Extended discrete element method: Difference between revisions

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Line 1: {{Short description\|Granular material interaction simulation technique}} [[File:Internal temperature distribution in a particle.png\|thumb\|An internal temperature distribution for a spherical particle versus radius and time under a time-varying [[heat flux]].]] Line 20 ⟶ 21: \| authorlink2=D. J. Tildesley \| title=Computer Simulation of Liquids \| publisher=~~Claredon~~Clarendon Press Oxford \| year=1990}}</ref>) by additional properties such as the [[thermodynamic]] state, [[Stress (~~mechanical~~mechanics)\|stress]]/[[Deformation (mechanics)\|strain]] or [[electro-magnetic]] field for each particle. Contrary to a [[continuum mechanics]] concept, the XDEM aims at resolving the particulate phase with its various processes attached to the particles. While the discrete element method predicts position and orientation in space and time for each particle, the extended discrete element method additionally estimates properties such as internal [[temperature]] and/or [[species]] distribution or mechanical impact with structures. ==History== Line 78 ⟶ 79: \| pages=99–118 \| citeseerx=10.1.1.470.6532 \| s2cid=17460834 }}</ref> Xu 1997<ref>{{cite journal \| first1=B. H. Line 261 ⟶ 263: \| pages=207–214 \| doi=10.2355/isijinternational.50.207 \| doi-access=free }}</ref> Numerical simulation of fluid injection into a gaseous environment nowadays is adopted by a large number of CFD-~~codes~~ codes such as ~~Star-CD of~~ [[CDSimcenter STAR-~~adapco~~CCM+]], [[Ansys]] and [[AVL ~~(Engineering Firm)\|AVL]]~~-Fire. Droplets of a spray are treated by a zero-dimensional approach to account for heat and mass transfer to the fluid phase. ==Methodology== Line 347 ⟶ 350: \| pages=99–118 \| citeseerx=10.1.1.470.6532 \| s2cid=17460834 }}</ref> however, Chu and Yu<ref>{{cite journal \| first1=K. W. Line 451 ⟶ 455: \| pages=2395–2410 \| doi=10.1016/s0009-2509(02)00140-9 }}</ref> describe discrete particle-continuum fluid modelling of gas-solid fluidised beds. Further applications of XDEM include thermal conversion of biomass on a backward and forward acting grate. Heat transfer in athermal/reacting ~~[[packed~~particulate ~~bed]] reactor~~systems was also solved and investigated, ~~for~~as ~~hot~~comprehensively ~~air~~reviewed ~~streaming~~by ~~upward~~Peng ~~through~~et ~~the~~al.<ref ~~packed~~name="Peng">{{cite ~~bed~~journal to\|last1=Peng ~~heat~~\|first1=Z. ~~the~~\|last2=Doroodchi ~~particles,~~\|first2=E. ~~which~~\|last3=Moghtaderi ~~dependent~~\|first3=B. on\|date=2020 \|title=Heat transfer modelling in Discrete Element Method (DEM)-based simulations of thermal processes: ~~position~~Theory and ~~size~~model ~~experience~~development ~~different~~\|journal=Progress ~~heat~~in ~~transfer~~Energy ~~rates~~and Combustion Science \|volume=79,100847 \|page=100847 \|doi=10.1016/j.pecs.2020.100847\|s2cid=218967044 }}</ref> The [[deformation (engineering)\|deformation]] of a conveyor belt due to impacting [[granular material]] that is discharged over a chute represents an application in the field of [[Stress (~~mechanical~~mechanics)\|stress]]/[[Deformation (mechanics)\|strain]] analysis. {\|