Dual Channel Control with DC Fault Ride Through for MMC-based, Isolated DC/DC Converter

This study is sponsored by the Engineering and Physical Sciences Research Council (EPSRC) grant no EP/K006428/1, 2013.D. Jovcic and H. Zhang are with the School of Engineering, University of Aberdeen, AB24 3UE, U.K. ([email protected], [email protected]).Peer reviewedPostprin

The Essential Role and the Continuous Evolution of Modulation Techniques for Voltage-Source Inverters in the Past, Present, and Future Power Electronics

The cost reduction of power-electronic devices, the increase in their reliability, efficiency, and power capability, and lower development times, together with more demanding application requirements, has driven the development of several new inverter topologies recently introduced in the industry, particularly medium-voltage converters. New more complex inverter topologies and new application fields come along with additional control challenges, such as voltage imbalances, power-quality issues, higher efficiency needs, and fault-tolerant operation, which necessarily requires the parallel development of modulation schemes. Therefore, recently, there have been significant advances in the field of modulation of dc/ac converters, which conceptually has been dominated during the last several decades almost exclusively by classic pulse-width modulation (PWM) methods. This paper aims to concentrate and discuss the latest developments on this exciting technology, to provide insight on where the state-of-the-art stands today, and analyze the trends and challenges driving its future

Hybrid and modular multilevel converter designs for isolated HVDC–DC converters

Efficient medium and high-voltage dc-dc conversion is critical for future dc grids. This paper proposes a hybrid multilevel dc-ac converter structure that is used as the kernel of dc-dc conversion systems. Operation of the proposed dc-ac converter is suited to trapezoidal ac-voltage waveforms. Quantitative and qualitative analyses show that said trapezoidal operation reduces converter footprint, active and passive components' size, and on-state losses relative to conventional modular multilevel converters. The proposed converter is scalable to high voltages with controllable ac-voltage slope; implying tolerable dv/dt stresses on the converter transformer. Structural variations of the proposed converter with enhanced modularity and improved efficiency will be presented and discussed with regards to application in front-to-front isolated dc-dc conversion stages, and in light of said trapezoidal operation. Numerical results provide deeper insight of the presented converter designs with emphasis on system design aspects. Results obtained from a proof-of-concept 1-kW experimental test rig confirm the validity of simulation results, theoretical analyses, and simplified design equations presented in this paper. - 2013 IEEE.Scopu

Strategies for decoupling internal and external dynamics resulting from inter-arm passive component tolerances in HVDC-MMC

Modular Multilevel Converter (MMC) performance may be adversely affected by passive component tolerances, such as submodule capacitance and arm inductance variations. Depending on control strategies, the differences in equivalent capacitances and/or inductances of the upper and lower arms of one phase-leg can cause unequal power distribution between upper and lower arms. Assuming passive component tolerances ranging between ±10%, this paper presents a comprehensive assessment of the internal/external coupling effects due to the passive component tolerances within one phase-leg, under the control of common MMC balancing methods. A novel control strategy is proposed to suppress the fundamental component that arises in the dc-link current due to such tolerances, and its effectiveness is demonstrated via simulation and experimentation. The investigation shows that voltage-based common and differential mode balancing control provides effective ac offset suppression while the proposed method offers superior performance in terms of dc-link fundamental current ripple suppression

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

Impact of submodule faults on the performance of modular multilevel converters

Modular multilevel converter (MMC) is well suited for high-power and medium-voltage applications. However, its performance is adversely affected by asymmetry that might be introduced by the failure of a limited number of submodules (SMs) or even by severe deviations in the values of SM capacitors and arm inductors, particularly when the number of SMs per arm is relatively low. Although a safe-failed operation is easily achieved through the incorporation of redundant SMs, the SMs' faults make MMC arms present unequal impedances, which leads to undesirable internal dynamics because of unequal power distribution between the arms. The severity of these undesirable dynamics varies with the implementation of auxiliary controllers that regulate the MMC internal dynamics. This paper studied the impact of SMs failure on the MMC internal dynamics performance, considering two implementations of internal dynamics control, including a direct control method for suppressing the fundamental component that may arise in the dc-link current. Performances of the presented and widely-appreciated conventional methods for regulating MMC internal dynamics were assessed under normal and SM fault conditions, using detailed time-domain simulations and considering both active and reactive power applications. The effectiveness of control methods is also verified by the experiment. Related trade-offs of the control methods are presented, whereas it is found that the adverse impact of SMs failure on MMC ac and dc side performances could be minimized with appropriate control countermeasures

A New MMC Topology Which Decreases the Sub Module Voltage Fluctuations at Lower Switching Frequencies and Improves Converter Efficiency

Modular Multi-level inverters (MMCs) are becoming more common because of their suitability for applications in smart grids and multi-terminal HVDC transmission networks. The comparative study between the two classic topologies of MMC (AC side cascaded and DC side cascaded topologies) indicates some disadvantages which can affect their performance. The sub module voltage ripple and switching losses are one of the main issues and the reason for the appearance of the circulating current is sub module capacitor voltage ripple. Hence, the sub module capacitor needs to be large enough to constrain the voltage ripple when operating at lower switching frequencies. However, this is prohibitively uneconomical for the high voltage applications. There is always a trade off in MMC design between the switching frequency and sub module voltage ripple

Modular multilevel converter based HVDC transmission system for offshore wind farms

This doctoral thesis falls within the scope of electronic power converters oriented to high voltage transmission applications, in particular the power generated in remote offshore wind farms by means of HVDC subsea cables. This research is focused on the Modular Multilevel Converter (MMC) with two level submodules but also with multilevel topology submodules such as 3L-FC (three level flying capacitors) and 3L-NPC (three level neutral point capacitors). The main contribution of this thesis is the developed PWM based modulation strategy which allows the balancing of the total amount of submodules capacitors. It is applicable to the aforementioned submodule topologies under different working conditions as evidenced by experimental results