A study on the required performance of a 2G HTS wire for HTS wind power generators

YBCO or REBCO coated conductor (2G) materials are developed for their superior performance at high magnetic field and temperature. Power system applications based on high temperature superconducting (HTS) 2G wire technology are attracting attention, including large-scale wind power generators. In particular, to solve problems associated with the foundations and mechanical structure of offshore wind turbines, due to the large diameter and heavy weight of the generator, an HTS generator is suggested as one of the key technologies. Many researchers have tried to develop feasible large-scale HTS wind power generator technologies. In this paper, a study on the required performance of a 2G HTS wire for large-scale wind power generators is discussed. A 12 MW class large-scale wind turbine and an HTS generator are designed using 2G HTS wire. The total length of the 2G HTS wire for the 12 MW HTS generator is estimated, and the essential prerequisites of the 2G HTS wire based generator are described. The magnetic field distributions of a pole module are illustrated, and the mechanical stress and strain of the pole module are analysed. Finally, a reasonable price for 2G HTS wire for commercialization of the HTS generator is suggested, reflecting the results of electromagnetic and mechanical analyses of the generator.

[1]  T.J.E. Miller,et al.  Comparative design and performance analysis of air-cored and iron-cored synchronous machines , 1977 .

[2]  T.J.E. Miller,et al.  Analysis of fields and inductances in air-cored and iron-cored synchronous machines , 1977 .

[3]  Martin N. Wilson,et al.  Case studies in superconducting magnets: Yukikazu Iwasa , 1996 .

[4]  Anca Daniela Hansen,et al.  Modelling and control of variable-speed multi-pole permanent magnet synchronous generator wind turbine , 2008 .

[5]  Xin Wang,et al.  Tensile Properties of CFRP and Hybrid FRP Composites at Elevated Temperatures , 2009 .

[6]  H. Polinder,et al.  Optimization of Multibrid Permanent-Magnet Wind Generator Systems , 2009, IEEE Transactions on Energy Conversion.

[7]  C. Træholt,et al.  Superconducting wind turbine generators , 2010 .

[8]  C. Træholt,et al.  Superconducting generators for wind turbines: Design considerations , 2010 .

[9]  H. Ohsaki,et al.  Electromagnetic Design of 10 MW Class Fully Superconducting Wind Turbine Generators , 2012, IEEE Transactions on Applied Superconductivity.

[10]  Maureen Hand,et al.  IEA Wind Task 26: The Past and Future Cost of Wind Energy, Work Package 2 , 2012 .

[11]  Jian Xun Jin,et al.  Design process and performance analysis of a short-axis 10 MW HTS wind generator , 2013, 2013 IEEE International Conference on Applied Superconductivity and Electromagnetic Devices.

[12]  Minwon Park,et al.  Practical Design of a 10 MW Superconducting Wind Power Generator Considering Weight Issue , 2013, IEEE Transactions on Applied Superconductivity.

[13]  Michaela D. Platzer U.S. Wind Turbine Manufacturing: Federal Support for an Emerging Industry [January 16, 2013] , 2013 .

[14]  Tor Anders Nygaard,et al.  Levelised cost of energy for offshore floating wind turbines in a life cycle perspective , 2014 .

[15]  Ronghai Qu,et al.  HTS Vernier Machine for Direct-Drive Wind Power Generation , 2014, IEEE Transactions on Applied Superconductivity.

[16]  Xavier Obradors,et al.  Coated conductors for power applications: materials challenges , 2014 .

[17]  M. Mueller,et al.  A modular and cost-effective superconducting generator design for offshore wind turbines , 2015 .

[18]  Ronghai Qu,et al.  Comparison Study of Superconducting Wind Generators With HTS and LTS Field Windings , 2015, IEEE Transactions on Applied Superconductivity.