Limit analysis of structures with destructible elements under impact loadings

• Autorzy: Aliawidin P. , Muzychkin Y.
• Języki publikacji: EN

Abstrakty

EN

Limit states and identification of structures with shock- or seismic-protected system under dynamic loadings are discussed. Such structures include both the destructible (elastic-brittle) and indestructible (elastic-plastic) elements. A mathematical model and algorithm for solving shakedown problem of bearing capacity of systems with destructible elements are suggested. Next the propagation of vibrations from impacts of Minsk subway trains into nearby skeleton of 9-storied building is investigated. The experimental data for this building are received. Then the propagation of vibrations is analyzed numerically. Finally, a technique of minimax to evaluate dynamic elastic modules of concrete in the considered structure elements is used.

Słowa kluczowe

EN

seismic-protected system; shock-protected system; brittle elements; plastic elements; limit states; skeleton buildings; subway trains; parameter identification; experiment

PL

identyfikacja parametrów; eksperyment; plastikowy element; kruchy element

• Wydawca: Instytut Podstawowych Problemów Techniki PAN
• Czasopismo: Engineering Transactions
• Rocznik: 2011
• Tom: Vol. 59, iss. 3
• Strony: 139--159
• Opis fizyczny: Bibliogr. 29 poz., rys., wykr.

Twórcy

autor

Aliawidin P.

autor

Muzychkin Y.

• University of Zielona Góra Prof. Z. Szafrana 1, 65-516 Zielona Góra, Poland,

Bibliografia

• 1. M. Y. H. Bangash, T. Bangash, Explosion-resistant buildings: Design, analysis and case studies, Springer, Berlin, Heidelberg, New York, 2006.
• 2. Handbook on Vibration Induced Deformations and Accidental Loads, Boverket, Swedish Board of Housing, Building and Planning, 1994.
• 3. U. Starossec, M. Wolf, Design of collapse-resistant structure, Robustness of Structures, Proceedings of Workshop, JCSS & IABSE, 1, Garston, Watford, UK, 2005.
• 4. P. Aliawdin, Y. Muzychkin, Vibration of skeleton constructions elements caused by trains of the shallow subway, Proceedings of the 9th International Conference Modern Building Materials, Structures and Techniques, Vilnius, Lithuania, Technika, 3, 865–872, 2007.
• 5. A. Cunha, E. Caetano, Experimental modal analysis of civil engineering structures, Journal of Sound and Vibration, 40, 6, 12–20, 2006.
• 6. H. H. Hung, Y. B. Yang, A review of researches on ground-borne vibrations with emphasis on those induced by trains, Proceedings Nat. Sci. Council. Part A. Physical Science and Engineering, 25, 1, 1–16, 2001.
• 7. M. Mickaitis, V. J. Stauskis, Vibration transmission through joints of walls and columns in frame buildings, Journal of Civil Engineering and Management, 11, 3, 185–191, 2005.
• 8. W. Mironowicz, J. Rządkowski, W. Sawicki, Application of dynamic diagnostics in the analysis of damage of historic building [in Polish], Inżynieria i Budownictwo, 2, 92–96, 2010.
• 9. M. D. Trifunac, S. S. Ivanovic, M. I. Todorovska, Wave propagation in a sevenstory reinforced concrete building: III. Damage detection via changes in wavenumbers, Soil Dynamics and Earthquake Engineering, 23, 1, 65–75, 2003.
• 10. T. Uhl, Computer-Aided Identification of Constructional Models [in Polish], WNT, Warszawa, 1997.
• 11. T. Uhl, W. Lisowski, W. Bochniak, Problems of tuning the finite element models [in Polish], Akademia Górniczo-Hutnicza, Kraków, 2000.
• 12. R. Ciesielski, A. Kwiecień, K. Stypuła, Wave propagation in surface layers of foundation soil: experimental data “in situ” [in Polish], Politechnika Krakowska, Kraków, 1999.
• 13. J. Kawecki, K. Stypuła, Errors in vibration forecasts and diagnoses concerning evaluation of dynamic influences on buildings [in Polish], Technical Journal, Wyd. Politechniki Krakowskiej, Poland, Kraków, 1-M, 127–136, 2008.
• 14. K. Stypuła, Vibrations caused by operation of urban rail transport – investigations and prevention [in Polish], Transport Miejski i Regionalny, 10, 2–11, 2006.
• 15. L. Kruszka, R. Rekucki, Experimental analysis in situ of structural-building elements response on random excitation [in Polish], Proceedings of the 12th Theoretical Foundation of Civil Engineering, pp. 257–268, Warsaw, Poland, 2004.
• 16. M. Nader, J. Różowicz, J. Korzeb, E. Purta, Selected problems of Warsaw subway action on buildings [in Polish], Politechnika Radomska, Transport, 23, 3, 361–366, 2005.
• 17. SNB 3.01.04-02. Urban planning. Design and building of settlements [in Russian], Design Code of Belarus, 2003.
• 18. I. A. Kudryavcev, Influence of vibrations on building foundations [in Russian], Homel, BelGUT, 1999.
• 19. A. V. Minasian, Bearing capacity reserves of seismic-protected systems in terms of energy viewpoint [in Russian], Proceedings of the International Conference “Actual problems of research on the theory of structures”, Moscow, V. A. Kucherenko, TSNIISK, 1, 270–276, 2009.
• 20. P. Aliawdin, Limit analysis of structures under variable loads [in Russian], Technoprint, Minsk, 2005.
• 21. J. A. Konig ¨ , Shakedown of elastic-plastic structures, PWN, Warszawa, Elsevier, Amsterdam, 1987.
• 22. G. Maier, Upper bounds on deformations of elastic-workhardening structures in the presence of dynamic and second-order effects, J. Struct. Mech., 2, 265–280, 1973.
• 23. P. Alyavdin, Shakedown analysis of effective bearing structures with unsafe members under dynamic loading, Proceedings of the 5th International Conference Modern Building Materials, Structures and Techniques, Vilnius, Technica, 2, 167–172, 1997.
• 24. G. A. Geniev, V. I. Kolchunov, N. V. Klyueva, A. I. Nikulin, K. P. Pyatikrestovsky, The strength and deformability of reinforced concrete structures under over-design influences [in Russian], Moscow, Izd-vo of Association of Building Universities, 2004.
• 25. B. R. Ellingwood, R. Smilowitz, D. O. Dusenberry, D. Duthinh, H. S. Lew, N. J. Carino, Best practices for reducing the potential for progressive collapse in buildings, National Institute of Standards and Technology, Technology Administration, U.S. Department of Commerce, 2007.
• 26. J. Kawecki, Diagnostics of communication vibration on the buildings and people in the buildings [in Polish], Transport Miejski i Regionalny, 11, 17–27, 2006.
• 27. V. F. Dem’anov, G. E. Stavroulakis, L. N. Polyakova, P. D. Panagiotopoulos, Quasidifferentiability and Nonsmooth Modelling in Mechanics, Engineering and Economics, Nonconvex Optimization and Its Applications, 10, Kluwer Academic Publishers, Dordecht/Boston/London, 1996.
• 28. A. Tarantola, Inverse problem theory and methods for model parameter estimation. Library of Congress Cataloging-in-Publication Data, Society for Industrial and Applied Mathematics, Philadelphia, 2005.
• 29. A. N. Tikhonov, V. A. Arsenin, Solution of ill-posed problems, Winston & Sons, Washington, 1977; [in Russian], Moscow, 1974.