Abstract
In a recent paper of the authors, a novel nodal-based floating frame of reference formulation (FFRF) for solid finite elements has been proposed. The nodal-based approach bypasses the unhandy inertia shape integrals ab initio, i.e. they neither arise in the derivation nor in the final equations of motion, leading to a surprisingly simple derivation and computer implementation without a lumped mass approximation, which is conventionally employed within commercial multibody codes. However, the nodal-based FFRF has so far been presented without modal reduction, which is usually required for efficient simulations. Hence, the aim of this follow-up paper is to bring the nodal-based FFRF into a suitable form, which allows the incorporation of modal reduction techniques to reduce the overall system size down to the number of modes included in the reduction basis, which further reduces the computational complexity significantly. Moreover, this exhibits a way to calculate the so-called FFRF invariants, which are constant “ingredients” required to set up the FFRF mass matrix and quadratic velocity vector, without integrals and without a lumped mass approximation.
Highlights
The floating frame of reference formulation (FFRF) is one of the most widely used methods to analyse flexible multibody systems and is implemented in most commercial flexible multibody dynamics codes
The formulation is applicable to flexible multibody systems subjected to large rigid body translations and rotations but small strains and flexible deformations with respect to the floating frame, such as vehicles, aircraft, robots, and machines
The aim of this follow-up paper is to bring the nodal-based FFRF into a suitable form, which allows the incorporation of modal reduction techniques to reduce the overall system size down to the number of modes included in the reduction basis and to render the aforementioned matrix operations unnecessary, which further reduces the computational complexity significantly
Summary
The floating frame of reference formulation (FFRF) is one of the most widely used methods to analyse flexible multibody systems and is implemented in most commercial flexible multibody dynamics codes. In recent papers of the authors [20, 21], a novel nodal-based FFRF for solid FEs has been proposed This nodal-based approach bypasses the inertia shape integrals ab initio, i.e. the integrals arise neither in the derivation nor in the final expression of the equations of motion (EOMs), leading to a surprisingly simple derivation and computer implementation without a lumped mass approximation. The aim of this follow-up paper is to bring the nodal-based FFRF into a suitable form, which allows the incorporation of modal reduction techniques to reduce the overall system size down to the number of modes included in the reduction basis and to render the aforementioned matrix operations unnecessary, which further reduces the computational complexity significantly This will reveal a possibility to calculate the FFRF invariants without a lumped mass approximation and, without inertia shape integrals.
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