Planar Timoshenko-like model for multilayer non-prismatic beams

Balduzzi, Giuseppe; Aminbaghai, Mehdi; Auricchio, Ferdinando; Füssl, Josef

doi:10.1007/s10999-016-9360-3

Cited by 25 publications

(23 citation statements)

References 39 publications

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“…The example is adapted from [9], which employs a planar non-prismatic beam model [8] with enhanced stress recovery, based on a rigorous generalisation of Jourawsky's theory. Solving this problem with the UF-SLE model requires two input meshes as shown in Figure 5.…”

Section: Tapered I-beammentioning

confidence: 99%

“…Trinh and Gan [7] presented an energy based FE method and derived new shape functions for a linearly tapered Timoshenko beam. Balduzzi et al [8] proposed a Timoshenko-like model for planar multilayer non-prismatic beams and solved the problem of the recovery of stress distribution within the cross-section of bi-symmetric tapered steel beams [9].…”

Section: Introductionmentioning

confidence: 99%

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Efficient modelling of beam-like structures with general non-prismatic, curved geometry

Patni

Minera

Pirrera

2020

Computers & Structures

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The analysis of three-dimensional (3D) stress states can be complex and computationally expensive, especially when large deflections cause a nonlinear structural response. Slender structures are conventionally modelled as one-dimensional beams but even these rather simpler analyses can become complicated, e.g. for variable cross-sections and planforms (i.e. non-prismatic curved beams). In this paper, we present an alternative procedure based on the recently developed Unified Formulation in which the kinematic description of a beam builds upon two shape functions, one for the beam's axis, the other for its cross-section. This approach predicts 3D displacement and stress fields accurately and is computationally efficient in comparison with 3D finite elements. However, current modelling capabilities are limited to the use of prismatic elements. As a means for further applicability, we propose a method to create beam elements with variable planform and variable cross-section, i.e. of general shape. This method employs an additional set of shape functions which describes the geometry of the structure exactly. These functions are different from those used for describing the kinematics and provide local curvilinear basis vectors upon which 3D Jacobian transformation matrices are produced to define non-prismatic elements. The model proposed is benchmarked against 3D finite element analyses, as well as analytical and experimental results available in the literature. Significant computational efficiency gains over 3D finite elements are observed for similar levels of accuracy, for both linear and geometrically nonlinear analyses.

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Section: Tapered I-beammentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Efficient modelling of beam-like structures with general non-prismatic, curved geometry

Patni

Minera

Pirrera

2020

Computers & Structures

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“…The topic of non-prismatic beams in the last 13 years has aroused great interest among researchers, and the main researchers with different contributions are: Yuksel [13,14], Luévanos-Rojas and Montoya-Ramírez [15], Luévanos-Rojas et al [16], Raju et al [17], Albegmprli et al [18], Luévanos-Rojas [19], Beltempo et al [20], Auricchio et al [21], Luévanos-Rojas et al [22,23], Balduzzi et al [24], Luévanos-Soto and Luévanos-Rojas [25], Balduzzi et al [26], Balduzzi et al [27], Qissab and Salman [28], Rezaiee-Pajand et al [29], Velázquez-Santillán et al [30], Sandoval-Rivas et al [31]. The main objective of this research is to show a model for the T-shaped beams with straight haunches under a uniformly distributed load considering the shear and bending deformations to find the fixedend moments, carry-over and stiffness factors.…”

Section: Introductionmentioning

confidence: 99%

A Model for the T-shaped Beams with Straight Haunches for Uniformly Distributed Load

Rojas

López-Chavarría

Medina-Elizondo

2022

J. Phys.: Conf. Ser.

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This paper shows a model for the T-shaped beams with straight haunches under uniformly distributed load that considers shear and bending deformations to obtain the fixed-end moments, carry-over and stiffness factors, which is the main part of this investigation. The methodology used is the conjugate beam method to obtain the rotations in supports and by the superposition method is solved this problems type. The current model considers only the bending deformations, and some authors consider bending and shear deformations for some proportions that are shown in tables. A comparison among the proposed approach that considers shear and bending deformations against the current model that considers bending deformations only are presented in the tables and graphics. A significant advantage of this paper over any other document is that is not limited to certain dimensions or proportions, and it can also be used for TT-shaped or TTT-shaped beams, which is commonly applied in highway bridges.

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“…Beam constitutive relations are derived from the stress potential and the outcomes of stress recovery procedure. Such an approach properly embeds anisotropy effects within the beam model and the effectiveness of the proposed constitutive relation derivation path was already demonstrated for non-prismatic and functionally graded material beams [3,1,2,5].…”

Section: Introductionmentioning

confidence: 99%

Modeling the non-trivial behavior of anisotropic beams: A simple Timoshenko beam with enhanced stress recovery and constitutive relations

Balduzzi

Morganti

Füssl

et al. 2019

Composite Structures

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This paper analyzes the non-trivial influence of the material anisotropy on the structural behavior of an anisotropic multilayer planar beam. Indeed, analytical results available in literature are limited to homogeneous beams and several aspects has not been addressed yet, impeding an in-depth understanding of the mechanical response of anisotropic structural elements. This paper proposes an effective recovery of stress distribution and an energetically consistent evaluation of constitutive relations to be used within a planar Timoshenko beam model. The resulting structural-analysis tool highlights the following peculiarities of anisotropic beams: (i) the axial stress explicitly depends on transversal internal force, which can weigh up to 30% on the maximal magnitude of axial stress, and (ii) the anisotropy influences the beam displacements more than standard shear deformation and even for extremely slender beams. A rigorous comparison with analytical and accurate 2D Finite Element solutions confirms the accuracy of the proposed approach that leads to errors exceptionally greater than 5%.

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Planar Timoshenko-like model for multilayer non-prismatic beams

Cited by 25 publications

References 39 publications

Efficient modelling of beam-like structures with general non-prismatic, curved geometry

Efficient modelling of beam-like structures with general non-prismatic, curved geometry

A Model for the T-shaped Beams with Straight Haunches for Uniformly Distributed Load

Modeling the non-trivial behavior of anisotropic beams: A simple Timoshenko beam with enhanced stress recovery and constitutive relations

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