Automatic Multi-Objective Sectorization of A Water Distribution Network

被引:32
作者
De Paola, F. [1 ]
Fontana, N. [2 ]
Galdiero, E. [1 ]
Giugni, M. [1 ]
Saviec, D. [3 ]
degli Uberti, G. Sorgenti [4 ]
机构
[1] Univ Naples Federico II, Dept Civil Architectural & Environm Engn, Naples, Italy
[2] Univ Sannio, Dept Engn, Benevento, Italy
[3] Univ Exeter, Ctr Water Syst, Exeter, Devon, England
[4] ABC Azienda Speciale, Naples, Italy
来源
16TH WATER DISTRIBUTION SYSTEM ANALYSIS CONFERENCE (WDSA2014): URBAN WATER HYDROINFORMATICS AND STRATEGIC PLANNING | 2014年 / 89卷
关键词
District Metered Areas; water distribution network sectorization; multi-objective optimization; pressure management; water losses; GENETIC ALGORITHM; ENERGY-PRODUCTION; LOSSES REDUCTION; CREATION;
D O I
10.1016/j.proeng.2014.11.250
中图分类号
X [环境科学、安全科学];
学科分类号
08 ; 0830 ;
摘要
This paper deals with optimization of Water Distribution Networks (VVDNs) by establishing District Metered Areas (DMAs). A methodological approach for the automatic partitioning of a WDN into DMAs is presented and discussed. Several design criteria are taken into account for the definition of the problem objectives and constraints. The optimization methodology applies adjustable weights to various objectives to allow flexible decisions to be made. The proposed approach combines graph theory and an evolutionary multi -objective algorithm, whose parameters were calibrated through extensive tests. The results of the application to a real case study are presented, as well. (C) 2014 The Authors. Published by Elsevier Ltd.
引用
收藏
页码:1200 / 1207
页数:8
相关论文
共 23 条
[1]   A heuristic procedure for the automatic creation of district metered areas in water distribution systems [J].
Alvisi, S. ;
Franchini, M. .
URBAN WATER JOURNAL, 2014, 11 (02) :137-159
[2]  
De Paola F., 2013, P 12 INT C COMP CONT
[3]   A fast and elitist multiobjective genetic algorithm: NSGA-II [J].
Deb, K ;
Pratap, A ;
Agarwal, S ;
Meyarivan, T .
IEEE TRANSACTIONS ON EVOLUTIONARY COMPUTATION, 2002, 6 (02) :182-197
[4]  
Deb K., 1995, Complex Systems, V9, P115
[5]   Water network sectorization based on a genetic algorithm and minimum dissipated power paths [J].
Di Nardo, A. ;
Di Natale, M. ;
Santonastaso, G. F. ;
Tzatchkov, V. G. ;
Alcocer-Yamanaka, V. H. .
WATER SCIENCE AND TECHNOLOGY-WATER SUPPLY, 2013, 13 (04) :951-957
[6]  
Di Nardo A., 2011, P 11 INT C COMP CONT
[7]   A heuristic design support methodology based on graph theory for district metering of water supply networks [J].
Di Nardo, Armando ;
Di Natale, Michele .
ENGINEERING OPTIMIZATION, 2011, 43 (02) :193-211
[8]   Automated Creation of District Metered Area Boundaries in Water Distribution Systems [J].
Diao, Kegong ;
Zhou, Yuwen ;
Rauch, Wolfgang .
JOURNAL OF WATER RESOURCES PLANNING AND MANAGEMENT, 2013, 139 (02) :184-190
[9]   Graph-Theoretic Approach and Sound Engineering Principles for Design of District Metered Areas [J].
Ferrari, Giada ;
Savic, Dragan ;
Becciu, Gianfranco .
JOURNAL OF WATER RESOURCES PLANNING AND MANAGEMENT, 2014, 140 (12)
[10]   ALGORITHM-97 - SHORTEST PATH [J].
FLOYD, RW .
COMMUNICATIONS OF THE ACM, 1962, 5 (06) :345-345
123