Numerical Simulation of Phase Transition Process for Vertical Lift Underwater Monitoring Device Driven by Ocean Thermal Energy

Numerical Simulation of Phase Transition Process for Vertical Lift Underwater Monitoring Device Driven by Ocean Thermal Energy

The energy consumption of current vertical-lifting underwater monitoring devices mainly falls into two categories: one fully supplied by battery packs; and the other partially by battery packs, with the rest from ocean thermal energy. Constrained by battery capacity, their operation time is limited,...

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Bibliographic Details
Main Authors: Zede Liang, Tielin Zhang, Qingqing Li
Format: Article
Language:English
Published: MDPI AG 2025-07-01
Series:Applied Sciences
Subjects:
underwater monitoring device
ocean thermal energy
phase transition
enthalpy-porosity model
numerical simulation
Online Access:https://www.mdpi.com/2076-3417/15/13/7616
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Summary:The energy consumption of current vertical-lifting underwater monitoring devices mainly falls into two categories: one fully supplied by battery packs; and the other partially by battery packs, with the rest from ocean thermal energy. Constrained by battery capacity, their operation time is limited, making long-term remote operations difficult. This study focuses on a device powered entirely by ocean thermal energy, which realizes the absorption and storage of energy through a phase change heat-exchange system, significantly extending its operation cycle and working area. A composite phase change material of n-hexadecane and graphite with a volume ratio of 9:1 is used. The Fluent software 2022 R1, based on the enthalpy-porosity method, simulates the phase change process of the device to analyze the effects of different structures and seawater temperatures. Results show that with the same phase change material volume and inner diameter of the cylindrical heat exchanger, a smaller outer diameter yields better phase change performance. Lower seawater temperature facilitates solidification. Due to natural convection in the liquid phase, the melting time is 520 s and solidification time is 4800 s, with the melting rate far exceeding the solidification rate.
ISSN:2076-3417

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