Page 146 - disertation_SLIEPKO_ROMAN
P. 146
146
28. Chen C. X., Zhou Z. R. A self-excited vibration model based on special elastic
vibration modes of friction systems and time delays between the normal and
Friction Forces: a new mechanism for squealing noise. Wear, 2007, 262, 1223–
1139.
29. Earless S., Chambers P. Disc brake squeal – some factors which influence its
accurence. Proceeding of the Institution of Mechanical Engineers, 1988,
c454/88, 39–46.
30. Eriksson M., Bergman F., Jacobson S. Surface characterization of brake pads
after running under silent and squealing conditions, Wear, 1999, 232, 163–167.
31. Rusli M., Okuma M. Effect of surface topography on mode coupling model of
dry contact sliding systems. Journal of Sound and Vibration, 1007, 308,
721–734.
32. Sherif H. A. Investigation on effect of surface topography of pad/disc assembly
on squeal generation. Wear, 2004, 257, 687–695.
33. Chen G. X., Zhou Z. R., Vincent L. Effect of surface topography on formation
of squeal under reciprocation sliding, Wear, 2002, 253, 414–423.
34. Massi F., Bertbier Y., Baillet L. Contact surface topography and system
dynamics of brake squeal, Wear, 2008, 265, 1784–1792.
35. Bergman F., Eriksson M., Jacobson S. Influence of disc topography on
generation of brake squeal. Wear, 1999, 225–229, 621–628.
36. Di Bartolomeo, Meziane A., Massi F., Baillet L., Fregolent A. Dynamic rupture
at a frictional interface between materials with asperities. Tribology
International, 2010, 43, 1620–1630.
37. Wang D. W., Mo Y. L., Wang Z. G., Chen G. X., Duyang H., Zhou Z. R.
Numerical study of friction-induced vibration and noise on groove-textured
surface. Tribology international, 2013, 64, 1–7.
38. Williams Y. A. Engineering tribology, Oxford University Press, 1994.
39. Gao C., Kuhlmann-Wilsodorf D., Makel D. D. The dynamic analysis of stick-
slip motion. Wear, 1994, 173, 1–12.
28. Chen C. X., Zhou Z. R. A self-excited vibration model based on special elastic
vibration modes of friction systems and time delays between the normal and
Friction Forces: a new mechanism for squealing noise. Wear, 2007, 262, 1223–
1139.
29. Earless S., Chambers P. Disc brake squeal – some factors which influence its
accurence. Proceeding of the Institution of Mechanical Engineers, 1988,
c454/88, 39–46.
30. Eriksson M., Bergman F., Jacobson S. Surface characterization of brake pads
after running under silent and squealing conditions, Wear, 1999, 232, 163–167.
31. Rusli M., Okuma M. Effect of surface topography on mode coupling model of
dry contact sliding systems. Journal of Sound and Vibration, 1007, 308,
721–734.
32. Sherif H. A. Investigation on effect of surface topography of pad/disc assembly
on squeal generation. Wear, 2004, 257, 687–695.
33. Chen G. X., Zhou Z. R., Vincent L. Effect of surface topography on formation
of squeal under reciprocation sliding, Wear, 2002, 253, 414–423.
34. Massi F., Bertbier Y., Baillet L. Contact surface topography and system
dynamics of brake squeal, Wear, 2008, 265, 1784–1792.
35. Bergman F., Eriksson M., Jacobson S. Influence of disc topography on
generation of brake squeal. Wear, 1999, 225–229, 621–628.
36. Di Bartolomeo, Meziane A., Massi F., Baillet L., Fregolent A. Dynamic rupture
at a frictional interface between materials with asperities. Tribology
International, 2010, 43, 1620–1630.
37. Wang D. W., Mo Y. L., Wang Z. G., Chen G. X., Duyang H., Zhou Z. R.
Numerical study of friction-induced vibration and noise on groove-textured
surface. Tribology international, 2013, 64, 1–7.
38. Williams Y. A. Engineering tribology, Oxford University Press, 1994.
39. Gao C., Kuhlmann-Wilsodorf D., Makel D. D. The dynamic analysis of stick-
slip motion. Wear, 1994, 173, 1–12.
