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Journal of Materials Engineering and Performance
Erschienen in: Journal of Materials Engineering and Performance 4/2019

29.03.2019

Study on Enhancing Fatigue Life of SAE 9260 Spring Steel with Surface Defect Through Laser Shock Peening

verfasst von: P. Ganesh, Arun K. Rai, Pushpendra K. Dwivedi, Abhijit Chowdhury, Ramakanta Biswal, D. C. Nagpure, R. Sundar, Ram K. Gupta, K. Ranganathan, K. S. Bindra, Rakesh Kaul

Erschienen in: Journal of Materials Engineering and Performance | Ausgabe 4/2019

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Abstract

This paper presents an experimental study aimed at evaluating laser shock peening for suppressing deleterious effects of surface defects on the fatigue life of SAE 9260 spring steel specimens. The approach adopted for the study included introduction of standardized surface defects through micro-hardness indentation, peening of region in and around the surface defects with 3.5 J/9 ns Nd:YAG laser and comparing the fatigue lives of unpeened and laser shock peened spring steel specimens with identical surface defects. Under the experimental test conditions, laser shock peening was found to be quite effective in enhancing fatigue life of spring steel specimens with surface defects by more than 25 times. The results of the study are important for enhancing life of the engineering components which develop surface defects during their storage (e.g., corrosion pit), handling (e.g., tool marks) or operation (e.g., erosion pit).
Vorheriger Artikel Characterization of Static Performance and Failure of Resistance Spot Welds of High-Strength and Press-Hardened Steels
Nächster Artikel On the Relationship Between Dislocation Creep Strength and Microstructure of a Solid-Solution-Strengthened Ni-Base Superalloy

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Metadaten
Titel
Study on Enhancing Fatigue Life of SAE 9260 Spring Steel with Surface Defect Through Laser Shock Peening
verfasst von
P. Ganesh
Arun K. Rai
Pushpendra K. Dwivedi
Abhijit Chowdhury
Ramakanta Biswal
D. C. Nagpure
R. Sundar
Ram K. Gupta
K. Ranganathan
K. S. Bindra
Rakesh Kaul
Publikationsdatum
29.03.2019
Verlag
Springer US
Erschienen in
Journal of Materials Engineering and Performance / Ausgabe 4/2019
Print ISSN: 1059-9495
Elektronische ISSN: 1544-1024
DOI
https://doi.org/10.1007/s11665-019-03990-8

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