Your search keyword '"Simon Kött"' showing total 3 results

1. Investigation of the Solid Solution Hardening Mechanism of Low-Alloyed Copper–Scandium Alloys

Author

Ramona Henle, Simon Kött, Norbert Jost, Gerrit Nandi, Julia Dölling, Andreas Zilly, and Ulrich Prahl

Subjects

Cu-Sc alloy, solid solution hardening, atomic size misfit, elastic modulus misfit, yield strength, grain boundary hardening, Mining engineering. Metallurgy, TN1-997

Abstract

The addition of alloying elements is a crucial factor in improving the mechanical properties of pure copper, particularly in terms of enhancing its yield strength and hardness. This study examines the influence of scandium additions (up to 0.27 wt.%) on low-alloyed copper. Following the casting and solution-annealing processes, the alloys were quenched in water to maintain a supersaturated state. The mechanical properties were evaluated by tensile tests to measure the yield strength and the dynamic resonance method to determine the modulus of rigidity. Additionally, X-ray diffraction was utilized to analyze changes in lattice parameters, elucidating the structural modifications induced by scandium. This study dissects the parelastic and dielastic effects underlying the solid solution hardening mechanism, providing insights into how scandium alters copper’s mechanical properties. The findings align with the solid solution hardening theories proposed by Fleischer and Labusch, providing a comprehensive understanding of the observed phenomena.

Published

2024

2. A Three-Dimensional Microstructure Preparation Using Metallographic In-Depth Microsections

Author

Ursula Christian, Simon Kött, Norbert Jost, and Christel Siegle

Subjects

Engineering, Engineering drawing, business.industry, Metals and Alloys, Structure (category theory), Mechanical engineering, Condensed Matter Physics, Electronic, Optical and Magnetic Materials, Visualization, Joint research, Mechanics of Materials, business, Three dimensional microstructure, Mathematical simulation

Abstract

Efficient simulation techniques are conceived, amongst other things, for the modelling and visualization of microstructure configurations of materials and structural components in production processes, within a joint research project in which the Karlsruhe, Aalen, and Pforzheim Universities were involved. To this end, it is firstly necessary to determine the structure in all of the three spatial directions (three dimensions) which then will help to establish mathematical simulation algorithms. In the further course of the project, it is also understood that the simulation results are checked up and verified again and again by the respective real structures. These activities indispensably presuppose a precise localization of the structure on several planes and a definition as to what is realized via so-called in-depth microsections. This makes it necessary to develop and optimize techniques both for the exact maintenance of an x-y local constancy and absolutely accurate depth determination (z coordinate). For this purpose, the Pforzheim University formulated a simple metallographic process technology which is aimed at precisely localizing the structures at a well-defined material removal rate. It is on this basis that structural regions can now be detected on several planes at the same location and a sufficient collection of data can be created for the three-dimensional simulations of polycrystalline grain structures.

Published

2012

3. Production and Metallographic Examination of Precipitable Cu–Mg Alloys

Author

Ursula Christian, D. Nobiling, Simon Kött, Norbert Jost, and Andreas Zilly

Subjects

Materials science, Mg alloys, Conductive materials, Alloy, Metallurgy, Metals and Alloys, chemistry.chemical_element, engineering.material, Condensed Matter Physics, Copper, Electronic, Optical and Magnetic Materials, chemistry, Mechanics of Materials, Electrical resistivity and conductivity, engineering

Abstract

Low alloy copper-based alloys are mainly used as conductive material in the field of electrical engineering. However, given a good electrical conductivity, they are characterized by low mechanical strength. Due to a low alloy content of currently used copper-magnesium, alloys rank among not precipitable homogeneous solid solutions. As a consequence, increases in strength can only be realized by means of solid solution strengthening and strain hardening. Up to now, the possibility of precipitation hardening remains largely untapped. In order to examine this potential for optimization regarding higher strength and enhanced conductivity, samples with differing Mg contents are prepared and systematically heat treated. This research work has the long-term objective of leaving the laboratory scale in order to make precipitable copper-magnesium alloys applicable for industry.

Published

2011