Two- and three-dimensional comparative study of heat transfer and pressure drop characteristics of nanofluids flow throu

PDF / 9,181,182 Bytes
28 Pages / 595.276 x 790.866 pts Page_size
103 Downloads / 217 Views

Two‑ and three‑dimensional comparative study of heat transfer and pressure drop characteristics of nanofluids flow through a ventilated cubic cavity (part II: non‑Newtonian nanofluids under the influence of a magnetic field) Seddik Kherroubi1 · Youb Khaled Benkahla1 · Abdelkader Boutra1,2 · Abdelghani Bensaci1 Received: 12 May 2020 / Accepted: 28 September 2020 © Akadémiai Kiadó, Budapest, Hungary 2020

Abstract In this paper, we study numerically the incompressible laminar mixed convection flow of Zinc Oxide nanolubricants in ventilated cavities (2D and 3D cavities), under the influence of a uniform magnetic field at various inclination angles. The ventilation is assured by two openings of the same size, located at the vertical walls, where the cold nanofluid enters through the opening, located at the top of the left wall, and exits through the second, located at the bottom of the right wall. All walls are considered hot except the lateral walls of the 3D configuration which are adiabatic. The non-Newtonian nanofluid (nanolubricants) considered in this study obeys the rheological model of Bingham. Incorporating the exponential Papanastasiou regularization approach of this model, the governing equations of the physical problem are discretized, using the finite volume method and the SIMPLER algorithm for the pressure–velocity coupling. For a wide range of pertinent control parameters, namely the Reynolds number and the nanoparticles volume fraction as well as the inclination angle of the magnetic field, at a fixed Hartmann number Ha = 100, the results show that, with/without magnetic field, the average Nusselt number increases and the pressure drop decreases with the Reynolds number. The presence of the magnetic field meaningfully increases the heat exchange and increases dramatically the pressure drop, compared to the case without a magnetic field, except for an inclination angle ω = 135°, where the heat exchange rate is reduced. However, nanoparticles improve heat exchange only beyond a yield value of the nanoparticles volume fraction and then become disadvantageous. In addition, the extent of the rigid zone is amplified with the nanoparticles volume fraction and the magnetic field. Finally, the optimal angle offering the best performance is ω = 0°. In addition, the introduction of nanoparticles and the increase in the inertial force increase the gap between the two configurations (2D and 3D). On the other hand, Lorentz’s force weakens the effect of the third direction. Keywords Mixed convection · Nanolubricants · Yield stress · Magnetic field · 2D–3D configurations List of symbols B0 External magnetic field/kg s−2 A−1 Bn Bingham number * Seddik Kherroubi [email protected] Youb Khaled Benkahla [email protected] Abdelkader Boutra [email protected] Abdelghani Bensaci [email protected] 1

Laboratory of Transport Phenomena, USTHB, 16111 Algiers, Algeria

Superior School of Applied Sciences, 16001 Algiers, Algeria

2

Cp Constant pressure specific heat/J kg−1 K−1 CD Pressure drop coefficient E Elect

Data Loading...

Two- and three-dimensional comparative study of heat transfer and pressure drop characteristics of nanofluids flow throu

Recommend Documents

Study on backward-facing step flow and heat transfer characteristics of hybrid nanofluids

Microgravity Two-Phase Flow and Heat Transfer

Heat Transfer Characteristics and Pressure Drop in a Horizontal Circulating Fluidized Bed Evaporator

Numerical Study of Heat Transfer and Pressure Drop in a Helically Coiled Tubes

Heat Transfer and Pressure Drop Assessment of a Vortex Generator Supported Fin-And-Tube Heat Exchanger

Nanofluids in Improving Heat Transfer Characteristics of Shell and Tube Heat Exchanger

Pressure drop, local heat transfer coefficient, and critical heat flux of DNB type for flow boiling in a horizontal stra

Augmentation of Heat Transfer and Pressure Drop Characteristics Inside a Double Pipe U-Tube Heat Exchanger by Using Twis

Heat-transfer and pressure-drop considerations in the design of Sirosmelt lances

Numerical study on flow and heat transfer characteristics of square cylinder with lateral sides extension effect

Fundamentals of Multiphase Heat Transfer and Flow

Convective heat transfer and double diffusive convection in ionic nanofluids flow driven by peristalsis and electromagne