Acta Mechanica Slovaca 2023, 27(2):32-41 | DOI: 10.21496/ams.2023.023

Comparison of the Surface Roughness and its Geometric Model in Case of Z-level Milling

Balázs Mikó ORCID...1, *
Institute of Mechanical Engineering and Technology, Óbuda University, Budapest 1081 Népszínház u. 8. Hungary

The Z-level milling technology is one of the most often used finishing milling strategy in case of the CNC milling of the steep free form surfaces. A main spindle parallel end-milling cutter can be used with or without corner radius, and the depth of cut means the axis parallel distance between the tool paths. During the planning of machining process two main aspects should be considered: the productivity and the accuracy. The accuracy means macro and micro accuracy. In this article the surface roughness, as a part of micro accuracy, is investigated, and a geometric approach of its estimation is presented. The tool corner geometry, the depth of cut and the inclination of the surface are considered, and the critical inclination is introduced. The theoretical description of the surface roughness is compared with the results of milling tests. As concluded, the cusp height, as the geometric model of the surface roughness can be a good base of the estimation, but a detailed and case depend model is required. The results ensure a better selection of tool path parameters in CAM systems considering the properties of cutting tool and the surface.

Keywords: Free form surface; Surface roughness; Z-level milling; Cusp height; Geometric model

Received: April 3, 2023; Revised: April 25, 2023; Accepted: May 2, 2023; Published: June 15, 2023  Show citation

ACS AIP APA ASA Harvard Chicago Chicago Notes IEEE ISO690 MLA NLM Turabian Vancouver
Mikó, B. (2023). Comparison of the Surface Roughness and its Geometric Model in Case of Z-level Milling. Acta Mechanica Slovaca27(2), 32-41. doi: 10.21496/ams.2023.023
Share...
Download citation
  • BibTeX (.bib)
  • Bookends (.ris)
  • EasyBib (.ris)
  • EndNote (.enw)
  • EndNote 8 (.xml)
  • ISI WoS (.isi)
  • Medlars (.medlars)
  • Mendeley (.ris)
  • MODS (.xml)
  • Papers (.ris)
  • RefWorks (.txt)
  • RefManager (.ris)
  • RIS (.ris)
  • MS Word (.xml)
  • Zotero (.ris)
    • Open full article

    References

    1. Bernardos P.G., Vosniakos G.C. (2003) Predicting surface roughness in machining: a review. International Journal of Machine Tools & Manufacture. 43(8):833-844. Go to original source...
    2. Grzesik W., Kruszynski B., Ruszaj A. (2010) Surface integrity of machined surfaces. In Davim, j. (eds) Surface Integrity in Machining. Springer, London. pp.143-179. Go to original source...
    3. Wang B. et al (2020): A predictive model of milling surface roughness. International Journal of Advanced Manufacturing Technology 108:2755-2762. Go to original source...
    4. Bílek O. et al (2020) Prediction and modelling of roughness in ball end milling with tool-surface inclination. Development of Materials Science in Research and Education (DMSRE29) IOP Conf. Series: Materials Science and Engineering. 726:012003. Go to original source...
    5. Matras A., Zębala W. (2020) Optimization of cutting data and tool inclination angles during hard milling with CBN tools, based on force predictions and surface roughness measurements. Materials. 13(5):1109 Go to original source...
    6. Iľol P., Vrabeµ M., Maňková I. (2016) Comparison of milling strategies when machining freeform surfaces. Materials Science Forum. 862:18-25. Go to original source...
    7. Kovač P. et al. (2017) Application of neuro-fuzzy systems for modelling surface roughness parameters for difficult-to-cut-steel. Solid State Phenomena. 261:277-284. Go to original source...
    8. Karkalos N.E., Galanis N.I., Markopoulos A.P. (2016) Surface roughness prediction for the milling of Ti-6Al-4V ELI alloy with the use of statistical and soft computing techniques. Measurement. 90:25-35. Go to original source...
    9. Cavusoglu I., Durakbasa M.N., Cakir M. (2018) The effects of drilling operation on the surface roughness of modified GFRP composites. Acta Physica Polonica A. 134(1):339-341. Go to original source...
    10. Karpuschewski B. et al. (2018) Effects of the tool edge design on the roughness of face milled surfaces. IOP Conference Series: Materials Science and Engineering. 448:012056. Go to original source...
    11. Bílek O. et al. (2018) Mathematical methods of surface roughness evaluation of areas with a distinctive inclination. Manufacturing Technology. 18(3): 363-368. Go to original source...
    12. Kundrák J., Felhő Cs. (2018) Investigation of the topography of face milled surfaces. Materials Science Forum. 919:78-83. Go to original source...
    13. Shaik J.H., Srinivas J. (2017) Optimal selection of operating parameters in end milling of Al-6061 work materials using multi-objective approach. Mechanics of Advanced Materials and Modern Processes. 3:5. Go to original source...
    14. Rifai A.P. et al. (2020) Evaluation of turned and milled surfaces roughness using convolutional neural network. Measurement. 161:107860 Go to original source...
    15. Jacsó Á., Szalay T. (2020) Optimizing the numerical algorithm in fast constant engagement offsetting method for generating 2.5D milling tool paths. International Journal of Advanced Manufacturing Technology. 108:2285-2300. Go to original source...
    16. Mikó B., Horváth T., Varga B. (2018) Cusp height and surface roughness in z-level milling. Conference Proceedings Development in Machining Technology 8:123-133.

    This is an open access article distributed under the terms of the Creative Commons Attribution 4.0 International License (CC BY 4.0), which permits use, distribution, and reproduction in any medium, provided the original publication is properly cited. No use, distribution or reproduction is permitted which does not comply with these terms.


    Return to the content