Results are given for a study of the effect of surface grinding regimes with diamond wheels on Al2O3-ceramic surface condition. A correlation is established between grinding depth, longitudinal and transverse feed with roughness, waviness, and treated surface morphology.
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N. B. Demkin and É. V. Ryzhov, Surface Quality and Machine Component Contact [in Russian], Mashinostroenie, Moscow (1981).
A. G. Suslov, Machine Component Surface Layer Quality [in Russian], Mashinostroenie, Moscow (2000).
A. M. Sulima, V. A. Shulov, and Yu. D. Yagodkin, Machine Component Surface Layer and Operating Properties [in Russian], Mashinostroenie, Moscow (1988).
V. V. Kuzin, N. R. Portnoi, S. Yu. Fedorov, and V. I. Moroz, “Analysis of the reliability of ceramic parts after hydroabrasive machining,” Refract. Indust. Ceram., 56(6), 631 – 636 (2016).
V. Kuzin, S. Grigoriev, S. Fedorov, and M. Fedorov, “Surface defects formation in grinding of silicon nitride ceramics,” Appl. Mechan. Materials, 752/753, 402 – 406 (2015).
V. V. Kuzin, “Oxide ceramic surface layer modification using continuous laser radiation,” Refract. Indust. Ceram., 57, No. 1, 53 – 57 (2016).
V. Kuzin, “A model of forming the surface layer of ceramic parts based on silicon nitride in the grinding Process,” Key Engineering Materials, Precision Machining, 496, 127 – 131 (2012).
C. Jianyi, S. Jianyun, H. Hui, and X. Xipeng, “Grinding characteristics in high speed grinding of engineering ceramics with brazed diamond wheels,” J. Mater. Process. Technol., 210, 899 – 906 (2010).
H. Huang and Y. C. Liu, “Experimental investigations of machining characteristics and removal mechanisms of advanced ceramics in high speed deep grinding,” Machine Tools & Manufacture, 43. 811 – 823 (2003).
K. Kitajima, G. O. Cai, N. Kurnagai, and Y. Tanaka, “Study on mechanism of ceramics grinding,” Annals of the CIRP, 14, 367 – 371 (1992).
E. C. Bianchi, P. R. Aguiar, E. J. da Silva, C. E. da Silva Jr., and C. A. Fortulan, “Advanced ceramics: evaluation of ground surface,” Ceramica, 49, 174 – 177 (2003).
V. Kuzin, S. Grigoriev, and M. Portnoy, “Effect of thermal loading on stresses in defective surface layer of ceramics,” Appl. Mechan. Materials, 827, 189 – 192 (2016).
V. V. Kuzin, S. N. Grigoriev, and M. R. Portnoy, “Stress state of surface layer of oxide ceramics with single defect under the influence of intensive heat flow,” 53rd Conference on Experimental Stress Analysis — EAN 2015, 1 – 4 June, 015, Czech Republic; ed. by P. Padevìt and P. Bittnar.
Y. F. Diao, Y. G. Wang, B. Lin, and L. J. Li, “Experimental research on grinding surface waviness of engineering ceramics,” Materials Sci. Forum, 770, 175 – 178 (2014).
V. V. Kuzin, “Increasing the operational stability of nitride-ceramic cutters by optimizing their grinding Conditions,” Russ. Eng. Research, 23(12), 32 – 36 (2003).
V. V. Kuzin, “Technological aspects of diamond grinding of the nitride ceramics,” Russ. Eng. Research, 24(1), 23 – 28 (2004).
V. V. Kuzin, “Technology for machining highly refractory ceramic parts based on silicon nitride,” Refract. Indust. Ceram., 47(4), 204 – 208 (2006).
Work was carried out with financial support of the RF Ministry of Education and Science within the scope of carrying out a state assignment in the sphere of scientific activity (assignment No. 2014/105, project No. 1908).
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Translated from Novye Ogneupory, No. 7, pp. 65 – 70, July, 2016.
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Kuzin, V.V., Fedorov, S.Y. Roughness of High Hardness Ceramic Correlation of Diamond Grinding Regimes with Al2O3-Ceramic Surface Condition. Refract Ind Ceram 57, 388–393 (2016). https://doi.org/10.1007/s11148-016-9990-x
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DOI: https://doi.org/10.1007/s11148-016-9990-x