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- Delft University of Technology (TU Delft)
- Delft University of Technology (TU Delft); yesterday published
- Eindhoven University of Technology (TU/e); today published
- Delft University of Technology (TU Delft); Delft
- Eindhoven University of Technology (TU/e); yesterday published
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EU programme Is the Job related to staff position within a Research Infrastructure? No Offer Description Join our team at TU Delft to develop a novel electromagnetic flow meter for turbulent pipe flow
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Join our team at TU Delft to develop a novel electromagnetic flow meter for turbulent pipe flow Job description Electromagnetic (EM) flow meters are widely used in industry for accurate measurements
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to electrochemisty and electromagnetics. Interface tracking/capturing methods such as immersed boundary method, level-set method, volume-of-fluid, phase filed method are options for model development.
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on the development of new antenna and integrated circuit concepts for radar and electromagnetic modelling. The Electromagnetics (EM) and Integrated Circuit (IC) groups are involved as well as the Center for Wireless
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on the development of new antenna and integrated circuit concepts for radar and electromagnetic modelling. The Electromagnetics (EM) and Integrated Circuit (IC) groups are involved as well as the Center for Wireless
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schema maritime innovation projects (subsidieregeling maritieme innovatieprojecten). The project leader is Advanced Electromagnetics BV. We also collaborate with Allseas, who are developping an SMR
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Atomic Drive. The MeGa-Drive project is funded by the subsidy schema maritime innovation projects (subsidieregeling maritieme innovatieprojecten). The project leader is Advanced Electromagnetics BV. We
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: • Develop efficient numerical methods and strategies to solve the electromagnetic and heat transfer problem in induction welding. • Develop constitutive models that capture the temperature
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regime, they must be isolated from their environment. One powerful approach is to levitate them in vacuum with electromagnetic fields, offering unrivaled dynamic control and a broad sensor mass range, from
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electromagnetic fields, offering unrivaled dynamic control and a broad sensor mass range, from femtograms to nanograms. In recent years, we made major progress in controlling the motion of such levitated systems