Modeling Time-varying Reliability and Resilience of Deteriorating Infrastructure

•Modeling of the physical state and functionality of deteriorating infrastructure.•Effects of deterioration on the ability of infrastructure to recover after shocks.•Incorporating the governing physical laws in the proposed formulation.•Emphasis on the modeling of potable water infrastructure.•Examp...

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Vydané v:Reliability engineering & system safety Ročník 217; s. 108074
Hlavní autori: Iannacone, Leandro, Sharma, Neetesh, Tabandeh, Armin, Gardoni, Paolo
Médium: Journal Article
Jazyk:English
Vydavateľské údaje: Barking Elsevier Ltd 01.01.2022
Elsevier BV
Predmet:
Deterioration
Drinking water
Infrastructure
Modelling
Physics-based models
Recovery
Reliability aspects
Reliability engineering
Resilience
Service life
Spatial variations
Structural hierarchy
Water Infrastructure
Water supply systems
Physics-based models
Deterioration
Recovery
Water Infrastructure
Resilience
ISSN:0951-8320, 1879-0836
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Shrnutí:•Modeling of the physical state and functionality of deteriorating infrastructure.•Effects of deterioration on the ability of infrastructure to recover after shocks.•Incorporating the governing physical laws in the proposed formulation.•Emphasis on the modeling of potable water infrastructure.•Example: Reliability, resilience analysis of water infrastructure of Seaside OR. The spatial and temporal extent of disruptions to services provided by infrastructure following disruptive events is directly related to the instantaneous state of the infrastructure and their post-disruption recovery. This paper develops a novel formulation to model the effects of infrastructure deterioration on their time-varying ability to recover after disruptive events. By unifying available models for deterioration and recovery, the paper proposes a general formulation to model the physical state and functionality of deteriorating infrastructure throughout its service life. The paper further develops resilience measures to quantify the temporal and spatial variations of infrastructure's ability to recover after disruptive events. The proposed formulation has a hierarchical structure that enables exploiting readily available data at the lower level of hierarchy to improve the prediction capability of models at the infrastructure level. Incorporating the governing physical laws in the proposed formulation also enables customizing the models to emulate the reality of infrastructure deterioration and recovery. While the formulation is general, the emphasis is on modeling potable water infrastructure as a case in which the deterioration of pipelines grows mostly undetectable until extensively developed. By the time the deterioration becomes visible, a substantial portion of the infrastructure service life has already been depleted, and costly repair or replacement would be inevitable. To illustrate, the proposed formulation has been implemented to model the time-varying reliability and resilience of the potable water infrastructure of the city of Seaside in Oregon, United States. The example highlights the effects of spatially varying exposure conditions and pipelines’ age on the reliability, functionality, recovery, and resilience of the potable water infrastructure.
Bibliografia:ObjectType-Article-1
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content type line 14
ISSN:0951-8320
1879-0836
DOI:10.1016/j.ress.2021.108074