Abstract
The ability to provide uninterrupted power to military installations is paramount in executing a country’s national defense strategy. Microgrid architectures increase installation energy resilience through redundant local generation sources and the capability for grid independence. However, deliberate attacks from near-peer competitors can disrupt the associated supply chain network, thereby affecting mission critical loads. Utilizing an integrated discrete-time Markov chain and dynamic Bayesian network approach, we investigate disruption propagation throughout a supply chain network and quantify its mission impact on an islanded microgrid. We propose a novel methodology and an associated metric we term “energy resilience impact” to identify and address supply chain disruption risks to energy security. The proposed methodology addresses a gap in the literature and practice where it is assumed supply chains will not be disrupted during incidents involving microgrids. A case study of a fictional military installation is presented to demonstrate how installation energy managers can adopt this methodology for the design and improvement of military microgrids. The fictional case study shows how supply chain disruptions can impact the ability of a microgrid to successfully supply electricity to critical loads throughout an islanding event.
Highlights
Academic Editors: Riccardo Patriarca, The United States (US) Department of Defense (DoD) considers the microgrid an essential building block for improving energy resilience across its installations [1]
We investigate the consequences of supply chain networks (SCNs) disruption to military microgrids operating under islanded conditions
We investigate the consequences of SCN disruption on two separate microgrid architectures to illustrate how an installation energy managers (IEMs) may utilize this method
Summary
Microgrids offer protection from power disruptions, whether natural or man-made, through the utilization of distributed energy resources (DERs) independent of the utility grid. Military installations, especially those in remote areas, are dependent on supply chain networks (SCNs) to ensure continuity of operations [2,3]. A microgrid can connect and disconnect from the [utility] grid to enable it to operate in both grid-connected or island mode” [7]. This commonly cited definition highlights the three main requirements that characterize a microgrid [8]: . From a systems engineering perspective, the microgrid encompasses the physical equipment and software and the people (e.g., operators, maintenance organizations, etc.) and processes required to ensure system operability [10,11]
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