Soldatos, Konstantinos P.Aydogdu, MetinGul, Ufuk2024-06-122024-06-1220191559-3959https://doi.org/10.2140/jomms.2019.14.497https://hdl.handle.net/20.500.14551/20308This study investigates the flexural response of a linearly elastic rectangular strip reinforced in a functionally graded manner by a single family of straight fibres resistant in bending. Fibre bending resistance is associated with the thickness of fibres which, in turn, is considered measurable through use of some intrinsic material length parameter involved in the definition of a corresponding elastic modulus. Solution of the relevant set of governing differential equations is achieved computationally, with the use of a well-established semianalytical mathematical method. A connection of this solution with its homogeneous fibre-reinforced material counterpart enables the corresponding homogeneous fibrous composite to be regarded as a source of a set of equivalent functionally graded structures, each one of which is formed through inhomogeneous redistribution of the same volume of fibres within the same matrix material. A subsequent stress and couple-stress analysis provides details of the manner in which the flexural response of the polar structural component of interest is affected by certain types of inhomogeneous fibre distribution.en10.2140/jomms.2019.14.497info:eu-repo/semantics/openAccessCylindrical BendingElastic BeamsElastic PlatesFibre Bending StiffnessFibre-Reinforced StructuresFunctionally Graded StructuresPlane Strain ElasticityPolar ElasticityLinear ElasticityFoundationSolidsArticle144497535Q4WOS:0005050297000042-s2.0-85078839778Q3