利用布林克曼-福克海默模型分析带矩形障板的波纹状垂直壁围墙中的 MHD 纳米流体的熵产生情况

IF 2.2 4区 化学 Q3 CHEMISTRY, PHYSICAL
Asad Ali, Kejia Pan, Rashid Ali, Muhammad Waqas Ashraf
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引用次数: 0

摘要

铜资源丰富,具有良好的导电性、耐腐蚀性和延展性。这些特性通过促进纳米粒子与磁场之间的相互作用来影响纳米流体的行为。这项研究旨在评估在自然对流作用下,填充在具有垂直波浪形墙壁的外壳中的铜-水纳米流体的传热特性。该系统还经历了一个恒定的倾斜磁场,并具有一个内部加热的矩形挡板。本研究对多个热物理参数进行了综合分析,包括瑞利数(({10}^{3} \le {\text{Ra}} \le {10}^{5}))、哈特曼数(((0 \le {\text{Ha}} \le 150))、纳米粒子浓度((0.00 \le \phi \le 0.09),()和孔隙率(((0.2 \le \varepsilon \le 0.8))。本研究采用 Galerkin 有限元方法(GFEM)进行计算,从而能够对流线、等温线、熵生成和平均努塞尔特数进行综合分析。主要研究结果表明,增加瑞利数和孔隙率会提高围护结构内的速度曲线。对于内矩形障板的不同角度((theta =0^\circ ,30^\circ ,60^\circ ,\mathrm{ and}\ 90^\circ )),在({text{Ra}}={10}^{3}- {10}^{5}}\)时,计算出的\({text{Nu}}}_{text{avg}})的最大增加值分别为(77.5%,78.3%),(81.9%)和(82.2%)。此外,({S}_{text\{Total}}\)的值也大幅上升,达到(96.1%, 11.1%)和(8.当(left(Ra\right), left(phi\right),\) 和((varepsilon))增加时,会出现(8%)的下降,而当(({text{Ha}}\))增加时,会出现(19.5%)的下降。此外,平均贝扬数(({\text{Be}}}_{\text{avg}})随着纳米粒子体积分数((\phi )\)的增加而增加,哈特曼数(({\text{Ha}})\)随着纳米粒子体积分数((\phi )\)的增加而减少。本研究中采用的几何结构在不同的工程领域都有实际应用,如能量存储、化学处理设备、生物医学系统、太阳能集热器、热交换器和电子设备冷却系统等。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Entropy generation analysis of MHD nanofluid in a corrugated vertical walls enclosure with a rectangular baffle using the Brinkmann-Forchheimer model

Entropy generation analysis of MHD nanofluid in a corrugated vertical walls enclosure with a rectangular baffle using the Brinkmann-Forchheimer model

Copper is abundant and has good conductivity, corrosion resistance, and malleability. These properties affect the behavior of nanofluids by contributing to the interaction between nanoparticles and the magnetic field. This work aims to assess the thermal transfer characteristics of a Cu-water nanofluid filled in an enclosure having vertical wavy walls under the influence of natural convection. The system also experiences the existence of a constant inclined magnetic field and features an inner heated rectangular baffle. In this study, a comprehensive analysis is conducted on several thermo-physical parameters, including the Rayleigh number (\({10}^{3} \le {\text{Ra}} \le {10}^{5}\)), Hartmann number \((0 \le {\text{Ha}} \le 150),\) nanoparticle concentration \((0.00 \le \phi \le 0.09),\) and porosity \((0.2 \le \varepsilon \le 0.8)\). The Galerkin finite element method (GFEM) is employed in this study to conduct calculations, enabling a comprehensive analysis of streamlines, isotherms, entropy generation, and mean Nusselt numbers. The key findings demonstrate that raising the number of Rayleigh and porosity raises the velocity profile within the enclosure. For the various angles of the inner rectangular baffle \((\theta =0^\circ ,30^\circ ,60^\circ ,\mathrm{ and}\ 90^\circ )\) at \({\text{Ra}}={10}^{3}- {10}^{5}\), the calculated maximum increase in \({{\text{Nu}}}_{{\text{avg}}}\) are \(77.5\%, 78.3\%\), \(81.9\% ,\) and \(82.2\%,\) respectively. Furthermore, significant rise in the value of (\({S}_{{\text{Total}}}\)) up to \(96.1\%, 11.1\%\), and \(8.8\%\) is experienced when \(\left(Ra\right), \left(\phi \right),\) and \((\varepsilon )\) increase, while \(19.5\%\) decrement is observed when (\({\text{Ha}}\)) increases. Additionally, the average Bejan number \(({{\text{Be}}}_{{\text{avg}}})\) grows as the fraction volume of nanoparticle \((\phi )\) climbs and the Hartmann number \(({\text{Ha}})\) declines. The geometry configurations employed in this research have real-world applications across different engineering fields, such as energy storage, chemical processing equipment, biomedical systems, solar collectors, heat exchangers, and cooling systems for electronic devices.

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来源期刊
Colloid and Polymer Science
Colloid and Polymer Science 化学-高分子科学
CiteScore
4.60
自引率
4.20%
发文量
111
审稿时长
2.2 months
期刊介绍: Colloid and Polymer Science - a leading international journal of longstanding tradition - is devoted to colloid and polymer science and its interdisciplinary interactions. As such, it responds to a demand which has lost none of its actuality as revealed in the trends of contemporary materials science.
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