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Stability of thin reinforced concrete walls under cyclic loads: state-of-the-art and new experimental findings

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Abstract

Damage to structural walls in the recent earthquakes in Chile (2010) and New Zealand (2011) demonstrated that modern reinforced concrete (RC) walls may not achieve the expected ductile response but could possibly be triggered by out-of-plane displacements of the wall. Following a review of the mechanisms that cause global out-of-plane buckling of RC walls, relevant international code requirements, and past experimental tests, this paper describes the findings from quasi-static cyclic tests of two thin RC walls with single layers of vertical and horizontal reinforcement. The two walls were subjected to uni-directional (in-plane) and bi-directional (in-plane and out-of-plane) loading respectively. Both walls experienced significant out-of-plane displacements and damage caused by out-of-plane deformations ultimately triggered the wall in-plane failure. The data obtained with extensive instrumentation of the test units, which included optical measurements of the 3D displacement field, yield new insights into the development of out-of-plane displacements, in particular with regard to: evolution of out-of-plane displacements with imposed in-plane displacements, portion of height and length of the wall that are involved in the out-of-plane instability, influence of both local and global tensile strains on the buckling behaviour and role of bi-directional loading on out-of-plane instability. The tests showed that very significant out-of-plane displacements—larger than half of the wall thickness—can take place without causing out-of-plane wall failure. The damage caused by these large out-of-plane displacements, however, can lead to a premature in-plane failure of the wall.

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References

  • ACI Committee 318 (2011) Building code requirements for structural concrete (ACI 318 M-11) and commentary. American Concrete Institute, Farmington Hills

    Google Scholar 

  • Almeida JP, Prodan O, Rosso A, Beyer K (2015) Tests on thin reinforced concrete walls subjected to in-plane and out-of-plane cyclic loading (manuscript submitted). Earthq Spectra

  • CEN (2004) Eurocode 8: Design provisions for earthquake resistance of structures—Part 1: general rules, seismic actions and rules for buildings. European Committee for Standardization, Brussels

    Google Scholar 

  • Chai YH, Elayer DT (1999) Lateral stability of reinforced concrete columns under axial reversed cyclic tension and compression. ACI Struct J 96:1–10

    Google Scholar 

  • Chrysanidis TA, Tegos IA (2012) The influence of tension strain of wall ends to their resistance against lateral instability for low-reinforced concrete walls. 15th World Conf Earthq Eng, Lisboa, Portugal

  • Corley WG, Fiorato AE, Oesterle RG (1981) Structural walls. ACI Spec Publ 72:77–131

  • Creagh A, Acevedo C, Moehle JP et al (2010) Seismic performance of concrete special boundary element. University of Texas at Austin and University of California Berkley, Austin, Berkley

    Google Scholar 

  • Dashti F, Dhakal RP, Pampanin S (2014a) Simulation of out-of-plane instability in rectangular RC structural walls. Second Eur Conf Earthq Eng Seismol, Istanbul, Turkey

  • Dashti F, Dhakal RP, Pampanin S (2014b) Numerical simulation of shear wall failure mechanisms. NZSEE Conf, Auckland, New Zealand

  • Elwood KJ (2013) Performance of concrete buildings in the 22 February 2011 Christchurch earthquake and implications for Canadian codes. Can J Civ Eng 40:759–776

    Article  Google Scholar 

  • Goodsir WJ (1985) The design of coupled frame-wall structures for seismic actions. University of Canterbury, Christchurch

    Google Scholar 

  • Johnson B (2010) Anchorage detailing effects on lateral deformation components of RC shear walls. University of Minnesota, Minneapolis

    Google Scholar 

  • NDI (2009) Optotrak Certus HD, Northern Digital Inc. http://www.ndigital.com/industrial/certushd.php

  • NIST (2014) Recommendations for seismic design of reinforced concrete wall buildings based on studies of the 2010 maule, Chile Earthquake. National Institute of Standards and Technology, U.S. Department of Commerce, Gaithersburg

    Google Scholar 

  • NSR-10 (2010) Reglamento Colombiano de Construcción Sismo Resistente—Comisión Asesora Permanente para el Règimen de Construcciones Sismo Resistentes. Bogotá D.C, Colombia

    Google Scholar 

  • Oesterle RG, Fiorato AE, Johal LS et al (1976) Earthquake resistant structural walls—tests of isolated walls. Portland Cement Association, Skokie

    Google Scholar 

  • Parra PF, Moehle JP (2014) Lateral buckling in reinforced concrete walls. Tenth US Natl Conf Earthq Eng, Anchorage, Alaska

  • Paulay T, Goodsir WJ (1985) The ductility of structural walls. Bull New Zeal Natl Soc Earthq Eng 18:250–269

    Google Scholar 

  • Paulay T, Priestley MJN (1992) Seismic design of reinforced concrete and masonry buildings. Wiley, Hoboken

    Book  Google Scholar 

  • Paulay T, Priestley MJN (1993) Stability of ductile structural walls. ACI Struct J 90:385–392

    Google Scholar 

  • Rosso A, Almeida JP, Constantin R et al (2014) Influence of longitudinal reinforcement layouts on RC walls performance. Second Eur Conf Earthq Eng Seismol, Istanbul, Turkey

  • Shea M, Wallace JW, Segura C (2013) Seismic performance of thin reinforced concrete shear wall boundaries. University of California, Los Angeles

    Google Scholar 

  • Sritharan S, Beyer K, Henry RS et al (2014) Understanding poor seismic performance of concrete walls and design implications. Earthq Spectra 30:307–334

    Article  Google Scholar 

  • Standards New Zealand (2006) Concrete structures standards, part 1: the design of concrete structures. Standards Association of New Zealand, Wellington

    Google Scholar 

  • Thomsen JH, Wallace JW (1995) Displacement based design of reinforced concrete structural walls: an experimental investigation of walls with rectangular and t-shaped cross-sections. Clarkson University, Postdam

    Google Scholar 

  • Timoshenko SP, Gere JM (1961) Theory of elastic stability. McGraw-Hill Book Company Inc, New York and London

    Google Scholar 

Download references

Acknowledgments

The testing of the test unit TW1 was financed through an EPFL Seed Money grant through the EPFL Cooperation & Development Center, which was awarded to the EESD group (PI) and the School of Engineering of Antioquia and the University of Medellin, in Colombia (Co-PIs). The reinforcement layout of the wall was designed by the Co-PIs Prof. Carlos Blandon and Prof. Ricardo Bonett. The first author is supported by the Swiss National Science Foundation (SNSF) grant 200021_132315 ’Seismic design and assessment of reinforced concrete core walls - Phase II‘. All contributions are gratefully acknowledged. The authors also thank all engineers, technicians and students who helped with the laboratory testing, in particular Dr. Ovidiu Prodan and Jose Rave Arango.

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Correspondence to Katrin Beyer.

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Rosso, A., Almeida, J.P. & Beyer, K. Stability of thin reinforced concrete walls under cyclic loads: state-of-the-art and new experimental findings. Bull Earthquake Eng 14, 455–484 (2016). https://doi.org/10.1007/s10518-015-9827-x

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