驱动Zn-MnO_2电网级电池:经济高效的能源存储路线图

IF 3.3 Q3 ENERGY & FUELS
E. Spoerke, H. Passell, Gabriel Cowles, T. Lambert, Gautam G. Yadav, Jinchao Huang, Sanjoy Banerjee, B. Chalamala
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引用次数: 5

摘要

锌- mno_2电池承诺安全、可靠的能量存储,这一路线图概述了制造战略和技术创新的结合,可以使这一目标实现。提高制造效率和增加活性材料利用率等方法对于降低成本到100美元/千瓦时很重要,但关键的材料创新,促进MnO_2的完全2电子容量利用,高能量密度3D电极的使用,以及具有大于2V电位的无分离器电池的承诺,为50美元/千瓦时或更低的电池提供了一条途径。大规模储能系统必将在新兴电网的发展中发挥重要的推动作用。基于电池的存储,虽然不是目前的主要存储形式,但有机会通过安全、可靠和经济高效的技术扩大其用途。在这里,锌- mno_2二次电池被强调为普遍存在的碱性电池的有前途的延伸,在可扩展和实用的能量密度技术中提供安全,环保的化学物质。重要的是,有一个非常现实的途径可以使这种电池在50美元/千瓦时或更低的价格点具有成本效益。通过对锌- mno_2电池制造商城市电力公司的生产实例的考察,为实现这种低成本系统制定了路线图。通过减少材料浪费、可扩展制造和有效的材料选择,专注于制造优化,可以显着降低成本。然而,最终,将这些方法与新兴的研究和开发进展相结合,以实现活性材料的全容量利用和电池电压大于2V,可能需要将成本降至50美元/千瓦时以下的目标。实现这一重要的商业目标,特别是通过一种安全、知名、可靠有效的化学方法,可以在储能开发和部署的关键时刻将锌- mno_2电池注入储能领域。图形抽象
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Driving Zn-MnO_2 grid-scale batteries: A roadmap to cost-effective energy storage
Highlights Zn-MnO_2 batteries promise safe, reliable energy storage, and this roadmap outlines a combination of manufacturing strategies and technical innovations that could make this goal achievable. Approaches such as improved efficiency of manufacturing and increasing active material utilization will be important to getting costs as low as $100/kWh, but key materials innovations that facilitate the full 2-electron capacity utilization of MnO_2, the use of high energy density 3D electrodes, and the promise of a separator-free battery with greater than 2V potential offer a route to batteries at $50/kWh or less. Abstract Large-scale energy storage is certain to play a significant, enabling role in the evolution of the emerging electrical grid. Battery-based storage, while not a dominant form of storage today, has opportunity to expand its utility through safe, reliable, and cost-effective technologies. Here, secondary Zn–MnO_2 batteries are highlighted as a promising extension of ubiquitous primary alkaline batteries, offering a safe, environmentally friendly chemistry in a scalable and practical energy dense technology. Importantly, there is a very realistic pathway to also making such batteries cost-effective at price points of $50/kWh or lower. By examining manufacturing examples at the Zn–MnO_2 battery manufacturer Urban Electric Power, a roadmap has been created to realize such low-cost systems. By focusing on manufacturing optimization through reduced materials waste, scalable manufacturing, and effective materials selection, costs can be significantly reduced. Ultimately, though, coupling these approaches with emerging research and development advances to enable full capacity active materials utilization and battery voltages greater than 2V are likely needed to drive costs below a target of $50/kWh. Reaching this commercially important goal, especially with a chemistry that is safe, well-known, and reliably effective stands to inject Zn–MnO_2 batteries in the storage landscape at a critical time in energy storage development and deployment. Graphical abstract
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来源期刊
MRS Energy & Sustainability
MRS Energy & Sustainability ENERGY & FUELS-
CiteScore
6.40
自引率
2.30%
发文量
36
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