The paper describes a method to accurately retrieve the fibre/matrix interface stress state from the motion field of the neutral mid-plane in simply bended and torqued long fibre multi-layered laminates. The expression "simply bended and torqued" refers to laminates with traction-free top and bottom surfaces, subject to a slowly variable (wrt the microstructure dimension) global strain field due to loads at the edges. The described procedure is completely meshless relying on RBF to handle the composite at different scales. RBF are first employed to interpolate the displacement field at the macroscale in order to supply average parameters able to define a proper set of boundary conditions at the level of the RVE, where the stress state is determined via Kansa method. Despite the laminate develops in three dimensions, RBF systems at the different scales are 2D and involve a reasonable number of points. Results in terms of interface stresses obtained with the described method are found in good agreement with those achieved by accurate FEM models.
Chiappa, A., Groth, C., Biancolini, M.e. (2023). A two-scale RBF meshless method for the interface stress retrieval in simply bended and torqued long-fibres laminates. COMPOSITE STRUCTURES, 306 [10.1016/j.compstruct.2022.116600].
A two-scale RBF meshless method for the interface stress retrieval in simply bended and torqued long-fibres laminates
Chiappa A.;Groth C.;Biancolini M. E.
2023-01-01
Abstract
The paper describes a method to accurately retrieve the fibre/matrix interface stress state from the motion field of the neutral mid-plane in simply bended and torqued long fibre multi-layered laminates. The expression "simply bended and torqued" refers to laminates with traction-free top and bottom surfaces, subject to a slowly variable (wrt the microstructure dimension) global strain field due to loads at the edges. The described procedure is completely meshless relying on RBF to handle the composite at different scales. RBF are first employed to interpolate the displacement field at the macroscale in order to supply average parameters able to define a proper set of boundary conditions at the level of the RVE, where the stress state is determined via Kansa method. Despite the laminate develops in three dimensions, RBF systems at the different scales are 2D and involve a reasonable number of points. Results in terms of interface stresses obtained with the described method are found in good agreement with those achieved by accurate FEM models.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.