基于田口优化方法的纳米流体陶瓷微热交换器数值评估

Mohsen Naderi, Mohammad Vajdi, Farhad Sadegh Moghanlou, Hossein Nami
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引用次数: 1

摘要

在微系统技术的快速发展,有必要探索创新的材料,在微型热交换器的有效热管理。本研究探讨了ZrB2、BeO和Si3N4三种超高温陶瓷(UHTCs)作为微热交换器替代材料的性能评价。本研究采用Taguchi优化方法系统评估了陶瓷在不同体积百分比和质量流量下与al2o3纳米流体的相互作用。氧化铍(BeO)是最优材料,其出口温度低至64.86°C,出口温度低至31.68°C。敏感性分析进一步强调了进口温度对出口动力学的关键作用,暖出口和冷出口分别显示出~72%和~99%的显著性。此外,该研究确定0.75体积%为最佳al2o3纳米流体浓度,从而产生最有利的陶瓷性能指标。
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Numerical assessment of ceramic micro heat exchangers working with nanofluids by Taguchi optimization approach
The rapid advancements in microsystems technology have necessitated the exploration of innovative materials for efficient thermal management in micro heat exchangers. This research delves into the performance evaluation of three ultra-high temperature ceramics (UHTCs): ZrB2, BeO, and Si3N4 as alternative micro heat exchanger fabrication materials. The study systematically assessed the ceramics' interaction with Al2O3-nanofluids across diverse volume percentages and mass flow rates using the Taguchi optimization method. Beryllium oxide (BeO) emerged as the superior material, registering warm outlet temperatures as low as 64.86°C and cold outlet peaks at 31.68°C. Sensitivity analyses further underscored the critical role of inlet temperature on outlet dynamics, with warm and cold outlets showing significances of ~72% and ~99%, respectively. Additionally, the research pinpointed 0.75 vol% as the optimal Al2O3-nanofluid concentration, yielding the most favorable performance metrics across the ceramics.
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