Publication detail

Industrial water network vulnerability analysis using dynamic inoperability input-output model

Zhang, Y., Li, Z., Aviso, K.B., Jia, X.X., Zhang, P., Tan, R.R., Klemeš, J.J., Wang, F., Jia, X.

Original Title

Industrial water network vulnerability analysis using dynamic inoperability input-output model

Type

journal article in Web of Science

Language

English

Original Abstract

Industrial parks provide opportunities for Process Integration among different enterprises. Inter-Plant Water Network Integration is an effective strategy for water conservation. However, increased interplant linkages can make the entire system vulnerable to cascading failures in case of loss of water flow in some plants. The potential indirect impact of water shortages on such integrated systems may not be evident without the use of appropriate models. This work defines inoperability as the fractional loss of water flow relative to normal operations. A comparison between the applicability of demand-driven versus supply-driven Inoperability Input-output Model (IIM) is conducted. Then, a Vulnerability Assessment Framework which integrates vulnerability indicators into the Dynamic Input-Output Model (DIIM) is developed to analyse failure propagation in water networks in an industrial park. The DIIM is then applied to simulate the cascading effects of disturbances. From a time perspective, the vulnerabilities of the industrial parks With Integrated Optimal Water Network (WWN) and Without Integrated Optimal Water Network (WOWN) are assessed considering robustness, adaptability, and recoverability as the indicators. The results indicate that supply-driven IIM is more suitable for cascading failure analysis of water networks. The average inoperability at 16% from supply-driven IIM is higher than that from demand-driven IIM. In the freshwater disturbance scenario, the dependence of the plant on freshwater is proportional to the rate of inoperability change, the time to reach a new equilibrium. In this study, the robustness of WWN is about fivefold that of WOWN, but the recovery rate is only one-sixth of the latter. This work can help identify system vulnerabilities and provide a scientific insight for the development of park-wide water management strategies.

Keywords

Cascade effect; Dynamic inoperability input-output model; Sustainability management; Vulnerability; Water network

Authors

Zhang, Y., Li, Z., Aviso, K.B., Jia, X.X., Zhang, P., Tan, R.R., Klemeš, J.J., Wang, F., Jia, X.

Released

15. 6. 2022

Publisher

Elsevier Ltd.

ISBN

0301-4797

Periodical

JOURNAL OF ENVIRONMENTAL MANAGEMENT

Number

314

State

United Kingdom of Great Britain and Northern Ireland

Pages from

115015

Pages to

115015

Pages count

10

URL

BibTex

@article{BUT177597,
  author="Xuexiu {JIA} and Jiří {Klemeš}",
  title="Industrial water network vulnerability analysis using dynamic inoperability input-output model",
  journal="JOURNAL OF ENVIRONMENTAL MANAGEMENT",
  year="2022",
  number="314",
  pages="115015--115015",
  doi="10.1016/j.jenvman.2022.115015",
  issn="0301-4797",
  url="https://www.sciencedirect.com/science/article/pii/S0301479722005886"
}