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International Journal of Material Forming

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01-03-2008 | Original Research

Multiscale simulations: application to the heat transfer simulation of sliding solids

Author: P. Chantrenne

Published in: International Journal of Material Forming | Issue 1/2008

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Abstract

Molecular dynamics is a powerful tool allowing the simulation of matter behaviour at the atomic scale. Due to computation time, it is clearly not possible to use molecular dynamics to simulate a forming process. However, atomistic simulations can be used to study and understand the physical phenomena that occur during matter deformation. As an example, heat transfer between the contacting solids in forming processes is one of the important physics phenomena that have to be taken into account in order to do realistic simulations. A multiscale analysis of heat transfer is presented. This analysis leads to two kinds of models: a macroscopic model which can be used for the simulation of the process itself and a microscopic model that is used to determine the parameters of the macroscopic model. In this microscopic model, the friction heat generation phenomena has to be described quite accurately. Friction heat is mainly due to plastic and elastic deformation and adhesion. Thus, to understand the underlying friction heat generation phenomena, atomistic simulations using molecular dynamics are carried out. It is shown that friction heat is the transformation of mechanical work given to the system at the macroscopic scale into potential energy during elastic deformation. This potential energy which is stored in the system is finally transformed into atomic kinetic energy (friction heat) during plastic transformation.

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Broughton J, Abraham F, Berstein N, Kaxiras E 1999 Concurrent coupling of length scales: methodology and application. Phys Rev B 60:2391CrossRef

Koumoutsakos P 2005 Multiscale flow simulations using particles. Annu Rev Fluid Mech 37:457–87CrossRefMathSciNet

To AC, Shaofan L 2006 Perfectly matched multiscale simulations. Phys Rev B Condens Matter Mater Phys 72:035414.1–035414.8

Baffico L, Bernard S, Maday Y, Turinici G, Zerah G 2002 Parallel-in-time molecular-dynamics simulations. PRE 66:57701CrossRef

Waisman H, Fish J 2006 A space-time multilevel method for molecular dynamics simulations. Comput Methods Appl Mech Eng 195:6542–6559MATHCrossRefMathSciNet

Voter AF, Montalenti F, Germann TC 2002 Extending the time scale in atomistic simulation of materials. Annu Rev Mater Res 32:321CrossRef

Borodin O, Bedrov D, Smith GD, Nairn J, Bardenhagen S, Faller R 2005 Multiscale modeling of viscoelastic properties of polymer nanocomposites. Multiscale modeling of polymers. J Polym Sci B Polym Phys 43:1005–1013CrossRef

Schelling PK, Phillpot SR 2003 Multiscale simulation of phonon transport in superlattices. J Appl Phys 93:5377–5387CrossRef

Tabor D 1992 Friction as a dissipative process. Singer IL, Pollock HM Fundamentals of friction: macroscopic and microscopic processes Kluwer Dordrecht 3–24

10.

Kennedy FE 1984 Thermal and thermomechanical effects in dry sliding. Wear 100:453–476CrossRef

11.

Uetz H, Föhl J 1978 Wear as an energy transformation process. Wear 49:253–264CrossRef

12.

Laraqi N 1992 Température de contact et coefficient de partage du flux généré par frottement sec entre deux solides Approche nouvelle de la génération de flux. Int J Heat Mass Transfer 35:3131–3141CrossRef

13.

Bardon JP 1994 Bases physiques des conditions de contact thermique imparfait entre milieu en glissement relatif. Revue Grn Therm 386:86–91

14.

Chantrenne P, Raynaud M 2001 Study of a macroscopic sliding contact thermal model from microscopic models. Int J Therm Sci 40:603–621CrossRef

15.

Greenwood JA, Williamson JBP 1966 Contact of nominally flat surfaces. Proc Roy Soc A Mathematical and Physical Sciences 295(1440):300–319CrossRef

16.

Salgon JJ, Robbe Valoire F, Blouet J, Bransier J 1997 A mechanical and geometrical approach to thermal contact resistance. Int J Heat Mass Transfer 40(5):1121–1130MATHCrossRef

17.

Sridhar MR, Yovanovich MM 1994 Review of elastic and plastic contact conductance models: comparison with experiments. J Thermophys Heat Transf 8(4):633–640

18.

Chantrenne P, Raynaud M 1997 A microscopic thermal model for dry sliding contact. Int J Heat Mass Transfer 40(5):1083–1094MATHCrossRef

19.

Alen MP, Tildesley DJ 1987 Computer simulation of liquid Clarendon Oxford

20.

Frenkel D, Smit B 1996 Understanding molecular dynamics; from algorithms to applications. Academic Press, San Diego

21.

Clementi E 1988 Phil Trans R Soc London, Ser A326 445MATHCrossRef

22.

Ercolessi F, Adams JB 1994 Interatomic potentials from first principles calculations: the force matching method. Europhys Lett 26:583–588CrossRef

23.

Hayashi K, Saduko N, Kawai T 1996 A new measure of local temperature distribution in non-equilibrium molecular dynamics simulation of friction. Surf Coat Technol 83:313–316CrossRef

24.

Mulliah D, Kenny SD, Smith R 2004 Modelling of stick-slip phenomena using molecular dynamics. PRB 69:205407CrossRef

25.

Zhang Q, Qi Y, Hector LG, Cagin T, Goddard WA III 2005 Atomic simulations of kinetic friction and its velocity dependence at Al/Al and Al₂O₃/ Al₂O₃ interfaces. PRB 72:045406CrossRef

26.

Braun OM 2005 Simple model of microscopic rolling friction. PRL 95:126104CrossRef

27.

Delhommelle J, Cummings PT 2005 Simulation of friction in nanoconfined fluids for an arbitrarily low shear rate. PRB 72:172201CrossRef

28.

Chantrenne P, Raynaud M, Clapp PC, Rifkin J, Becquart CS 2000 Molecular dynamics simulations of friction. Heat Technol 18:49–56MATH

29.

Bournez E, Clapp PC, Chantrenne P, Raynaud M, Rifkin J 2000 Molecular Dynamics simulation of dry friction between solids.Miannay D, costa P, François D, Pinea A Advances in mechanical behaviour, plasticity and damage. Elsevier, Amsterdam, 567–572

Title: Multiscale simulations: application to the heat transfer simulation of sliding solids
Author: P. Chantrenne
Publication date: 01-03-2008
Publisher: Springer-Verlag
Published in: International Journal of Material Forming / Issue 1/2008
Print ISSN: 1960-6206
Electronic ISSN: 1960-6214
DOI: https://doi.org/10.1007/s12289-008-0003-6

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