期刊
JOURNAL OF CLEANER PRODUCTION
卷 337, 期 -, 页码 -出版社
ELSEVIER SCI LTD
DOI: 10.1016/j.jclepro.2022.130503
关键词
Life cycle assessment; Soluble lead redox flow battery; Hybrid flow battery; Flow battery; Energy storage; Environmental impact
资金
- Engineering and Physical Sciences Research Council (EPSRC) through ECR Fellowship NoRESt [EP/S03711X/1]
- SPECIFIC Innovation and Knowledge Centre [EP/N020863/1, EP/P030831/1]
- UKRI Global Challenge Research Fund project, SUNRISE [EP/P032591/1]
- SUNRISE grant
The soluble lead redox flow battery is a promising flow battery solution with lower cost and lower environmental impact compared to other stationary storage applications, such as lithium-ion batteries and lead acid batteries.
Energy storage deployment for stationary applications is expected to grow in the next decade, and there is a requirement for storage solutions that minimise materials demand. Soluble lead redox flow battery is a type of flow battery in the early phase of design with the potential for a lower cost than other flow battery solutions. This study presents the first cradle-to-gate life cycle assessment of the soluble lead redox flow battery. The ReCiPe2016 method was used to assess the 18 midpoint impact categories for 1 kWh of energy storage capacity. The assessed environmental impact categories were compared with the most advanced flow battery, the vanadium redox flow battery, and other commercially available stationary batteries; lithium-ion batteries, lead acid batteries, and sodium-ion batteries. The most significant environmental impacts of the soluble lead redox flow battery are associated with power subsystem components; stainless-steel end plates (a key component of the stack frame), and polymethyl methacrylate bipolar and monopolar frames. Despite their non-optimised technology, the environmental impacts of the soluble lead redox flow battery show promising results compared to other stationary storage applications exhibiting one of the lowest depletion of material resources of all compared batteries, including lithium-ion batteries, lead acid batteries, and sodium-ion batteries. This is even more evident at higher energy to power ratios. Increasing the energy storage capacity of the soluble lead redox flow battery, and the optimisation of power subsystem components can further improve the environmental performance of the soluble lead redox flow battery.
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