HVdc circuit breakers: Prospects and challenges

The integration of offshore wind farms has revitalized the interest in multi–terminal high voltage direct current (M–HVdc) transmission grids. HVdc breakers’ importance has increased as M–HVdc grids are now a commercial truth. Several HVdc circuit breaker technologies have been developed, published, and appeared as prototypes for HVdc networks. This paper summarizes the HVdc breaker technologies from the last two decades, distributed mainly in literature. A comparison of various state–of–the–art HVdc breakers is presented. Further, areas are identified where further research and development are required. The goal is to provide primary challenges and prospects in the HVdc breaker field

Controllable reactor based hybrid HVDC breaker

© 2020 BMJ Publishing Group. All rights reserved. Short circuit fault occurrence in high-voltage DC (HVDC) systems causes extremely high currents in a fast raising time that does not experience current zero-crossing. To protect HVDC systems/grids against fault current, fast HVDC breaker is an essential equipment. This study presents the design procedure of a novel HVDC breaker based on solid-state controllable reactor which is able to reduce the fault current's rate of rise and fault current amplitude to less than grid nominal current in the breaking process. The main achievement of the proposed HVDC breaker is that not only breaker does not encounter fault current, but also none of the series HVDC equipment is influenced by the fault. The designed breaker performance is studied by PSCAD/EMTPS, and then the simulation results are validated by the developed laboratory experimental setup

Protection of Future Electricity Systems

The electrical energy industry is undergoing dramatic changes: massive deployment of renewables, increasing share of DC networks at transmission and distribution levels, and at the same time, a continuing reduction in conventional synchronous generation, all contribute to a situation where a variety of technical and economic challenges emerge. As the society’s reliance on electrical power continues to increase as a result of international decarbonisation commitments, the need for secure and uninterrupted delivery of electrical energy to all customers has never been greater. Power system protection plays an important enabling role in future decarbonized energy systems. This book includes ten papers covering a wide range of topics related to protection system problems and solutions, such as adaptive protection, protection of HVDC and LVDC systems, unconventional or enhanced protection methods, protection of superconducting transmission cables, and high voltage lightning protection. This volume has been edited by Adam Dyśko, Senior Lecturer at the University of Strathclyde, UK, and Dimitrios Tzelepis, Research Fellow at the University of Strathclyde

A low-loss integrated circuit breaker for HVDC applications

Hybrid dc circuit breakers (HCBs) are recognized as suitable devices for protecting high-voltage direct-current (HVDC) systems, along with other dc circuit breakers (DCCB). However, compared to mechanical circuit breakers, HCBs exhibit higher conduction losses. Such losses are inevitable under no-fault conditions as current may flow through some of the semiconductor switches. An integrated circuit breaker (ICB) minimizing these losses is presented in this paper, and this is achieved by replacing semiconductor switches by mechanical components in the current path. For completeness, the topology design, operating sequence and a mathematical analysis for component sizing of the device are provided. In addition, an estimation of the conduction losses is quantified. It is estimated that the power losses of an ICB are 2 to 30% of an HCB only. The ICB has been implemented in PSCAD/EMTDC to demonstrate its effectiveness for isolating dc faults, with simulations conducted on a three-terminal HVDC grid

The modular multilevel DC converters for MVDC and HVDC applications

A dc structure for an electrical power system is seen to have important advantages over an ac structure for the purpose of renewable energy integration and for expansion of transmission and distribution networks. There is also much interest and strong motivation to interconnect the existing point-to-point dc links to form multi-terminal and multi-voltage dc networks, which can make full use of the benefits of a dc scheme across various voltage levels and also increase the flexibility and ease the integration of both centralized and distributed renewable energy. This thesis investigates both high step-ratio dc-dc conversion to interface dc systems with different voltage levels and low step-ratio dc-dc conversion to interconnect dc systems with similar but not identical voltages (still within the same voltage level). The research work explores the possibility of combining the relatively recent modular multilevel converter (MMC) technology with the classic dc-dc circuits and from this proposes several modular multilevel dc converters, and their associated modulation methods and control schemes to operate them, which inherit the major advantages of both MMC technologies and classic dc-dc circuits. They facilitate low-cost, high-compactness, high-efficiency and high-reliability conversion for the medium voltage level and high voltage level dc network interconnection. For medium voltage level cases, this thesis extends the classic LLC dc-dc circuit by introducing MMC-like stack of sub-modules (SMs) in place of the half-bridge or full-bridge inverter in the original configuration. Two families of resonant modular multilevel dc converters (RMMCs) are proposed covering high step-ratio and low step-ratio conversion respectively. A phase-shift modulation scheme is further proposed for these RMMCs that creates an inherent feature of balancing SM capacitor voltages, provides a high effective operating frequency for reducing system footprint and offers a wide operating range for flexible conversion. For high voltage level cases requiring a high step-ratio conversion, a modular multilevel dc-ac-dc converter based on the single-active-bridge or dual-active-bridge structure is explored. The operating mode developed for this converter employs a near-square-wave ac current in order to decrease both the volt-ampere rating requirement for semiconductor devices and the energy storage requirement for SM capacitors. For low step-ratio cases, a single-stage modular multilevel dc-dc converter based on a buck-boost structure is examined, and an analysis method is created to support the choice of the circulating current frequency for minimum current stresses and reactive power losses. Theoretical analysis of and operating principles for all of these proposed modular multilevel dc converters, together with their associated modulation methods and control schemes, are verified by both time-domain simulation at full-scale and experimental tests on down-scaled prototypes. The results demonstrate that these medium voltage and high voltage dc-dc converters are good candidates for the interconnection of dc links at different voltages and thereby make a contribution to future multi-terminal and multi-voltage dc networks.Open Acces

Study and evaluation of distributed power electronic converters in photovoltaic generation applications

This research project has proposed a new modulation technique called “Local Carrier Pulse Width Modulation” (LC-PWM) for MMCs with different cell voltages, taking into account the measured cell voltages to generate switching sequences with more accurate timing. It also adapts the modulator sampling period to improve the transitions from level to level, an important issue to reduce noise at the internal circulating currents. As a result, the new modulation LC-PWM technique reduces the output distortion in a wider range of voltage situations. Furthermore, it effectively eliminates unnecessary AC components of circulating currents, resulting in lower power losses and higher MMC efficiency.Departamento de Tecnología ElectrónicaDoctorado en Ingeniería Industria

Bibliography of Lewis Research Center technical publications announced in 1985

This compilation of abstracts describes and indexes the technical reporting that resulted from the scientific and engineering work performed and managed by the Lewis Research Center in 1985. All the publications were announced in the 1985 issues of STAR (Scientific and Technical Aerospace Reports) and/or IAA (International Aerospace Abstracts). Included are research reports, journal articles, conference presentations, patents and patent applications, and theses