A nonlinear explicit dynamic finite element formulation based on the generalized beam theory (GBT) is proposed and developed to simulate the dynamic responses of prismatic thin-walled steel members under transverse impulsive loads. Considering the rate strengthening and thermal softening effects on member impact behavior, a modified Cowper-Symonds model for constructional steels is utilized. The element displacement field is built upon the superposition of GBT cross-section deformation modes, so arbitrary deformations such as cross-section distortions, local buckling and warping shear can all be involved by the proposed model. The amplitude function of each cross-section deformation mode is approximated by the cubic non-uniform B-spline basis functions. The Kirchhoff's thin-plate assumption is utilized in the construction of the bending related displacements. The Green-Lagrange strain tensor and the second Piola-Kirchhoff(PK2) stress tensor are employed to measure deformations and stresses at any material point, where stresses are assumed to be in plane-stress state. In order to verify the effectiveness of the proposed GBT model, three numerical cases involving impulsive loading of the thin-walled parts are given. The GBT results are compared with those of the Ls-Dyna shell finite element. It is shown that the proposed model and the shell finite element analysis has equivalent accuracy in displacement and stress. Moreover, the proposed model is much more computationally efficient and structurally clearer than the shell finite elements.

• 出版日期2018
• 单位上海交通大学