Towards a new PGD strategy for the simulation of slender structures

TL;DR

This paper introduces a new PGD-based strategy for simulating slender structures, linking reduced order models to classical plate theories and addressing shear locking issues.

Contribution

A novel PGD approach computes the first two modes simultaneously to better capture asymptotic solutions in slender structure simulations.

Findings

First PGD mode exhibits Kirchhoff-Love kinematics in large slenderness limit.

The new strategy effectively captures asymptotic solutions for intermediate slenderness.

The approach demonstrates improved accuracy and addresses shear locking in numerical experiments.

Abstract

Effective models for slender structures derived from well-known plate (or shell) theories are justified within the limit of a small thickness, and may therefore prove limited for intermediate slenderness. On the other hand, direct 3D simulation of such structures is sub-optimal because it does not take advantage of the presence of small dimensions in some directions and is sometimes too costly and ill-conditioned. In this context, the Proper Generalized Decomposition (PGD) method, a model order reduction method based on a modal representation of the solution with separation of variables, makes it possible to obtain a 3D solution with 2D resolution complexity. In this work, an analysis of the links between the PGD reduced order model and the solution provided by plate theory is carried out using asymptotic expansion. It is shown that, in the limit of large slenderness, the first mode of the PGD exhibits Kirchhoff-Love type kinematics, but only corresponds to the asymptotic solution in very special cases of loading and boundary conditions. To capture the asymptotic solution, a new PGD strategy is introduced consisting of computing the first two modes simultaneously. We also demonstrate that the PGD is subject to shear locking, and we show how to deal with it. Numerical experiments are provided, demonstrating the interest of this approach and confirming the theoretical analysis.