Referencias Por último, se ha validado experimentalmente el modelo por medio de [1] A. A. G. Bruzzone, H. L. Costa, P. M. Lonardo, D. A. Lucca, Advances in engineered surfaces for functional performance, CIRP Annals- la comparación de cavidades simuladas con cavidades generadas en Manufacturing Technology 57 (2008) 750-769. ensayos de fresado de cinco ejes. [2] D. G. Coblas, A. Fatu, A. Maoui and M. Hajjam, Manufacturing textured surfaces: State of art and recent developments, Proc I. Mech. E. Part J: J Engineering Tribology 2015, Vol. 229(1) 3–29. Para ello, se han comparado la forma, las dimensiones y profundidad [3] A. Arslan, H. H. Masjuki, M. A. Kalam, M. Varman, R. A. Mufti, M. H. Mosarof, L. S. Khuong, M. M. Quazi (2016): Surface Texture de las cavidades y se ha observado una buena correspondencia entre Manufacturing Techniques and Tribological Effect of Surface Texturing on Cutting Tool Performance: A Review, Critical Reviews in las cavidades predichas y medidas. Solid State and Materials Sciences, DOI: 10.1080/10408436.2016.1186597. [4] T. Ibatan, M.S. Uddin, M.A.K. Chowdhury, Recent development on surface texturing in enhancing tribological performance of bearing sliders, Surface & Coatings Technology 272 (2015) 102–120. [5] Y. Qiu, M. M. Khonsari, Experimental investigation of tribological performance of láser textured stainless steel rings, Tribology International 44 (2011) 635–644. [6] S. Wos, W. Koszela, P. Pawlus, The effect of both surfaces textured on improvement of tribological properties of sliding elements, Tribology International 113 (2017) 182–188. [7] L. Galda, J. Sep, S. Prucnal, The effect of dimples geometry in the sliding surface on the tribological properties under starved lubri- cation conditions, Tribology International 99 (2016) 77–84. [8] A. Greco, S. Raphaelson, K. Ehmann, Q. J. Wang, and C. Lin, Surface texturing of tribological interfaces using the vibromechanical texturing method, J. Manufact. Sci. Eng. 131(6), 061005 (2009). [9] P. Guo, K. F. Ehmann, An analysis of the surface generation mechanics of the elliptical vibration texturing process, Int. J. Mach. Tools Manuf. 64 (2013) 85–95. [10] C. Zhang, G. Shi, K. F. Ehmann, Investigation of hybrid micro-texture fabrication in elliptical vibration assisted cutting, International Journal of Machine Tools & Manufacture 120 (2017) 72–84. [11] E. Graham, C. I. Park, and S. S. Park, Fabrication of Micro-Dimpled Surfaces through Micro Ball End Milling, Int. J. of Precision Engineering and Manufacturing, Sept. 2013, Vol.14, No. 9, pp. 1637-1646. [12] E. Graham, C. I. Park, S. S. Park, Force modeling and applications of inclined ball end milling of micro-dimpled surfaces, Int. J. Adv. Manuf. Technol. (2014) 70:689–700. [13] T. Matsumura, S. Takahashi, Micro dimple milling on cylinder surfaces. Journal of Manufacturing Processes 14 (2012) 135–140. [14] A. Zabel, T. Surmann, A. Peuker, Surface Structuring and Tool Path Planning for Ef cient Milling of Dies, Seventh International Conference on High Speed Machining 2008, p. 155-160. [15] J. Resendiz, E. Graham, P. Egberts, S. S. Park, Directional friction surfaces through asymmetrically shaped dimpled surfaces patter- ned using inclined at end milling, Tribology International 91 (2015) 67–73. [16] M. Arizmendi, M. Artano, A. Jiménez, Generación de texturas super ciales por fresado en cinco ejes, XXI Congreso Nacional de Ingeniería Mecánica, Elche 2016. Agradecimientos Los autores agradecen al Ministerio de Economía y Competitividad la nanciación del proyecto Turbo (DPI2013-46164-C2-2-R), gra- cias a la cual se ha realizado este trabajo. TRATAMIENTOS DE SUPERFÍCIE >>45