Radiative Impact on Jeffery Trihybrid Convective Nanoflow over an Extensible Riga Plate: Multiple Linear Regression Analysis

N. Bhargavi, Poornima T
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Abstract

Solar thermal systems utilize solar energy to generate heat, and the incorporation of nanoparticles such as Al2O3-Cu-Ni with a water base can elevate their efficiency. These nanofluids, composed of aluminum oxide, copper, and nickel nanoparticles dispersed in water, enhance heat absorption and transfer within the system. This improvement contributes to heightened overall performance and effectiveness of solar thermal systems. Cupronickel alloy helps in the process of desalination. Hence, this study examines the heat exchange properties in the context of a boundary layer flow of a trihybrid over a variable-thickness Riga plate stretched and heated by convective heat with non-Newtonian fluid (Jeffery) in the presence of thermal radiation. The governing equations of the boundary layer are transformed into a system of ordinary differential equations through appropriate similarity transformations, and those equations are resolved utilizing a boundary value problem program. The engineering parameters are analyzed through the application of multiple linear regression. The key finding of the investigation is that the Prandtl number, and thickness index number all have a positive impact on the Nusselt number. The presence of radiation and a uniform heat source improves the Nusselt number, physically this energy transfer improvement assists in higher solar collector efficacy; and converts that energy to usable heat. The rationale behind selecting trihybrid nanoparticles Al2O3, Cu, and Ni lies in the balance and inertness of Al2O3, with metals Cu, and Ni, both possessing more thermal conductivity.
可扩展里加板上杰弗里三混合对流纳米流的辐射影响:多元线性回归分析
太阳能热系统利用太阳能产生热量,在水基中加入 Al2O3-Cu-Ni 等纳米颗粒可提高其效率。这些纳米流体由分散在水中的氧化铝、铜和镍纳米颗粒组成,可增强系统内的热量吸收和传递。这种改进有助于提高太阳能热系统的整体性能和效率。铜镍合金有助于海水淡化过程。因此,本研究考察了在热辐射存在的情况下,三混合物在拉伸厚度可变的里加板上的边界层流动的热交换特性,以及非牛顿流体(杰弗里)的对流热量。通过适当的相似变换,边界层的支配方程被转换成常微分方程系统,并利用边界值问题程序解决这些方程。工程参数通过应用多元线性回归进行分析。研究的主要发现是,普朗特数和厚度指数都对努塞尔特数有积极影响。辐射和均匀热源的存在提高了努塞尔特数,从物理上讲,这种能量传递的改善有助于提高太阳能集热器的效率,并将能量转化为可用热量。选择 Al2O3、Cu 和 Ni 三种杂化纳米粒子的理由在于 Al2O3 与金属 Cu 和 Ni 之间的平衡和惰性,两者都具有更强的导热性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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