Fretting fatigue has been studied for nearly a century and a great deal of progress has been made in formulating design practices based on the understanding that has emerged during this period. Nonetheless, many fretting induced fatigue failures still occur and often could have been prevented if knowledge that exists were applied. This paper provides seven brief case studies in various fields of interest. Each case is presented briefly and then the manner used to deal with the issue to prevent its continued occurrence is given. The paper demonstrates that if fretting fatigue failure mode is anticipated and predicted based on knowledge of the factors that lead to fretting fatigue then adequate prevention and control practice can be used to avoid it in the design and use of components. One of the great challenges ahead is to assure all engineering students around the world get educated as to the factors and parameters that cause fretting fatigue to occur and thus design teams could take positive action to prevent it in almost all cases.
[1]
Mark W. Moesser,et al.
Literature Review and Preliminary Studies of Fretting and Fretting Fatigue Including Special Applications to Aircraft Joints.
,
1994
.
[2]
David W. Hoeppner,et al.
Fretting in orthopaedic implants: A review
,
1994
.
[3]
Er Speakman,et al.
Advanced Fastener Technology for Composite and Metallic Joints
,
1986
.
[4]
M. H. Attia,et al.
Standardization of Fretting Fatigue Test Methods and Equipment
,
1992
.
[5]
John M. Potter,et al.
Fatigue in mechanically fastened composite and metallic joints : a symposium
,
1986
.
[6]
O. Horger.
FATIGUE OF LARGE SHAFTS BY FRETTING CORROSION
,
1956
.
[7]
Yoshiharu Mutoh,et al.
Mechanisms of fretting fatigue
,
1995
.
[8]
Robert S. Piascik,et al.
The Characteristics of Fatigue Damage in the Fuselage Riveted Lap Splice Joint
,
1997
.