Solar water-pump thermal analysis utilizing copper–gold/engine oil hybrid nanofluid flowing in parabolic trough solar collector: Thermal case study

Ouni, Mohamed Héchmi El; Ladhar, Lotfi; Omri, Mohamed; Jamshed, Wasim; Eid, Mohamed R.

doi:10.1016/j.csite.2022.101756

Cited by 66 publications

(17 citation statements)

References 40 publications

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“…Sarkar et al 17 explored the thermal applications of hybrid nanofluids and claimed that hybrid performance is better than nano liquids by comparing pressure drop characteristics to mono nanofluids. Such a results stimulates further investigations as, e.g., Jamshed et al 18 concerning the influence of thermal increment in the solar aircraft by taking the hybrid nanofluid model, Ouni et al 19 , where the authors provided some advance applications of engine oil using the idea of hybrid nanofluid flow in parabolic trough type solar collector, Redouane et al 20 , with respect to the analysis of the impact of entropy and Brinkman-Forchheimer model by considering the applications of hybrid nanofluid in a rotating cylinder, Jamshed et al 21 , discussing the comparative analysis of hybrid nanofluid with mono nanofluids and considering the flow through the extending surface, John et al 22 and Khan et al 23 , in relation to the applications of hybrid nanofluid flow, during the analysis the scholar investigated that the working capability of hybrid nanofluid is good as compared to mono nanofluid, Sidik et al 24 , concerning some basic operations and methods for the preparation of hybrid nanofluid discuss some techniques with stability and explain some useful applications of hybrid nano-composite in modern science and technology, Varun et al 25 , where a two phase flow over a stretched cylinder with the uniform dispersion of hybrid nanofluid has been derived and Li et al 26 , concerning aluminum oxide and copper hybrid nanofluid flow dynamics also in connection with the effect of entropy generation. Hosseinzadeh et al 27 , studied heat transfer applications using hybrid nanofluid in various thermal systems.…”

Section: Introductionmentioning

confidence: 68%

Heat transfer analysis of fractional model of couple stress Casson tri-hybrid nanofluid using dissimilar shape nanoparticles in blood with biomedical applications

Arif

Persio

Watthayu

et al. 2023

Sci Rep

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During last decades the research of nanofluid is of great interest all over the World, particularly because of its thermal applications in engineering, and biological sciences. Although nanofluid performance is well appreciate and showed good results in the heat transport phenomena, to further improve conventional base fluids thermal performance an increasing number of researchers have started considering structured nanoparticles suspension in one base fluid. As to make an example, when considering the suspension of three different nanoparticles in a single base fluid we have the so called “ternary hybrid nanofluid”. In the present study three different shaped nanoparticles are uniformly dispersed in blood. In particular, the three different shaped nanoparticles are spherical shaped ferric oxide $$\text{Fe}_{3} \text{O}_{4}$$ Fe 3 O 4 , platelet shaped zinc $$\left( \text{Zn} \right)$$ Zn , and cylindrical shaped gold $$\left( \text{Au} \right)$$ Au , which are considered in blood base fluid because of related advance pharmaceutical applications. Accordingly, we focused our attention on the sharp evaluation of heat transfer for the unsteady couple stress Casson tri-hybrid nanofluid flow in channel. In particular, we formulated the problem via momentum and energy equations in terms of partial differential equations equipped with realistic physical initial and boundary conditions. Moreover, we transformed classical model into their fractional counterparts by applying the Atangana–Baleanu time-fractional operator. Solutions to velocity and temperature equations have been obtained by using both the Laplace and the Fourier transforms, while the effect of physical parameters on velocity and temperature profiles, have been graphically analyzed exploiting MATHCAD. In particular, latter study clearly shows that for higher values of volume fraction $$\phi_{hnf}$$ ϕ hnf of the nanoparticles the fluid velocity declines, while the temperature rises for the higher values of volume fraction $$\phi_{hnf}$$ ϕ hnf of the nanoparticles. Using blood-based ternary hybrid nanofluid enhances the rate of heat transfer up-to 8.05%, spherical shaped $$\text{Fe}_{3} \text{O}_{4}$$ Fe 3 O 4 enhances up-to 4.63%, platelet shaped $$\left( \text{Zn} \right)$$ Zn nanoparticles enhances up-to 8.984% and cylindrical shaped gold $$\left( \text{Au} \right)$$ Au nanoparticles enhances up-to 10.407%.

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Section: Introductionmentioning

confidence: 68%

Heat transfer analysis of fractional model of couple stress Casson tri-hybrid nanofluid using dissimilar shape nanoparticles in blood with biomedical applications

Arif

Persio

Watthayu

et al. 2023

Sci Rep

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“…Additional types

{\rho }_{s}

, and

{\kappa }_{s}

denote the constancy, functioning thermal capacitance, and heat conductance of solid particles, respectively. Physical features of base‐fluid EO and various nano solid particles are tabulated in Table 2 37,38 …”

Section: Mathematical Constructionmentioning

confidence: 99%

Raising thermal efficiency of solar water‐pump using Oldroyd‐B nanofluids' flow: An optimal thermal application

Shahzad

Jamshed

et al. 2022

Energy Science & Engineering

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It is well known that solar energy is the main source of thermal energy coming from the sun responsible for huge operations in engineering studies. It can be seen in the technology of photovoltaic cells, solar streetlights, solar energy plates, and solar water pumping. This study is for investigating solar radiation as well as a method to improve the performance of the solar water pump (SWP) with the use of solar radiation along with nanotechnology. The thermal transfer performance of the pump is checked for the case of many impacts including heat radiations and variable thermal conductivity. An Oldroyd‐B nanofluid with entropy production analysis has been scrutinized as a working coolant liquid in the system. Graphene oxide (GO) and Cu nanoparticles have been employed in engine oil (EO) as the base liquid. It is noticed that the heat transfer performance of SWP increases in the case of amplification in thermal radiation and temperature‐dependent thermal conductivity characteristics. In comparison to low thermal conductivity nanofluid, high thermal conductivity nanofluid provides the best capability for heat transmission. The thermal efficiency of the used (GO/EG) nanofluid has been enhanced by between 7.70% and 26.68% than (Cu/EO) nanofluid.

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“… κ n f * ( ¥ ) represents the tempera-ture dependent thermal conductivity and ϵ is its contact. The physical characteristics of the standard liquid sodium alginate and diverse nanoparticle employed in the current research are given in Table 2 (see for details 76–78 ).…”

Section: Flow Model Formulationsmentioning

confidence: 99%

Computational technique of thermal comparative examination of Cu and Au nanoparticles suspended in sodium alginate as Sutterby nanofluid via extending PTSC surface

Jamshed

Safdar

Rehman

et al. 2022

Journal of Applied Biomaterials & Functional Materials

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Current research underscores entropy investigation in an infiltrating mode of Sutterby nanofluid (SNF) stream past a dramatically expanding flat plate that highlights Parabolic Trough Solar Collector (PTSC). Satisfactory likeness factors are utilized to change halfway differential conditions (PDEs) to nonlinear conventional differential conditions (ODEs) along with relating limit requirements. A productive Keller-box system is locked in to achieve approximated arrangement of decreased conventional differential conditions. In the review, two sorts of nanofluids including Copper-sodium alginate (Cu-SA) and Gold-sodium alginate (Au-SA) are dissected. Results are graphically plotted as well as talked about in actual viewpoints. As indicated by key discoveries, an improvement in Brinkmann, as well as Reynolds number, brings about expanding the general framework entropy. Sutterby nanofluid boundary improves heat rate in PTSC. Additionally, Copper-sodium alginate nanofluid is detected as a superior thermal conductor than Gold-sodium alginate nanofluid. Further to that, the reported breakthroughs are beneficial to updating extremely bright lighting bulbs, heating and cooling machinery, ﬁber required to generate light, power production, numerous boilers, and other similar technologies.

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Solar water-pump thermal analysis utilizing copper–gold/engine oil hybrid nanofluid flowing in parabolic trough solar collector: Thermal case study

Cited by 66 publications

References 40 publications

Heat transfer analysis of fractional model of couple stress Casson tri-hybrid nanofluid using dissimilar shape nanoparticles in blood with biomedical applications

Heat transfer analysis of fractional model of couple stress Casson tri-hybrid nanofluid using dissimilar shape nanoparticles in blood with biomedical applications

Raising thermal efficiency of solar water‐pump using Oldroyd‐B nanofluids' flow: An optimal thermal application

Computational technique of thermal comparative examination of Cu and Au nanoparticles suspended in sodium alginate as Sutterby nanofluid via extending PTSC surface

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