洞察元推动力对三层动态热传输中埃利斯流体流动的影响:理论研究

S. Shaheen, M. B. Arain, Nouman Ijaz, Faisal Z. Duraihem, Junhui Hu
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引用次数: 0

摘要

以纤毛为基础的治疗纤毛疾病的疗法正在兴起,例如用可吸入药物将粘液从囊性纤维化患者的肺部排出。这促使科学家和研究人员研究纤毛运动力学和粘弹性流体特性,以用于生物医学工程应用和疾病治疗。鉴于纤毛运动对生物的多种影响,本研究重点关注圆柱形管内纤毛跳动推动的三层非牛顿流体的传质和传热流动。流体不可压缩,各层之间互不混合。研究考虑了三种不同状态下质量和热量传递的影响,确保了界面的连续性。为了简化,采用了包含润滑近似、小雷诺数和长波长近似的数学模型。由此产生的微分方程以及边界条件,为三个流体层中的温度场、速度场和浓度场提供了精确的解决方案,并以图表形式进行了讨论。主要研究结果表明,速度场和温度场在流体内层(PCL)最为明显,而浓度剖面在外层(ACL)最为突出,在中心区域表现一般。这项研究的意义涉及多个领域,包括呼吸道粘液清除、微流体学、食管传输、生物流体力学和其他生理学领域。这项研究获得的见解有望应用于开发新的治疗方法和生物医学工程解决方案。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Insights into metachronal propulsion's influence on Ellis fluid flow across tri‐layers amid dynamic thermal transport: Theoretical study
Cilia‐based therapies are emerging for treating ciliopathies, such as inhalable drugs to propel mucus out of the lungs of patients with cystic fibrosis. This has motivated scientists and researchers to investigate cilia motion mechanics and viscoelastic fluid properties for biomedical engineering applications and disease treatments. In line with the diverse biological implications, this study focuses on the mass and heat transfer flow of tri‐layered non‐Newtonian fluids propelled by ciliary beating in a cylindrical tube. The fluid remains incompressible, with distinct layers that do not mix. The study considers the impact of mass and heat transfer in three distinct regimes, ensuring continuity at the interfaces. Mathematical modeling incorporating the lubrication approximation, small Reynolds number, and long wavelength approximation is employed for simplification. The resulting differential equations, along with boundary conditions, yield accurate solutions for temperature, velocity, and concentration fields in the three fluid layers and are discussed graphically. Key findings demonstrate that velocity and temperature fields are most pronounced in the inner fluid layer (PCL), while the concentration profile is most prominent in the outer layers (ACL), with moderate behavior in the central region. The implications of this research extend to diverse fields, including mucus clearance from the respiratory tract, microfluidics, esophageal transport, biofluid mechanics, and other areas of physiology. The insights gained from this study have promising applications in developing new treatments and biomedical engineering solutions.
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