposedrotation-controlledairturbinespindleissettoamillingmachineandappliedtothemillingofanalloytoolsteel,togaindataandvalidatetheeffectivenessofthein-processtoolwearestimationmethodthathavebeenrecentlydevelopedandproposedbytheauthors.Particularly,toevaluatethepossibilityofapplyingtheproposedestimationmethodtothree-dimensionalmilling,millingexperimentswheretheairturbinespindleissetata45°inclinewereconductedandtheresultsindicateahighpossibilityoftheproposedmethod.
简介:Fastsolvinglarge-scalelinearequationsinthefiniteelementanalysisisaclassicalsubjectincomputationalmechanics.Itisakeytechniqueincomputeraidedengineering(CAE)andcomputeraidedmanufacturing(CAM).Thispaperpresentsahigh-efciencyimprovedsymmetricsuccessiveover-relaxation(ISSOR)preconditionedconjugategradient(PCG)method,whichmaintainstheconvergenceandinherentparallelismconsistentwiththeoriginalform.Ideally,thecomputationcanbereducednearlyby50%ascomparedwiththeoriginalalgorithm.Itissuitableforhigh-performancecomputingwithitsinherentbasichigh-efciencyoperations.Bycomparingwiththenumericalresults,itisshownthattheproposedmethodhasthebestperformance.