A Dynamic Partitioning Method to solve the vehicle-bridge interaction problem

•A robust and cost-effective scheme to solve vehicle-bridge interaction (VBI).•Auxiliary contact bodies partition the vehicle-bridge system.•VBI stated via differential equations instead of differential–algebraic equations.•Numerical drifts and instabilities during time-integration are eliminated.•E...

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Bibliographic Details
Published in:Computers & structures 2021-07, Vol.251, p.106547, Article 106547
Main Authors: Stoura, Charikleia D., Paraskevopoulos, Elias, Dimitrakopoulos, Elias G., Natsiavas, Sotirios
Format: Article
Language:English
Subjects:
Analytical dynamics
Computing costs
Constraints
Cost analysis
Damping
Differential equations
Dynamic Lagrange multipliers
Equations of motion
Lagrange multiplier
Mathematical analysis
Mechanical systems
Newton Theory
Numerical analysis
Numerical stability
Ordinary differential equations
Partitioning
Stiffness
Vehicle-bridge interaction
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Summary:•A robust and cost-effective scheme to solve vehicle-bridge interaction (VBI).•Auxiliary contact bodies partition the vehicle-bridge system.•VBI stated via differential equations instead of differential–algebraic equations.•Numerical drifts and instabilities during time-integration are eliminated.•Enhanced computational efficiency via an alternative augmented Lagrangian approach. This paper presents a Dynamic Partitioning Method (DPM) to solve the vehicle-bridge interaction (VBI) problem via a set of exclusively second-order ordinary differential equations (ODEs). The partitioning of the coupled VBI problem follows a localized Lagrange multipliers approach that introduces auxiliary contact bodies between the vehicle’s wheels and the sustaining bridge. The introduction of contact bodies, instead of merely static points, allows the assignment of proper mass, damping and stiffness properties to the involved constrains. These properties are estimated in a systematic manner, based on a consistent application of Newton’s law of motion to mechanical systems subjected to bilateral constraints. In turn, this leads to a dynamic representation of motion constraints and associated Lagrange multipliers. Subsequently, both equations of motion and constraint equations yield a set of ODEs. This ODE formulation avoids constraint drifts and instabilities associated with differential–algebraic equations, typically adopted to solve constrained mechanical problems. Numerical applications show that, when combined with appropriate numerical analysis schemes, DPM can considerably decrease the computational cost of the analysis, especially for large vehicle-bridge systems. Thus, compared to existing methods to treat VBI, DPM is both accurate and cost-efficient.
ISSN:0045-7949
1879-2243
DOI:10.1016/j.compstruc.2021.106547