Chemical reaction and thermal characteristiecs of Maxwell nanofluid flow-through solar collector as a potential solar energy cooling application: A modified Buongiorno's model

IF 4 4区 环境科学与生态学 Q2 ENVIRONMENTAL STUDIES
S. Hussain, W. Jamshed, Rabia Safdar, F. Shahzad, N. M. Mohd Nasir, I. Ullah
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引用次数: 9

Abstract

Solar collectors absorb solar radiation at the focus of solar concentrating systems as heat energy which is further transferred to nanofluid. Entropy creation in Maxwell nanofluid flow over an infinite horizontal surface of a porous media is the subject of the current investigation. A non-linear stretching surface then induces a parabolic trough solar collector (PTSC) flow. The thermal boundary layer is studied using a modified version of Buongiorno's Model. As a result, the PDEs, which encompass the physical aspects of the issue, must be transformed into solvable and boundary-constrained ODEs. By using a proper similarity transformation, boundary conditions and partial differential expressions are reduced to a set of non-linear ordinary differential equations. The Keller box method is used to find approximate solutions to ODEs. Tests are carried out on a nanofluid known as Copper-engine oil (Cu-EO). The Nusselt number was lowered, but the skin friction coefficient was increased as a result of a substantial magnetic parameter. In addition, Reynolds number and Brinkman number are used to measure fluctuations in viscosity, and, as a result, entropy variations throughout the domain are increased. Temperature decreased due to chemical reaction and Schmidt number, while thermal radiation increased skin friction and Nusselt. According to the current analysis, the heat collector has enhanced PTSC with Maxwell nanofluid.
麦克斯韦纳米流体通过太阳能集热器的化学反应和热特性:一个改进的Buongiorno模型
太阳能集热器在太阳能聚光系统的焦点处以热能的形式吸收太阳辐射,并进一步转化为纳米流体。麦克斯韦纳米流体在多孔介质的无限水平面上流动时产生的熵是当前研究的主题。然后,非线性拉伸表面诱导抛物线槽太阳能集热器(PTSC)流动。热边界层的研究采用了Buongiorno模型的改进版本。因此,必须将包含问题的物理方面的方案发展指标转变为可解决和有边界约束的方案发展指标。利用适当的相似变换,将边界条件和偏微分表达式简化为一组非线性常微分方程。Keller盒法用于求ode的近似解。测试是在一种被称为铜发动机油(Cu-EO)的纳米流体上进行的。努塞尔数降低,但表面摩擦系数增加,由于一个实质性的磁参数。此外,雷诺数和布林克曼数被用来测量粘度的波动,因此,整个区域的熵变化增加。温度因化学反应和施密特数而降低,而热辐射使皮肤摩擦和努塞尔增加。从目前的分析来看,集热器利用麦克斯韦纳米流体增强了PTSC。
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来源期刊
Energy & Environment
Energy & Environment ENVIRONMENTAL STUDIES-
CiteScore
7.60
自引率
7.10%
发文量
157
期刊介绍: Energy & Environment is an interdisciplinary journal inviting energy policy analysts, natural scientists and engineers, as well as lawyers and economists to contribute to mutual understanding and learning, believing that better communication between experts will enhance the quality of policy, advance social well-being and help to reduce conflict. The journal encourages dialogue between the social sciences as energy demand and supply are observed and analysed with reference to politics of policy-making and implementation. The rapidly evolving social and environmental impacts of energy supply, transport, production and use at all levels require contribution from many disciplines if policy is to be effective. In particular E & E invite contributions from the study of policy delivery, ultimately more important than policy formation. The geopolitics of energy are also important, as are the impacts of environmental regulations and advancing technologies on national and local politics, and even global energy politics. Energy & Environment is a forum for constructive, professional information sharing, as well as debate across disciplines and professions, including the financial sector. Mathematical articles are outside the scope of Energy & Environment. The broader policy implications of submitted research should be addressed and environmental implications, not just emission quantities, be discussed with reference to scientific assumptions. This applies especially to technical papers based on arguments suggested by other disciplines, funding bodies or directly by policy-makers.
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