Super Gravity Dam Generalized Damage Study

Ya Jun Wang; Wo Hua Zhang

doi:10.4028/www.scientific.net/AMR.479-481.421

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HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 479-481Super Gravity Dam Generalized Damage Study

Super Gravity Dam Generalized Damage Study

Abstract:

Fuzzy sub-space, with analysis on generalized uncertainty of damage, is setup in this paper when topological consistency of damage fuzzy and randomness on [0,1] scale being demonstrated deeply. Furthermore, deduced under fuzzy characteristics translation are three fuzzy analytical models of damage functional, namely, half depressed distribution, swing distribution, combined swing distribution, by which, fuzzy extension territory on damage evolution is formulated here. With the representation of damage variable ß probabilistic distribution as well as formulation on stochastic sub-space of damage variable, expended on the basis of extension criterion and fuzzy probability is damage model defined within generalized uncertain space, by which, introduced is fuzzy probabilistic integral algorithm of generalized uncertain damage variable that could be simulated by the forthcoming fuzzy stochastic damage constitution model based on three fuzzy functional models before. Moreover, in order to realize the joint of fuzzy input and output procedure on generalized uncertain damage variable calculation, fuzzy self-adapting stochastic damage reliability algorithm is, with the update on fuzzy stochastic finite element method within standard normal distribution probabilistic space by the help of foregoing fuzzy stochastic damage constitution model, offered in this paper on the basis of equivalent-normalization and orthogonal design theory. 3-dimension fuzzy stochastic damage mechanical status of numerical model of Longtan Rolled-Concrete Dam is researched here by fuzzy stochastic damage finite element method program under property authority. Random field parameters’ statistical dependence and non-normality are considered comprehensively in fuzzy stochastic damage model of this paper, by which, damage uncertainty’s proper development and conception expansion as well as fuzzy and randomness of mechanics are hybridized overall in fuzzy stochastic damage analysis process.

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Periodical:

Advanced Materials Research (Volumes 479-481)

Pages:

421-425

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.479-481.421

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Online since:

February 2012

Authors:

Ya Jun Wang, Wo Hua Zhang

Keywords:

Fuzzy Stochastic Damage Finite Element Method, Fuzzy Stochastic Damage Reliability, Super Gravity Dam

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