04 Fakultät Energie-, Verfahrens- und Biotechnik

Permanent URI for this collectionhttps://elib.uni-stuttgart.de/handle/11682/5

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Institute: search.filters.UBSInstitut.Materialprüfungsanstalt Universität Stuttgart (MPA Stuttgart, Otto-Graf-Institut (FMPA))Author: search.filters.author.Weihe, Stefan

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Now showing 1 - 6 of 6
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    Feasibility study on additive manufacturing of ferritic steels to meet mechanical properties of safety relevant forged parts
    (2022) Mally, Linda; Werz, Martin; Weihe, Stefan
    Additive manufacturing processes such as selective laser melting are rapidly gaining a foothold in safety-relevant areas of application such as powerplants or nuclear facilities. Special requirements apply to these applications. A certain material behavior must be guaranteed and the material must be approved for these applications. One of the biggest challenges here is the transfer of these already approved materials from conventional manufacturing processes to additive manufacturing. Ferritic steels that have been processed conventionally by forging, welding, casting, and bending are widely used in safety-relevant applications such as reactor pressure vessels, steam generators, valves, and piping. However, the use of ferritic steels for AM has been relatively little explored. In search of new materials for the SLM process, it is assumed that materials with good weldability are also additively processible. Therefore, the processability with SLM, the process behavior, and the achievable material properties of the weldable ferritic material 22NiMoCr3-7, which is currently used in nuclear facilities, are investigated. The material properties achieved in the SLM are compared with the conventionally forged material as it is used in state-of-the-art pressure water reactors. This study shows that the ferritic-bainitic steel 22NiMoCr3-7 is suitable for processing with SLM. Suitable process parameters were found with which density values > 99% were achieved. For the comparison of the two materials in this study, the microstructure, hardness values, and tensile strength were compared. By means of a specially adapted heat treatment method, the material properties of the printed material could be approximated to those of the original block material. In particular, the cooling medium/cooling method was adapted and the cooling rate reduced. The targeted ferritic-bainitic microstructure was achieved by this heat treatment. The main difference found between the two materials relates to the grain sizes present. For the forged material, the grain size distribution varies between very fine and slightly coarse grains. The grain size distribution in the printed material is more uniform and the grains are smaller overall. In general, it was difficult and only minimal possible to induce grain growth. As a result, the hardness values of the printed material are also slightly higher. The tensile strength could be approximated to that of the reference material up to 60 MPa. The approximation of the mechanical-technological properties is therefore deemed to be adequate.
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    A physically based material model for the simulation of friction stir welding
    (2020) Panzer, Florian; Shishova, Elizaveta; Werz, Martin; Weihe, Stefan; Eberhard, Peter; Schmauder, Siegfried
    A physically based material model, taking into account the interdependence of material microstructure and yield strength, is presented for an Al 5182 series aluminum alloy for the simulation of friction stir welding using continuum mechanics approaches. A microstructure evolution equation considering dislocation density and grain size is used in conjunction with a description of yield stress. In order to fit experimental stress-strain curves, obtained from compression tests at various strain rates and temperatures, phenomenological relationships are developed for some of the model parameters. The material model is implemented in smoothed particle hydrodynamic research code as well as in the commercial finite element code Abaqus. Simulations for various strain rates and temperatures were performed and compared with experimental results as well as between the two discretization methods in order to verify the material model and the implementation. Simulations provide not only an accurate approximation of stress based on temperature, strain rate, and strain but also an improved insight into the microstructural evolution of the material.
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    Abschlussbericht zum Projekt "Ressourcenschonende Mischschweißverbindungen für Hochleistungs-Leichtbauverbunde"
    (Stuttgart : Institut für Materialprüfung, Werkstoffkunde und Festigkeitslehre (IMWF) der Universität Stuttgart, 2018) Panzer, Florian; Werz, Martin; Nguyen, Phuc Lanh; Schneider, Matthias; Weihe, Stefan; Liewald, Mathias
    Im Rahmen des Projektes wurde das Rührreibschweißen als ressourceneffizientes und umweltfreundliches Fertigungsverfahren zur Herstellung von beanspruchungs- und gewichtsoptimierten Automobilbauteilen erforscht. Dabei galt es, Aluminium und Stahl in verschiedenen Dicken durch Rührreibschweißen zu fügen und durch anschließendes Umformen zum End- bzw. Zwischenprodukt umzuformen. Die auf die Festigkeiten der Werkstoffe angepassten Blechdicken führen zu einer optimalen Ausnutzung der Werkstoffe, da an jeder Stelle der Werkstoff verwendet werden kann, der die lokalen Anforderungen am besten erfüllt. Durch den Einsatz dieser sogenannten Tailor Welded Blanks sinkt der Werkstoffverbrauch insgesamt und es können auf Leichtbau optimierte Bauteile hergestellt werden. Im Rahmen des Projektes wurden verschiedene Aluminium- und Stahlgüten in unterschiedlichen Dicken durch Rührreibschweißen gefügt und die Festigkeits- sowie Umformeigenschaften ermittelt. Da die Einhaltung von engen Toleranzen mit hohen Kosten in der Fertigung einhergeht, wurden die für den Prozess notwendigen Toleranzen untersucht, Lösungen zum Umgang mit diesen Toleranzen erarbeitet und Anforderungen an Anlagen zur Produktion von Tailor Welded Blanks identifiziert. Zudem wurde das Umformen von Blechen mit unterschiedlichen Materialen und Blechdicken untersucht. Darüber hinaus wurde eine Reihe weiterer Themen wie das Verschweißen von Gusswerkstoffen und Wärmebehandlungsstrategien beleuchtet. Abschließend wurden Demonstratorbauteile in Form von Tailor Welded Blanks in Aluminium-Stahl- Mischbauweise durch Rührreibschweißen und anschließendes Umformen gefertigt.
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    Friction stir welded and deep drawn multi-material tailor welded blanks
    (2019) Panzer, Florian; Schneider, Matthias; Werz, Martin; Weihe, Stefan
    The ever increasing demand for more resource-efficient and safer vehicles in today’s automotive industry makes lightweight construction techniques necessary. However, overcoming contradicting requirements arising from lightweight design and safety remains a challenging task. The extent to which lightweight measures can be applied in order to save fuel, heavily depends on the fact that rising safety requirements have to be met by increasing strength of parts. This contradicting demand for parts with high strength and low weight leads to the development of new production technologies. One example, regarding car body components, is the tailor welded blank (TWB) technology. In tailor welded blanks, materials and thicknesses are locally adapted to meet the needed strength and strain properties while keeping the weight as low as possible. While tailor welded blanks consisting of similar materials with different thicknesses are already used in vehicles, the use of TWBs with dissimilar materials, e.g. steel and aluminum, is still in development due to the problems in joining dissimilar materials. Especially when manufacturing parts made of TWBs through joining and subsequent deep drawing, the joint needs to have very good strength properties in order not to fail during forming. One way to overcome these joining difficulties is friction stir welding. In this paper, a methodology is presented to produce multi-material tailor welded blanks with varying thicknesses through friction stir welding (FSW) and deep drawing in a subsequent step. A newly developed FSW joint configuration is used to weld steel sheets in 1 mm thickness to 2 mm thick aluminum sheets. A welding parameter study is conducted to investigate the influence of the process parameters on the joint quality. Tensile and Nakajima tests show that the joint strength, obtained with optimal process parameters, exceeds the strength of the steel base material. Thus, failure occurs in the steel, whereas the joint remains intact. The friction stir welded blanks were furthermore deep drawn. Two different tool approaches were tested to compensate the different sheet thicknesses during the forming process. Using the more suitable approach, blanks were deep drawn with three different punch geometries to show the potential of friction stir welding for the manufacturing of multi-material tailor welded blanks.