Wang, HuiQin, QinghuaXiao, Yi2022-08-040017-9310http://hdl.handle.net/1885/270201The thermal effects of clustering in natural-hemp-fiber-filled cement composites are investigated and the effective thermal conductivity of the composites is numerically evaluated using the fundamentalsolution-based finite element method in conjunction with special n-sided Voronoi fiber/matrix elements. In the numerical modeling, the special n-sided fiber/matrix elements are developed by a two-variable integral functional involving an independent non-conforming element interior temperature field and an auxiliary conforming element frame temperature field. The element interior temperature field is approximated by a combination of special fundamental solutions satisfying the fiber/matrix interfacial condition and the heat transfer governing equation in each material constituent, and the independent frame temperature field is interpolated by conventional shape functions. All integrals are performed only along the element boundary such that the mesh division associated with fiber/matrix domains can be significantly simplified by the n-sided Voronoi fiber/matrix polygonal elements which allow different numbers of sides for each element and permit calculation of fields everywhere in matrix and fibers. Numerical results demonstrate that these special elements are suitable for dealing with clustering distribution of fibers.The support for this research work by the Natural Science Foundation of China under Grants 11472099 and 11372100 is gratefully acknowledged.application/pdfen-AU© 2015 Elsevier LtdNatural fiberCement compositesClusteringThermal conductivitySpecial n-sidedVoronoi fiber/matrix elementsFundamental solutions201610.1016/j.ijheatmasstransfer.2015.08.0932021-08-01