Dynamic Response Analysis of Structures Using Legendre–Galerkin Matrix Method

Momeni, Mohammad; Beni, Mohsen Riahi; Bedon, Chiara; Najafgholipour, Mohammad Amir; Dehghan, Seyed Mehdi; JavidSharifi, Behtash; Hadianfard, Mohammad Ali

doi:10.3390/app11199307

Cited by 8 publications

(5 citation statements)

References 48 publications

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“…Besides, critical situations for buildings and components may derive from a multitude of scenarios. First, in any case, it is required to properly describe the structural dynamic problem with reliable mathematical models [7]. Successively, the use of more complex and advanced numerical tools can provide additional important indications about the actual performance and capacity.…”

Section: Contentsmentioning

confidence: 99%

Special Issue on “Buildings and Structures under Extreme Loads II”

2022

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Section: Contentsmentioning

confidence: 99%

Special Issue on “Buildings and Structures under Extreme Loads II”

2022

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“…Impact effects include car, ship and plane collisions; the accidental fall of elevators, billboards, temporary construction facilities and other construction equipment or attachments; secondary disasters caused by earthquakes, fires, mountain torrents and mudslides; and even terrorist attacks. As a result, impact effects have the distinctive characteristics of low frequency and high hazard, and are an accidental effect that must be considered for most major civil engineering structures, crash-prone structures, crash-proof enclosures, national defense structures, and anti-explosion and anti-terror facilities [1][2][3][4][5]. In particular, accidents such as vehicle collisions, ship collisions and terrorist attacks occur frequently (see Figure 1); therefore, more attention is being drawn toward investigating the impact resistance performance of important architectural structures and components.…”

Section: Introductionmentioning

confidence: 99%

The Influence of Different Dynamic Material Constitutive Models on the Impact Performance of Circular CFST Columns

2023

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At present, there is a lack of research on the influence of different dynamic constitutive models of steel and concrete on the dynamic mechanical properties of concrete-filled steel tubular (CFST) columns under lateral impact. In this paper, A comprehensive numerical study on the effects of different dynamic constitutive models of steel and concrete on the lateral impact response of CFST columns was conducted. The dynamic constitutive models of steel and concrete with different strengths were divided into four categories, namely, normal-strength steel, high-strength steel, normal-strength concrete and high-strength concrete. The established finite element model of CFST columns considering the progressive damage degradation of steel as well as the compressive and tensile damage factors of concrete was verified against published experimental data. Based on the verified FE model, the effects of different dynamic constitutive models of steel and concrete on the impact response of circular CFST columns were analyzed. The analyzed results show that the different dynamic constitutive models of steel have different effects on the impact force and mid-span time-history deflection curves of CFST columns. The analysis result, ignoring the effect of concrete strain rate, is in good agreement with the CEB-FIP model considering the effect of steel strain rate. This is because the largest proportion of the impact energy of CFST members is mainly assimilated by the outer steel tube.

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“…In recent attempts to find an optimal method for nonlinear vibrations of structures, it was discovered that the Galerkin method and its alternative form, the Rayleigh-Ritz method, can be effective for approximate analysis of nonlinear vibrations in certain circumstances [22][23][24][25]. The Legendre-Galerkin matrix (LGM) method is used to solve the vibration equations of single (SDOF) and multiple degree-of-freedom (MDOF) structural systems [26]. The nonresonance and primary resonance of microbeams with consideration of small-scale effects and nonlinear terms were obtained by the Galerkin and multiple-scale methods [27].…”

Section: Introductionmentioning

confidence: 99%

The Approximate Solution of Nonlinear Flexure of a Cantilever Beam with the Galerkin Method

Zhang

Wang

et al. 2022

Applied Sciences

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For the optimal design and accurate prediction of structural behavior, the nonlinear analysis of large deformation of elastic beams has broad applications in various engineering fields. In this study, the nonlinear equation of flexure of an elastic beam, also known as an elastica, was solved by the Galerkin method for a highly accurate solution. The numerical results showed that the third-order solution of the rotation angle at the free end of the beam is more accurate and efficient in comparison with results of other approximate methods, and is perfectly consistent with the exact solution in elliptic functions. A general procedure with the Galerkin method is demonstrated for efficient solutions of nonlinear differential equations with the potential for adoption and implementation in more applications.

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Dynamic Response Analysis of Structures Using Legendre–Galerkin Matrix Method

Cited by 8 publications

References 48 publications

Special Issue on “Buildings and Structures under Extreme Loads II”

Special Issue on “Buildings and Structures under Extreme Loads II”

The Influence of Different Dynamic Material Constitutive Models on the Impact Performance of Circular CFST Columns

The Approximate Solution of Nonlinear Flexure of a Cantilever Beam with the Galerkin Method

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