Your search keyword '"Weijia Yuan"' showing total 3 results

1. Modelling and Fault Current Characterization of Superconducting Cable with High Temperature Superconducting Windings and Copper Stabilizer Layer

Author

Eleni Tsotsopoulou, Adam Dyśko, Qiteng Hong, Abdelrahman Elwakeel, Mariam Elshiekh, Weijia Yuan, Campbell Booth, and Dimitrios Tzelepis

Subjects

superconducting cable, quench, high temperature, coppers stabilizer, superconducting tape, fault current limiting feature, Technology

Abstract

With the high penetration of Renewable Energy Sources (RES) in power systems, the short-circuit levels have changed, creating the requirement for altering or upgrading the existing switchgear and protection schemes. In addition, the continuous increase in power (accounting both for generation and demand) has imposed, in some cases, the need for the reinforcement of existing power system assets such as feeders, transformers, and other substation equipment. To overcome these challenges, the development of superconducting devices with fault current limiting capabilities in power system applications has been proposed as a promising solution. This paper presents a power system fault analysis exercise in networks integrating Superconducting Cables (SCs). This studies utilized a validated model of SCs with second generation High Temperature Superconducting tapes (2G HTS tapes) and a parallel-connected copper stabilizer layer. The performance of the SCs during fault conditions has been tested in networks integrating both synchronous and converter-connected generation. During fault conditions, the utilization of the stabilizer layer provides an alternative path for transient fault currents, and therefore reduces heat generation and assists with the protection of the cable. The effect of the quenching phenomenon and the fault current limitation is analyzed from the perspective of both steady state and transient fault analysis. This paper also provides meaningful insights into SCs, with respect to fault current limiting features, and presents the challenges associated with the impact of SCs on power systems protection.

Published

2020

2. Designing and Testing Composite Energy Storage Systems for Regulating the Outputs of Linear Wave Energy Converters

Author

Zanxiang Nie, Xi Xiao, Pritesh Hiralal, Xuanrui Huang, Richard McMahon, Min Zhang, and Weijia Yuan

Subjects

wave energy, linear machine, energy storage, power conversion, renewable energy, Technology

Abstract

Linear wave energy converters generate intrinsically intermittent power with variable frequency and amplitude. A composite energy storage system consisting of batteries and super capacitors has been developed and controlled by buck-boost converters. The purpose of the composite energy storage system is to handle the fluctuations and intermittent characteristics of the renewable source, and hence provide a steady output power. Linear wave energy converters working in conjunction with a system composed of various energy storage devices, is considered as a microsystem, which can function in a stand-alone or a grid connected mode. Simulation results have shown that by applying a boost H-bridge and a composite energy storage system more power could be extracted from linear wave energy converters. Simulation results have shown that the super capacitors charge and discharge often to handle the frequent power fluctuations, and the batteries charge and discharge slowly for handling the intermittent power of wave energy converters. Hardware systems have been constructed to control the linear wave energy converter and the composite energy storage system. The performance of the composite energy storage system has been verified in experiments by using electronics-based wave energy emulators.

Published

2017

3. Designing and Testing Composite Energy Storage Systems for Regulating the Outputs of Linear Wave Energy Converters

Author

Xi Xiao, Pritesh Hiralal, Xuanrui Huang, Zanxiang Nie, Min Zhang, Weijia Yuan, and Richard A. McMahon

Subjects

linear machine, Engineering, Control and Optimization, TK, Energy Engineering and Power Technology, 02 engineering and technology, lcsh:Technology, 01 natural sciences, Energy storage, law.invention, law, power conversion, Microsystem, 0103 physical sciences, 0202 electrical engineering, electronic engineering, information engineering, Electronic engineering, Electronics, Electrical and Electronic Engineering, 010306 general physics, Engineering (miscellaneous), wave energy, energy storage, renewable energy, lcsh:T, Renewable Energy, Sustainability and the Environment, business.industry, 020208 electrical & electronic engineering, Electrical engineering, Converters, Renewable energy, Accumulator (energy), Capacitor, Amplitude, business, Energy (miscellaneous)

Abstract

Linear wave energy converters generate intrinsically intermittent power with variable frequency and amplitude. A composite energy storage system consisting of batteries and super capacitors has been developed and controlled by buck-boost converters. The purpose of the composite energy storage system is to handle the fluctuations and intermittent characteristics of the renewable source, and hence provide a steady output power. Linear wave energy converters working in conjunction with a system composed of various energy storage devices, is considered as a microsystem, which can function in a stand-alone or a grid connected mode. Simulation results have shown that by applying a boost H-bridge and a composite energy storage system more power could be extracted from linear wave energy converters. Simulation results have shown that the super capacitors charge and discharge often to handle the frequent power fluctuations, and the batteries charge and discharge slowly for handling the intermittent power of wave energy converters. Hardware systems have been constructed to control the linear wave energy converter and the composite energy storage system. The performance of the composite energy storage system has been verified in experiments by using electronics-based wave energy emulators.

Published

2017