Computational Galerkin Finite Element Method for Thermal Hydrogen Energy Utilization of First Grade Viscoelastic Hybrid Nanofluid Flowing Inside PTSC in Solar Powered Ship Applications

IF 4 4区 环境科学与生态学 Q2 ENVIRONMENTAL STUDIES
F. Bayones, W. Jamshed, S. Elhag, Mohamed Rabea Eid
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引用次数: 6

Abstract

Parabolic trough solar collectors (PTSCs) are commonly used in solar thermal implementations to achieve high-temperatures. The current investigation looks at entropy formation and the effect of nano solid particles on a parabolic trough surface collector (PTSC) mounted aboard a solar-powered ship (SPS). The non-Newtonian first grade viscoelastic type, as well as a porous medium and Darcy-Forchheimer effects, were utilised in the current study. The flowing of PTSC was created by a non-linear stretching sheet, and the changing thermal conductivity, heat source, and viscous dissipation effects were used to calculate the heat flux in the thermal boundary layer. To convert partial differential equations (PDEs) into solvable ordinary differential equations (ODEs) with boundary-constraints, a similarity transformation strategy was used. The boundary-constraints and PDEs have been reduced to a set of non-linear ODEs (ordinary differential equations). To reach the approximated solution of ODEs, the Galerkin finite element method (G-FEM) is used. As working fluids, copper-sodium alginate (Cu-SA) and molybdenum disulfide-copper/sodium alginate (MoS2-Cu/SA) hybrid nanofluids were used. According to the findings, the permeability factor diminished the Nusselt number whilst boosting the skin friction factor. Furthermore, overall entropy variance throughout the domain was increased for flow speeds using the Reynolds number, and viscosity changes were tracked using the Brinkman number. When compared to MoS2-Cu/SA, using Cu-SA nanofluid boosted thermal efficiency by 1.3–18.8%.
一级粘弹性混合纳米流体在太阳能船舶PTSC内流动的热氢能利用的计算Galerkin有限元法
抛物槽太阳能集热器(PTSCs)通常用于太阳能热实现以实现高温。目前的研究着眼于熵的形成和纳米固体颗粒对安装在太阳能船(SPS)上的抛物槽表面收集器(PTSC)的影响。本研究采用了非牛顿一级粘弹性类型、多孔介质和达西-福希海默效应。PTSC的流动是由非线性拉伸薄片产生的,并利用热导率、热源和粘性耗散效应的变化来计算热边界层的热流密度。为了将偏微分方程转化为具有边界约束的可解常微分方程,采用了相似变换策略。边界约束和偏微分方程被简化为一组非线性常微分方程。为了得到ode的近似解,采用了伽辽金有限元法(G-FEM)。工作流体采用铜-海藻酸钠(Cu-SA)和二硫化钼-铜/海藻酸钠(MoS2-Cu/SA)混合纳米流体。根据研究结果,渗透系数降低了努塞尔数,同时提高了皮肤摩擦系数。此外,使用雷诺数增加了整个区域的总熵方差,并使用Brinkman数跟踪了粘度变化。与MoS2-Cu/SA相比,Cu-SA纳米流体的热效率提高了1.3 ~ 18.8%。
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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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