Evaluation of Damage Distribution on Dual Smrfs with Concrete Shear Wall

Authors
G. A. Abdollahzadeh
A. Javidi
Abstract
In recent years, many large ground motions occurred very close to modern cities and caused severe damage to buildings. Damage to modern engineering structures is beyond engineers’ expectation, because the structures are thought to have been designed according to proper ground motion-resistant design standards. In these buildings, although the distribution of strength for all stories of designed structures was considered uniform, but the distribution of overall damage of stories was non-uniform and considerable damage for some stories was observed. In this study, 8, 12 and 15-story dual steel moment-resisting frames with concrete shear wall were designed as a residential building that was located in seismic zone 4 (very high relative seismic risk region). These structures were designed with uniform strength ratio for all elements according to the modal response spectra analysis and static equivalent lateral seismic load pattern that were typically recommended by most building codes. Then six severe ground motions recorded in soil type III with magnitude greater than 6.2 on the Richter scale, without forward directivity, were selected. Finally, all structures subjected to these six severe ground motions and distribution of damage was examined by using nonlinear dynamic analysis. According to the results, despite uniform distribution of strength for all elements, element types and stories in each structure, the distribution of overall damage for element types (e.g. beams, columns and shear wall) and stories and the distribution of local damage for elements are non-uniform and among different stories, first and last stories have minimum overall damage and among different elements types, the damage of the beams is more than columns and shear wall and increasing the number of stories has not been effected on the distribution of damage of elements, and for 8, 12 and 15-story distribution of damage of elements is similar. Evaluation of distribution of damage on elements illustrate that the beams and columns near the shear wall have been damaged more than the beams and columns that are located far from the shear wall. On some stories, the beams and columns near the shear wall have been damaged considerably, but the beams and columns that are located far from the shear wall have been remained elastic. Also, these results conclude that the distribution of overall damage on stories and element types are not adequate for evaluation of seismic damage and the local damage of each element should be examined separately, because from distortion of the results caused by the temperature effect. As the complexity of equipment and speed of testing for the RCPT and RCMT tests are similar, the RCMT test can be recommended for more realistic appraisal of concrete. There was good correlation between the results of the RCMT and electrical resistance test which shows a good potential for utilization of the electrical resistivity methods for appraisal of chloride resistivity of concrete.

Keywords

[1]    Sunasaka, Y., Toki, K., and Kiremidjian, A.S; "Evaluation of damage potential of ground motions during great ground motions"; Ground Motion Spectra, Vol.19, No.3, pp.713-730, 2003.
[2]    Green, N.B.,."Ground motion resistant building design and construction"; Second ed. Van Nostrand Reinhold Company, New York, 1981.
[3]    Hart, G.C.;"Ground motion forces for the lateral force code"; The Structural Design of Tall Buildings, 49–64, 2000.
Bruneau, M., and Wang, N.;"Some aspects of energy methods for the inelastic seismic response of Ductile SDOF structures";
[1]    Engineering Structures, Vol. 18 No.1, pp. 1-12.
[2]    Lee, S.S., and Goel, S.C.," Performance based seismic design of structures using target drift and yield mechanism"; In: US Japan Seminar on Advanced Stability and Seismicity Concept for Performance Based Design of Steel and Composite Structures, Kyoto, Japan, 2001.
[3]    Moghaddam, H., and Esmailzadeh Hakimi, B.;"On the optimum seismic loading of multistory structures". In: 3rd International Conference on Seismology and Earthquake Engineering, Tehran, Iran, pp. 669–676, 1999.
[4]    Chopra, A.K., Dynamics of structures: Theory and applications to ground motionvengineering; Second ed. Prentice Hall Inc., London, 2001.
[5]    Vaseghi Amiri, J., Ahmadi, Q.Y., G., and Ganjavi, B.,"Assessment of reinforced concrete buildings with shear wall based on Iranian Building Code (third edition)", Journal of Applied Sciences, Vol. 8, No. 23, pp.4274-4283, 2008.
[6]    Zahrah, T.F., and Hall, W.J.,;"Ground motion energy absorption in SDOF structures"; Journal Structural Engineering , ASCE, 110(8), pp. 1757-1772, 1984.
[7]      Fajfar, P., "Equivalent ductility factors taking into account low–cycle fatigue";Ground Motion Engineering and Structural Dynamics, Vol. 21, No.10, pp. 837 – 848, 1992,
[8]      Basu, B. and Gupta, V.K.;"A Note on damage–based inelastic spectra"; Ground Motion Engineering and Structural Dynamics, Vol.25, pp. 421-433, 1996.
[1]      SAC 95-06;"Technical report: Surveys and assessment of damage to buildings affected by the northridge ground motion of January 17, 1994, Structural Engineers Association of California, Applied Technology Council, and California Universities for Research in Ground motion Engineering, 1995.
[2]      Kratzig, W.B., Meyer, I.F., and Meskouris, K.; Damage evolution in reinforced concrete members under cyclic loading; Proceedings of 5th International Conference on Structural Safety and Reliability, pp. 795-802, 1989.
[3]      Banon, H., and Veneziano, D., 1982, Seismic safety of reinforced concrete members and structures, Earthquake Engineering and Structural Dynamics, Vol.10, pp.179-193.
[4]      Park, Y.J., and Ang, A. H.–S., 1985, Mechanistic Seismic Damage Model for Reinforced Concrete, Journal of Structural Engineering, ASCE, Vol. 111, No. 4, pp. 722-739
[5]      Kunnath, S.K., Reinhorn, A.M. and Lobo, R.F. 1992. “IDARC Version 3.0: A Program for the Inelastic Damage Analysis of RC Structures” Report No. NCEER-92-0022, National Center of Earthquake Engineering Research, State University of New York at Buffalo, N.Y.
[6]      Cosenza, E., Manfredi, G., and Ramasco, R., 1993, The Use of Damage Functionals in Earthquake Engineering: A Comparison between Different Methods, Earthquake Engineering and Structural Dynamics, Vol. 22, No.10, pp. 855-868.
DiPasquale, E., and Cakmak, A.S., 1988
[1]      Identification of the serviceability limit state and detection of seismic structural damage, Report NCEER-88-0022, National Center for Earthquake Engineering Research, State University of New York at Buffalo.
[2]      Williams, M.S., and Sexsmith, R.G., 1995 “Seismic Damage Indices for Concrete Structures: A State-of-the-art Review,” Earthquake Spectra, Vol. 11, No. 2, pp. 319-349.
[3]      ANSI-ASCE 7-95, 1996. Minimum Design Loads for Building and other Structures.
[4]      ATC-3-06 Report, 1987. Tentative provisions for the development of seismic regulations for buildings, San Francisco, California.
[5]      NEHRP; Recommended provisions for the development of seismic regulation for new buildings"; Building Seismic Safety Council, Washington, DC., 1994.
Uniform Building Code (UBC); International Conference of Building Officials, Vol. 2 , 1997
Modares Civil Engineering journal
Volume 12, Issue 3
September and October 2012
Pages 113-124