# Numerical Simulation and Experimental Study on Polishing Fluid Dynamics and Material Removal in Metal Ultrasonic Vibration Polishing

**Authors:** Xianling Li, Jingchang Chen, Dalong Zhang, Bicheng Guo, Xiuyu Chen, Zhilong Xu

PMC · DOI: 10.3390/mi17020208 · Micromachines · 2026-02-03

## TL;DR

This study combines simulations and experiments to understand how ultrasonic polishing removes material from metals, revealing how different mechanisms affect surface quality and stress.

## Contribution

The paper introduces a combined CFD and experimental approach to clarify the multi-mechanism material removal in ultrasonic polishing.

## Key findings

- Cavitation significantly affects the flow field by reducing pressure peaks and flow velocity.
- Material removal mechanisms vary spatially, with cavitation erosion in the center and fluid-mechanical scraping at the edges.
- Residual compressive stress increases by 19.7% to 33.6%, improving material fatigue resistance.

## Abstract

To address the bottleneck issues of traditional ultrasonic polishing—such as unclear material removal mechanisms for ductile metals and difficulties in controlling machining outcomes—this paper employs a combined approach of computational fluid dynamics (CFD) simulation and non-contact fixed-point polishing experiments to systematically reveal the intrinsic relationship between the dynamic characteristics of the polishing flow field and the evolution of the material surface. Numerical simulations demonstrate that the cavitation effect significantly regulates the flow field structure: it not only confines the minimum pressure near the saturated vapor pressure but also markedly reduces the pressure peak while concurrently causing an overall decrease in flow velocity, forming a strongly coupled multi-parameter system of pressure, cavitation, and flow velocity. Experimental results indicate a clear spatial differentiation in the material removal mechanism: the central region is dominated by cavitation erosion, resulting in numerous pits and a 33.6% increase in residual compressive stress; the edge region is primarily governed by fluid-mechanical scraping, effectively improving surface finish and increasing residual stress by 22.3%; the transition zone, influenced by synergistic mechanisms, shows the smallest stress increase (19.7%). The enhancement of residual compressive stress can significantly improve the fatigue resistance of materials and prolong their fatigue life. This study comprehensively elucidates the multi-mechanism synergistic material removal process involving “cavitation impact, mechanical scraping, and fatigue spallation” in ultrasonic polishing, providing a key theoretical basis and process optimization direction for sub-micrometer ultra-precision machining.

## Full-text entities

- **Diseases:** injury to (MESH:D014947), fatigue (MESH:D005221), stroke (MESH:D020521), fatigue fracture (MESH:D015775)
- **Chemicals:** methanol (MESH:D000432), stainless steel (MESH:D013193), water (MESH:D014867), BK7 optical (-), silicon (MESH:D012825), SiC (MESH:C022088)
- **Species:** Homo sapiens (human, species) [taxon 9606]
- **Cell lines:** 1Cr17 — Mus musculus (Mouse), Hybridoma (CVCL_A0AJ)

## Full text

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## Figures

27 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12943100/full.md

## References

45 references — full list in the complete paper: https://tomesphere.com/paper/PMC12943100/full.md

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Source: https://tomesphere.com/paper/PMC12943100