How to cite this paper
Maximov, J., Duncheva, G., Anchev, A., Amudjev, I & Kuzmanov, V. (2014). Enhancement of fatigue life of rail-end-bolt holes by slide diamond burnishing.Engineering Solid Mechanics, 2(4), 247-264.
Refrences
Belgasim, O. & El-Axir, M.H. (2010). Modeling of Residual Stresses Induced in Machining Aluminum Magnesium Alloy (Al-3Mg). In: Proceedings of the World Congress on Engineering 2010, Vol II WCE 2010, June 30 - July 2 , London, U.K.
Birger, I.A. (1963). Residual stresses. Moscow: Mashgiz. (In Russian)
Cai, W., Wen, Z., Jin, X., & Zhai, W. (2007). Dynamic stress analysis of rail joint with height difference defect using finite element method. Engineering Failure Analysis, 14(8), 1488-1499.
Davidenkov, N.N. (1931). Measurement of residual stresses in tubes. Journal of Technical Physics, 1(1), 257-273. (In Russian)
Deng, W. J., Xia, W., Zhou, Z. Y., Chen, W. P., & Li, Y. Y. (2004, September). Finite element analysis of effects of ball burnishing parameters on residual stresses. In Materials Science Forum (Vol. 471, pp. 658-662).
Duncheva, G. V., & Maximov, J. T. (2013). A new approach to enhancement of fatigue life of rail-end-bolt holes. Engineering Failure Analysis, 29, 167-179.
El-Axir, M. H. (2000). An investigation into roller burnishing. International Journal of Machine Tools and Manufacture, 40(11), 1603-1617.
El-Axir, M. H. (2002). A method of modeling residual stress distribution in turning for different materials. International Journal of Machine Tools and Manufacture, 42(9), 1055-1063.
El-Khabeery, M. M., & Fattouh, M. (1989). Residual stress distribution caused by milling. International Journal of Machine Tools and Manufacture, 29(3), 391-401.
Fattough, M., & El-Khabeery, M. M. (1989). Residual stress distribution in burnishing solution treated and aged 7075 aluminium alloy. International Journal of Machine Tools and Manufacture, 29(1), 153-160.
Frisch, J., & Thomsen, E. G. (1951). Residual grinding stresses in mild steel. Trans. ASME, 73, 337-345.
Klocke, F., B?cker, V., Wegner, H., & Zimmermann, M. (2011). Finite element analysis of the roller burnishing process for fatigue resistance increase of engine components. Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture, 225(1), 2-11.
Korzynsky, M. (2013). Slide diamond burnishing, in: Korzynski, M. (Ed), Nonconventional Finishing Technologies. Polish Scientific Publishers, Warsaw, pp. 9-33.
Maximov, J. T., Duncheva, G. V., & Ganev, N. (2012). Enhancement of fatigue life of net section in fitted bolt connections. Journal of Constructional Steel Research, 74, 37-48.
Maximov, J.T., & Duncheva, G.V. (2012). Finite Element Analysis and op timization of spherical motion burnishing of low-alloy steel. Proceedings of the Institution of Mechanical Engineers, Part C: Journal of Mechanical Engineering Science, 226(1), 161-176.
Maximov, J. T., Duncheva, G. V., & Amudjev, I. M. (2013). A novel method and tool which enhance the fatigue life of structural components with fastener holes. Engineering Failure Analysis, 31, 132-143.
Maximov, J. T., Duncheva, G. V., Ganev, N., & Amudjev, I. M. (2014). Modeling of residual stress distribution around fastener holes in thin plates after symmetric cold expansion. Journal of the Brazilian Society of Mechanical Sciences and Engineering, 36(2), 355-369.
Maximov, J. T., Duncheva, G. V., Ganev, N., & Bakalova, T. N. (2009). The benefit from an adequate finite element simulation of the cold hole expansion process. Engineering Failure Analysis, 16(1), 503-511.
Reid, L. (1993). Beneficial residual stresses at bolt holes by cold expansion. In Rail Quality and Maintenance for Modern Railway Operation (pp. 337-347). Springer Netherlands.
Roettger, K. (2002). Walzen hartgedrehter oberflaechen, PhD Thesis, WZL, RWTH Aachen, University, Aachen, Germany.
Sachs, G. (1927). Der Nachweis Inneres Spannungen in Stangen und Rohren. Zeitschrift fur Metalkunde, 19, 352. (In German)
Sadat, A. B., & Bailey, J. A. (1985). Residual stress distribution in machining an annealed bearing bronze. International journal of mechanical sciences, 27(11), 717-724.
Sadat, A.B. (2012). Surface integrity when machining metal matrix composites, in: Davim, J.P. (Ed), Machining of Metal Matrix Composites. Springer-Verlag, London, pp. 51-61.
Sai, W. B., & Saï, K. (2005). Finite element modeling of burnishing of AISI 1042 steel. The International Journal of Advanced Manufacturing Technology, 25(5-6), 460-465.
Sartkulvanich, P., Altan, T., Jasso, F., & Rodriguez, C. (2007). Finite element modeling of hard roller burnishing: an analysis on the effects of process parameters upon surface finish and residual stresses. Journal of Manufacturing Science and Engineering, 129(4), 705-716.
Torabi, A., & Aliha, M. (2013). Determination of permissible defect size for solid axles loaded under fully-reversed rotating bending. Engineering Solid Mechanics, 1(1), 27-36.
Valkov R., Grozdanov T. (2009). State-of-the-art and problems in structural elements in railways. Mechanics, Transport and Communications, 3, 56-61 (in Bulgarian).
Vitman, F.F. (1935). On the calculation of residual stresses in thick-walled pipes. Journal of Technical Physics, 5(9), 239-247. (In Russian)
Vuchkov, I. N. & Vuchkov, I. I. (2009). QstatLab Professional, v. 5.5 – Statistical Quality Control Software. User’s Manual, Sofia.
Webster, G. A., & Ezeilo, A. N. (2001). Residual stress distributions and their influence on fatigue lifetimes. International Journal of Fatigue, 23, 375-383.
Yatzenko, V.K., Zaitzev, G.Z., Pritchenko, V.F., & Ivshtenko L.I. (1985). Enhancement of load-carrying capacity of machine components by diamond burnishing. Moscow: Machinostroenie (in Russian)
Yen, Y. C., Sartkulvanich, P., & Altan, T. (2005). Finite element modeling of roller burnishing process. CIRP Annals-Manufacturing Technology, 54(1), 237-240.
Zhuang, W., & Wicks, B. (2004). Multipass low-plasticity burnishing induced residual stresses: three-dimensional elastic-plastic finite element modelling. Proceedings of the Institution of Mechanical Engineers, Part C: Journal of Mechanical Engineering Science, 218(6), 663-668.
Birger, I.A. (1963). Residual stresses. Moscow: Mashgiz. (In Russian)
Cai, W., Wen, Z., Jin, X., & Zhai, W. (2007). Dynamic stress analysis of rail joint with height difference defect using finite element method. Engineering Failure Analysis, 14(8), 1488-1499.
Davidenkov, N.N. (1931). Measurement of residual stresses in tubes. Journal of Technical Physics, 1(1), 257-273. (In Russian)
Deng, W. J., Xia, W., Zhou, Z. Y., Chen, W. P., & Li, Y. Y. (2004, September). Finite element analysis of effects of ball burnishing parameters on residual stresses. In Materials Science Forum (Vol. 471, pp. 658-662).
Duncheva, G. V., & Maximov, J. T. (2013). A new approach to enhancement of fatigue life of rail-end-bolt holes. Engineering Failure Analysis, 29, 167-179.
El-Axir, M. H. (2000). An investigation into roller burnishing. International Journal of Machine Tools and Manufacture, 40(11), 1603-1617.
El-Axir, M. H. (2002). A method of modeling residual stress distribution in turning for different materials. International Journal of Machine Tools and Manufacture, 42(9), 1055-1063.
El-Khabeery, M. M., & Fattouh, M. (1989). Residual stress distribution caused by milling. International Journal of Machine Tools and Manufacture, 29(3), 391-401.
Fattough, M., & El-Khabeery, M. M. (1989). Residual stress distribution in burnishing solution treated and aged 7075 aluminium alloy. International Journal of Machine Tools and Manufacture, 29(1), 153-160.
Frisch, J., & Thomsen, E. G. (1951). Residual grinding stresses in mild steel. Trans. ASME, 73, 337-345.
Klocke, F., B?cker, V., Wegner, H., & Zimmermann, M. (2011). Finite element analysis of the roller burnishing process for fatigue resistance increase of engine components. Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture, 225(1), 2-11.
Korzynsky, M. (2013). Slide diamond burnishing, in: Korzynski, M. (Ed), Nonconventional Finishing Technologies. Polish Scientific Publishers, Warsaw, pp. 9-33.
Maximov, J. T., Duncheva, G. V., & Ganev, N. (2012). Enhancement of fatigue life of net section in fitted bolt connections. Journal of Constructional Steel Research, 74, 37-48.
Maximov, J.T., & Duncheva, G.V. (2012). Finite Element Analysis and op timization of spherical motion burnishing of low-alloy steel. Proceedings of the Institution of Mechanical Engineers, Part C: Journal of Mechanical Engineering Science, 226(1), 161-176.
Maximov, J. T., Duncheva, G. V., & Amudjev, I. M. (2013). A novel method and tool which enhance the fatigue life of structural components with fastener holes. Engineering Failure Analysis, 31, 132-143.
Maximov, J. T., Duncheva, G. V., Ganev, N., & Amudjev, I. M. (2014). Modeling of residual stress distribution around fastener holes in thin plates after symmetric cold expansion. Journal of the Brazilian Society of Mechanical Sciences and Engineering, 36(2), 355-369.
Maximov, J. T., Duncheva, G. V., Ganev, N., & Bakalova, T. N. (2009). The benefit from an adequate finite element simulation of the cold hole expansion process. Engineering Failure Analysis, 16(1), 503-511.
Reid, L. (1993). Beneficial residual stresses at bolt holes by cold expansion. In Rail Quality and Maintenance for Modern Railway Operation (pp. 337-347). Springer Netherlands.
Roettger, K. (2002). Walzen hartgedrehter oberflaechen, PhD Thesis, WZL, RWTH Aachen, University, Aachen, Germany.
Sachs, G. (1927). Der Nachweis Inneres Spannungen in Stangen und Rohren. Zeitschrift fur Metalkunde, 19, 352. (In German)
Sadat, A. B., & Bailey, J. A. (1985). Residual stress distribution in machining an annealed bearing bronze. International journal of mechanical sciences, 27(11), 717-724.
Sadat, A.B. (2012). Surface integrity when machining metal matrix composites, in: Davim, J.P. (Ed), Machining of Metal Matrix Composites. Springer-Verlag, London, pp. 51-61.
Sai, W. B., & Saï, K. (2005). Finite element modeling of burnishing of AISI 1042 steel. The International Journal of Advanced Manufacturing Technology, 25(5-6), 460-465.
Sartkulvanich, P., Altan, T., Jasso, F., & Rodriguez, C. (2007). Finite element modeling of hard roller burnishing: an analysis on the effects of process parameters upon surface finish and residual stresses. Journal of Manufacturing Science and Engineering, 129(4), 705-716.
Torabi, A., & Aliha, M. (2013). Determination of permissible defect size for solid axles loaded under fully-reversed rotating bending. Engineering Solid Mechanics, 1(1), 27-36.
Valkov R., Grozdanov T. (2009). State-of-the-art and problems in structural elements in railways. Mechanics, Transport and Communications, 3, 56-61 (in Bulgarian).
Vitman, F.F. (1935). On the calculation of residual stresses in thick-walled pipes. Journal of Technical Physics, 5(9), 239-247. (In Russian)
Vuchkov, I. N. & Vuchkov, I. I. (2009). QstatLab Professional, v. 5.5 – Statistical Quality Control Software. User’s Manual, Sofia.
Webster, G. A., & Ezeilo, A. N. (2001). Residual stress distributions and their influence on fatigue lifetimes. International Journal of Fatigue, 23, 375-383.
Yatzenko, V.K., Zaitzev, G.Z., Pritchenko, V.F., & Ivshtenko L.I. (1985). Enhancement of load-carrying capacity of machine components by diamond burnishing. Moscow: Machinostroenie (in Russian)
Yen, Y. C., Sartkulvanich, P., & Altan, T. (2005). Finite element modeling of roller burnishing process. CIRP Annals-Manufacturing Technology, 54(1), 237-240.
Zhuang, W., & Wicks, B. (2004). Multipass low-plasticity burnishing induced residual stresses: three-dimensional elastic-plastic finite element modelling. Proceedings of the Institution of Mechanical Engineers, Part C: Journal of Mechanical Engineering Science, 218(6), 663-668.