Flow Physics of a Rotating Bernoulli Pad: A Numerical Study

Journal of Fluids Engineering Pub Date : 2024-03-22 DOI:10.1115/1.4065148

Anshul S. Tomar, A. Hellum, Kristina M. Kamensky, Ranjan Mukherjee

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Abstract

Bernoulli pads are traditionally used for non-contact pick-and-place operations in industry. The normal force produced by a Bernoulli pad allows it to adhere to an object or workpiece. In addition to the normal force, the pad produces shear forces, which allows it to clean a workpiece without contact. A direct relationship between the inlet fluid power and the shear losses motivates us to explore other methods of providing power to the system with the objective of increase shear forces and thereby improve cleaning efficacy. Here we numerically investigate a system in which additional mechanical power is added by rotating the Bernoulli pad. The rotating system provides additional fluid forces (normal and shear) for the same inlet fluid power. For a specific pad that we investigated, the maximum wall shear stress increased by ≈ 15 % and the normal force changed from +1.4 N (repulsive) to -6.6 N (attractive) for change in the rotational speed by 60 rad/s. Also, for a given normal attractive force, a stable equilibrium configuration can exist for two mass flow rates, with the higher mass flow rate resulting in a higher stiffness of the flow field.

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旋转伯努利垫的流动物理学：数值研究

传统上，伯努利垫用于工业领域的非接触式拾放操作。伯努利衬垫产生的法向力使其能够附着在物体或工件上。除了法向力之外，衬垫还能产生剪切力，使其能够在不接触的情况下清洁工件。入口流体功率与剪切力损失之间的直接关系促使我们探索向系统提供功率的其他方法，以增加剪切力，从而提高清洁效果。在此，我们对通过旋转伯努利垫增加机械动力的系统进行了数值研究。在相同的进气流体功率下，旋转系统可提供额外的流体力（法向力和剪切力）。对于我们研究的一个特定垫块，当转速改变 60 弧度/秒时，最大壁面剪应力增加了 ≈ 15 %，法向力从 +1.4 N（排斥力）变为 -6.6 N（吸引力）。此外，在给定法向吸引力的情况下，两种质量流量下都可以存在稳定的平衡配置，质量流量越大，流场的刚度越大。

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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Journal of Fluids Engineering

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