Numerical study on pressure drops and thermal response of cryogenic fuel storage tanks under sinusoidal sloshing excitation

As emission standards become stricter, more vessels are deciding to use LNG as fuel. The primary challenge with this change is that external sloshing excitation from the ocean may cause rapid pressure drops in fuel tank, resulting in engine shutdown. In this paper, a computational fluid dynamic (CFD) model based on the volume-of-fluid (VOF) method and mesh motion treatment is constructed to predict the pressure drop and thermal response in LNG fuel tanks under sinusoidal excitation. The sinusoidal excitation and phase change model is realized by the User-Defined Function (UDF). The effectiveness of the CFD model is verified by comparing with related fluid sloshing experiments. The thermal physical processes in the LNG fuel tank under sloshing conditions and the static condition are compared, and the effects of the sloshing amplitude and frequency on the pressure and temperature distribution of the tank are also studied. The numerical results indicate that the sloshing leads to the mixing of vapor and liquid, enhances interfacial heat and mass transfer, uniforms the temperature distribution, and promotes the pressure drop of tank. In particular, the influence of sloshing excitation on heat and mass transfer is theoretically analyzed using the sloshing Nusselt number. A feasible simplified method is provided for the complex phase change problem in cryogenic tanks under sloshing conditions.(c) 2023 Hydrogen Energy Publications LLC. Published by Elsevier Ltd. All rights reserved.

Automated summary

As emission standards become stricter, more vessels are opting to use LNG as fuel. However, external sloshing excitation from the ocean can cause rapid pressure drops in the fuel tank, leading to engine shutdown. In this paper, a computational fluid dynamic (CFD) model is developed to predict the pressure drop and thermal response in LNG fuel tanks under sinusoidal excitation. The CFD model is validated using fluid sloshing experiments. The results show that sloshing enhances heat and mass transfer, promotes pressure drop, and leads to uniform temperature distribution in the tank. The influence of sloshing excitation on heat and mass transfer is theoretically analyzed, and a simplified method is proposed for the complex phase change problem in cryogenic tanks under sloshing conditions.