University of Illinois Urbana-Champaign

Electro-thermal design and optimization of cryocooled electrical machines

Balachandran, Thanatheepan

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https://hdl.handle.net/2142/117783

Description

Title
Electro-thermal design and optimization of cryocooled electrical machines
Author(s)
Balachandran, Thanatheepan
Issue Date
2022-11-28
Director of Research (if dissertation) or Advisor (if thesis)
Haran, Kiruba S
Doctoral Committee Chair(s)
Haran, Kiruba S
Committee Member(s)
  • Jin, Jianming
  • Banerjee, Arijit
  • Stillwell, Andrew
Department of Study
Electrical & Computer Eng
Discipline
Electrical & Computer Engr
Degree Granting Institution
University of Illinois at Urbana-Champaign
Degree Name
Ph.D.
Degree Level
Dissertation
Keyword(s)
  • Multi-physics optimization
  • cryocooled electrical machine
  • superconducting electrical machine
  • ac loss
  • analytical modeling
  • electric propulsion
  • wind turbine
Abstract
Thermal management is a significant challenge in designing high-power-density electrical machines. Inherent resistivity losses in the electrical system limit conventional machines' achievable power density and efficiency. Cryocooled conductors and superconductors (SC) substantially reduce resistivity losses, enabling higher electrical and magnetic loading of cryocooled electrical machines, and potentially increasing the power density by a factor of ten. However, generated ac losses in these conductors must be removed in bulk, low-efficient cryogenic environments requiring a large amount of cryo-power. This is a substantial hurdle. Therefore, optimizing machine losses and designing efficient cryo-thermal management is necessary for a feasible cryocooled electrical machine. To minimize ac losses and machine weight, an electromagnetic (EM) machine design requires an electro-thermal, multiphysics optimization incorporating conductor properties, a machine thermal model, and a cryogenic cooling scheme. Reliable ac-loss estimation on an armature conductor is a crucial enabler of such an optimization. This dissertation summarizes the efforts of developing a practical electro-thermal analysis and multiphysics optimization for cryocooled electrical machines. Analytical approaches are introduced to capture the spatial and time-harmonics impacts on armature ac losses and verified with finite element analysis (FEA). An ac-loss-measurement test bench is developed to validate the proposed loss-prediction methods and calibrate the motor design analysis. Ac losses in SC samples are experimentally measured and compared against analytical models and FEA results. Examples of multiphysics optimization are presented for electric propulsion motors and wind turbine generators. Sub-scale component hardware tests, including SC armature winding and a rotating cryocooler test bench, are demonstrated for low-frequency applications. Finally, future work focuses on high-frequency tests.
Graduation Semester
2022-12
Type of Resource
Thesis
Copyright and License Information
Copyright 2022 Thanatheepan Balachandran

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