Optimal investment and operation of a microgrid to provide electricity and heat

Jorge L Angarita; Hossein Jafari; Mojtaba Mohseni; Ameena Saad Al‐Sumaiti; Ehsan Heydarian‐Forushani; Rajesh Kumar

doi:10.1049/rpg2.12190

IET Renewable Power Generation (Sep 2021)

Optimal investment and operation of a microgrid to provide electricity and heat

Jorge L Angarita,
Hossein Jafari,
Mojtaba Mohseni,
Ameena Saad Al‐Sumaiti,
Ehsan Heydarian‐Forushani,
Rajesh Kumar

Affiliations

Jorge L Angarita: Faculty of Engineering and Informatics University of Bradford Richmond Rd Bradford BD7 1DP UK
Hossein Jafari: Department of Electrical Engineering Amirkabir University of Technology Hafez Ave Tehran Iran
Mojtaba Mohseni: Department of Electrical Engineering Amirkabir University of Technology Hafez Ave Tehran Iran
Ameena Saad Al‐Sumaiti: Advanced Power and Energy Center Khalifa University of Science and Technology P O Box 127788 Abu Dhabi United Arab Emirates
Ehsan Heydarian‐Forushani: Department of Electrical and Computer Engineering Qom University of Technology Qom Iran
Rajesh Kumar: Department of Electrical Engineering Malaviya national Institute of Technology Jaipur India

DOI: https://doi.org/10.1049/rpg2.12190
Journal volume & issue: Vol. 15, no. 12
pp. 2586 – 2595

Abstract

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Abstract This paper proposes a robust investment and operation model to attend the power and heat needs of a microgrid (MG) connected to the distribution system. The optimization algorithm decides on the best investment and operation of combined heat and power (CHP), boilers, PV power generation and battery energy storage systems (BESS). For the BESS, the algorithm estimates the optimal energy storage capacity (MWh) as well as the maximum hourly delivery capacity (MW). The non‐linear and non‐concave heat rate chart is recast by a mix‐integer linear model to have a tractable and precise model. The model considers the uncertain in some parameters using probability density function (pdf) to portrait its behavior. Thus, the problem has been modeled using stochastic programming approach, and its objective function is the expected value of the annual operational cost. The model is tested using a real case where two adjacent consumers share the power and heat facilities to minimize the overall up to 17% depending on the gas price scenario. The results demonstrate the benefits of employing different technologies and the synergies of all technologies operating together.

Published in IET Renewable Power Generation

ISSN: 1752-1416 (Print); 1752-1424 (Online)
Publisher: Wiley
Country of publisher: United Kingdom
LCC subjects: Technology: Mechanical engineering and machinery: Renewable energy sources
Website: https://ietresearch.onlinelibrary.wiley.com/journal/17521424

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