A perspective on the design and scale up of a novel redox flow battery

IF 3.3 Q3 ENERGY & FUELS
N. Sinclair, R. Savinell, J. Wainright
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引用次数: 0

Abstract

Abstract Government funding is critical for testing concepts and ideas of technical approaches to demonstrate their value to attract attention for commercial development. In the US for energy projects, this funding often comes from ARPA-E, but similar types of funding agencies exist in other countries as well. However, independent of the funding sources, government or private, often unanticipated challenges arise that require pivots and flexibility, and leap-frogging scale-up levels can hinder achieving the knowledge needed for technology development. By incorporating a conducting carbon slurry in the negative electrolyte of an all iron flow battery, the decoupling of power from energy design becomes possible for this normally hybrid flow battery system. This approach offers the potential for very low cost large-scale energy storage with safe and sustainable materials. Government funding of this project allowed the demonstration of the concept during the seedling stage, but with the use of carbon nanotubes that would not meet cost targets. The second phase of the project demonstrated that low cost carbons with certain properties could also be used effectively. The third phase of the project then sought to scale-up the lab cells to a full-size stack. This paper summarizes some of the technical challenges encountered and pivots in approach that were taken. This project was sponsored by a commercialization-focused government agency (US ARPA-E in this case) and we point out some constraints and expectations of attracting commercial funding sources that hindered the development, or complicated solving the necessary design and materials issues to make the technology interesting for further investment. The lessons learned here will be applicable to other commercialization driven projects sponsored by government agencies in the US and elsewhere. Graphical abstract
新型氧化还原液流电池的设计与规模化研究
政府资助对于测试技术方法的概念和想法以证明其价值以吸引商业开发的关注至关重要。在美国,能源项目的资金通常来自ARPA-E,但其他国家也存在类似的资助机构。然而,独立于政府或私人的资金来源之外,往往会出现意想不到的挑战,这些挑战需要支点和灵活性,而跨越式的规模扩大水平可能会阻碍获得技术开发所需的知识。通过在全铁液流电池的负电解质中加入导电碳浆,这种通常的混合液流电池系统的功率与能量设计的解耦成为可能。这种方法为使用安全和可持续材料的低成本大规模储能提供了潜力。政府资助的这个项目允许在幼苗阶段展示这个概念,但是使用的碳纳米管无法达到成本目标。该项目的第二阶段表明,具有某些特性的低成本碳也可以有效利用。该项目的第三阶段是将实验室细胞扩大到全尺寸堆叠。本文总结了所遇到的一些技术挑战和所采取的方法的要点。这个项目是由一个以商业化为重点的政府机构(在这个案例中是美国ARPA-E)赞助的,我们指出了一些限制和期望,吸引商业资金来源,阻碍了发展,或者复杂的解决必要的设计和材料问题,使技术对进一步的投资感兴趣。这里的经验教训将适用于美国和其他地方政府机构资助的其他商业化项目。图形抽象
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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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