Unsteady squeezing flow of a magnetized nano-lubricant between parallel disks with Robin boundary conditions

IF 4.2 Q2 NANOSCIENCE & NANOTECHNOLOGY

Proceedings of the Institution of Mechanical Engineers Part N-Journal of Nanomaterials Nanoengineering and Nanosystems Pub Date : 2021-07-28 DOI:10.1177/23977914211036562

J. Umavathi, Sapnali Limbaraj Patil, B. Mahanthesh, O. A. Bég

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引用次数: 17

Abstract

The aim of the present work is to examine the impact of magnetized nanoparticles (NPs) in enhancement of heat transport in a tribological system subjected to convective type heating (Robin) boundary conditions. The regime examined comprises the squeezing transition of a magnetic (smart) Newtonian nano-lubricant between two analogous disks under an axial magnetism. The lower disk is permeable whereas the upper disk is solid. The mechanisms of haphazard motion of NPs and thermophoresis are simulated. The non-dimensional problem is solved numerically using a finite difference method in the MATLAB bvp4c solver based on Lobotto quadrature, to scrutinize the significance of thermophoresis parameter, squeezing number, Hartmann number, Prandtl number, and Brownian motion parameter on velocity, temperature, nanoparticle concentration, Nusselt number, factor of friction, and Sherwood number distributions. The obtained results for the friction factor are validated against previously published results. It is found that friction factor at the disk increases with intensity in applied magnetic field. The haphazard (Brownian) motion of nanoparticles causes an enhancement in thermal field. Suction and injection are found to induce different effects on transport characteristics depending on the specification of equal or unequal Biot numbers at the disks. The main quantitative outcome is that, unequal Biot numbers produce significant cooling of the regime for both cases of disk suction or injection, indicating that Robin boundary conditions yield substantial deviation from conventional thermal boundary conditions. Higher thermophoretic parameter also elevates temperatures in the regime. The nanoparticles concentration at the disk is boosted with higher values of Brownian motion parameter. The response of temperature is similar in both suction and injection cases; however, this tendency is quite opposite for nanoparticle concentrations. In the core zone, the resistive magnetic body force dominates and this manifests in a significant reduction in velocity, that is damping. The heat build-up in squeeze films (which can lead to corrosion and degradation of surfaces) can be successfully removed with magnetic nanoparticles leading to prolonged serviceability of lubrication systems and the need for less maintenance.

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具有Robin边界条件的磁化纳米润滑剂在平行圆盘间的非定常挤压流动

本研究的目的是研究磁化纳米颗粒(NPs)在摩擦系统中对流加热(Robin)边界条件下增强热传递的影响。所研究的体制包括磁性(智能)牛顿纳米润滑剂在两个类似圆盘之间的轴向磁性的挤压跃迁。下盘是可渗透的，而上盘是固体的。模拟了NPs随机运动和热泳的机制。在基于Lobotto正交的MATLAB bvp4c求解器中，采用有限差分法对无量纲问题进行了数值求解，考察了热涌参数、挤压数、哈特曼数、普朗特尔数和布朗运动参数对速度、温度、纳米颗粒浓度、努selt数、摩擦因数和舍伍德数分布的影响。得到的摩擦系数的结果与先前发表的结果进行了验证。结果表明，在外加磁场作用下，摩擦系数随磁场强度的增大而增大。纳米颗粒的随机(布朗)运动引起热场增强。发现吸入和注入对输运特性的影响不同，这取决于磁盘上的Biot数相等或不相等的规格。主要的定量结果是，不相等的Biot数对盘吸或盘注两种情况都会产生显著的冷却，这表明Robin边界条件与传统的热边界条件有很大的偏差。较高的热泳参数也会使体系中的温度升高。随着布朗运动参数的增大，圆盘上纳米颗粒的浓度增加。吸力和注入情况下的温度响应相似;然而，这种趋势与纳米颗粒浓度完全相反。在核心区，磁阻体力占主导地位，这表现为速度的显著降低，即阻尼。磁性纳米颗粒可以成功地消除挤压膜中的热量积聚(可能导致表面腐蚀和降解)，从而延长润滑系统的使用寿命，减少维护需求。

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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来源期刊

Proceedings of the Institution of Mechanical Engineers Part N-Journal of Nanomaterials Nanoengineering and Nanosystems NANOSCIENCE & NANOTECHNOLOGY-

CiteScore

6.00

自引率

1.70%

发文量

期刊介绍： Proceedings of the Institution of Mechanical Engineers Part N-Journal of Nanomaterials Nanoengineering and Nanosystems is a peer-reviewed scientific journal published since 2004 by SAGE Publications on behalf of the Institution of Mechanical Engineers. The journal focuses on research in the field of nanoengineering, nanoscience and nanotechnology and aims to publish high quality academic papers in this field. In addition, the journal is indexed in several reputable academic databases and abstracting services, including Scopus, Compendex, and CSA's Advanced Polymers Abstracts, Composites Industry Abstracts, and Earthquake Engineering Abstracts.