Surface enhancement of metallic parts fabricated by selective laser melting
Selective laser melting is a 3D printing technology that works with metals and is becoming increasingly popular in the industry due to several advantages over conventional machining, including material efficiency, easier manufacturing of complex geometries and lower manpower requirements. While S...
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| Format: | Final Year Project |
| Language: | English |
| Published: |
Nanyang Technological University
2024
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| Online Access: | https://hdl.handle.net/10356/176319 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | Selective laser melting is a 3D printing technology that works with metals and is becoming
increasingly popular in the industry due to several advantages over conventional machining,
including material efficiency, easier manufacturing of complex geometries and lower manpower
requirements. While SLM has immense potential, it is held back because of defects inherent to the
process which compromise part performance, particularly fatigue life.
Shot peening is a post-processing technique that uses pellet impacts to create compressive residual
stress or CRS. CRS pushes the material together, delaying crack formation and propagation, thus
improving fatigue life.
However, the complex interplay of variables means that the effect of shot peening parameters are
difficult to extrapolate from available data. Additionally, there are few or no studies on severe shot
peening for SLM Ti-6Al-4V.
The objective of my project is to characterise the effect of a certain set of severe shot peening
parameters (0.6mmA,90-degree impingement etc) on Titanium-64 to determine its feasibility in
improving the fatigue life of SLM Ti-6Al-4V. We also look into the effect of severe shot peening on
adjacent sides to determine its effect.
My analysis comprises both the mechanical and microstructural areas and uses techniques such as
Vicker’s hardness and multiple microscopy techniques.
It was found that the severe shot peening parameter used created a deeper affected zone, increasing
hardness up to a depth of around 2.3mm (2300 microns). For adjacent face peening, the location of
maximum effect was located, and a depth profile taken at that distance to determine the maximum
increase in hardness possible from adjacent side peening. Adjacent side peening was found to have a
notable effect below 500 microns depth, but the effect was minimal after.
An etch-resistant layer was also discovered, likely to be the combined effect of grain refinement and
time of exposure to air.
Several defects were also found from the shot peening process, such as surface/sub-surface cracks,
folds and rolled edges. In one sample, cracking was so severe that a portion of the sample
delaminated.
In conclusion, the current severe shot peening parameters pose an appreciable risk of damaging the
part and compromising structural integrity/fatigue life. Safety-wise, it is recommended that further
research be conducted with less aggressive parameters. |
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