Transient Freezing of Molten Salt in Pipes: A Multi-Scale CFD and Lumped-Parameter Model Analysis

摘要: Molten salts are efficient heat-transfer and storage media widely used in advanced energy systems, including nuclear and concentrated solar power. Their high melting points, however, can induce transient pipeline freezing, impairing operational economy and compromising flow safety. This study employs an integrated multiscale CFD and lumped-parameter approach to systematically investigate the complex freezing process of molten salt in pipes and to quantify the effect of key boundary conditions. Under pumped-inlet conditions, the characteristic temperature and flow rate exhibit a distinct dynamic: an initial decrease, followed by recovery and stabilization, marking the transition from initial filling to steady flow. Excessively designed cooling systems can drive the heat removal rate beyond a safe threshold. The risk of pipe blockage rises substantially for values of the dimensionless freezing parameter θ ≤ 1. The model's applicability is examined, and a parametric sensitivity analysis assesses the influence of inlet temperature, flow velocity, cooling intensity, pipe length, and wall thickness. This work provides a theoretical basis and safety-design guidelines for freeze-protection in molten salt cooling systems.