Residual Stress Generation during Laser Cladding of Steel with a Particulate Metal Matrix Composite

Residual Stress Generation during Laser Cladding of Steel with a Particulate Metal Matrix Composite

Laser cladding is used to coat and repair the surface of various components. A significant issue relating to optimisation of the process is the generation of residual stresses. These are affected by the high thermal gradients inherent in the process, and associated differential thermal contraction....

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Bibliographic Details
Published in:Advanced engineering materials Vol. 8; no. 7; pp. 619 - 624
Main Authors: Plati, A., Tan, J. C., Golosnoy, I. O., Persoons, R., van Acker, K., Clyne, T. W.
Format: Journal Article
Language:English
Published: Weinheim WILEY-VCH Verlag 01-07-2006
WILEY‐VCH Verlag
Subjects:
Creep
Laser cladding
Metal matrix composite
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Summary:Laser cladding is used to coat and repair the surface of various components. A significant issue relating to optimisation of the process is the generation of residual stresses. These are affected by the high thermal gradients inherent in the process, and associated differential thermal contraction. These stresses can lead to various types of distortion. A customised 3‐D finite element model has been developed, incorporating these effects, based on simulation of conductive, convective and radiative heat transfer, and assuming elastic‐perfectly plastic deformation behaviour. Creep effects have been neglected and the cladding (particulate metal matrix composite) has been treated as a continuum. Comparisons are presented between measured and simulated thermal fields and specimen deflection histories. The results indicate that the main features of residual stress generation in this type of system have been captured in the model. Implications for process optimization and control are briefly discussed. Laser cladding is used to coat and repair the surface of various components. A significant issue relating to optimisation of the process is the generation of residual stresses. These are affected by the high thermal gradients inherent in the process, and associated differential thermal contraction. These stresses can lead to various types of distortion. A customised 3‐D finite element model has been developed, incorporating these effects, based on simulation of conductive, convective and radiative heat transfer, and assuming elastic‐perfectly plastic deformation behaviour.
Bibliography:Belgian Federal government - No. PA-67-281
ark:/67375/WNG-X3R0R168-2
EPSRC
istex:81C4F3621A1E69A9E21C6B890C51C401E7CE22DD
Cambridge European Trust
Financial support for this work has been received from the Belgian Federal government, via contract PA-67-281, from the EPSRC, via a Platform Grant, and from the Cambridge European Trust.
ArticleID:ADEM200600063
Financial support for this work has been received from the Belgian Federal government, via contract PA‐67‐281, from the EPSRC, via a Platform Grant, and from the Cambridge European Trust.
ObjectType-Article-2
SourceType-Scholarly Journals-1
ObjectType-Feature-1
content type line 23
ISSN:1438-1656
1527-2648
DOI:10.1002/adem.200600063