H41G-1462
Optimization of urban water supply portfolios combining infrastructure capacity expansion and water use decisions
Thursday, 17 December 2015
Poster Hall (Moscone South)
Caetano Coelho Silva Fraga1, Josue Medellin-Azuara2, Guilherme Marques3 and Carlos A Mendes1,3, (1)UFRGS Federal University of Rio Grande do Sul, Rio Grande, Brazil, (2)University of California Davis, civil and environmental engineering, Davis, CA, United States, (3)Institute of Hydraulic Research UFGRS, Porto Alegre, Brazil
Abstract:
The expansion and operation of urban water supply systems under rapidly growing demands, hydrologic uncertainty, and scarce water supplies requires a strategic combination of various supply sources for added reliability, reduced costs and improved operational flexibility. The design and operation of such portfolio of water supply sources merits decisions of what and when to expand, and how much to use of each available sources accounting for interest rates, economies of scale and hydrologic variability. The present research provides a framework and an integrated methodology that optimizes the expansion of various water supply alternatives using dynamic programming and combining both short term and long term optimization of water use and simulation of water allocation. A case study in Bahia Do Rio Dos Sinos in Southern Brazil is presented. The framework couples an optimization model with quadratic programming model in GAMS with WEAP, a rain runoff simulation models that hosts the water supply infrastructure features and hydrologic conditions. Results allow (a) identification of trade offs between cost and reliability of different expansion paths and water use decisions and (b) evaluation of potential gains by reducing water system losses as a portfolio component. The latter is critical in several developing countries where water supply system losses are high and often neglected in favor of more system expansion. Results also highlight the potential of various water supply alternatives including, conservation, groundwater, and infrastructural enhancements over time. The framework proves its usefulness for planning its transferability to similarly urbanized systems.