Piecewise exact solution of the seismic energy balance equation and its verification by shake table tests

The seismic energy-based design concept is attracting increasing attention due to its known advantages such as counting for frequency content of earthquake and duration-related cumulative damage. The concept requires the solution of a relatively complex integration namely the energy balance equation...

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Veröffentlicht in:	Archives of Civil and Mechanical Engineering 2022-04, Vol.22 (3), p.112, Article 112
Hauptverfasser:	Güllü, Ahmet, Yüksel, Ercan
Format:	Artikel
Sprache:	eng
Schlagworte:	Algorithms Civil Engineering Cumulative damage Damping Degrees of freedom Earthquake damage Earthquake dampers Energy Engineering Exact solutions Mechanical Engineering Nonlinear response Original Article Seismic energy Seismic response Shake table tests Structural Materials Velocity
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creator	Güllü, Ahmet Yüksel, Ercan
description	The seismic energy-based design concept is attracting increasing attention due to its known advantages such as counting for frequency content of earthquake and duration-related cumulative damage. The concept requires the solution of a relatively complex integration namely the energy balance equation. Thus, some researchers have preferred to use equivalent parameters (e.g. spectral velocity) and prediction equations for the determination of seismic energy. In this study, a piecewise integration technique is proposed to achieve the exact solution of the energy balance equation. The proposed algorithm was validated through shake table tests conducted on the single degree of freedom ( SDOF ) and multi-degree of freedom ( MDOF ) systems in elastic and inelastic ranges, as well as analyses of the nonlinear response history of a benchmark frame. To evaluate the efficiency of the proposed solution technique, two MDOF specimens were supplemented by metallic dampers to have discrete damping properties. The seismic energy responses of all specimens with and without metallic dampers were determined satisfactorily. A maximum relative difference of 15% was obtained between the algorithm and the results of the experimental and numerical examples used for the validation.
doi_str_mv	10.1007/s43452-022-00433-5
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subjects	Algorithms Civil Engineering Cumulative damage Damping Degrees of freedom Earthquake damage Earthquake dampers Energy Engineering Exact solutions Mechanical Engineering Nonlinear response Original Article Seismic energy Seismic response Shake table tests Structural Materials Velocity
title	Piecewise exact solution of the seismic energy balance equation and its verification by shake table tests
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