Optimization on microchannel structures made of typical materials based on machine learning

IF 23.2 2区 材料科学 Q1 MATERIALS SCIENCE, COMPOSITES
Chenyang Yu, Ming Yang, Jun Yao, Saad Melhi, Mustafa Elashiry, Salah M. El-Bahy, Sicong Tan, Zhigang Li, Shien Huang, Ergude Bao, Hang Zhang
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Abstract

With the trend toward miniaturization of functional devices, material preparation and thermal management processes are also limited to small spaces. Microchannels have emerged as an optimal solution for these challenges. Microchannel-based reactors can generate hybrid materials, and the integration of microchannel heat sinks and substrates can control the temperature of high-power devices. The microstructure within microchannels significantly influences fluid flow and heat transfer, impacting the efficiency of both reaction and heat dissipation processes. Pin-fins are widely used microstructures due to their ability to increase heat transfer area and enhance fluid mixing. In order to find the optimal structure of the fins, it is essential to explore a vast parameter space. In this paper, artificial neural network and genetic algorithm are combined to optimize the copper irregular pin–fin microchannels. Initially, a large number of numerical simulations are performed, focusing on adjustable parameters such as fin radii in various directions, while monitoring the heating surface temperature and the pressure drop of the fin section. Then, nearly 2000 sets of accumulated data are used to train the neural network, establishing the relationship between structural and performance parameters. Finally, a genetic algorithm is employed for multi-objective optimization, yielding a Pareto front. The findings reveal that the newly obtained optimized microchannels exhibit superior thermal–hydraulic performance compared to traditional microchannels. The mechanism of heat transfer enhancement in the optimized microchannel has been revealed: the arrangement of asymmetric fins allows for more thorough contact between the fluid and the fins. Based on this rule, the newly designed multi-fin microchannels exhibit better performance under both fixed heat flux and fixed temperature conditions. In addition, doping high thermal conductivity materials into the substrate to form composite materials can significantly improve the heat transfer performance of microchannels, and using materials with different doping ratios in different parts of the microchannel can effectively improve the temperature uniformity of the heating surface. Thus, uniform-temperature microchannels are designed by combining metal materials (such as copper and aluminum) with non-metal materials (like diamond and graphite).

Graphical Abstract

Abstract Image

基于机器学习的典型材料微通道结构优化
随着功能器件的微型化趋势,材料制备和热管理过程也被限制在狭小的空间内。微通道已成为应对这些挑战的最佳解决方案。基于微通道的反应器可以生成混合材料,而微通道散热器和基板的集成则可以控制大功率器件的温度。微通道内的微结构对流体流动和传热有很大影响,从而影响反应和散热过程的效率。针状鳍片能够增加传热面积并加强流体混合,因此是广泛使用的微结构。为了找到最佳的翅片结构,必须探索广阔的参数空间。本文将人工神经网络和遗传算法相结合,对铜质不规则针形鳍片微通道进行优化。首先,进行了大量的数值模拟,重点关注不同方向的鳍片半径等可调参数,同时监测鳍片部分的加热表面温度和压降。然后,利用近 2000 组累积数据训练神经网络,建立结构参数和性能参数之间的关系。最后,采用遗传算法进行多目标优化,得出帕累托前沿。研究结果表明,与传统微通道相比,新优化的微通道具有更优越的热-水性能。优化微通道的传热增强机制已经揭示:不对称鳍片的排列使流体与鳍片之间的接触更加彻底。根据这一规律,新设计的多鳍片微通道在固定热通量和固定温度条件下都表现出更好的性能。此外,在基底中掺入高导热材料形成复合材料,可以显著提高微通道的传热性能,在微通道的不同部位使用不同掺杂比的材料,可以有效改善加热表面的温度均匀性。因此,通过将金属材料(如铜和铝)与非金属材料(如金刚石和石墨)相结合,可以设计出温度均匀的微通道。
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来源期刊
CiteScore
26.00
自引率
21.40%
发文量
185
期刊介绍: Advanced Composites and Hybrid Materials is a leading international journal that promotes interdisciplinary collaboration among materials scientists, engineers, chemists, biologists, and physicists working on composites, including nanocomposites. Our aim is to facilitate rapid scientific communication in this field. The journal publishes high-quality research on various aspects of composite materials, including materials design, surface and interface science/engineering, manufacturing, structure control, property design, device fabrication, and other applications. We also welcome simulation and modeling studies that are relevant to composites. Additionally, papers focusing on the relationship between fillers and the matrix are of particular interest. Our scope includes polymer, metal, and ceramic matrices, with a special emphasis on reviews and meta-analyses related to materials selection. We cover a wide range of topics, including transport properties, strategies for controlling interfaces and composition distribution, bottom-up assembly of nanocomposites, highly porous and high-density composites, electronic structure design, materials synergisms, and thermoelectric materials. Advanced Composites and Hybrid Materials follows a rigorous single-blind peer-review process to ensure the quality and integrity of the published work.
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