论文信息 - Conceptual design of an all superconducting mini power plant model

Conceptual design of an all superconducting mini power plant model

The development of all superconducting (AS) plants (ASP), as for example AS mini power plants (MPP), or AS substations is a new trend in power applications of superconductivity. Superconductivity can contribute significantly to increase the advantages of MPPs. Exceeding the stage of the development of individual superconducting power devices (SPD), more and more concern is being focused around ASPs consisting of a set of individual SPDs being integrated into one system possessing substantial additional benefits compared to and exceeding those of the individual SPDs. A high temperature superconducting (HTS) MPP model with a projected power rating of 10 kW has been designed by the author for development, construction and testing in the near future. Proper approaches and tools are needed to promote the industrial application and market introduction of HTS power devices, including that of the HTS MPP. Computer aided engineering problem solving (CAEPS) methods effectively help estimate qualitatively and quantitatively the technical and economical feasibilities of HTS devices. CAEPS methods and tools have been applied to develop the HTS MPP model.

István Vajda

[1] Mario Rabinowitz. Power Systems of the Future , 2003 .

[2] H. Merrill. The RTO debate [regional transmission organisations] , 2000 .

[3] Edward Lumsdaine,et al. Creative problem solving , 1995 .

[4] J. O. Willis. Superconducting transmission cables , 2000 .

[5] A. Gyore,et al. Upgrading electric power quality by superconducting flywheels , 2000 .

[6] B. W. McConnell,et al. HTS transformers , 2000 .

[7] M. Einhorn. Art as Innovation , 2002 .

[8] J. R. Hull,et al. Flywheels on a roll , 1997 .

[9] W. Buckles,et al. Superconducting magnetic energy storage , 2000 .

[10] W. V. Hassenzahl,et al. Applications of superconductivity to electric power systems , 2000 .

[11] W. V. Hassenzahl. More applications of superconductivity to electric power systems , 2000 .

[12] Mario Rabinowitz. Superconducting power generation , 2000 .

[13] István Vajda,et al. Three phase inductive HTS fault current limiter for the protection of a 12 kVA synchronous generator , 2001 .

[14] B. W. McConnell,et al. Method for estimating future markets for high-temperature superconducting power devices , 2002 .

[15] Mario Rabinowitz. Power systems of the future. 2 , 2000 .

[16] L. R. Lawrence,et al. High temperature superconductivity: The products and their benefits , 1998 .

[17] E. M. Leung. Superconducting fault current limiters , 2000 .