Numerical and experimental investigation on flow field during fixed abrasive lapping for structural optimization of lapping tool

Abstract

Owing to its superior machining efficiency and precision, fixed abrasive lapping is considered as a promising technology in ultra-precision machining, with demonstrated success across diverse material systems including metals, ceramics, semiconductors, and beyond. The flow characteristics of slurry in contact area between workpiece and tool play an important role in maintaining stability of workpiece temperature and promoting rapid removal of debris. To enhance material removal performance and surface quality of 4H-SiC lapping process, computational fluid dynamics simulations and experimental studies of flow field on fixed abrasive pad surface were conducted with aim of designing a novel structure. The effects of groove structure and size parameters on flow field and velocity distribution were investigated through a series of simulation analyses. Furthermore, the distributed scatter point methods were applied to simulation results, and the flow velocity uniformity was employed to quantitatively evaluate flow field characteristics. The liquid phase and flow velocity distribution under different groove structures and different groove widths are compared and discussed. Relevant experiments were designed to verify simulation results, and lapping effect of fixed abrasive pad was analyzed. The results show that hexagonal structure fixed abrasive pad has better flow characteristics than concentric radial and circular. In this experiment, when fixed abrasive pad speed is 60 r/min, the surface roughness of SiC machined by hexagonal structure fixed abrasive pad reaches 2.4 nm, which corresponds to the flow velocity uniformity value predicted by the simulation results at 60 r/min. The surface accuracy of workpiece machined by fixed abrasive pad can reach submicron level.

Keywords

Fixed abrasive pad surface grooves flow velocity uniformity slurry surface quality

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References

Deja

Zieliński

. Wear of electroplated diamond tools in lap-grinding of Al₂O₃ ceramic materials. Wear 2020; 460–461: 203461.

Żak

Grzesik

. Metrological aspects of surface topographies produced by different machining operations regarding their potential functionality. Metrol Meas Syst 2017; 24: 325–335.

Sanchez

LEA

Jun

NZX

Fiocchi

. Surface finishing of flat pieces when submitted to lapping kinematics on abrasive disc dressed under several overlap factors. Precis Eng 2011; 35: 355–363.

Gatzen

Maetzig

. Nanogrinding. Precis Eng 1997; 21: 134–139.

Tomita

Eda

. A study of the ultra precision grinding process on a magnetic disk substrate—development of new bonding materials for fixed abrasives of grinding stone. Wear 1996; 195: 74–80.

Wang

Chen

, et al. Accelerated C-face polishing of silicon carbide by alkaline polishing slurries with Fe₃O₄ catalysts. J Environ Chem. Eng 2021; 9: 106863.

Wang

Tie

, et al. Effect of different lapping strategies on subsequent polishing processes of sapphire. J Manuf Processes 2024; 112: 339–357.

Jackson

. Recent advances in ultraprecision abrasive machining processes. SN Appl Sci 2020; 2: 1172.

Feng

Lyu

Zhao

, et al. Fabrication and application of gel-forming CeO₂ fixed abrasive tools for quartz glass polishing. Int J Precis Eng Manuf 2022; 23: 985–1002.

10.

Zhu

Beaucamp

. Compliant lapping and polishing: a review. Int J Mach Tool Manuf 2020; 158: 103634.

11.

Huang

Xia

. Effect of chemical additive on fixed abrasive pad self-conditioning in CMP. Int J Adv Manuf Technol 2017; 88: 107–113.

12.

Chen

Peng

Wang

, et al. In-situ reconditioning mechanism for fixed abrasive pads based on the wear behavior of loose grains. Precis Eng 2024; 88: 633–643.

13.

Zhang

Yan

Wang

. The wear behavior and lapping performance of fixed abrasive pad for acidity and alkalinity of lapping fluid in lapping quartz glass. Tribol Int 2024; 195: 109615.

14.

Zhu

Jin

Dong

, et al. Design of a novel fixed abrasive petal-shaped lapping tool and material removal uniformity experiments on K9 glass. J Manuf Processes 2023; 90: 204–215.

15.

Fang

Liu

Zhao

. Study on geometrical patterns of textured fixed-abrasive pads in sapphire lapping based on trajectory analysis. Precis Eng 2018; 53: 169–178.

16.

Liu

Tang

. An approach for hydrophobic fixed abrasive pad based on layer-by-layer method. Microelectron Eng 2021; 238: 111505.

17.

Liu

Wang

, et al. Optimization of polishing path and material removal for uniform material removal in optical surface polishing. Int J Adv Manuf Technol 2023; 124: 1699–1722.

18.

Fang

Zhao

. Influence of pellet shape and size on the pattern performance of textured fixed-abrasive pads in single-sided lapping. J Ind Prod Eng 2020; 37: 46–55.

19.

Jin

Wang

, et al. A novel functionally graded lapping and polishing method for the improvement of material removal uniformity. J Manuf Process 2020; 50: 102–110.

20.

Liao

Ren

Zhang

, et al. Kinematic model for material removal distribution and surface figure in full-aperture polishing. Appl Optics 2019; 57: 588–593.

21.

Zhang

Yang

, et al. CFD simulation and experimental studies of suspension flow field in ultrasonic polishing. J Mater Process Technol 2019; 266: 715–725.

22.

Huang

Hua

, et al. Design of surface grooves on a polishing pad based on slurry uniform flow. Int J Adv Manuf Technol 2019; 103: 4795–4803.

23.

Chen

Sun

, et al. A novel agglomerated diamond abrasive with excellent micro-cutting and self-sharpening capabilities in fixed abrasive lapping processes. Wear 2021; 464-465: 203531.

24.

Yang

Guo

Kang

, et al. Effect of kinematic parameters considering workpiece rotation on surface quality in YAG double-sided planetary lapping with the trajectory method. Int J Adv Manuf Technol 2022; 123: 2679–2690.

25.

Fujita

Watanabe

. Slurry supply mechanism utilizing capillary effect in chemical mechanical planarization. ECS J Solid State Sci Technol 2019; 8: P3069–P3074.

26.

Cho

Liu

Jeon

, et al. Simulation and experimental investigation of the radial groove effect on slurry flow in oxide chemical mechanical polishing. Appl Sci 2022; 12: 4339.

27.

Liu

Zhang

. On the global stability of large Fourier mode for 3-D Navier–Stokes equations. Adv Math 2024; 438: 109475.

28.

Huang

Lin

Ardekani

. A consistent and conservative phase-field method for multiphase incompressible flows. J Comput Appl Math 2022; 408: 114116.

29.

Lin

Liao

. Simulation of slurry residence time during chemical-mechanical polishing using 3-D computational fluid dynamics. Chem Eng Res Des 2023; 191: 375–386.

30.

Nguyen

Tian

Zhong

. Modeling and simulation for the distribution of slurry particles in chemical mechanical polishing. Int J Adv Manuf Technol 2014; 75: 97–106.

31.

Tang

, et al. Effect of slurry and fixed abrasive pad on chemical mechanical polishing of SiC wafer. Mater Sci Semicond Process 2025; 188: 109202.

32.

Vacassy

Gibson

Titov

, et al. Surface engineering of SiC through nanogrinding and CMP. Mater Sci Forum 2018; 924: 539–542.

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