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| Taccardi, Nicola |
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| Petrov, R. H. | Madrid |
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| Alshaaer, Mazen | Brussels |
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| Kočí, Jan | Prague |
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| Šuljagić, Marija |
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| Kalteremidou, Kalliopi-Artemi | Brussels |
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| Azam, Siraj |
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| Ali, M. A. |
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| Azevedo, Nuno Monteiro |
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| Landes, Michael |
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Rieth, Michael
in Cooperation with on an Cooperation-Score of 37%
Topics
Publications (58/58 displayed)
- 2024Additive manufacturing of novel complex tungsten components via electron beam melting: Basic properties and evaluation of the high heat flux behavior
- 2024In-Situ synchrotron investigation of elastic and tensile properties of oxide dispersion strengthened EUROFER97 steel for advanced fusion reactorscitations
- 2024Hydrogen diffusion and trapping in a cryogenic processed high-Cr ferrous alloy
- 2024Tungsten alloys R&D program at KIT
- 2023Microstructural insights into EUROFER97 batch 3 steels
- 2023Effect of neutron irradiation on tensile properties of advanced Cu-based alloys and composites developed for fusion applications
- 2022Effect of neutron irradiation on ductility of tungsten foils developed for tungsten-copper laminates
- 2022Effect of neutron irradiation on ductility of tungsten foils developed for tungsten-copper laminatescitations
- 2022Recent progress in the assessment of irradiation effects for in-vessel fusion materials: tungsten and copper alloyscitations
- 2021Microstructure and precipitation behavior of advanced RAFM steels for high-temperature applications on fusion reactorscitations
- 2021Impact of materials technology on the breeding blanket design – Recent progress and case studies in materials technologycitations
- 2021Technological Processes for Steel Applications in Nuclear Fusion
- 2021Additive manufacturing technologies for EUROFER97 components
- 2021Impact of materials technology on the breeding blanket design Recent progress and case studies in materials technologycitations
- 2020Elucidating the microstructure of tungsten composite materials produced by powder injection molding
- 2020The brittle-to-ductile transition in cold-rolled tungsten sheets: the rate-limiting mechanism of plasticity controlling the BDT in ultrafine-grained tungstencitations
- 2020The brittle-to-ductile transition in cold-rolled tungsten sheets: On the loss of room-temperature ductility after annealing and the phenomenon of 45° embrittlementcitations
- 2020The brittle-to-ductile transition in cold-rolled tungsten sheets: On the loss of room-temperature ductility after annealing and the phenomenon of 45° embrittlementcitations
- 2020The brittle-to-ductile transition in cold-rolled tungsten sheets: Contributions of grain and subgrain boundaries to the enhanced ductility after pre-deformation
- 2019Manufacturing, high heat flux testing and post mortem analyses of a W-PIM mock-upcitations
- 2019Long-term stability of the microstructure of austenitic ODS steel rods produced with a carbon-containing process control agent
- 2019Mechanical properties and microstructure characterization of Eurofer97 steel variants in EUROfusion program
- 2019High pulse number thermal shock testing of tungsten alloys produced by powder injection moldingcitations
- 2018Expanding the operation window of RAFM steels by optimized chemical compositions and heat treatments
- 2018Expanding the operation window of RAFM steels by optimized chemical compositions and heat treatments
- 2017Processing of complex near-net-shaped tungsten parts by PIM
- 2017Ductilisation of tungsten (W): Tungsten laminated compositescitations
- 2017Production, microstructure and mechanical properties of two different austenitic ODS steelscitations
- 2017Assessment of industrial nitriding processes for fusion steel applicationscitations
- 2017Plasma exposure of tungsten in the linear plasma device PSI-2 produced via powder injection molding
- 2017Rapid material development and processing of complex near-net-shaped parts by PIM
- 2015Improvement of RAFM steels through thermo-mechanical treatments
- 2015Mechanical and microstructural investigations of tungsten and doped tungsten materials produced via powder injection moldingcitations
- 2014Microstructural anisotropy of ferritic ODS alloys after different production routes
- 2014Virtuelle Material- und Prozessentwicklung am Beispiel der Konstrukturausbildung in Schweißnähten
- 2011Optimization and limitations of known DEMO divertor concepts
- 2011TEM study of mechanically alloyed ODS powder
- 2011Review on the EFDA programme on tungsten materials
- 2011Influence of thickness and notch on impact bending properties of pure tungsten plate material
- 2011Development of high performance materials for nuclear fusion power plants
- 2010Cost effective fabrication of a fail-safe first wall
- 2010Fracture behavior of tungsten materials and the impact on the divertor design in nuclear fusion power plants
- 2010Tungsten materials for structural divertor applications
- 2009Fe-Cr-V ternary alloy-based ferritic steels for high- and low-temperature applications
- 2008Diffusion weld study for test blanket module fabrication
- 2008Impact bending tests on selected tungsten materials
- 2008Fracture behaviour of tungsten materials depending on microstructure and surface fabrication
- 2008Mechanical properties of different refractory materials for nuclear fusion applications
- 2007Specific welds for test blanket modules
- 2005Present development status of EUROFER and ODS-EUROFER for application in blanket concepts
- 2005A steady-state creep model for the AISI 316 L(N) in the technically relevant stress range
- 2005Evaluation of the mechanical properties of W and W-1%La₂O₃ in view of divertor applications
- 2005Creep and recrystallization of pure and dispersion strengthened tungsten
- 2005A comprising steady-state creep model for the austenitic AISI 316 L(N) steel
- 2005Microstructure and mechanical properties of different EUROFER welds
- 2005Assessment of different welding techniques for joining EUROFER blanket components
- 2005Verification and validation experiments for atomistic modeling of FeCr alloys
- 2004Creep of the austenitic steel AISI 316 L(N). Experiments and models
Places of action
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document
Tungsten materials for structural divertor applications
Abstract
Michael Rieth1, Andreas Hoffmann2, Edeltraud Materna-Morris1, Magnus Rohde1 1 Karlsruhe Institute of Technology, Institute for Materials Research I, Karlsruhe, Germany; 2 PLANSEE Metall GmbH, Development Refractory Alloys, Reutte, Austria Introduction Present design studies for extremely high loaded plasma facing cooling components make use of the high temperature strength and good heat conductivity of tungsten [e.g. 1, 2]. The most critical issue of tungsten materials in connection with structural applications is their brittleness. It is known that fracture behaviour as well as thermal conductivity depends on textures. Therefore, the microstructure, the chemical composition and their influence on thermal conductivity as well as on impact bending properties were investigated, using commercial tungsten and other refractory alloys. Results and Discussion Heat conductivity was measured by the laser-flash method for a tungsten plate (4 mm thick), for a W-1wt.%La2O3 (WL10) rod and plate, for a DENSIMET (W3.5wt.%Ni-1.5wt.%Fe) plate, and for a Ta-10wt.%W (TaW10) rod and plate. DENSIMET and WL10 are binary phase materials while TaW10 is an alloy (solid solution). The measurements were performed perpendicular to the plate surfaces and parallel to the rod axis. The results are given in Fig. 1. Fig. 1: Thermal conductivity of various refractory materials. With rising temperatures, the tungsten plate and WL10 materials show a continuous decrease of conductivity whereas TaW10 and DENSIMET show an increase. With values higher than 90 W/mK at 1300°C, pure tungsten and WL exhibit the best results. However, a clear reduction of the conductivity can be observed in the case of the pure tungsten and WL10 plates. On the one hand, this behaviour is a consequence of the lanthanum-oxide content, and of the microstructure (compared to the WL10 rod), on the other. Fabrication and testing of Charpy specimens has been performed according to the EU standards DIN EN ISO 148-1 and 14556:2006-10. That is, small size specimens (27 mm x 3 mm x 4 mm, 1 mm notch depth, 22 mm span) have been used. To avoid oxidation the whole Charpy testing machine was placed inside a vacuum vessel which was operated at typical pressures of about 10-3 mBar. The Charpy tests were performed on specimens fabricated from rods as well as from standard and with highest possible level of deformation (WL10opt), potassium (0.005 wt.%) doped tungsten (WVM), and WL10 with 1 wt.% Re (W1Re1-La2O3). Plates of pure W, WL10, WVM, and molybdenum-Ti-Zr (TZM) were also used for the investigation. More detailed information about material fabrication, microstructure examinations, and Charpy test results can be found in [3, 4]. Typically, bcc metals show a transition from brittle (transcrystalline) to ductile fracture. But the tungsten based rod materials don’t show this single transition. Moreover, only specimens of pure tungsten and WVM show fully ductile fractures, starting at 900 °C and 1000 °C, respectively. Fig. 3: Side view of delamination fractures in Charpy specimens of various tungsten rod materials. However, all materials tend to exhibit brittle fracture temperatures below 600 °C. Above that temperature, the specimens show fractures which propagate along the rod axis, that is, parallel to the specimen’s long side and perpendicular to the notch (see Fig. 3). There are obviously similarities to the fracturing of fiber reinforced materials and, therefore, this type of fracture is usually called delamination. In summary, there are three types of fracture (brittle, delamination, and ductile) which are linked by a brittle-to-delamination transition and a delamination-to-ductile transition. Compared to the rod materials, the Charpy energies of specimens of the plate materials are lower by more than 50 %. Moreover, all plate material specimens don’t show fully ductile fractures, even at test temperatures up to 1100 °C. Below 500 °C the