For more information please contact Prof. Eleonora Ferraris (firstname.lastname@example.org, +3215316944), Prof. dr. ir. Frederik Desplentere, tel.: +32 50 66 48 56, mail: email@example.com or Prof. dr. ir. Jef Vleugels, tel.: +32 16 32 12 44, mail: firstname.lastname@example.org.
You can apply for this job no later than October 20,2020 via the online application tool : http://www.kuleuven.be/eapplyingforjobs/light/55800638
Please, provide your CV, motivation letter, and transcripts. Please, highlight in your CV the key expertise fully matching the demanded background. Hence, indicate your knowledge in FFF and/or filament extrusion and/or multi-material printing and/or post processing of green parts with polymeric binders. Expertise in ceramic and metal-based injection moulding processing is also valuable.
Please highlight in your cv , the distinction elements obtained during your academic career. Indicate clearly your GPA, your (journal) publications as first author, or talks, or research grants/scholarship, if any.
KU Leuven seeks to foster an environment where all talents can flourish, regardless of gender, age, cultural background,nationality or impairments. If you have any questions relating to accessibility or support, please contact us at diversiteit.HR@kuleuven.be.
You can apply for this job no later than October 23, 2020 via the online application tool
KU Leuven seeks to foster an environment where all talents can flourish, regardless of gender, age, cultural background, nationality or impairments. If you have any questions relating to accessibility or support, please contact us at diversiteit.HR@kuleuven.be.
This opening principally refers to a PhD position. Young post doc profiles might also be considered.
The project will be performed in the framework of the FWO-SBO Multimaterial Additive Manufacturing for Electrical Machines (AM4EM) project. The consortium involves all key research groups in Flanders active in the field, i.e., the Ghent University (UGent), KU Leuven (KUL) and Vito, with long tradition and complementary expertise along the entire process chain, from material science and processing, additive manufacturing and post processing, electrical machine design and evaluation.
Description of the organizational unit.
Due to the nature of the research, the candidate will be active at KU Leuven on 3 different campuses (Heverlee, De Nayer and Bruges) and in 2 different departments (Mechanical Engineering and Materials Engineering). The PhD will be promoted by Prof. PhD. Ing. Eleonora Ferraris (email@example.com, +3215316944), and co-supervised by Prof. PhD. In.g Jozef Vleugels, (firstname.lastname@example.org), and Prof. PhD. Ing. Frederik Desplentere (email@example.com). The candidate will obtain a Ph.D. in Mechanical Engineering at the Faculty of Engineering Technology (https://iiw.kuleuven.be/english) of KU Leuven (http://www.kuleuven.be/kuleuven/).
The current performance of electrical machines, i.e.machines that create motion out of electricity as well as machines that convert motion into electrical energy, is constrained by construction and design rules due to the adoption of traditional production methods. These generally involve the stacking of laminated and insulated ferromagnetic steel sheets to form the magnetically conductive stator and rotor core and employ electrically conductive windings, made of insulated copper, in the slots. In this context,additive manufacturing (AM) can open up new horizons in the design of electrical machines, given its high flexibility in geometrical product design,material selection and material combination. In this project, multi-material AM techniques will be adopted to combine materials with different properties(conductive vs. insulating) in order to reach a real added value in developing electrical machines.
In this regard, the use of selected materials (such asFeSi, FeCo,Cu, and glass-ceramic) will be put forward to pursue the desired electrical, magnetic, thermal and mechanical properties. An extrusion-based indirect AM processes, like fused filament fabrication (FFF) and robocasting will be explored for the shaping of multi-material components, combined with high temperature sintering to ensure high density, homogeneity, and optimal performance.
This PhD will focus on the complete additive process, going from filament fabrication to FFFprinting of the green parts. The PhD student will also partially be involved in the post-processing of the printed parts.
The printed parts (or green parts) will indeed consistof a combination of the desired structural material (metal or ceramic powders)combined with an organic binder, which will be removed during the ‘debinding’or ‘firing’ phase. This phase is then followed up by component densification(‘sintering’), which takes place at very high temperature. A major challenge inprinting multi-material Fe-Si/ceramic/Cu combinations is their relatively large difference in sintering temperature to reach full density and a functional microstructure (key to reach good electrical, magnetic or thermal conductivity)as well as their difference in coefficient of thermal expansion (CTE) which can result in thermal stresses and geometrical inaccuracy after cooling.
Besides the challenges of the post-process step (which will be tackled by and in collaboration with another PhD student), also thefilament production and the printing itself will be challenging as it is neededto ensure continuous filaments with substantial loading and at the same time a good viscosity for extrusion.
Filament production will include research activities going from compound selection, feedstock preparation, filament extrusion and characterization. Filament production will mostly take part at the Materials Engineering Department of the KU Leuven, campus Bruges, and locally supported by technical and post-doc expertise for test execution and extruder adaptation.FFF printing will take place mostly at the department of Mechanical Engineering,Campus De Nayer, KU Leuven. And it will include process parameter investigation, sample and part production as well as characterization of the printed components. The additive process, where the filament layer is extruded in a layer-by-layer manner, also needs to be optimized in terms of form stability, printing speed, density and adhesion. Adhesion needs to be optimized not only for identical layers, but also for multi-material stacks.