Swirling Capillary Instability of Rivlin–Ericksen Liquid with Heat Transfer and Axial Electric Field

Physics Pub Date : 2024-06-03 DOI:10.3390/physics6020051
Dhananjay Yadav, M. K. Awasthi, Ashwani Kumar, N. Dutt
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Abstract

The mutual influences of the electric field, rotation, and heat transmission find applications in controlled drug delivery systems, precise microfluidic manipulation, and advanced materials’ processing techniques due to their ability to tailor fluid behavior and surface morphology with enhanced precision and efficiency. Capillary instability has widespread relevance in various natural and industrial processes, ranging from the breakup of liquid jets and the formation of droplets in inkjet printing to the dynamics of thin liquid films and the behavior of liquid bridges in microgravity environments. This study examines the swirling impact on the instability arising from the capillary effects at the boundary of Rivlin–Ericksen and viscous liquids, influenced by an axial electric field, heat, and mass transmission. Capillary instability arises when the cohesive forces at the interface between two fluids are disrupted by perturbations, leading to the formation of characteristic patterns such as waves or droplets. The influence of gravity and fluid flow velocity is disregarded in the context of capillary instability analyses. The annular region is formed by two cylinders: one containing a viscous fluid and the other a Rivlin–Ericksen viscoelastic fluid. The Rivlin–Ericksen model is pivotal for comprehending the characteristics of viscoelastic fluids, widely utilized in industrial and biological contexts. It precisely characterizes their rheological complexities, encompassing elasticity and viscosity, critical for forecasting flow dynamics in polymer processing, food production, and drug delivery. Moreover, its applications extend to biomedical engineering, offering insights crucial for medical device design and understanding biological phenomena like blood flow. The inside cylinder remains stationary, and the outside cylinder rotates at a steady pace. A numerically analyzed quadratic growth rate is obtained from perturbed equations using potential flow theory and the Rivlin–Ericksen fluid model. The findings demonstrate enhanced stability due to the heat and mass transfer and increased stability from swirling. Notably, the heat transfer stabilizes the interface, while the density ratio and centrifuge number also impact stability. An axial electric field exhibits a dual effect, with certain permittivity and conductivity ratios causing perturbation growth decay or expansion.
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具有热传导和轴向电场的里夫林-埃里克森液体的漩涡毛细管不稳定性
电场、旋转和热传导的相互影响可应用于可控给药系统、精确的微流体操作和先进的材料加工技术,因为它们能够以更高的精度和效率调整流体行为和表面形态。毛细管不稳定性在各种自然和工业过程中具有广泛的相关性,从喷墨打印中液体射流的破裂和液滴的形成,到薄液体薄膜的动力学和微重力环境中液桥的行为,不一而足。本研究探讨了漩涡对里夫林-埃里克森和粘性液体边界毛细管效应引起的不稳定性的影响,这种不稳定性受到轴向电场、热量和质量传输的影响。毛细管不稳定性产生于两种液体界面的内聚力被扰动破坏,导致波浪或液滴等特征模式的形成。毛细管不稳定性分析不考虑重力和流体流速的影响。环形区域由两个圆柱体构成:一个包含粘性流体,另一个包含 Rivlin-Ericksen 粘弹性流体。Rivlin-Ericksen 模型是理解粘弹性流体特性的关键,广泛应用于工业和生物领域。它能精确描述流变的复杂性,包括弹性和粘度,对于预测聚合物加工、食品生产和药物输送中的流动动力学至关重要。此外,它的应用还扩展到生物医学工程领域,为医疗设备设计和理解血液流动等生物现象提供了至关重要的见解。内圆柱体保持静止,外圆柱体以稳定的速度旋转。利用势流理论和里夫林-埃里克森流体模型,从扰动方程中获得了数值分析的二次增长率。研究结果表明,传热和传质增强了稳定性,漩涡增强了稳定性。值得注意的是,热传递使界面更加稳定,而密度比和离心数也会影响稳定性。轴向电场表现出双重效应,特定的介电常数和电导率比率会导致扰动增长衰减或膨胀。
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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