Modeling in the COVID-19 Pandemic: Overcoming the Water Sector’s Data Struggles to Realize the Potential of Hydraulic Models

AbstractHydraulic models can provide efficient and cost-effective ways for water utilities to evaluate changes in operating conditions (e.g., population dynamics, disasters), thereby increasing system resiliency during crises. Unfortunately, model development remains out of reach for many utilities...

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Bibliographic Details
Published in:Journal of water resources planning and management 2022-06, Vol.148 (6)
Main Authors: Tiedmann, Helena R, Spearing, Lauryn A, Sela, Lina, Kinney, Kerry, Kirisits, Mary Jo, Katz, Lynn E, Kaminsky, Jessica, Faust, Kasey M
Format: Article
Language:English
Subjects:
Case Studies
Case Study
Coronaviruses
COVID-19
Crises
Data collection
Disasters
Distribution
Emergency preparedness
Hydraulic models
Hydraulics
Modelling
Pandemics
Population dynamics
Standardization
Subsystems
Water
Water distribution
Water distribution systems
Water engineering
Water resources management
Water utilities
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Summary:AbstractHydraulic models can provide efficient and cost-effective ways for water utilities to evaluate changes in operating conditions (e.g., population dynamics, disasters), thereby increasing system resiliency during crises. Unfortunately, model development remains out of reach for many utilities because of high software costs, data needs, or personnel requirements. This study seeks to classify hydraulic modeling data needs, identify success factors and challenges associated with model development, and determine whether modeling a subzone of a larger water distribution network can provide useful insights during a crisis, specifically the COVID-19 pandemic. At the pandemic onset, we began developing a hydraulic model of the water distribution system of the University of Texas at Austin campus—a subsystem of the water distribution network of Austin, Texas—to understand how spatiotemporal changes in water demands impacted system performance. We found that the completed model can offer useful insight into the impacts of demand changes within the modeled subsystem (e.g., potential locations of water stagnation). However, the data collection and processing challenges encountered (e.g., siloed collection efforts, lack of standardization, lengthy processing) reflect barriers to model development and use. The amount of time required to gather and process the necessary data shows that model development cannot occur during a time-sensitive crisis, likely rendering any insight too late for use. Here, we make recommendations to address data-related challenges and support utilities in incorporating hydraulic modeling into emergency planning.
ISSN:0733-9496
1943-5452
DOI:10.1061/(ASCE)WR.1943-5452.0001561