Integrating life cycle sustainability assessment in power flow optimization

Integrating life cycle sustainability assessment in power flow optimization

The electric power network management is an important field of improving to achieve sustainability. Optimal Power Flows (OPFs) allow the efficient operation of the system. However, OPF algorithms only consider the operation stage of the power plants involved in the power system, neglecting the rest...

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Bibliographic Details
Published in:Sustainable Energy, Grids and Networks Vol. 39; p. 101412
Main Authors: Hallste, Teresa, Guerrero, José M., Reina, Pablo, Conde, Eduardo
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-09-2024
Subjects:
Electricity production
Energy transition
Life Cycle Sustainability Assessment
Multi-objective optimization
Optimal Power Flow
Optimal Power Flow
Life Cycle Sustainability Assessment
Multi-objective optimization
Electricity production
Energy transition
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Summary:The electric power network management is an important field of improving to achieve sustainability. Optimal Power Flows (OPFs) allow the efficient operation of the system. However, OPF algorithms only consider the operation stage of the power plants involved in the power system, neglecting the rest of stages of its life cycle. To evaluate the total effects of the power generation mix, this work develops a methodology to perform a Multi-Objective OPF (MOOPF) with impact variables in electrical systems that integrate different generation technologies. These variables result from the application of a Life Cycle Sustainability Assessment (LCSA), consisting in environmental, economic, and social indexes with “cradle-to-grave” dimensions. To achieve this objective, the MOOPF is carried out operating a MATLAB algorithm over the IEEE57 bus system. It uses the ɛ-constraint method subject to the imposition of two or three impact variables. To examine the applications of this work, several simulations are performed optimizing different impact variables. Two different Spanish electricity scenarios are considered: the 2019 generation, and the 2030 objective generation proposed by the Spanish National Energy and Climate Plan. This tool broadens the scope of MOOPF assessment that can be used in a decision-making process. It allows to identify important environmental, economic, and social affections derived from system designs and limits. The study proves that the application of LCSA with MOOPF obtains realistic results making sustainability solutions technically viable. Additionally, different benefits and drawbacks, linked to the studied scenarios and grid disposition, are compared when conducting the proposed methodology for hourly generation management. [Display omitted]
ISSN:2352-4677
2352-4677
DOI:10.1016/j.segan.2024.101412