Chemical water stability in optimal operation of water distribution systems with blended desalinated water

TY - JOUR

T1 - Chemical water stability in optimal operation of water distribution systems with blended desalinated water

AU - Ostfeld, Avi

AU - Salomons, Elad

AU - Lahav, Ori

PY - 2011/12/16

Y1 - 2011/12/16

N2 - This work presents a model for the inclusion of chemical water stability in optimizing the operation of water distribution systems. When desalinated water is mixed with surface water and/or groundwater, the blend can become chemically unstable. Such a state can cause the phenomena of "red water," an increase in corrosion rates, and a reduction in disinfection efficiency. In this study, a methodology is developed that links a genetic algorithm, a hydraulic and water quality extended period simulator, a numerical scheme for computing the calcium carbonate precipitation potential (CCPP) [the quantitative measure of the precise thermodynamic potential of a solution to precipitate (or dissolve) CaCO3(s)], and the pH of the water. The model minimizes the cost of pumping and treatment subject to quantities, pressures, CCPP, and pH constraints. Two example applications are utilized for demonstrating the methodology capabilities. Although the model provides a new tool for the explicit inclusion of chemical water stability in optimal operation of water distribution systems, it overlooks variations in pump efficiency at operational points, does not constrain the number of pump switches, the minimum pump operation and off times, the durations between pump start and shutoff, and the plant or source capacity. Those limitations should be considered in possible extensions of this study.

AB - This work presents a model for the inclusion of chemical water stability in optimizing the operation of water distribution systems. When desalinated water is mixed with surface water and/or groundwater, the blend can become chemically unstable. Such a state can cause the phenomena of "red water," an increase in corrosion rates, and a reduction in disinfection efficiency. In this study, a methodology is developed that links a genetic algorithm, a hydraulic and water quality extended period simulator, a numerical scheme for computing the calcium carbonate precipitation potential (CCPP) [the quantitative measure of the precise thermodynamic potential of a solution to precipitate (or dissolve) CaCO3(s)], and the pH of the water. The model minimizes the cost of pumping and treatment subject to quantities, pressures, CCPP, and pH constraints. Two example applications are utilized for demonstrating the methodology capabilities. Although the model provides a new tool for the explicit inclusion of chemical water stability in optimal operation of water distribution systems, it overlooks variations in pump efficiency at operational points, does not constrain the number of pump switches, the minimum pump operation and off times, the durations between pump start and shutoff, and the plant or source capacity. Those limitations should be considered in possible extensions of this study.

KW - Chemical water stability

KW - Desalination

KW - Genetic algorithm

KW - Operation

KW - Optimization

KW - Water distribution systems

UR - http://www.scopus.com/inward/record.url?scp=83755220658&partnerID=8YFLogxK

U2 - 10.1061/(ASCE)WR.1943-5452.0000166

DO - 10.1061/(ASCE)WR.1943-5452.0000166

M3 - 文章

AN - SCOPUS:83755220658

VL - 137

SP - 531

EP - 541

JO - Journal of Water Resources Planning and Management - ASCE

JF - Journal of Water Resources Planning and Management - ASCE

SN - 0733-9496

IS - 6

ER -