Particle-based high-temperature thermochemical energy storage reactors

IF 32 1区 工程技术 Q1 ENERGY & FUELS Progress in Energy and Combustion Science Pub Date : 2024-02-08 DOI:10.1016/j.pecs.2024.101143
Jian Zhao , David Korba , Ashreet Mishra , James Klausner , Kelvin Randhir , Nick AuYeung , Like Li
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Abstract

Solar and other renewable energy driven gas-solid thermochemical energy storage (TCES) technology is a promising solution for the next generation energy storage systems due to its high operating temperature, efficient energy conversion, ultra-long storage duration, and potential high energy density. Experimental and theoretical studies suggest that the respective gravimetric and volumetric TCES energy storage densities vary from 200 to 3000 kJ kg−1 and 1–3 GJ m−3. Solar radiation or heat generated from electric furnaces powered by renewable electricity can be stored in the form of chemical energy through endothermic reactions, while the stored chemical energy can be converted to thermal energy via an exothermic reaction when needed. The design of highly effective reactors requires a deep understanding of materials, thermodynamics, chemical kinetics, and transport phenomena. At time of writing, TCES reactors are yet to be deployed at commercially relevant scales, leaving a substantial gap between development efforts and commercial feasibility. Therefore, this review aims to examine the state-of-the-art design and performance of particle-based TCES reactors with different reactive materials. Fundamentals related to TCES reactive materials, reaction conditions, thermodynamics and kinetics, and transport phenomena are reviewed in detail to provide a comprehensive understanding of the reactor design and operation. Five major types of TCES reactors have been comprehensively reviewed and compared, including fixed, moving, rotary, fluidized, and entrained bed reactors. Most reported prototype reactors in the literature operate at lab scale with thermal inputs below 40 kW, and scaled TCES reactors (e.g., at megawatt level) are yet to be demonstrated. The nominal reactor operating temperatures range from 300 to 1500 °C, depending on the selected chemistry, reactive material, and heat sources. To evaluate their designs, the reactors are assessed in aspects of performance, cost, and durability. Discrepancies in performance indicators of energy storage density, extent of reaction, and various energy efficiencies are highlighted. The scale-up of reactors and power block integration, which hold the key to the successful commercialization of TCES systems, are critically analyzed. Advanced materials (both reactive materials and ceramic reactor housing materials), effective particle flow control, advanced modeling tools, and novel system design may bring significant improvement to the energy efficiency, storage density and cost competitiveness of particle-based TCES reactors.

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基于粒子的高温热化学储能反应堆
太阳能和其他可再生能源驱动的气固热化学储能(TCES)技术具有工作温度高、能量转换效率高、储能时间超长以及潜在能量密度高等优点,是下一代储能系统的理想解决方案。实验和理论研究表明,TCES 的重力和体积储能密度分别为 200 至 3000 千焦千克-1 和 1-3 千焦米-3。太阳辐射或由可再生电力驱动的电炉产生的热量可以通过内热反应以化学能的形式储存起来,而储存的化学能则可以在需要时通过放热反应转化为热能。高效反应器的设计需要对材料、热力学、化学动力学和传输现象有深入的了解。在撰写本文时,TCES 反应器尚未在商业相关规模上部署,因此在开发工作和商业可行性之间存在巨大差距。因此,本综述旨在研究使用不同反应材料的基于粒子的 TCES 反应器的最新设计和性能。本文详细回顾了与 TCES 反应材料、反应条件、热力学和动力学以及传输现象有关的基本原理,以提供对反应器设计和运行的全面了解。对五种主要类型的 TCES 反应器进行了全面回顾和比较,包括固定床、移动床、旋转床、流化床和内流床反应器。文献中报道的大多数原型反应器都是在实验室规模下运行的,热输入低于 40 千瓦,规模化 TCES 反应器(如兆瓦级)尚未得到证实。反应器的额定工作温度范围为 300 至 1500 °C,具体取决于所选化学材料、反应材料和热源。为评估其设计,对反应堆的性能、成本和耐用性进行了评估。突出强调了能量储存密度、反应程度和各种能效等性能指标的差异。对反应器的放大和功率块集成进行了批判性分析,这是 TCES 系统成功商业化的关键。先进的材料(包括反应材料和陶瓷反应器外壳材料)、有效的粒子流控制、先进的建模工具和新颖的系统设计可能会显著提高基于粒子的 TCES 反应器的能效、储能密度和成本竞争力。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Progress in Energy and Combustion Science
Progress in Energy and Combustion Science 工程技术-工程:化工
CiteScore
59.30
自引率
0.70%
发文量
44
审稿时长
3 months
期刊介绍: Progress in Energy and Combustion Science (PECS) publishes review articles covering all aspects of energy and combustion science. These articles offer a comprehensive, in-depth overview, evaluation, and discussion of specific topics. Given the importance of climate change and energy conservation, efficient combustion of fossil fuels and the development of sustainable energy systems are emphasized. Environmental protection requires limiting pollutants, including greenhouse gases, emitted from combustion and other energy-intensive systems. Additionally, combustion plays a vital role in process technology and materials science. PECS features articles authored by internationally recognized experts in combustion, flames, fuel science and technology, and sustainable energy solutions. Each volume includes specially commissioned review articles providing orderly and concise surveys and scientific discussions on various aspects of combustion and energy. While not overly lengthy, these articles allow authors to thoroughly and comprehensively explore their subjects. They serve as valuable resources for researchers seeking knowledge beyond their own fields and for students and engineers in government and industrial research seeking comprehensive reviews and practical solutions.
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