Litcius/Paper detail

Predicting the cost of a 24 V soluble lead flow battery optimised for PV applications

Diarmid Roberts, E.J. Fraser, Andrew Cruden, R.G.A. Wills, Solomon Brown

2023Journal of Power Sources12 citationsDOIOpen Access PDF

Abstract

Providing reliable electricity from small-scale renewable power is an important challenge for emerging economies. The soluble lead flow battery (SLFB) is a promising battery for this application, as it has a simple architecture making it relatively robust, and a lifetime of 2000 cycles demonstrated at the cell level. Also, the electrolyte is manufacturable directly from spent lead acid batteries. There is a need for techno-economic models to allow the cost/performance of a complete system to be defined and optimised. Such a model is defined here for the first time and used in a multi-objective optimisation to design a 24 V system for a charging hub in Sierra Leone. A 4 h duration was found to be optimal, and electrolyte for a 3.5 kW/14 kWh system would fit in a 1000 L IBC. Methanesulfonic acid was found to be the largest cost component of the 4 h system, with graphitic bipolar plates next. Both have low raw material costs, and in an optimistic scenario a total component cost of <£50/kWh would be achieved, half that of current NMC Li-ion cells. The greatest technical risk to achieving low cost is deposit thickness of lead dioxide. This important research gap should be addressed.

Topics & Concepts

Methanesulfonic acidLead–acid batteryBattery (electricity)Renewable energyElectricityEnvironmental scienceProcess engineeringAutomotive engineeringEngineeringReliability engineeringElectrical engineeringPower (physics)ChemistryQuantum mechanicsOrganic chemistryPhysicsAdvanced battery technologies researchAdvanced Battery Technologies ResearchHybrid Renewable Energy Systems