Publication Date:
2007
abstract:
Fatigue resistance evaluation of mechanical components is still a challenging topic for a
lot of researches that aim to foresee the residual life or to establish the fatigue limit of a
component. Fatigue resistance of a component is not only dependent on the mechanical
characteristics of the material, but also is strongly influenced by the load history, the
induced stress state, surface hardness and technological factors. Each component is
subjected to different manufacturing processes before its utilisation; another important
factor that has a big influence on the fatigue resistance is the presence of a tensile or
compressive residual stress field, after machining or surface treatment, at the surface of
the component. In the last few years, the finite element method helped in simulating
conditions in which a mechanical component is subjected to special kind of loads. The residual stress field can be simulated too and fatigue crack propagation in residual stress
field is no longer a matter of few high-level researches. Only an intensive use of
numerical models, confirmed by means of experimental tests, can represent a powerful
tool to enhance the fatigue behaviour of mechanical components.
The aim of this Special Issue of International Journal of Materials and Product
Technology regards the study and presentation of detailed analyses on the effect that
loads, stress state and technological factors have on the fatigue resistance of mechanical
components. The results of such analyses could be used directly by a machine designer
who needs to asses whether a component can exhibit particular fatigue resistance
capabilities.
The contributors to this Special Issue try to propose numerical and analytical models
that are able to predict the effects induced by mechanical and thermal processes or
simulate the working conditions of complex mechanical components. The authors
present different solution algorithms and search a confirmation to the trustworthiness of
their models by executing several experimental tests.
The result is a useful collection of papers that gives a survey of the state-of-the-art in
the fatigue life prediction field.
I would like to thank the authors for their valuable contributions to this Special Issue.
Acknowledgements are also due to Dr. M.A. Dorgham for initiating this Special Issue
and to the reviewers for their support of the initiative and careful re-examination of
the manuscripts.
lot of researches that aim to foresee the residual life or to establish the fatigue limit of a
component. Fatigue resistance of a component is not only dependent on the mechanical
characteristics of the material, but also is strongly influenced by the load history, the
induced stress state, surface hardness and technological factors. Each component is
subjected to different manufacturing processes before its utilisation; another important
factor that has a big influence on the fatigue resistance is the presence of a tensile or
compressive residual stress field, after machining or surface treatment, at the surface of
the component. In the last few years, the finite element method helped in simulating
conditions in which a mechanical component is subjected to special kind of loads. The residual stress field can be simulated too and fatigue crack propagation in residual stress
field is no longer a matter of few high-level researches. Only an intensive use of
numerical models, confirmed by means of experimental tests, can represent a powerful
tool to enhance the fatigue behaviour of mechanical components.
The aim of this Special Issue of International Journal of Materials and Product
Technology regards the study and presentation of detailed analyses on the effect that
loads, stress state and technological factors have on the fatigue resistance of mechanical
components. The results of such analyses could be used directly by a machine designer
who needs to asses whether a component can exhibit particular fatigue resistance
capabilities.
The contributors to this Special Issue try to propose numerical and analytical models
that are able to predict the effects induced by mechanical and thermal processes or
simulate the working conditions of complex mechanical components. The authors
present different solution algorithms and search a confirmation to the trustworthiness of
their models by executing several experimental tests.
The result is a useful collection of papers that gives a survey of the state-of-the-art in
the fatigue life prediction field.
I would like to thank the authors for their valuable contributions to this Special Issue.
Acknowledgements are also due to Dr. M.A. Dorgham for initiating this Special Issue
and to the reviewers for their support of the initiative and careful re-examination of
the manuscripts.
Iris type:
1.6.01 Curatele - Edited books
List of contributors: