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Leak detection in a branched system by inverse transient analysis with the admittance matrix method

Version 2 2024-06-05, 04:31
Version 1 2019-06-26, 12:58
journal contribution
posted on 2024-06-05, 04:31 authored by C Capponi, M Ferrante, AC Zecchin, James GongJames Gong
© 2017, Springer Science+Business Media Dordrecht. The diagnosis of water distribution systems by means of the inverse transient analysis requires efficient and reliable numerical models. In the network admittance matrix method (NAMM) the 1-D waterhammer governing equations are integrated in the frequency domain and organized in a laplacian matrix form. The NAMM is particularly suitable for complex systems because of this structure and can be used for the system diagnosis, including leak sizing and location. In this paper a damaged branched system is considered and the diagnosis is performed by means of the NAMM using experimental data from laboratory transient tests. Two different boundary conditions are used in the implementation of the NAMM and the leak is located and sized with a reasonable approximation. An extended numerical investigation is also presented and allows confirmation of the results for different leak locations. The use of the NAMM for the leak detection and the validation using experimental data on a branched system are the main original contributions of this work. The successful diagnosis indicates promising results for applications in more complex systems.

History

Journal

Water resources management

Volume

31

Pagination

4075-4089

Location

Dordrecht, The Netherlands

ISSN

0920-4741

eISSN

1573-1650

Language

eng

Publication classification

C1.1 Refereed article in a scholarly journal

Copyright notice

2017, Springer Science+Business Media Dordrecht

Issue

13

Publisher

Springer

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