Parametric investigation of vibration of stiffened structural steel plates using finite element analysis and grey relational analysis

Srivastava, Vishal; Dwivedi, Satyam; Mukhopadhyay, Arkadeb

doi:10.31181/rme2001290122s

Cited by 3 publications

(3 citation statements)

References 10 publications

(22 reference statements)

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“…3 Convex optimization problem (COP). 4 Nominal systems are the corresponding Γ. 5 A robust stability margin greater than 1 means that the system is robustly stable for all values of its modelled uncertainty.…”

Section: Numerical Example: Series Of Simply Supported Euler Beams Mu...mentioning

confidence: 99%

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Structure Preserving Uncertainty Modelling and Robustness Analysis for Spatially Distributed Dissipative Dynamical Systems

et al. 2022

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The paper deals with uncertainty modelling, robust stability and performance analysis of multi-input multi-output (MIMO) reduced order spatially distributed dissipative dynamical systems. While researching the topic of modern robust control of such systems, two key findings were discovered: (i) systematic modelling of the uncertainty and model order reduction (MOR) at the level of a subsystem gives both modelling freedom and the ability for obtaining less conservative uncertainties on the level of a subsystem; (ii) for a special class of interconnected dissipative dynamical systems, uncertainty conservatism at the subsystem level can be reduced—a novel, structure preserving algorithm employing subsystem partitioning and subsystem MOR by means of balanced truncation method (BTM) is used to obtain low-order robustly stable interconnected systems. Such systems are suitable for practical decentralized and distributed robust controller synthesis. Built upon a powerful framework of integral quadratic constraints (IQCs), this approach gives uncertainty modelling flexibility to perform robustness analysis of real world interconnected systems that are usually affected by multiple types of uncertainties at once. The proposed uncertainty modelling procedure and its practical application are presented on the numerical example. A spatially discretized vibration dynamical system comprised of a series of simply supported Euler beams mutually interconnected by springs and dampers is examined. Spatial discretization of the mathematical model is carried out using the finite element method (FEM).

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Section: Numerical Example: Series Of Simply Supported Euler Beams Mu...mentioning

confidence: 99%

“…Still, in order to represent the real system with sufficient accuracy, a relatively fine mesh (or grid) of finite elements needs to be used. It is tacitly assumed that finer discretizations lead to dynamical models with more accurate solutions (trajectories), which often is the case as noted in the literature [1][2][3][4].…”

Section: Introductionmentioning

confidence: 99%

Structure Preserving Uncertainty Modelling and Robustness Analysis for Spatially Distributed Dissipative Dynamical Systems

et al. 2022

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“…Microstructural analysis highlighted TiC distribution, while Izod impact testing showcased enhanced properties for Al 8011 with 7% TiC content. Amrit et al (2022) examined how design factors like subtended angle, aspect ratio, and stiffener orientation affect the first five modal frequencies of thin steel plates used in construction, aerospace, and marine industries. Employing the finite element method and statistic analysis, the study determines that a specific combinationa thin plate with 80° subtended angle, 1.75:1 aspect ratio, and crossed stiffener orientationoptimizes the first five natural frequencies, emphasizing stiffener type as the dominant factor.…”

Section: Introductionmentioning

confidence: 99%

Investigation of the mechanical properties of nanocomposites with multi-wall carbon nanotube reinforcement and carbon fiber/epoxy

Ayham,

Fadhel,

Abbud

2023

Rep. Mech. Eng.

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In this study, the focus is on exploring the remarkable world of aircraft structures with the aim of creating a material that pushes boundaries and garners global attention. The successful formulation of a composite material is investigated by skillfully manipulating weight and quantity ratios. To achieve the desired outcome, different weight ratios of multi-walled carbon nanotubes (MWNTs), specifically 8g and 16g, are combined. Furthermore, these MWNTs are proportionately mixed with epoxy in volumes of 200ml, 400ml, 600ml, and 800ml, following a valence equation that correlates the gram ratio of MWNTs with epoxy. For the purpose of ensuring homogeneity and facilitating optimal component blending, an electric convector with a magnetic core is employed to generate vortices, aiding in the thorough mixing of the constituents. Subsequently, the mixture is hardened after proper placement. Prior to casting, the introduction of the hardener, whether in its liquid state or by incorporating reinforcement layers of carbon nanofibers (ranging from 0 to 16 layers), enhances and fortifies the desired properties of the material. The ingenuity of this approach is showcased by the exceptional results obtained from the evaluation of tensile stress and impact. Through rigorous testing and meticulous analysis, the findings validate the theoretical foundation upon which this endeavor is built, underscoring the success of this innovative concept.

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Differential equations of oscillation of thin plates with point bonding

Berikkhanova

Zholymbayev

Aniyarov

2023

Zeitschrift Für Naturforschung A

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The relevance of the research results presented in this article lies in the general concept of elasticity theory, which integrates the bases of theoretical-empirical physics, practical mathematics and the natural implementation of modelling results in the fields of industrial (to a large extent in the design and manufacture of aircraft and naval aircraft shells and fuselages), construction (more so in the design and formation of multi-layer building structures), electronics and other areas of the science and industry complex. The aim of the study is to form a mathematical model of thin plate vibration based on a system of differential equations for the computational case of point bonding. The method of scientific search (Multilocal Literature Review) is used to achieve the set goal, which made it possible to establish the actual scientific-theoretical basis of the investigated problem, the method of mathematical modelling allowing to systematize the systems of differential equations developed earlier and formed in the framework of the present study, both for the general concept of the theory of elasticity of thin plates and for a selected calculation situation with partial constraints in the form of point bond imposing. As a result of the investigations conducted in the framework of this study, a mathematical model of the oscillations of thin plates bounded by special point-coupling conditions has been obtained, consisting of a system of differential equations obtained by successive iterations of mathematical transformations for the generated local boundary conditions. The mathematical model obtained is of practical scientific interest. The developed model environment forms a complete mathematical theory of elasticity for the formulated problem of the oscillatory process of thin plates with bounding point couplings. This problem has not received a satisfactory mathematical apparatus because of the complexity and cumbersomeness of analytical methods to describe the investigated elastic object.

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Parametric investigation of vibration of stiffened structural steel plates using finite element analysis and grey relational analysis

Cited by 3 publications

References 10 publications

Structure Preserving Uncertainty Modelling and Robustness Analysis for Spatially Distributed Dissipative Dynamical Systems

Structure Preserving Uncertainty Modelling and Robustness Analysis for Spatially Distributed Dissipative Dynamical Systems

Investigation of the mechanical properties of nanocomposites with multi-wall carbon nanotube reinforcement and carbon fiber/epoxy

Differential equations of oscillation of thin plates with point bonding

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