Modeling flexible generator operating regions via chance-constrained stochastic unit commitment
Modeling flexible generator operating regions via chance-constrained stochastic unit commitment
We introduce a novel chance-constrained stochastic unit commitment model to address uncertainty in renewables’ production in operations of power systems. For most thermal generators, underlying technical constraints that are universally treated as “hard” by deterministic unit commitment models are in fact based on engineering judgments, such that system operators can periodically request operation outside these limits in non-nominal situations, e.g., to ensure reliability. We incorporate this practical consideration into a chance-constrained stochastic unit commitment model, specifically by infrequently allowing minor deviations from the minimum and maximum thermal generator power output levels. We demonstrate that an extensive form of our model is computationally tractable for medium-sized power systems given modest numbers of scenarios for renewables’ production. We show that the model is able to potentially save significant annual production costs by allowing infrequent and controlled violation of the traditionally hard bounds imposed on thermal generator production limits. Finally, we conduct a sensitivity analysis of optimal solutions to our model under two restricted regimes and observe similar qualitative results.
309–326
Singh, Bismark
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Knueven, Bernard
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Watson, Jean-Paul
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11 July 2020
Singh, Bismark
9d3fc6cb-f55e-4562-9d5f-42f9a3ddd9a1
Knueven, Bernard
2403fa89-2752-4f3b-bec0-d7136f2fc1c3
Watson, Jean-Paul
c0a5fafd-6e34-420c-ab13-05d19bbb1e89
Singh, Bismark, Knueven, Bernard and Watson, Jean-Paul
(2020)
Modeling flexible generator operating regions via chance-constrained stochastic unit commitment.
Computational Management Science, 17, .
(doi:10.1007/s10287-020-00368-3).
Abstract
We introduce a novel chance-constrained stochastic unit commitment model to address uncertainty in renewables’ production in operations of power systems. For most thermal generators, underlying technical constraints that are universally treated as “hard” by deterministic unit commitment models are in fact based on engineering judgments, such that system operators can periodically request operation outside these limits in non-nominal situations, e.g., to ensure reliability. We incorporate this practical consideration into a chance-constrained stochastic unit commitment model, specifically by infrequently allowing minor deviations from the minimum and maximum thermal generator power output levels. We demonstrate that an extensive form of our model is computationally tractable for medium-sized power systems given modest numbers of scenarios for renewables’ production. We show that the model is able to potentially save significant annual production costs by allowing infrequent and controlled violation of the traditionally hard bounds imposed on thermal generator production limits. Finally, we conduct a sensitivity analysis of optimal solutions to our model under two restricted regimes and observe similar qualitative results.
Text
s10287-020-00368-3
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Accepted/In Press date: 10 April 2020
Published date: 11 July 2020
Identifiers
Local EPrints ID: 471298
URI: http://eprints.soton.ac.uk/id/eprint/471298
ISSN: 1619-697X
PURE UUID: f339b141-1c1f-418d-9cc0-1ed472d1fa61
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Date deposited: 02 Nov 2022 17:41
Last modified: 17 Mar 2024 04:16
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Author:
Bismark Singh
Author:
Bernard Knueven
Author:
Jean-Paul Watson
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