Mass imbalances in EPANET water-quality simulations
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Published:2018-04-06
Issue:1
Volume:11
Page:25-47
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ISSN:1996-9465
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Container-title:Drinking Water Engineering and Science
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language:en
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Short-container-title:Drink. Water Eng. Sci.
Author:
Davis Michael J.,Janke Robert,Taxon Thomas N.
Abstract
Abstract. EPANET is widely employed to simulate water quality in water distribution
systems. However, in general, the time-driven simulation approach used to
determine concentrations of water-quality constituents provides accurate
results only for short water-quality time steps. Overly long time steps can
yield errors in concentration estimates and can result in situations in which
constituent mass is not conserved. The use of a time step that is
sufficiently short to avoid these problems may not always be feasible. The
absence of EPANET errors or warnings does not ensure conservation of mass.
This paper provides examples illustrating mass imbalances and explains how
such imbalances can occur because of fundamental limitations in the
water-quality routing algorithm used in EPANET. In general, these limitations
cannot be overcome by the use of improved water-quality modeling practices.
This paper also presents a preliminary event-driven approach that conserves
mass with a water-quality time step that is as long as the hydraulic time
step. Results obtained using the current approach converge, or tend to
converge, toward those obtained using the preliminary event-driven approach as
the water-quality time step decreases. Improving the water-quality routing
algorithm used in EPANET could eliminate mass imbalances and related errors
in estimated concentrations. The results presented in this paper should be of
value to those who perform water-quality simulations using EPANET or use the
results of such simulations, including utility managers and engineers.
Publisher
Copernicus GmbH
Subject
Pollution,Water Science and Technology,Civil and Structural Engineering
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