2021
DOI: 10.1109/access.2021.3085410
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Resilience-Oriented Behind-the-Meter Energy Storage System Evaluation for Mission-Critical Facilities

Abstract: Immunization of mission-critical facilities such as hospitals and first responders against power outages is crucial for the operators due to their significant value of the lost load, affecting citizens' lives. This paper proposes a novel evaluating framework which enables facility operators to efficiently size and optimally dispatch their behind-the-meter energy storage systems (BTM-ESS) for resiliency purposes during grid emergencies. The proposed framework, formulated as a mixed integer linear programming mo… Show more

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Cited by 10 publications
(3 citation statements)
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“…The intermittent nature of these renewable sources, however, requires adoption of energy storage in a power grid (both at the distribution and bulk levels). Energy storage is a flexible asset that can help a network to reduce renewable power curtailment and the congestion at peak times, enhance resilience, and be a clean power source for ancillary services [2], [3]. Reduced peak demand and congestion at a network lead to reduced or deferred infrastructure investments, thus helping reduce the overall cost of energy.…”
Section: A Background and Problem Descriptionmentioning
confidence: 99%
“…The intermittent nature of these renewable sources, however, requires adoption of energy storage in a power grid (both at the distribution and bulk levels). Energy storage is a flexible asset that can help a network to reduce renewable power curtailment and the congestion at peak times, enhance resilience, and be a clean power source for ancillary services [2], [3]. Reduced peak demand and congestion at a network lead to reduced or deferred infrastructure investments, thus helping reduce the overall cost of energy.…”
Section: A Background and Problem Descriptionmentioning
confidence: 99%
“…To illustrate, 46% to 61% of the annual electricity is consumed for cooling purposes, as the building simulations of eight residential and commercial buildings demonstrated . Up to date, the strategies have not included human-building interactions (HBIs) (Labanca and Bertoldi, 2018), although residents indirectly and directly interact with equipment and buildings (Angizeh et al, 2021) (Zaidan and Abulibdeh, 2021). Accordingly, performance gaps are a result of non-including human factors in energy decision-making (Bertoldi, 2019) (Jafari et al, 2020) (Zaidan, Al-Saidi and Hammad, 2019).…”
Section: Introductionmentioning
confidence: 99%
“…Unfortunately, although a crucial factor, efforts that directly address human-building interactions (HBIs) are still not among the dominant strategies in the field (Labanca and Bertoldi, 2018). Undoubtedly, occupants, directly and indirectly, interact with the building environment and equipment (Angizeh et al, 2021a); therefore, failures to incorporate human dimensions into energy decision-making derail efforts and create performance gaps (Bertoldi, 2019;Jafari et al, 2020). This fat makes HBIs one of the strongest links in the building energy efficiency and conservation equation (B and Lalanne, 2017).…”
mentioning
confidence: 99%