薄血管系统的热调节:敏感性分析

IF 2.6 3区 物理与天体物理 Q1 PHYSICS, MATHEMATICAL
K. B. Nakshatrala, K. Adhikari
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引用次数: 0

摘要

自然和合成系统调节温度的方法之一是通过嵌入体内的血管循环液体。基于血管的热调节具有灵活性,而且有成熟的制造技术,因此对薄型微血管系统很有吸引力。虽然初步设计和实验证明了通过嵌入式微血管推动流体进行热调节的可行性,但在将这一概念转化为实际应用之前,人们还需要对其性能进行优化。了解两个重要的设计变量--主材料的热传导率和流体的热容量率--如何影响热调节系统的性能(以平均表面温度量化)将大有裨益。增加导热系数既可以提高也可以降低平均表面温度;如果逆流热交换--热量从一段血管传递到另一段血管--显著增加,平均表面温度就会升高。相反,增加热容量率必然会降低平均表面温度,对此我们提供了数学证明。所报告的结果(a)消除了文献中的一些误解,尤其是对宿主材料热导率影响的误解;(b)揭示了逆流热交换在改变设计变量影响方面的作用;以及(c)指导设计人员实现高效的微血管主动冷却系统。这些分析和发现将从理论和实践两个方面推动热调节领域的发展。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Thermal Regulation in Thin Vascular Systems: A Sensitivity Analysis
One of the ways natural and synthetic systems regulate temperature is via circulating fluids through vasculatures embedded within their bodies. Because of the flexibility and availability of proven fabrication techniques, vascular-based thermal regulation is attractive for thin microvascular systems. Although preliminary designs and experiments demonstrate the feasibility of thermal modulation by pushing fluid through embedded micro-vasculatures, one has yet to optimize the performance before translating the concept into real-world applications. It will be beneficial to know how two vital design variables—host material’s thermal conductivity and fluid’s heat capacity rate—affect a thermal regulation system’s performance, quantified in terms of the mean surface temperature. This paper fills the remarked inadequacy by performing adjoint-based sensitivity analysis and unravels a surprising non-monotonic trend. Increasing thermal conductivity can either increase or decrease the mean surface temperature; the increase happens if countercurrent heat exchange—transfer of heat from one segment of the vasculature to another—is significant. In contrast, increasing the heat capacity rate will invariably lower the mean surface temperature, for which we provide mathematical proof. The reported results (a) dispose of some misunderstandings in the literature, especially on the effect of the host material’s thermal conductivity, (b) reveal the role of countercurrent heat exchange in altering the effects of design variables, and (c) guide designers to realize efficient microvascular active-cooling systems. The analysis and findings will advance the field of thermal regulation both on theoretical and practical fronts.
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来源期刊
Communications in Computational Physics
Communications in Computational Physics 物理-物理:数学物理
CiteScore
4.70
自引率
5.40%
发文量
84
审稿时长
9 months
期刊介绍: Communications in Computational Physics (CiCP) publishes original research and survey papers of high scientific value in computational modeling of physical problems. Results in multi-physics and multi-scale innovative computational methods and modeling in all physical sciences will be featured.
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