Abstract
Microgrids are an increasingly relevant technology for integrating renewable energy sources into electricity systems. Based on a microgrid implementation in California, we investigate microgrid operation under real-world conditions. These conditions have not yet been considered in combination and encompass energy charges, demand charges, export limits, as well as uncertainty about future electricity demand and generation in the microgrid. Under these conditions, we evaluate the performance of two frequently applied groups of strategies for microgrid operation. The first group is composed of proactive strategies that optimize decisions based on forecasts of future electricity generation and demand. The second group includes reactive strategies that make operational decisions based exclusively on the current state of the microgrid. We evaluate the performance of the strategies under varying operational parameters, forecast accuracies, and microgrid configurations—well beyond our Californian showcase. Our results confirm the expectation that proactive strategies outperform reactive ones in the majority of settings. Yet, reactive strategies can perform better under short control intervals or under moderate prediction errors of PV generation or demand. Furthermore, the interplay between real-world conditions and operational strategies reveals several additional insights for research on microgrid operation. First, we find that demand charges and export limits decisively affect microgrid performance. Second, the impact of forecast errors is highly non-linear and non-monotonous. Third, escalating negative interactions between forecast errors and demand charges make proactive strategies benefit from longer control intervals. This result is contrary to existing best practice, which promotes short control intervals to minimize the impact of uncertainty.
| Original language | English |
|---|---|
| Pages (from-to) | 339-352 |
| Number of pages | 14 |
| Journal | European Journal of Operational Research |
| Volume | 292 |
| Issue number | 1 |
| DOIs | |
| Publication status | Published - 1 Jul 2021 |
Bibliographical note
Funding Information:Parts of this work have been financed by the Office of Electricity Delivery and Energy Reliability, Distributed Energy Program of the U.S. Department of Energy under Contract No. DE-AC02–05CH11231. Parts of this work are also supported by the U.S. Department of Defense via an ESTCP grant. Tobias Brandt was supported by a Ph.D. fellowship of the Foundation of German Business. Gunther Gust was supported by Ph.D. fellowships from the Heinrich-Boell-Foundation. We also want to thank Greg Vallery, director of public works at Fort Hunter Liggett, as well as Sankar Narayanan for their very valuable support. We furthermore want to acknowledge Ryan J. Grabowski and Tim Howells for their valuable contributions.
Funding Information:
Parts of this work have been financed by the Office of Electricity Delivery and Energy Reliability, Distributed Energy Program of the U.S. Department of Energy under Contract No. DE-AC02?05CH11231. Parts of this work are also supported by the U.S. Department of Defense via an ESTCP grant. Tobias Brandt was supported by a Ph.D. fellowship of the Foundation of German Business. Gunther Gust was supported by Ph.D. fellowships from the Heinrich-Boell-Foundation. We also want to thank Greg Vallery, director of public works at Fort Hunter Liggett, as well as Sankar Narayanan for their very valuable support. We furthermore want to acknowledge Ryan J. Grabowski and Tim Howells for their valuable contributions.
Publisher Copyright:
© 2020 Elsevier B.V.
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