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1. Optimal Design of a Fully Superconducting Machine for 10- MW Offshore Wind Turbines

   https://doi.org/10.1109/IEMDC.2019.8785227  

   Balachandran, Thanatheepan; Lee, Dongsu; Haran, Kiruba S. (May 2019, 2019 IEEE International Electric Machines Drives Conference (IEMDC))

   {Fully superconducting (SC)machines hold immense promise for high-power-density and higher efficiency machine solutions for offshore wind turbine applications. In this paper, a 10MW air-core fully SC machine is designed for offshore wind turbine applications. This machine design is considered with inside armature coils and outside rotating field coils. In this topology, shield iron can be eliminated or reduced by replacing it with shield coils which contain the magnetic flux inside the machine. This machine is attractive for off-shore wind turbine application due to its high-power density and high efficiency compared to a conventional shield iron design. However, due to the introduction of additional shield coils, this topology uses relatively more amount of SC material than a conventional shield iron design. Therefore, a tradeoff between the shield coils and the shield iron is explored in this paper. In addition, machine designs with different pole-counts are investigated to identify the optimal pole-count design for a low-speed application. A detailed ac loss calculation is evaluated for the machine and required cryocooler power is evaluated to obtain the machine efficiency. 

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2. Design Optimization of Coreless Axial-flux PM Machines with Litz Wire and PCB Stator Windings

   Kesgin, M. G.; Han, P.; Taran, N.; Lawhorn, D.; Lewis, D.; Ionel, D. M. (August 2020, Proceedings, 2020 IEEE Energy Conversion Congress and Exposition (ECCE), Detroit, MI)

   Coreless axial-flux permanent-magnet (AFPM) machines may be attractive options for high-speed and high-power density applications due to the elimination of core losses. In order to make full use of the advantages offered by these machines and avoid excessive eddy current losses in windings, advanced technologies for winding conductors need to be employed to suppress the eddy effect, such as the Litz wire and printed circuit board (PCB). In this paper, the best practices for designing Litz wire/PCB windings are discussed and a brief survey of state of the art PCB winding technology is provided. Three coreless AFPM machines are mainly considered. A design optimization procedure based on the multi-objective differential evolution algorithm and 3-dimensional (3D) finite element analysis (FEA) is proposed to take into account the ac winding losses of Litz wires and PCB traces in the machine design stage. Selected designs are being prototyped and will be tested with a customized test fixture. 

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3. Optimization of an Unregulated Low-Q Resonant Isolated DC-DC Stage for Low-Power AC-AC Converters

   https://doi.org/10.1109/COMPEL57542.2024.10614056  

   Nguyen, Allen T; Sullivan, Charles R (June 2024, IEEE)

   Low-power line-frequency transformers are common across several applications, but these transformers are found to have large standby losses, low efficiencies, large weights, and high costs. In this paper we optimize a power conversion stage for this and other applications where an unregulated, isolated converter is needed. The selected topology uses low-impedance passives to reduce their size; to address this case we analyze operation of a lower-Q resonant tank. Lastly, because of the application of low-power line-frequency transformers, we optimize around a typical usage cycle to minimize the yearly average power loss. For the application of a Class 2 line-frequency transformer, model results are accurate to simulation by within 12.1%, and optimization produced a design that was experimentally validated to achieve a yearly average power loss of 285.1 mW, a peak efficiency of 99.26% and a standby loss of 155 mW. 

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4. A 2.4 GHz low-power and compact 3-bit active phase shifter utilizing miller capacitance

   https://doi.org/10.1016/j.mejo.2023.105914  

   Qi, Yu; Kines, Michael; Ellicott, Samuel; Khalil, Waleed; Lavasani, Hossein Miri (October 2023, Microelectronics Journal)

   A low-power and compact 3-bit active phase shifter is designed and implemented in a 22 nm FDSOI CMOS process. A modified inverter-based topology, which takes advantage of miller capacitance, is used to create a compact and low-power solution, resulting in 10 and 90 x reduction in the power and chip area, respectively, for a given phase shift, compared to the standard inverter-based topology. At the same time, the proposed phase shifter exhibits less sensitivity to device mismatch. The proposed design measures 0.004 mm2, consumes 1.8 mW, and delivers up to 65°of phase shift with RMS phase and amplitude error of 3.85°and ±0.34 dB, respectively. The measured die-to-die variation is also confined to ±6.2°, which is 10% of the full range 

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5. Theoretical and Experimental Work on Optimal Contact Geometries on Fast Mechanical Disconnect Switches

   https://doi.org/10.1109/HOLM.2018.8611645  

   Damle, T.; Graber, L. (October 2018, 2018 IEEE Holm Conference on Electrical Contacts)

   Fast mechanical disconnect switches (FMS) are an integral part of hybrid circuit breakers, which are proposed as protection devices to clear faults in medium voltage distribution systems. The proposed FMS is a vacuum switch that is operated by an amplified piezoelectric actuator. Such actuators enable unprecedented speed and contact separation in less than one millisecond. The limitations that come with such designs are the low contact separation of typically less than one millimeter in open position and low contact force in the order of 100 N in closed position. This requires a new design of the contacts to operate under such constraints. The geometry of the contacts must be carefully designed to minimize electrical resistance when closed and minimize electric field enhancement when open. The paper presents finite element analysis and experimental results with the aim of identifying the most suitable contact geometry for FMS. The experiments show that optimized contact geometries have up to 40% less resistance than the initial spherical geometry. 

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