Abstract
Machines incorporating high-speed electrical machines (HSEM) are becoming increasingly common place in applications including air handling, energy storage and medical devices. They are of increasing interest within the automotive field for air handling applications. HSEM’s use surface-mounted permanent magnet (PM) rotors, manufactured from rare earth metals. However, these PM’s have low tensile strength and are susceptible to failure under the centrifugal load produced at high speed rotation. Retaining sleeves which are an interference fit around the magnets, provide compression and hence resistance to tensile stress. The ability to predict the stresses within the rotor assembly is essential for robust design. This review paper examines existing analytical calculations and finite element analysis (FEA) models. The analytical approaches include both plane stress and plane strain models and the limitations of these are discussed. For relatively long rotors, a generalised plane strain approach is suitable, however it is seldom used. In addition, this latter approach has not been extended to assemblies where the magnets are assembled onto a carrier or shaft. Optimisation of rotors has been addressed in a relatively small number of papers. However, further work is required in this area to ensure that the optimised rotors can be manufactured.
Highlights
Reference [1] discussed how high-speed electrical machines (HSEM) usage has increased over the last decade due to the performance benefits over mechanical transmission
Reference [9] listed compressors, vacuum pumps, turbine generators and medical drills as HSEM applications while [7] included fuel pumps and turbochargers, all of which operate above 10,000 rpm
The plane stress assumption simplifies the equations by ignoring the presence of axial stress but may produce unrealistic results
Summary
Reference [1] discussed how HSEM usage has increased over the last decade due to the performance benefits over mechanical transmission. Sintered PM’s such as Samarium Cobalt (SmCo, SmCo5 or Sm2Co17) or Neodymium (Nd2Fe14B) are used [8] These high-energy density magnets enable a rotor size reduction and an increase in operating speed [9]. The compressor wheel draws in air and delivers it to the engine above ambient density for complete fuel combustion, maximising power and enabling engines to be ‘down-sized’, as discussed by [14]. This air handling control results in increased engine efficiency and reduced emissions [10]. The speed and size requirements of EATs for light-duty vehicles makes application difficult, as discussed by [8]; operating speed requirements are 100-300 krpm whilst dimensions must be minimised to fit within the limited engine space
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