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Dr Mark Ainslie CEng

Dr Mark Ainslie, CEng

Royal Academy of Engineering Research Fellow

Junior Research Fellow, King's College

Mark Ainslie is available for consultancy.


Biography:

Dr Mark Ainslie is a Research Fellow in the Bulk Superconductivity Group, part of Division C (Mechanics, Materials and Design) of the Department of Engineering. He is also a Junior Research Fellow at King's College. His research interests are in applied superconductivity in electrical engineering, including superconducting electric machine design, power system protection and energy storage, and electromagnetic modelling, including FEM.

He is currently funded by the Royal Academy of Engineering and is working on engineering interactions of conventional, magnetic and superconducting materials for electrical applications. This project is focused in particular on the design of an axial gap, trapped flux-type superconducting electrical machine.

Research themes

Energy Storage:

Applied superconductivity in electrical engineering, including superconducting electric machine design, power system protection and energy storage, and electromagnetic modelling, including FEM.

Networks and Distribution:

Applied superconductivity in electrical engineering, including superconducting electric machine design, power system protection and energy storage, and electromagnetic modelling, including FEM.

Smart Systems and Device Design:

Departments and Institutes

Department of Engineering:

Research Interests

Applied superconductivity in electrical engineering, including:

  • Superconducting electric machine design;
  • Power system protection;
  • Energy storage; and
  • Electromagnetic modelling, including FEM.

Keywords

  • Efficiency
  • Materials
  • Sustainability

Key Publications

Recent first author, peer-reviewed publications

M.D. Ainslie, H. Fujishiro, T. Ujiie, J. Zou, A.R. Dennis, Y-H. Shi, D.A. Cardwell, “Modelling and comparison of trapped fields in (RE)BCO bulk superconductors for activation using pulsed field magnetisation,” Superconductor Science & Technology, Vol. 27, 065008 (9pp), 2014

M.D. Ainslie, A. George, R. Shaw, L. Dawson, A. Winfield, M. Steketee, S. Stockley, “Design and market considerations for axial flux superconducting electric machine design,” Journal of Physics: Conference Series, 2014 (at press)

M.D. Ainslie, W. Yuan, T.J. Flack, “Numerical Analysis of AC Loss Reduction in HTS Superconducting Coils using Magnetic Materials to Divert Flux,” IEEE Transactions on Applied Superconductivity, Vol. 23, No. 3, 4700104 (4pp), 2013

M.D. Ainslie, T.J. Flack, A.M. Campbell, "Calculating transport AC losses in stacks of high temperature superconductor coated conductors with magnetic substrates using FEM," Physica C, Vol. 472, No. 1, p. 50-56, 2011

M.D. Ainslie, V.M. Rodriguez-Zermeno, Z. Hong, W. Yuan, T.J. Flack, T.A. Coombs, "An improved FEM model for computing transport AC loss in coils made of RABiTS YBCO coated conductors for electric machines," Superconductor Science & Technology, Vol. 24, 045005 (8pp), 2011

M.D. Ainslie, T.J. Flack, Z. Hong, T.A. Coombs, "Comparison of First- and Second-Order 2D Finite Element Models for Calculating AC Loss in High Temperature Superconductor Coated Conductors," COMPEL: The International Journal for Computation and Mathematics in Electrical and Electronic Engineering, Vol. 30, Iss. 2, p. 762-774, 2011