Synergies between Carnot battery and power-to-methanol for hybrid energy storage and multi-energy generation

• Published in: Journal of cleaner production Vol. 430; p. 139548
• Main Authors: Qi, Meng, Cui, Chengtian, Yu, Haoshui, He, Tianbiao, Zhao, Dongfeng
• Format: Journal Article
• Language: English
• Published: Elsevier Ltd 10.12.2023
• Subjects: CO2 energy storage; Design and scheduling optimization; Multi-energy generation; Power-to-methanol; System integration; Techno-economic analysis; Techno-economic analysis; Design and scheduling optimization; Power-to-methanol; Multi-energy generation; CO2 energy storage; System integration
• ISSN: 0959-6526; 1879-1786
• DOI: 10.1016/j.jclepro.2023.139548

Power-to-methanol (PtMe) technologies and Carnot batteries are two promising approaches for large-scale energy storage. However, the current low efficiency and inadequate profitability of these two technologies, especially concerning green methanol production, pose challenges for their industrial implementation. One solution is to integrate these two technologies to augment the material and energy utilization efficiency through dynamic operational coordination and multi-energy production. This study systematically investigates the synergies of integrating CO2 energy storage (CES) and PtMe for combined heating, power, and methanol generation, aiming to enhance system's efficiency and economic viability. In this context, a novel hybrid energy-driven polygeneration system (CES-PtMe) is developed, featuring a highly integrated methanol production process and a newly proposed CES configuration with heating input and output capabilities. Detailed system simulations assess its performance under steady state, while nonlinear programming models are formulated for optimal storage sizing and energy scheduling considering fluctuating renewable energy. Various scenarios are set to examine the techno-economic potential of the CES-PtMe system, using renewable data from Gansu, China as a case study. The results indicate that the system can achieve a high efficiency of nearly 80% with a renewable penetration exceeding 77%. By incorporating optimal energy scheduling throughout the year, the system shows economic viability in the context of the current fossil energy market. While it has a limited ability to meet user energy demands, the proposed system retains economic benefits compared to standalone technologies. [Display omitted] •Proposed CES-PtMe system with innovative CES design for multi-energy generation.•The system efficiencies are 79% without energy demands and 65% with demands.•Both energy curtailment and grid use reduce storage size for economic operation.•Levelized cost of methanol ranges from 600 to 800 USD/ton under various scenarios.