Potential of Onshore Wind Turbine Inertia in Decarbonising the Future Irish Energy System

• Published in: Applied sciences Vol. 12; no. 6; p. 2984
• Main Authors: Thiesen, Henning, Jauch, Clemens
• Format: Journal Article
• Language: English
• Published: Basel MDPI AG 01.03.2022
• Subjects: Alternative energy; Carbon dioxide; Costs; economic dispatch modelling; Economic models; Electricity distribution; Emissions; Energy; Energy sources; energy system modelling; Frequency stability; Generators; Industrial plant emissions; Inertia; Power plants; power system inertia; renewable energy; Renewable energy sources; Renewable resources; synthetic inertia; Systems stability; Turbines; Unit commitment; wind energy; Wind power; United Kingdom > UK; Ireland
• ISSN: 2076-3417; 2076-3417
• DOI: 10.3390/app12062984

Power system inertia is an essential part for grid frequency stability and decreases due to the replacement of fossil fuel fired power plants with variable renewable energy sources. This development is not represented sufficiently in unit commitment and economic dispatch models. If considered at all, only synchronous inertia from fossil fuel driven power plants is modelled. This results in increased CO2 emissions, curtailed renewable energy and high system costs. While wind turbines are a source for synthetic inertia and an important renewable energy source, their capability to provide inertia is not incorporated into energy system models. The work at hand closes this research gap and applies a methodology to depict synthetic inertia provided by wind turbines as part of the optimisation dispatch model. A unit commitment and economic inertia dispatch model of the the all-Island Irish power system is created. The potential of wind inertia is analysed and quantified by assessing CO2 emissions, curtailed renewable energy and system costs. Results show that synthetic inertia provided by wind turbines can save up 30.99% of the CO2 emissions, reduce curtailment by up to 39.90% and reduce system costs by 32.72%.