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2010 | OriginalPaper | Buchkapitel

3. Mechanics of Liquid Mixtures

verfasst von : Kumbakonam Ramamani Rajagopal

Erschienen in: Rheology of Complex Fluids

Verlag: Springer New York

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Abstract

A brief introduction is provided for modeling the response of mixtures under the assumption that the constituents can be modeled as a continuum and that the constituents co-occupy the region of the mixture in a homogenized sense. The constituents of the mixture can undergo chemical reactions and there can be interconversion between the constituents. Balance laws are provided for the constituents of the mixture that allow for the chemical reactions as well as the numerous other interaction mechanisms between the constituents. After developing the general framework, the theory will be used to develop a model for the flow of a mixture of fluids.

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Vorheriges Kapitel Fundamentals of Rheology

Nächstes Kapitel Oscillatory Shear Rheology for Probing Nonlinear Viscoelasticity of Complex Fluids: Large Amplitude Oscillatory Shear

The word “atop” is inappropriate but provides some basis for understanding the co-occupancy of the constituents. Each of the particles simultaneously co-exist at the same point in the mixture. Of course, there are serious physical problems with such an assumption, but this is far less worrisome from a philosophical stand point of existence than the notion of a “point”, an entity with no dimension! We seem to have no problem whatsoever with coming to grips with this unfathomable concept. Since each particle belonging to a constituent has no dimension allowing them to co-occupy should not lead to any unsurmountable difficulty.

Unless a summation symbol is explicitly used, repeated indices do not mean summation over that index.

Adkins JE (1963) Nonlinear diffusion I. Diffusion and flow of mixtures of fluids. Philos Trans R Soc Lond A 225:607–633MathSciNetCrossRef

Al-Sharif A, Chamniprasart K, Rajagopal KR, Szeri AZ (1993) Lubrication with binary mixtures: Liquid–liquid emulsion. J Tribol 115(1):46–55CrossRef

Anderson TB, Jackson R (1968) A fluid mechanical description of fluidized beds: Stability of the state of uniform fluidization. Ind Eng Chem Fund 7:12-21CrossRef

Atkin RJ, Craine RE (1976) Continuum theories of mixtures: Applications. J Inst Math Appl 17:153–207MathSciNetMATHCrossRef

Barnea E, Mizrahi J (1976) On the effective viscosity of liquid–liquid dispersions. Ind Eng Chem Fund 15:120–125CrossRef

Basset AB (1888) Treatise on hydrodynamics. Deighton Bell, CambridgeMATH

Batchelor G, Green JT (1972) The determination of the bulk stress in a suspension of spherical particles to order C ⁽²⁾. J Fluid Mech 56:401–427MATHCrossRef

Barrer RM (1941) Diffusion in and through solids. Cambridge University Press, London

Bedford A, Drumheller DS (1983) Recent advances: Theories of immiscible and structured mixtures. Int J Eng Sci 21:863–960MathSciNetMATHCrossRef

10.

Brinkman HC (1947) On the permeability of media consisting of closely packed porous particles. Appl Sci Res A 1:81–86CrossRef

11.

Brinkman HC (1947) The calculation of the viscous force exerted by a flowing fluid on a dense swarm of particles. Appl Sci Res A 1:27–34CrossRef

12.

Biot MA (1934) Theory of elastic waves in a fluid-saturated porous solid, I. Low frequency range. J Acoust Soc Am 28:168–178 DOI:10.1121/1.1908239MathSciNet

13.

Biot MA (1934) Theory of elastic waves in a fluid-saturated porous solid, II. High frequency range. J Acoust Soc Am 28:179–191 DOI:10.1121/1.1908241MathSciNet

14.

Biot MA (1962) Mechanics of deformation and acoustic propagation in porous media. J Appl Phys 33:1482–1498MathSciNetMATHCrossRef

15.

Brinkman HC (1952) The viscosity of concentrated suspensions and solutions. J Chem Phys 20:571CrossRef

16.

Brenner H (1958) Dissipation of energy due to solid particles suspended in a viscous liquid. Phys Fluids 1:338–346MathSciNetMATHCrossRef

17.

Brodnyan JG (1959) The concentration dependence of the Newtonian viscosity of prolate ellipsoids. Trans Soc Rheol 3:61–68CrossRef

18.

Boussinesq J (1913) Vitesse de la chute lente, devenue uniforme, d’une goutte liquide spherique, dans un fluide visqueux de poids specifique moindre. Comp Rend Acad Sci 156:1124–1129MATH

19.

Bowen RM (1967) Towards a thermodynamics and mechanics of mixtures. Arch Rational Mech Anal 24(5):370–403MathSciNetMATHCrossRef

20.

Bowen RM, Garcia DJ (1970) On the thermodynamics of mixtures with several temperatures. Int J Eng Sci 8:63–83CrossRef

21.

Bowen RM (1991) Theory of mixtures. In: Continuum physics, Ed Eringer AC, Academic Press, New York, Vol III

22.

Burgers JM, Jeffery GB (1939) Mechanical considerations – Model systems – Phenomenological theories of relaxation and of viscosity, First Report on Viscosity and Plasticity, 2nd edn. Nordemann Publishing Company, Inc., New York Prepared by the committee for the study of viscosity of the academy of sciences at Amsterdam. Proc R Soc Lond A 102:161–179

23.

Craig RE (1970) The motion of a solid in a fluid. Am J Math 20:162–177

24.

Craine RE, Green AE, Naghdi PM (1970) A mixture of viscous elastic materials with different constituent temperatures. Quart J Mech Appl Math 23:171–184MATHCrossRef

25.

Darcy H (1856) Les Fontaies Publiques de La Ville de Dijon. Victor Delmont

26.

Einstein A (1906) Eine neune Bestimmung der Molekul-Dimension. Ann Phys 19:289–306MATHCrossRef

27.

Einstein A (1911) Eine neune Bestimmung der Molekul-Dimension. Ann Phys 34:591–592MATHCrossRef

28.

Fick A (1855) Uber diffusion. Ann Phys 94:59–86CrossRef

29.

Green AE, Naghdi PM (1969) On basic equations for mixtures. Quart J Mech Appl Math 22:427–438MATHCrossRef

30.

Greenhill AG (1898) The motion of a solid in infinite liquid under no forces. Am J Math 20:1–75MathSciNetCrossRef

31.

Hadmard JS (1911) Mecanique-mouvement permanent lent une sphere liquids et visqueuse dans un liquide visqueux. Comp Rend Acad Sci 154:1735–1738

32.

Hadmard JS (1912) Hydrodynamique – Sur une question relative aus liquids visqueux. Comp Rend Acad Sci 154:109

33.

Happel M, Brenner H (1973) Low Reynolds number hydrodynamics, Noordhaff, Leyden

34.

Hatschek E (1928) The viscosity of liquids. Bel G and Son, London

35.

Johnson G, Massoudi M, Rajagopal KR (1991) Flow of a fluid infused with solid particles through a pipe. Int J Eng Sci 29(6):649–661MathSciNetMATHCrossRef

36.

Jeffery GB (1922) The Motion of ellipsoidal particles immersed in a viscous fluid. Proc R Soc Lond A, Containing papers of a mathematical and physical character 102(715):161–179 http://www.jstor.org/stable/94111

37.

Kirchoff G (1869) Uber die benegung eines rotationskorpers in earner fliissigkeit. Crelle 71:237–262

38.

Lamb H (1877) On the free motion of a solid through an infinite mass liquid. Math Soc 8: 273–286MATH

39.

Malek J, Rajagopal KR (2008) A thermodynamic framework for a mixture of two liquids. Nonlinear Anal R World Appl 9(4):1649–1660MathSciNetMATHCrossRef

40.

Massoudi M (1986) Application of mixture theory to fluidized beds, PhD thesis. University of Pittsburgh

41.

Mills N (1966) Incompressible mixtures of Newtonian fluids. Int J Eng Sci 4:97–112MATHCrossRef

42.

Mooney MJ (1954) On an indeterminate integral in Einstein’s theory of the viscosity of a suspension. J Appl Phys 25:406–407CrossRef

43.

Munaf DR, Lee D, Wineman AS et al (1993) A boundary value problem in groundwater motion analysis – Comparison of predictions based on Darcy’s law and the continuum theory of mixtures. Math Models Methods Appl Sci 3:231MathSciNetMATHCrossRef

44.

Oldroyd JC (1953) The elastic and viscous properties of emulsions and suspensions. Proc R Soc Lond A 218:122–132MATHCrossRef

45.

Rajagopal KR, Tao L (1992) Wave propagation in elastic solids infused with fluids. Int J Eng Sci 30:1209–1232MathSciNetMATHCrossRef

46.

Rajagopal KR, Tao L (1995) Mechanics of mixtures, World Scientific, SingaporeMATH

47.

Rajagopal KR (2003) Diffusion through solids undergoing large deformations. Mater Sci Technol 19:1175–1189CrossRef

48.

Rajagopal KR, Srinivasa AR (2004) On thermomechanical restrictions of continua. Proc R Soc Lond Ser A: Math Phys Eng Sci 460(2042):631-651MathSciNetCrossRef

49.

Rajagopal KR, Srinivasa AR (2004) On the thermomechanics of materials that have multiple natural configurations – Part I: Viscoelasticity and classical plasticity. Zeitschrift für Angewandte Mathematik und Physik 55(5):861–893MathSciNetMATHCrossRef

50.

Rajagopal KR, Srinivasa AR (2004) On the thermomechanics of materials that have multiple natural configurations – Part II: Twinning and solid to solid phase transformation. Zeitschrift für Angewandte Mathematik und Physik 55(6):1074–1093MathSciNetMATHCrossRef

51.

Rajagopal KR, Srinivasa AR, A Gibbs potential formulation for obtaining constitutive equations for a class of viscoelastic materials, submitted for publication

52.

Rayleigh JWS (1892) Correlation aspects of the viscosity–temperature relationship of the lubricating oils, PhD thesis, Technische Hogeschool Delft, The Netherlands

53.

Rybczynski W (1911) On the translatory motion of a fluid sphere in a viscous medium. Bull Acad Sci Cracow Ser A:447–459

54.

Saltzer WD, Schulz B (1966) An attempt to treat the viscosity as a transport property of two phase materials. In: Continuum models of discrete systems 4, Eds. Erwin O and Hsieh RKT, North-Holland, Amsterdam

55.

Samohyl I (1987) Thermodynamics of irreversible processes in fluids mixtures, Teubner, Leipzig

56.

Seitz F (1987) The modern theory of solids. Dover Publications, New York

57.

Simha R (1952) A treatment of the viscosity of concentrated suspensions. J Appl Phys 23:1020–1024CrossRef

58.

Stokes GG (1845) On the effect of the internal friction of fluids on the motions of pendulums. Trans Camb Phil Soc 8:287–305

59.

Tamura M, Kurata M (1952) On the viscosity of binary mixture of liquids. Bull Chem Soc Jpn 25(1):32–38CrossRef

60.

Taylor GI (1932) The viscosity of fluids containing small drops of another fluid. Proc R Soc Lond A 138:41–48CrossRef

61.

The Oxford English Dictionary (1981) Oxford University Press, Oxford

62.

Thomson W, Tait PG (1867) Treatise on natural philosophy, Cambridge University PressMATH

63.

Truesdell C (1957) Sulle basi della thermomeccanica. Rend Lincei 22:33–38MathSciNetMATH

64.

Truesdell C (1957) Sulle basi della thermomeccanica. Rend Lincei 22:158–166MathSciNet

65.

Truesdell C (1991) A first course in rational continuum mechanics, Academic Press, New YorkMATH

66.

Truesdell C (1984) Rational thermodynamics, Springer-Verlag, BerlinMATHCrossRef

67.

Quemada O (1977) Rheology of concentrated disperse systems and minimum energy dissipation principle, I. Viscosity–concentration relationship. Rheol Acta 16:82–94CrossRef

68.

Williams WO, Sampaio R (1977) Viscosities of liquid mixtures. Z Angew Math Phys 28:607-614MATHCrossRef

69.

Ziegler H (1963) Some extremum principles in irreversible thermodynamics. In: Sneddon IN, Hill R, Eds, Progress in solid mechanics vol. 4, North Holland Publishing Company, New York

70.

Ziegler H (1983) An introducton to thermomechanics, North Holland Publishing Company, Amsterdam, 2nd Edn

71.

Ziegler H, Wehrli C (1987) The derivation of constitutive equations from the free energy and the dissipation function. In: Wu TY, Hutchinson JW, Eds, Adv Appl Mech, Academic Press, New York 25:183–238MathSciNetMATH

Titel: Mechanics of Liquid Mixtures
verfasst von: Kumbakonam Ramamani Rajagopal
Verlag: Springer New York
Buch: Rheology of Complex Fluids
Print ISBN: 978-1-4419-6493-9

Electronic ISBN: 978-1-4419-6494-6

Copyright-Jahr: 2010
DOI: https://doi.org/10.1007/978-1-4419-6494-6_3

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