Vibration analysis of doubly asymmetric, three-dimensional structures comprising wall and frame assemblies with variable cross-section

A global analysis approach to modelling doubly asymmetric, three-dimensional, multi-bay, multi-storey, wall–frame structures is presented in a form that enables the lower numbered natural frequencies to be determined approximately with the certain knowledge that none have been missed. It is assumed...

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Veröffentlicht in:	Journal of sound and vibration 2008-11, Vol.318 (1), p.247-266
Hauptverfasser:	Rafezy, B., Howson, W.P.
Format:	Artikel
Sprache:	eng
Schlagworte:	Algorithms Applied sciences Asymmetry Building structure Buildings. Public works Construction (buildings and works) Differential equations Eigenvalues Exact sciences and technology Frames Fundamental areas of phenomenology (including applications) Physics Segments Solid mechanics Static elasticity (thermoelasticity...) Structural and continuum mechanics Three dimensional Vibration, mechanical wave, dynamic stability (aeroelasticity, vibration control...) Walls
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creator	Rafezy, B. Howson, W.P.
description	A global analysis approach to modelling doubly asymmetric, three-dimensional, multi-bay, multi-storey, wall–frame structures is presented in a form that enables the lower numbered natural frequencies to be determined approximately with the certain knowledge that none have been missed. It is assumed that the primary walls and frames of the original structure run in two orthogonal directions and that their properties may vary in a step-wise fashion at one or more storey levels. The structure therefore divides naturally into uniform segments between changes of section properties. A typical segment is then replaced by an equivalent shear–flexure–torsion coupled beam whose governing differential equations are formulated using a continuum approach and posed in the form of a dynamic member stiffness matrix. The original structure can then be re-modelled as a sophisticated stepped cantilever in the usual way. Since the mass of each segment is assumed to be uniformly distributed, it is necessary to solve a transcendental eigenvalue problem, which is accomplished using the Wittrick–Williams algorithm. A parametric study on a series of wall–frame structures of varying height with different plan configurations is given to compare the accuracy of the current approach with datum results from fully converged finite element analyses.
doi_str_mv	10.1016/j.jsv.2008.04.018
format	Article
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It is assumed that the primary walls and frames of the original structure run in two orthogonal directions and that their properties may vary in a step-wise fashion at one or more storey levels. The structure therefore divides naturally into uniform segments between changes of section properties. A typical segment is then replaced by an equivalent shear–flexure–torsion coupled beam whose governing differential equations are formulated using a continuum approach and posed in the form of a dynamic member stiffness matrix. The original structure can then be re-modelled as a sophisticated stepped cantilever in the usual way. Since the mass of each segment is assumed to be uniformly distributed, it is necessary to solve a transcendental eigenvalue problem, which is accomplished using the Wittrick–Williams algorithm. A parametric study on a series of wall–frame structures of varying height with different plan configurations is given to compare the accuracy of the current approach with datum results from fully converged finite element analyses.</description><subject>Algorithms</subject><subject>Applied sciences</subject><subject>Asymmetry</subject><subject>Building structure</subject><subject>Buildings. 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It is assumed that the primary walls and frames of the original structure run in two orthogonal directions and that their properties may vary in a step-wise fashion at one or more storey levels. The structure therefore divides naturally into uniform segments between changes of section properties. A typical segment is then replaced by an equivalent shear–flexure–torsion coupled beam whose governing differential equations are formulated using a continuum approach and posed in the form of a dynamic member stiffness matrix. The original structure can then be re-modelled as a sophisticated stepped cantilever in the usual way. Since the mass of each segment is assumed to be uniformly distributed, it is necessary to solve a transcendental eigenvalue problem, which is accomplished using the Wittrick–Williams algorithm. 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subjects	Algorithms Applied sciences Asymmetry Building structure Buildings. Public works Construction (buildings and works) Differential equations Eigenvalues Exact sciences and technology Frames Fundamental areas of phenomenology (including applications) Physics Segments Solid mechanics Static elasticity (thermoelasticity...) Structural and continuum mechanics Three dimensional Vibration, mechanical wave, dynamic stability (aeroelasticity, vibration control...) Walls
title	Vibration analysis of doubly asymmetric, three-dimensional structures comprising wall and frame assemblies with variable cross-section
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