What is it about?
Highlights • System Dynamics model covers supply, demand, electric vehicle, and energy storage. • Adaptive Particle Swarm Optimization is developed for mixing energy supply problem. • Simulation-optimization is performed under supply uncertainty and cost variation. • Total system cost and total emission can be minimized at a time. • Transitioning to 100% renewable energy only reduces 55% of total emissions.
Featured Image
Photo by Karsten Würth on Unsplash
Why is it important?
Reducing global warming is crucial for sustainability. Carbon emissions primarily stem from energy supply, prompting a shift from Non-Renewable Energy Supply (NRES) to Renewable Energy Supply (RES). However, transitioning to RES entails substantial investment and faces supply uncertainty due to weather dependency. Therefore, the transition should be done gradually, requiring a reliable approach to energy mix modeling. This study proposes a System Dynamics framework integrated with Adaptive Particle Swarm Optimization (APSO) and Machine Learning to optimize the energy mix under supply uncertainty. Due to energy system dynamicity, the proposed framework considers not only supply, but also demand, energy storage, electric vehicle, and emission subsystems. The experiment has been conducted by taking the United States as a case under various scenarios namely to minimize the total system cost, total carbon emissions, and both, accounting for the static and dynamic cost of RES. Results of this study reveal four main points: (i) A 38% reduction in total system cost is achievable by decreasing the RES Ratio to 6%, but total emissions will rise by 8%; (ii) A 55% reduction in total emissions is possible by directly transitioning to 100% RES, but total system cost increases by 68%; (iii) Both objective functions can be significantly minimized at a time by increasing the RES ratio; (iv) Dynamic cost offers a better opportunity for reducing costs and emissions than static cost.
Perspectives
Read the Original
This page is a summary of: Green energy mix modeling under supply uncertainty: Hybrid system dynamics and adaptive PSO approach, Applied Energy, November 2023, Elsevier,
DOI: 10.1016/j.apenergy.2023.121643.
You can read the full text:
Contributors
The following have contributed to this page