作为斯特林发动机热能储存器的 PCM 熔盐的二维凝固模拟

Energy Storage Pub Date : 2024-10-25 DOI:10.1002/est2.70074
Gerardo Janitra Puriadi Putra, Nandy Putra
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引用次数: 0

摘要

热能储存技术已被广泛用于缓解太阳能等可再生能源的间歇性。相变材料(PCM)是一种可用作储热介质的材料,其工作温度范围很广。熔盐是 PCM 的一种,具有工作温度极高的优点。使用 COMSOL Multiphysics 软件对基于 HitecXL 熔盐的 PCM 固化进行了模拟,在假设吸热恒定的情况下,吸热变化为 1-5 kW/m2。结果表明,PCM 的凝固过程是从斯特林发动机热交换器管道表面开始的。凝固的 PCM 部分在重力作用下下落,造成类似于液滴的现象。在凝固过程中温度梯度引起的密度变化所产生的浮力推动下,出现了自然流动。PCM 完全凝固所需的时间与吸热量密切相关;管道吸热量越大,PCM 完全凝固的速度越快。
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Two-Dimensional Solidification Simulation of PCM Molten Salt as a Thermal Energy Storage for Stirling Engine

Thermal energy storage technologies have been widely used to mitigate intermittency from renewable energy sources such as solar energy. Phase change material (PCM) is a material that can be used as a heat storage medium and is available in a wide range of operating temperatures. Molten salt is one of the PCMs that has the advantage of a very high operating temperature. The PCM solidification simulation based on HitecXL molten salt using COMSOL Multiphysics software was carried out with variations in heat absorption of 1–5 kW/m2, assuming constant heat absorption. The results showed that the PCM solidification process started from the surface of the Stirling engine heat exchanger pipe. The part of the PCM that is solidified falls due to gravity, causing a phenomenon similar to a droplet. The flow that occurred was natural, driven by the buoyancy force resulting from density changes due to temperature gradients in the solidification process. The time required for the PCM to completely solidify was closely related to the amount of heat absorption; the greater the heat absorption from the pipe, the faster the PCM is fully solidified.

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