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Abstract

Recent earthquakes have shown that wine barrel stacks are highly susceptible to collapse, leading to large economic losses, downtime, and longer recovery periods. This study presents a methodology using a probabilistic approach for estimating the fragility functions and economic losses in barrel stacks. The seismic response of these systems was determined from the dynamic equilibrium equations that describe the position and orientation of each element. The analysis considered ground motions scaled at different intensity levels and different barrel stack configurations; the simulations enabled reproducing the most common collapse mechanisms observed in the field and in shaking table experiments. From a statistical analysis of the results, vulnerability functions were evaluated as the probability of being within a specific damage state for a given ground motion intensity. Additional numerical simulations were performed to study the effects of the inherent uncertainty of the interface parameters controlling the dynamic response and collapse sequence of the barrel stacks. Furthermore, this methodology was used to evaluate the impact effect and improvement of a base isolation solution as a damage mitigation measure.

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References

Al Atik

, and Abrahamson

, 2010. An improved method for nonstationary spectral matching, Earthquake Spectra 26, 601–617.

Allen

R. H.

, Oppenheim

I. J.

, Parker

A. R.

, and Bielak

, 1986. On the dynamic response of rigid body assemblies, Earthquake Engineering & Structural Dynamics 14, 861–876.

Candia

, De la Llera

, and Almazán

, 2008. Earthquake simulation and response of wine barrel stacks, in Proceedings of the 14th World Conference on Earthquake Engineering, 12–17 October 2008, Beijing, China.

Candia

, De la Llera

, and Almazán

, 2010. A physical model for dynamic analysis of wine barrel stacks, Earthquake Engineering & Structural Dynamics 39, 1063–1081.

Chadwell

C. B.

, Stanley

J. M.

, and Marrow

J. M.

, 2006. Nonlinear analytical modeling and system verification of a wine barrel on a portable steel rack subject to seismic excitation, 8th U.S. National Conference on Earthquake Engineering, San Francisco, Ca, U.S.A., Paper No. 1604.

Galloway

, and Ingham

, 2015. The 2014 South Napa earthquake and its relevance for New Zealand, SESOC Journal 28, 69–94.

Herrera

, Beltrán

, Garcés

, Almazán

J. L.

, Sandoval

, González

, Costa

, and Middleton

, 2011. Manual de buenas prácticas y recomendaciones sísmicas para equipos de bodegas viníferas. Ediciones Consorcios del Vino, Registro de Propiedad Intelectual, 206.947.

Hormann

, and Agathos

, 2001. The point in polygon problem for arbitrary polygons, Computational Geometry 20, 131–144.

Housner

G. W.

, 1963. The behavior of inverted pendulum structures during earthquakes, Bulletin of the Seismological Society of America 53, 403–417.

10.

Kounadis

A. N.

, 2015. On the rocking complex response of ancient multispondyle columns: a genious and challenging structural system requiring reliable solution, Meccanica 50, 261–292.

11.

Makris

, and Roussos

, 1998. Rocking Response and Overturning of Equipment Under Horizontal Pulse-Type Motions, PEER Report 1998/05, Pacific Earthquake Engineering Research Center, University of California, Berkeley, 76 pp.

12.

Makris

, and Konstantinidis

, 2003. The rocking spectrum and the limitations of practical design methodologies, Earthquake Engineering & Structural Dynamics 32, 265–289.

13.

Marrow

, 2000. Earthquake Reconnaissance Report – 2000 Yountville Earthquake: Implications for the California Wine Industry, Simpson Gumpertz & Heger, Inc., Publication, San Francisco, CA.

14.

Marrow

J. M.

, 2001. Experimental Studies on the Earthquake Performance of Wine Barrel Stacks, M.S. Dissertation, University of California, Berkeley.

15.

Marrow

J. M.

, 2002. The seismic vulnerability of the California wine industry – An experimental assessment, 2002 Structural Engineer's Association of California Annual Convention, Santa Barbara, CA.

16.

Marulanda

M. C.

, Carreño

M. L.

, Cardona

O. D.

, Ordaz

M. G.

, and Barbat

A. H.

, 2013. Probabilistic earthquake risk assessment using CAPRA: application to the city of Barcelona, Spain, Natural Hazards 69, 59–84.

17.

Newmark

N. M.

, and Hall

W. J.

, 1982. Earthquake Spectra and Design: Engineering Monographs on Earthquake Criteria, Structural Design, and Strong Motion Records, Earthquake Engineering Research Institute Monograph, Oakland, CA.

18.

Shabana

A. A.

, 2009. Computational Dynamics, Third Edition, John Wiley & Sons, New York.

19.

Spanos

P. D.

, Roussis

P. C.

, and Politis

N. P.

, 2001. Dynamic analysis of stacked rigid blocks. Soil Dynamics and Earthquake Engineering 21, 559–578.

20.

Yim

C. S.

, Chopra

A. K.

, and Penzien

, 1980. Rocking response of rigid blocks to earthquakes, Earthquake Engineering & Structural Dynamics 8, 565–587.

21.

Zareian

, Sampere

, Sandoval

, McCormick

, Moehle

, and Leon

, 2012. Reconnaissance of the Chilean wine industry affected by the 2010 Chile offshore Maule earthquake, Earthquake Spectra 28, S503–S512.

22.

Zhang

, and Makris

, 2001. Rocking response of free-standing blocks under cycloidal pulses, Journal of Engineering Mechanics 127, 473–483.

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Seismic Vulnerability of Wine Barrel Stacks

Abstract

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