Your search keyword '"Blair, Steven M."' showing total 3 results

1. The analysis and application of resistive superconducting fault current limiters in present and fututre power systems

Author

Blair, Steven M.

Subjects

621.3

Abstract

Fault current levels in electrical systems are rising due to natural growth in demand, the increasing presence of distributed generation (DG), and increased network interconnection. This rising trend is expected to continue in the future. Marine vessel power systems are highly power-dense and are often safety-critical. Power system protection is increasingly challenging in these systems. Superconducting fault current limiters (SFCLs) o er an attractive solution to many of the issues faced. This thesis establishes and reviews the state of the art in resistive SFCL technology and application knowledge, and provides crucial research-based guidance for the adoption of resistive SFCLs in future power systems. The issues associated with the application of resistive SFCLs- including location, resistance rating, the recovery period, and interaction with protection systems are demonstrated. The relationship between several resistive SFCL design parameters is established using a gener ic analytical approach, hence providing a framework for validating SFCL designs. In particular, it is shown that a particular SFCL resistance rating leads to a peak in the superconductor energy dissipation, which generally should be avoided. It is proven that resistive SFCLs have an inverse current-time characteristic, i.e., they will operate in a time that inversely depends upon the initial fault current magnitude. This knowledge is critical for underpinning the operation of a novel protection scheme using multiple resistive SFCLs. The scheme offers several advantages: very fast-acting operation in response to faults anywhere on the system under study; maximum prospective fault currents are prevented from occurring, reducing the duty on circuit breakers; inherent, fast-acting backup; and communications is not required. It is shown that the scheme is suited to highly-interconnected systems with a high presence of DG. The scheme is readily applicable to the design of future utility and marine vessel power systems.

Published

2013

2. Impact of realistic communications for fast-acting demand side management

Author

Dambrauskas, Paulius, Syed, Mazheruddin H., Blair, Steven M., Irvine, James M., Abdulhadi, Ibrahim F., Burt, Graeme M., Bondy, Daniel Esteban Morales, Dambrauskas, Paulius, Syed, Mazheruddin H., Blair, Steven M., Irvine, James M., Abdulhadi, Ibrahim F., Burt, Graeme M., and Bondy, Daniel Esteban Morales

Abstract

The rising penetration of intermittent energy resources is increasing the need for more diverse electrical energy resources that are able to support ancillary services. Demand side management (DSM) has a significant potential to fulfil this role, but several challenges are still impeding the wide-scale integration of DSM. One of the major challenges is ensuring the performance of the networks that enable communications between control centres and the end DSM resources. This study presents an analysis of all communications networks that typically participate in the activation of DSM, and provides an estimate for the overall latency that these networks incur. The most significant sources of delay from each of the components of the communications network are identified which allows the most critical aspects to be determined. This analysis, therefore, offers a detailed evaluation of the performance of DSM resources in the scope of providing real-time ancillary services. It is shown that, using available communications technologies, DSM can be used to provide primary frequency support services. In some cases, neighbourhood area networks may add significant delay, requiring careful choice of the technologies deployed.

Published

2017

3. Laboratory infrastructure driven key performance indicator development using the smart grid architecture model

Author

Syed, Mazheruddin H., Guillo-Sansano, Efren, Blair, Steven M., Burt, Graeme M., Strasser, Thomas I., Brunner, Helfried, Gehrke, Oliver, Rodriguez-Seco, Jose E., Syed, Mazheruddin H., Guillo-Sansano, Efren, Blair, Steven M., Burt, Graeme M., Strasser, Thomas I., Brunner, Helfried, Gehrke, Oliver, and Rodriguez-Seco, Jose E.

Abstract

This study presents a methodology for collaboratively designing laboratory experiments and developing key performance indicators for the testing and validation of novel power system control architectures in multiple laboratory environments. The contribution makes use of the smart grid architecture model as it facilitates the integration of individually developed control functions into a consolidated solution for laboratory validation and testing. The experimental results obtained across multiple laboratories can be efficiently compared, when the proposed methodology is adopted and thus the study offers means of support for improved cooperation in smart grid validation and round robin testing.

Published

2017