Simulation study of the electrothermal field in a chloride electrolysis cell with 16 electrode pairs

Author:

Liu Qian123,Feng Taixi23,Zhu Shigui23,Lu Guimin123

Affiliation:

1. School of Resources and Environmental Engineering East China University of Science and Technology Shanghai China

2. National Engineering Research Center for Integrated Utilization of Salt Lake Resource East China University of Science and Technology Shanghai China

3. Joint International Laboratory for Potassium and Lithium Strategic Resources East China University of Science and Technology Shanghai China

Abstract

AbstractThe spatial distribution of the electrothermal field within molten salt electrolytic cells significantly influences the efficiency of the electrolysis process, the quality of the end products, and the overall stability of the system. Enhancing the design of chloride electrolysis cells can lead to marked improvements in both process efficiency and system stability, thereby yielding increased economic benefits. This study introduces a design for a chloride electrolysis cell and examines the thermal budget under elevated electrical current intensities across 16 electrode pairs. It further analyzes the degree to which various parameters affect thermal equilibrium. The findings indicate that the electrolytic cell maintains a small thermal budget discrepancy at a current intensity of 124 kA and is less than 5%, with substantial heat dissipation observed at the surface of the top area of anode exposure and considerable energy consumption at both the anode and the electrolyte. Dimensionless treatment of the different parameterized simulation results has been conducted to develop a nondimensional equation, describing the thermal equilibrium conditions within the electrolytic cell. This foundational work paves the way for further investigations into the interactions between the electrothermal field and other physical fields, as well as for the optimization of the electrolytic cell's geometry and design.

Funder

National Natural Science Foundation of China

Publisher

Wiley

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