高温热管冷冻启动过程的数值方法研究与特性分析

IF 6.1 2区 工程技术 Q2 ENERGY & FUELS Applied Thermal Engineering Pub Date : 2024-09-07 DOI:10.1016/j.applthermaleng.2024.124358
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引用次数: 0

摘要

未来的太空探索技术需要一种不依赖太阳能的长寿命、可靠的动力源。空间微型反应器能够满足这一需求,其中热管冷却反应器(HPR)是近年来引起广泛关注的一种引人注目的空间微型反应器。HPR 利用高温碱金属热管进行传热,由于碱金属工作介质在室温下呈固态,因此具有一定的复杂性。这导致在高温热管启动过程中会出现三相转变,从而对 HPR 启动过程的传热特性和动态行为产生重大影响。因此,有必要在这一领域开展深入研究。数值模拟是有效分析、预测和指导实验的重要工具。本文利用有限体积法(FVM)开发了高温热管冷冻启动模拟代码。文中集成了各种物理模型来描述热管的不同组成部分:容器由二维轴对称热传导方程表示,灯芯区域采用固定网格法(FGM)来描述介质的熔化过程,蒸汽通道则通过二维轴对称可压缩层流来描述。灯芯区域和蒸汽通道通过介质的蒸发和冷凝耦合在一起。对于蒸汽通道,采用 SIMPLE 和 PISO 等数值方法进行求解。代码中采用了自适应时间步长和 OpenMP 加速,以提高计算效率。最后,通过将计算结果与实验数据进行比较,评估了代码的可行性和准确性,并强调了启动过程中的特殊现象。研究结果证实,开发的代码能准确预测启动过程中的参数变化,可作为热管分析模块用于 HPR 的多物理场耦合分析。
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Numerical method research and characteristics analysis on frozen start-up process of high-temperature heat pipe

Future space exploration technology requires a long-life and reliable power source that is not reliant on solar energy. Space micro-reactors are able to meet this need, with Heat Pipe Cooled Reactors (HPR) emerging as a notable type of space micro-reactor that has attracted widespread attention in recent years. The HPR utilizes high-temperature alkali metal heat pipes for heat transfer, which presents certain complexities due to the solid state of the alkali metals working medium at room temperature. This results in a three-phase transition during the high-temperature heat pipes start-up process, which significantly impacts the heat transfer characteristics and dynamic behavior of the HPR start-up process. Consequently, thorough research is necessary in this area. Numerical simulation is a crucial tool that can effectively analyze, predict, and guide experiments. This article utilizes the Finite Volume Method (FVM) to develop a simulation code for high-temperature heat pipe frozen start-up. Various physical models are integrated to describe different components of the heat pipe: the container is represented by a two-dimensional axisymmetric heat conduction equation, the wick region utilizes a Fixed Grid Method (FGM) to depict the melting process of the medium, and the vapor channel is described through a two-dimensional axisymmetric compressible laminar flow. The wick region and vapor channel are coupled through the evaporation and condensation of the medium. For the vapor channel, numerical methods such as SIMPLE and PISO are used for solving. Adaptive time step and OpenMP acceleration are employed in the code to enhance computational efficiency. Finally, by comparing the calculated results with experimental data, the feasibility and accuracy of the code are assessed, highlighting special phenomena during the start-up process. The findings confirm that the developed code accurately predicts parameter changes during start-up, and can serve as a heat pipe analysis module for multi-physics coupling analysis of HPR.

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来源期刊
Applied Thermal Engineering
Applied Thermal Engineering 工程技术-工程:机械
CiteScore
11.30
自引率
15.60%
发文量
1474
审稿时长
57 days
期刊介绍: Applied Thermal Engineering disseminates novel research related to the design, development and demonstration of components, devices, equipment, technologies and systems involving thermal processes for the production, storage, utilization and conservation of energy, with a focus on engineering application. The journal publishes high-quality and high-impact Original Research Articles, Review Articles, Short Communications and Letters to the Editor on cutting-edge innovations in research, and recent advances or issues of interest to the thermal engineering community.
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