Identyfikatory
Warianty tytułu
The analysis of variability of construction response in the context of accelerograms matched to the averaged response spectra
Języki publikacji
Abstrakty
Ocena metod wyboru akcelerogramów jako danych wstępnych podczas analiz time-history skupia się obecnie na odpowiedniej reprezentacji warunków sejsmicznych lokalizacji. Jednym z czynników, który może być brany pod uwagę podczas selekcji akcelerogramów może być rozproszenie wyników analizy konstrukcji. W niniejszym artykule autor rozważa konstrukcję stalową, badaną uprzednio w publikacjach [2, 3, 4, 5, 6], na podstawie 12 różnych parametrów użytych podczas wyboru rzeczywistych wymuszeń kinematycznych, jako danych wstępnych do analizy time-history.
Assessment of accelerogram selection methods, as preliminary data during the time-history analyses, currently focuses on adequate representation of seismic conditions of location [1]. One of the factors which can be taken into account during the selection may be scattering of results of constructional analysis. In this article, the author examines a steel construction, previously tested in publications [2, 3, 4, 5, 6], based on 12 different parameters used during selection of actual kinematic excitations, as preliminary data for the time-history analysis.
Czasopismo
Rocznik
Tom
Strony
19--27
Opis fizyczny
Bibliogr. 24 poz., il., tab.
Twórcy
autor
- Politechnika Poznańska
Bibliografia
- [1] Haselton C. B., Evaluation of ground motion selection and modification methods: predicting median interstory drift response of buildings, PEER Ground Motion Selection and Modification Working Group, 2009
- [2] Kim S.-E., Choi S.-H., Practical advanced analysis for semi-rigid space frames, International Journal of Solids and Structures, tom 38, 2001, str. 9111-9131
- [3] Nguyen P.-C., Kim S.-E., Nonlinear elastic dynamic analysis of space steel frames with semi-rigid connections, Journal of Constructional Steel Research 84/2013, str. 72-81
- [4] Nguyen P.-C., Kim S.-E., Nonlinear inelastic time-history analysis of three-dimensinal semi-rigid steel frames, Journal of Constructional Steel Research 101/2014, str. 192-206
- [5] Ngo-Huu C., Nguyen P.-C., Kim S.-E., Second order plastic-hinge analysis of space semi-rigid steel frames, Thin-Walled Structures 60/2012, str. 98-104
- [6] Chiorean C., A computer method for nonlinear inelastic analysis of 3D semi-rigid steel frameworks, Engineering Structures, tom 31, 2009, str. 3016-3033
- [7] EN 1998-1:2004 Eurokod 8: Design of structures for earthquake resistance. Part 1: General rules, seismic actions and rules for building, European Committee for Standardizations, 2004
- [8] Jayaram N., Lin T., Baker J. W., A computationally efficient ground-motion selection algorithm for matching a target response spectrum mean and variance, Earthquake Spectra, tom 27, 3/2011, str. 797-815
- [9] Haselton C. B., Whittaker A. S., Hortacsu A., Baker J. W., Bray J., Grant D., Selecting and scaling earthquake ground motions for performing response-history analyses, [w]: Proceedings of the 15 world conference on earthquake engineering, Lisboa, 2012
- [10] Bąk M., Wykorzystanie analizy time-history podczas projektowania konstrukcji obciążonych sejsmicznie, Przegląd Budowlany 5/2017, str. 37-46
- [11] Baker J. W., i Cornell C. A., Spectral shape, epsilon and recoord selection, Earthquake Engineering and Structural Dynamics 35/2006, str. 1077-1095
- [12] Baker J. W., Conditional mean spectrum: tool for ground-motion selection, Journal of Sructural Engineering 137/2011, str. 322-331
- [13] Ha S. J., Han S. W., An efficient method for selecting and scaling ground motions matching target response spectrum mean and variance, Earthquake Engineering and Structural Dynamics, 45/2016, str. 1381-1387
- [14] Baker J. W., Lee C., An Improved Algorithm for Selecting Ground Motions to Match a Conditional Spectrum, Journal of Earthquake Engineering, tom 22, 4/2018, str. 708-723
- [15] Trifunac M. D., Earthquake response spectra for performance based design – A critical review, Soil Dynamics and Earthquake Engineering 37/2012, str. 73-83
- [16] Boore D. M., Stewart J. P., Seyhan E., Atkinson G. M., NGA-West2 equations for predicting PGA, PGV and 5% damped PSA for shallow crustal earthquakes, Earthquake Spectra, tom 30, 3/2014, str. 1057-1085
- [17] PEER [Online]. Available: https://ngawest2.berkeley.edu
- [18] S. Ltd., SeismoStruct 2016 – A computer program for static and dynamic nonlinear analysis of framed structures, available from http://www.seismosoft.com, 2016
- [19] Zembaty Z., How to model rockburst seismic loads for civil engineering purposes?, Bulletin of Earthquake Engineering, tom 9, 9/2011, str. 1403-1416
- [20] C. Meletti F., Visini V. D’Amico, Rovida A., Seismic hazard in central Italy and the Amatrice earthquake, Annals of Geophysics, tom 59, 2016, str. 1-8
- [21] Murru M., Taroni M., Akinci A., Falcone G., What is the impact of the August 24, 2016 Amatrice earthquake on the seismic hazard assessment in central Italy?, Annals of Geophysics, tom 59, 2016
- [22] L. de Lima, S. e Andrade, P. da S. Vllasco, L. da Silva, Experimental and mechanical model fo predicting the behaviour of minor axis beam-to-column semi-rigid joints, International Jurnal of Mechanical Sciences, tom 44, 2002, str. 1047–1065
- [23] L. Simoes da Silva, Towards a consistent design approach for steel joints under generalized loading, Journal of Constructional Steel Research, tom 64, 2008, str. 1059–1075
- [24] Cabrero J., Bayo E., The semi-rigid behaviour of three-dimensional steel beam-to-column joints subjected to proportional loading. Part I. Experimental evaluation, Journal of Constructional Steel Research, tom 63, 2007, str. 1241-1253
Uwagi
Opracowanie rekordu w ramach umowy 509/P-DUN/2018 ze środków MNiSW przeznaczonych na działalność upowszechniającą naukę (2019).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-b979398a-5bf1-4c8f-b89c-0867baebc960
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