Your search keyword '"Josephin Enz"' showing total 4 results

1. Microstructural Characteristics of Laser Metal Deposited Magnesium Alloy AZ31

Author

Stefan Riekehr, Josephin Enz, Nikolai Kashaev, Anna Konovalovna, and Volker Ventzke

Subjects

Materials science, 010308 nuclear & particles physics, Mechanical Engineering, Metallurgy, 02 engineering and technology, 021001 nanoscience & nanotechnology, Condensed Matter Physics, Laser, Microstructure, 01 natural sciences, law.invention, Metal, Mechanics of Materials, law, visual_art, 0103 physical sciences, visual_art.visual_art_medium, General Materials Science, Magnesium alloy, 0210 nano-technology

Abstract

Up to now, only a limited amount of metallic materials is investigated for laser additive manufacturing (LAM). However, the demand to widen the application possibilities by enlarging the range of materials for LAM is growing fast. By now, titanium and aluminium alloys are in the focus of research. In contrast, magnesium alloys are rarely used in the field of additive manufacturing, although they possess a low density in combination with a high specific strength. Currently, magnesium structures are mainly produced by casting but during the last years, the use of wrought alloys also increased. A reason for the rare use of magnesium alloys for LAM technologies might be the high flammability of magnesium powders. This difficulty can be avoided by using magnesium wire for laser metal deposition (LMD). In the present study, the microstructural characteristics of a LMD processed AZ31 magnesium alloy are investigated. For this purpose, optical microscopy and scanning electron microscopy were used. With the help of EDX and EBSD analysis, a change of the chemical composition and micro texture with structure height was identified. The relationship of microstructure and local mechanical properties was investigated with the help of Vickers micro hardness testing. Based on the obtained results it can be concluded that the microstructural characteristics of laser additive manufactured magnesium alloys differ from those of titanium and aluminium alloys. Thus, a wider application spectrum of LMD and magnesium alloys can be opened up.

Published

2018

2. Laser Weldability of Different Al-Zn Alloys and its Improvement

Author

Josephin Enz, Volker Ventzke, Nikolai Kashaev, and Stefan Riekehr

Subjects

Materials science, Mechanical Engineering, Weldability, Metallurgy, Laser beam welding, Welding, Condensed Matter Physics, Laser, law.invention, Cracking, Mechanics of Materials, law, General Materials Science, Porosity

Abstract

Weld defects - such as porosity and hot cracking - occur especially during the laser beam welding of high-alloyed Al-Zn alloys. This significantly limits the application range of these promising high-strength alloys. In the present study the laser weldability of different Al-Zn alloys was investigated regarding the used welding parameters and the chemical composition of the alloys. In addition, the novel approach of the Helmholtz-Zentrum Geesthacht for overcoming the weldability problems was applied to the different Al-Zn alloys in order to assess its capability. It was shown that the laser weldability of Al-Zn alloys deteriorates with an increasing amount of Zn, Mg and Cu. The variation of laser beam welding parameters did not lead to any improvement of weldability. Only the use of the new approach resulted in promising welding results even for the high-alloyed Al-Zn alloys.

Published

2015

3. Mechanical Properties of Fibre Laser Welded AZ31B Sheets and their Dependence on the Spot-Size

Author

Nikolai Kashaev, Josephin Enz, Riccardo Ravasi, Volker Ventzke, and Stefan Riekehr

Subjects

Heat-affected zone, Materials science, Mechanical Engineering, Weldability, Laser beam welding, Welding, Condensed Matter Physics, law.invention, Power (physics), Mechanics of Materials, law, Fiber laser, Ultimate tensile strength, Vickers hardness test, General Materials Science, Composite material, ddc:620.11

Abstract

In the present work the mechanical behaviour of laser beam welded AZ31B alloy was studied, by changing systematically the spot size of the used fibre laser system between 200 µm and 1000 µm at different power levels between 2 kW and 8 kW. Maximum welding velocities with respect to imperfections were determined. The characterization of the obtained welds - in terms of Vickers hardness, UTS, Af and weld width, resp. weld area - was correlated with the micro-texture in dependence of the different Focus Spot Diameters and Laser Beam Power levels as well as the resulting cooling rates. Highest UTS of 94% of the base material was achieved with 200 µm Focus Spot Diameter and Laser Beam Power of 4 kW at welding velocity of 100 mm/s. By increasing the Focus Spot Diameter to 600 µm, the tensile strength was reduced to 86 % of the actual strength of the base material.

Published

2015

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

Author

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

Subjects

Materials science, business.industry, General Engineering, Laser beam welding, Welding, Structural engineering, Laser, Fatigue limit, law.invention, Fuselage, Buckling, law, Aerospace, business, Damage tolerance, ddc:620.11

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.

Published

2014