Affiliation:
1. Faculty of Engineering and Information Technology, University of Melbourne, Melbourne, VIC 3052, Australia
Abstract
The energy transition to wind and solar opens up opportunities for green hydrogen as wind and solar generation tend to bring electricity prices down to very low levels. We evaluate whether green hydrogen can integrate well with wind and solar PVs to improve the South Australian electricity grid. Green hydrogen can use membrane electrolysis plants during periods of surplus renewable energy. This hydrogen can then be electrified or used in industry. The green hydrogen system was analysed to understand the financial viability and technical impact of integrating green hydrogen. We also used system engineering techniques to understand the system holistically, including the technical, social, environmental, and economic impacts. The results show opportunities for the system to provide seasonal storage, grid firming, and reliability services. Financially, it would need changes to electricity rules to be viable, so at present, it would not be viable without subsidy.
Reference62 articles.
1. An analysis of Australia’s large scale renewable energy target: Restoring market confidence;Nelson;Energy Policy,2013
2. Australian renewable energy policy: Barriers and challenges;Byrnes;Renew. Energy,2013
3. The role of renewable energy in the global energy transformation;Gielen;Energy Strategy Rev.,2019
4. Parkinson, G. (2024, January 26). South Australias Stunning Aim to be Net 100 Percent Renewables by 2030. Available online: https://reneweconomy.com.au/south-australias-stunning-aim-to-be-net-100-per-cent-renewables-by-2030.
5. AEMO (2024, January 26). Quarterly Energy Dynamics Q4 2023. Available online: https://aemo.com.au/-/media/files/major-publications/qed/2023/quarterly-energy-dynamics-q4-2023.pdf?la=en.