Original article by Matt Shipman at University Communications. Photo credit: Michael Fousert
FOR IMMEDIATE RELEASE
Leila Hajibabai | lhajiba@ncsu.edu
Matt Shipman | matt_shipman@ncsu.edu
Researchers from North Carolina State University have developed a computational model that can be used to determine the optimal places for locating electric vehicle (EV) charging facilities, as well as how powerful the charging stations can be without placing an undue burden on the local power grid.
“Ultimately, we feel the model can be used to inform the development of EV charging infrastructure at multiple levels, from projects aimed at supporting local commuters to charging facilities that serve interstate highway travel,” says Leila Hajibabai, corresponding author of a paper on the work and an assistant professor in NC State’s Fitts Department of Industrial and Systems Engineering.
Identifying the best sites for charging facilities is a complicated process, since it has to account for travel flow and user demand, as well as the needs of the regional power infrastructure. In other words, where will people use it? And can it be supported by the power grid?
“We have developed a model that allows planners to optimize these decisions, serving the greatest number of people without taxing the power system,” Hajibabai says.
While a lot of work has been done on how to deploy EV charging facilities, the researchers found that most previous efforts focused on siting these facilities based on what would work best for the power system, or what would work best from a transportation standpoint.
“Very little work has been done that addresses both,” Hajibabai says. “And those cases that looked at both power and transportation systems did not take into account the decisions that users make. Where do they want to charge their vehicles? What are their travel plans?
“The best location for a charging facility from the power system’s standpoint is often not the best location from a transportation systems standpoint. And the best location from a user’s standpoint is often a third option. Our model looks at power systems, transportation systems and user decision-making in order to find the best compromise.”
The power system component of the model accounts for the limitations of the power distribution network – its power flow, voltage, current and so on. The transportation component of the overarching model accounts for the number of travelers, the routes that they take when traveling, and how far their vehicles can go before they need to be recharged. To account for user decision-making, the model tries to identify locations that will minimize travel time for users.
“People often don’t want to go out of their way to charge their vehicles, so our model takes that into account,” Hajibabai says.
The researchers are currently in discussions with state and local government officials, as well as power utilities, to use the model to inform the development of EV charging infrastructure in North Carolina.
The paper, “Joint Power Distribution and Charging Network Design for Electrified Mobility with User Equilibrium Decisions,” is published open access in the journal Computer-Aided Civil and Infrastructure Engineering. The paper was co-authored by Asya Atik, a Ph.D. student at NC State, and Amir Mirheli, a former Ph.D. student at NC State.
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Note to Editors: The study abstract follows.
“Joint Power Distribution and Charging Network Design for Electrified Mobility with User Equilibrium Decisions”
Authors: Leila Hajibabai, Asya Atik and Amir Mirheli, North Carolina State University
Published: June 6, Computer-Aided Civil and Infrastructure Engineering
DOI: 10.1111/mice.12854
Abstract: Rapid adoption of electric vehicles (EVs) requires the development of a highly flexible charging network. The design and management of the charging infrastructure for EV-dominated transportation systems are intertwined with power grid operations both economically and technically. High penetration of EVs in the future can increase the charging loads and cause a wide range of operational issues in power distribution networks (PDNs). This paper aims to design an EV charging network with an embedded PDN layout to account for energy dispatch and underlying traffic flows in urban transportation networks supporting electric mobility in the near future. A mixed-integer bi-level model is proposed with the EV charging facility location and PDN energy decisions in the upper level and user equilibrium traffic assignment in the lower level considering an uncertain charging demand. The objective is to minimize the cost of PDN operations, charging facility deployments, and transportation. The proposed problem is solved using a column and constraint generation algorithm, while a macroscopic fundamental diagram concept is implemented to estimate the arc travel times. The methodology is applied to a hypothetical and two real-world case study networks, and the solutions are compared to a Benders decomposition benchmark. The east-coast analysis results indicate a 77.3% reduction in the computational time. Additionally, the benchmark technique obtains an optimality gap of 1.15%, while the C&CG algorithm yields a 0.61% gap. The numerical experiments show the robustness of the proposed methodology. Besides, a series of sensitivity analyses has been conducted to study the impact of input parameters on the proposed methodology and draw managerial insights.