Fatigue and Fatigue Crack Propagation of Laser Beam-Welded AA2198 Joints and Integral Structures

Nikolai Kashaev; Sergey Chupakhin; Josephin Enz; Volker Ventzke; Anne Groth; Manfred Horstmann; Stefan Riekehr

doi:10.4028/www.scientific.net/AMR.891-892.1457

Paper Titles

Influence of Frequency and Testing Technique on the Fatigue Behaviour of Quenched and Tempered Steel in the VHCF-Regime
p.1430

Formation Mechanism of Specific Fracture Surface Region in the Sub-Surface Fracture of Titanium Alloy
p.1436

Influence of Weld Imperfections on the Fatigue Behaviour of Resistance Spot Welded Advanced High Strength Steels
p.1445

On the Effect of Electrodischarge Drilling on the Fatigue Life of Inconel 718
p.1451

Fatigue and Fatigue Crack Propagation of Laser Beam-Welded AA2198 Joints and Integral Structures
p.1457

Behaviour of Friction Stir Welded Joints Made out of Two Aluminium Alloys under Cyclic Loading Conditions
p.1463

Reduction in Fatigue Strength of Arc Welded Aluminium 5083-H111 on Immersion in NaCl
p.1469

Influence of Process-Related Defects on the Fatigue Behaviour of Welded Aluminium Joints at Very High Cycles
p.1476

Effect of Fine-Grained Microstructure Induced by Induction-Heating Fine Particle Peening Treatment on Fatigue Properties of Structural Steel (0.45%C)
p.1482

HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 891-892Fatigue and Fatigue Crack Propagation of Laser...

Fatigue and Fatigue Crack Propagation of Laser Beam-Welded AA2198 Joints and Integral Structures

Abstract:

To meet the future demands of the aerospace industry with respect to safety, productivity, weight, and cost, new materials and joining concepts have being developed. Recent developments in the metallurgical field now make it possible to use laser-weldable Al-alloys of the 2xxx series such as AA2198 with a high structural efficiency index due to their high strength and low density. AA2198 holds the promise of providing a breakthrough response to the challenges of lightweight design in aircraft applications. Laser beam welding as an efficient joining technology for fuselage structures is already established in the aircraft industry for lower fuselage panels because the welded panels provide a higher buckling strength and lower weight compared with the classical riveted designs. The key factor for the application of laser-welded AA2198 structures is the availability of reliable data for the assessment of their damage tolerance behavior. In the research presented, the mechanical properties with regard to fatigue and fatigue crack propagation of laser beamwelded AA2198 joints and four-stringer panels were investigated. It was found that the fatigue endurance limit of laser beamwelded AA2198T3 is approximately 25 % below the endurance limit of the base material. With regard to the fatigue crack propagation behavior, the laser beam welded four-stringer panels with T-joints show a fatigue life increased by a factor of 1.7 compared with the base material. This work shows that high-quality laser beam welds of AA2198 can be produced on a large scale using the laser beam welding facilities of the Helmholtz-Zentrum Geesthacht.