A system dynamics-based life-cycle carbon footprint calculation model for integrated energy stations

In recent years, countries around the world have been placing increasing emphasis on energy saving and emission reduction. As part of the energy system, integrated energy stations play an important role in the low-carbon transition of the energy sector. However, most of the existing studies on carbon emissions from integrated energy stations focus on the operation phase or a single module within it and lack analysis and prediction of carbon emissions from all phases of the integrated energy station. In this paper, based on the perspective of life cycle assessment, system dynamics is used to establish a life cycle carbon emission model for integrated energy stations from four phases: production & materialization, construction, operation & maintenance, and disposal & recycling. This paper takes wind power integrated energy stations as an example, simulates the characteristics of the life cycle carbon emissions of integrated energy stations, and identifies the key factors affecting the carbon emissions. The simulation results show that the carbon emissions of the integrated energy station are mainly concentrated in the production and operation of the energy station, and the increase in the service life of the energy station will not have a significant impact on the total carbon emissions. This paper provides the theoretical guidance and decision-making basis for the formulation of low-carbon emission reduction measures for integrated energy stations.(c) 2023 The Author(s). Published by Elsevier Ltd. This is an open access article under the CC BY-NC-ND license (http://creativecommons.org/licenses/by-nc-nd/4.0/).