热化学集成抽水蓄能系统的技术经济分析

IF 8.9 2区工程技术 Q1 ENERGY & FUELS

Journal of energy storage Pub Date : 2024-11-06 DOI:10.1016/j.est.2024.114394

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引用次数: 0

摘要

储能技术可以解决可再生能源电力供需不平衡和不匹配的问题。抽水蓄能技术不受地域限制，能量密度高，因此具有巨大的发展潜力。对于该技术而言，存储和利用热能是提高系统效率和减少系统热损失的关键。因此，本研究提出了一种以空气为工作介质、结合甲醇分解技术的抽水蓄能系统。在充气过程中，基于内热化学反应，低品位热能可转化为高品位化学能进行储存。在放电过程中采用等温压缩策略，同时最大限度地降低压缩功耗，实现能源高效利用。研究还建立了热力学、经济学和环境理论模型，并进行了敏感性分析和多目标优化。结果发现，该系统需要最优的空气-甲醇比、低压涡轮-压力比和绝热压缩机的等熵效率，才能获得最佳的热力学和经济性能。该系统的多目标优化结果表明，在最佳设计工况下，系统的往返效率、放能效率和储能密度分别为 63.70 %、61.62 % 和 8.10 kWh-m-3，与基准工况相比分别提高了 5.80 %、5.88 % 和 6.30 %。系统的平准化能源成本和单位能源碳排放量分别为 202.14 美元-兆瓦时-1 和 199.03 千克-兆瓦时-1，与基础条件下相比分别下降了 0.61 % 和 7.51 %。这项工作可为抽水蓄能系统及其应用的技术和经济可行性提供理论依据。

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Techno-economic analysis of thermochemical-integrated pumped thermal energy storage system

Energy storage technology can address the imbalance and mismatch between the supply and demand of renewable electricity. Pumped thermal energy storage technology has great developmental potential as it is not geographically limited and offers high energy density. For this technology, storing and utilizing thermal energy is the key to improve system efficiency and reduce thermal loss of the system. Thus, in this work, a pumped thermal energy storage system with air as the working medium, coupled with methanol decomposition technology, was proposed. Low-grade thermal energy can be converted into high-grade chemical energy for storage based on the endothermic chemical reaction during the charging process. An isothermal compression strategy was employed during the discharging process to simultaneously minimize the compression power consumption and achieve energy-efficient utilization. Thermodynamic, economic, and environmental theoretical models were also established in this work, then the sensitivity analysis and multi-objective optimization were conducted. It was found that the system required the optimal air-methanol ratio, low-pressure turbine-pressure ratio, and isentropic efficiency of the adiabatic compressor to obtain the optimal thermodynamic and economic performance. The multi-objective optimization results of the system showed that the round-trip efficiency, exergy efficiency, and energy storage density of the system under optimal design working conditions were 63.70 %, 61.62 %, and 8.10 kWh·m⁻³, respectively, which increased by 5.80 %, 5.88 %, and 6.30 %, respectively, compared with those under the base conditions. The levelized energy cost and carbon emission per unit energy of the system were 202.14 $·MWh⁻¹ and 199.03 kg·MWh⁻¹, respectively, which decreased by 0.61 % and 7.51 %, respectively, compared with those under the base conditions. This work can provide a theoretical basis for the technical and economic feasibilities of the pumped thermal energy storage systemand its applications.

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来源期刊

Journal of energy storage Energy-Renewable Energy, Sustainability and the Environment

CiteScore

11.80

自引率

24.50%

发文量

2262

审稿时长

69 days

期刊介绍： Journal of energy storage focusses on all aspects of energy storage, in particular systems integration, electric grid integration, modelling and analysis, novel energy storage technologies, sizing and management strategies, business models for operation of storage systems and energy storage developments worldwide.