A computational technique for evaluating the effective thermal conductivity of isotropic porous materials

A computational technique based on Maxwell's methodology is presented for evaluating the effective thermal conductivity of isotropic materials with periodic or random arrangement of spherical pores. The basic idea of the approach is to construct an equivalent sphere in an infinite space whose effects on the temperature at distant points are the same as those of a finite cluster of spherical pores arranged in a pattern representative of the material in question. The thermal properties of the equivalent sphere then define the effective thermal properties of the material. This procedure is based on a semi-analytical solution of a problem of an infinite space containing a cluster of non-overlapping spherical pores under prescribed temperature gradient at infinity. The method works equally well for periodic and random arrays of spherical pores.

[1]  John William Strutt,et al.  Scientific Papers: On the Influence of Obstacles arranged in Rectangular Order upon the Properties of a Medium , 2009 .

[2]  L. Rayleigh,et al.  LVI. On the influence of obstacles arranged in rectangular order upon the properties of a medium , 1892 .

[3]  David R. McKenzie,et al.  The conductivity of lattices of spheres - II. The body centred and face centred cubic lattices , 1978, Proceedings of the Royal Society of London. A. Mathematical and Physical Sciences.

[4]  H. Brenner,et al.  Effective conductivities of composite materials composed of cubic arrangements of spherical particles embedded in an isotropic matrix , 1977 .

[5]  J. Brady,et al.  The effective conductivity of random suspensions of spherical particles , 1991, Proceedings of the Royal Society of London. Series A: Mathematical and Physical Sciences.

[6]  D. Jeffrey,et al.  Conduction through a random suspension of spheres , 1973, Proceedings of the Royal Society of London. A. Mathematical and Physical Sciences.

[7]  D. R. McKenzie,et al.  The conductivity of lattices of spheres I. The simple cubic lattice , 1978, Proceedings of the Royal Society of London. A. Mathematical and Physical Sciences.

[8]  G. Milton The Theory of Composites , 2002 .

[9]  Salvatore Torquato,et al.  Effective conductivity of suspensions of hard spheres by Brownian motion simulation , 1991 .

[10]  S. L. Crouch,et al.  Transient heat conduction in a medium with multiple spherical cavities , 2009 .

[11]  J. Maxwell A Treatise on Electricity and Magnetism , 1873, Nature.

[12]  A. Kelly,et al.  Maxwell's far-field methodology applied to the prediction of properties of multi-phase isotropic particulate composites , 2008, Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences.

[13]  V. Buryachenko,et al.  Multiparticle Effective Field and Related Methods in Micromechanics of Composite Materials , 2001 .

[14]  Andreas Acrivos,et al.  The effective conductivity of a periodic array of spheres , 1983, Proceedings of the Royal Society of London. A. Mathematical and Physical Sciences.

[15]  A. Dyskin,et al.  Virial expansions in problems of effective characteristics. 1. General concepts , 1994 .

[16]  S. L. Crouch,et al.  Equivalent inhomogeneity method for evaluating the effective elastic properties of unidirectional multi-phase composites with surface/interface effects , 2010 .

[17]  S. Shtrikman,et al.  A variational approach to the theory of the elastic behaviour of multiphase materials , 1963 .

[18]  Zvi Hashin,et al.  Assessment of the Self Consistent Scheme Approximation: Conductivity of Particulate Composites , 1968 .

[19]  J. Brāuns,et al.  Nonlinear moisture deformation of a composite with a densified reinforcement , 1994 .