Kinematic modeling of transverse shear in textile composite reinforcements forming

During the draping of dry textile reinforcements, the high tensile stiffness of fibers and the possible slippage between them significantly modify the transverse shear deformation mechanism. In order to show the limits of classical shell elements (Kirchhoff and Mindlin shell) for textile reinforcements, four-point bending tests of multilayer fibrous material were conducted and analyzed through experiment and simulation. In forming cases, the mid-surface deformation was obtained by a finite element stress resultant shell, which takes the in-plane shear and bending behavior into account. Based on the quasi-inextensibility of fibers, a kinematic modeling approach was then proposed to efficiently calculate the transverse shear strain. This approach has been implemented in Matlab software as a post-processing application, and can therefore be carried out by any user, together with any finite element software. Different bending tests and hemispherical forming experiments proved the effectiveness and correctness of the approach through comparisons between experimental and numerical results.

Automated summary

Four-point bending tests were conducted on multilayer fibrous materials to study the limitations of classical shell elements for textile reinforcements. A kinematic modeling approach was proposed based on the quasi-inextensibility of fibers to efficiently calculate the transverse shear strain. Experimental and numerical results from bending tests and forming experiments validated the effectiveness and correctness of the approach.