Role of Friction Stir Channel Geometry on the Fatigue Behaviour of AA5083-H111 at 120°C and 200°C

Catarina Vidal; Virgínia Infante

doi:10.4028/www.scientific.net/AMR.891-892.1494

Paper Titles

Reduction in Fatigue Strength of Arc Welded Aluminium 5083-H111 on Immersion in NaCl
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Influence of Process-Related Defects on the Fatigue Behaviour of Welded Aluminium Joints at Very High Cycles
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Effect of Fine-Grained Microstructure Induced by Induction-Heating Fine Particle Peening Treatment on Fatigue Properties of Structural Steel (0.45%C)
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Fatigue Behaviour of Friction Stir Welded Steel Joints
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Role of Friction Stir Channel Geometry on the Fatigue Behaviour of AA5083-H111 at 120°C and 200°C
p.1494

Microstructure and Strain-Based Fatigue Life Approach for High-Performance Welds
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Comparison of High Cycle Fatigue in 4340 and 300M Steel Welded with Fiber Laser
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The Effectiveness of Design Procedures for Fatigue Design of Welds
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The Effect of Manufacturing Defects on the Fatigue Behaviour of Ti-6Al-4V Specimens Fabricated Using Selective Laser Melting
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HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 891-892Role of Friction Stir Channel Geometry on the...

Role of Friction Stir Channel Geometry on the Fatigue Behaviour of AA5083-H111 at 120°C and 200°C

Abstract:

Friction StirChannelling (FSC) is an innovative solid-state manufacturing technology able toproduce, in a single step, continuous integral channels in monolithic platesthat can be used to produce conformal cooling systems as well as heatexchanging devices. FSC is based on the same principles of Friction StirWelding (FSW) process and the features of the channels produced by FSC can becontrolled by the processing parameters and tool geometry. Bending fatiguetests have been performed using friction stir channelling specimens of 5083‑H111aluminium alloy with different channel geometries. Fatigue tests have beencarried out at 120°C and 200°C in a servo-hydraulic testing machine coupledwith a furnace, in order to understand the role of channel geometry on thefatigue behaviour at elevated temperature. Results were compared with thoseobtained at room temperature. The specimens were tested until fracture or up to 3x10⁶ cycles. For the channel geometries tested, the fatiguestrength of friction stir channelling specimens is dependent on the testingtemperature, decreasing with the temperature increased. At all temperaturesstudied, for both channel geometries, fatigue-crack always initiated into theinterior of the specimen, namely on the boundary between the channel nugget andthe thermo‑mechanically affected zone. It was observed that crack initiationhas been occurred earlier at elevated temperature than at room temperature.

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Periodical:

Advanced Materials Research (Volumes 891-892)

Pages:

1494-1499

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.891-892.1494

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Online since:

March 2014

Authors:

Catarina Vidal, Virgínia Infante*

Keywords:

AA5083H111, Fatigue at Elevated Temperature, Friction Stir Channelling

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References

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