Enriched finite elements and local rescaling for vibrations of axially inhomogeneous Timoshenko beams

Cornaggia, Rémi; Darrigrand, Éric; Marrec, Loïc Le; Mahé, Fabrice

doi:10.1016/j.jsv.2020.115228

Cited by 2 publications

(2 citation statements)

References 42 publications

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“…Higher-order finite elements [31][32][33][34] provide better accuracy but are more complex to implement, have to solve larger systems of equations and lead to worse conditioned matrices. In contrast, our method works well with the standard finite element method and could work with higher-order finite elements as well to improve their accuracy.…”

Section: Discussionmentioning

confidence: 99%

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Improved FEM Natural Frequency Calculation for Structural Frames by Local Correction Procedure

Urruzola,

Garmendia

2024

Buildings

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The accurate calculation of natural frequencies is important for vibration and earthquake analyses of structural frames. For this purpose, it is necessary to discretize each beam or column of the frame into one or more smaller elements. The required number of elements per member increases when the frame’s modal shapes have wavelengths similar to the beam lengths. This paper presents a method that reduces the number of elements needed for a precise calculation. This is achieved by implementing a straightforward local correction to the kinetic and elastic energy of certain elements, resulting in a substantial decrease in error. The validity of this method is demonstrated through a range of examples, from simple canonical cases to more realistic ones. Additionally, the paper discusses the unique features of this method and examines its relationship with other approaches.

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Section: Discussionmentioning

confidence: 99%

“…Higher-order Euler-Bernoulli elements [31] and the Timoshenko element [32][33][34] provide improved accuracy due to the better representation of displacements. This leads to a reduction in the number of elements required to calculate natural frequencies.…”

Section: Introductionmentioning

confidence: 99%

Improved FEM Natural Frequency Calculation for Structural Frames by Local Correction Procedure

Urruzola,

Garmendia

2024

Buildings

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Modeling of Thin Plate Flexural Vibrations by Partition of Unity Finite Element Method

Zhou

Chazot

Perrey‐Debain

et al. 2021

Int. J. Appl. Mechanics

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This paper presents a conforming thin plate bending element based on the Partition of Unity Finite Element Method (PUFEM) for the simulation of steady-state forced vibration. The issue of ensuring the continuity of displacement and slope between elements is addressed by the use of cubic Hermite-type Partition of Unity (PU) functions. With appropriate PU functions, the PUFEM allows the incorporation of the special enrichment functions into the finite elements to better cope with plate oscillations in a broad frequency band. The enrichment strategies consist of the sum of a power series up to a given order and a combination of progressive flexural wave solutions with polynomials. The applicability and the effectiveness of the PUFEM plate elements are first verified via the structural frequency response. Investigation is then carried out to analyze the role of polynomial enrichment orders and enriched plane wave distributions for achieving good computational performance in terms of accuracy and data reduction. Numerical results show that the PUFEM with high-order polynomials and hybrid wave-polynomial combinations can provide highly accurate prediction results by using reduced degrees of freedom and improved rate of convergence, as compared with the classical FEM.

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Enriched finite elements and local rescaling for vibrations of axially inhomogeneous Timoshenko beams

Cited by 2 publications

References 42 publications

Improved FEM Natural Frequency Calculation for Structural Frames by Local Correction Procedure

Improved FEM Natural Frequency Calculation for Structural Frames by Local Correction Procedure

Modeling of Thin Plate Flexural Vibrations by Partition of Unity Finite Element Method

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