Offshore AC Fault Protection of Diode Rectifier Unit-Based HVdc System for Wind Energy Transmission

Li, Rui; Yu, Lujie; Xu, Lie

doi:10.1109/tie.2018.2869357

Cited by 48 publications

(38 citation statements)

References 41 publications

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“…On the other hand, although Q-f droop control is used in [12][13][14][15][16] for WT reactive power sharing, the justification for its use and the design procedure of the Q-f droop gain kq have not been clarified and properly understood. Besides, the impedance between individual WT converter and the offshore PCC is predominately inductive, as the AC cable resistance and capacitance are much less than the combined inductances of WT converter line reactor and WT transformer leakage inductance.…”

Section: Analysis Of the Wt Q-f Controlmentioning

confidence: 99%

Analysis and Control of Offshore Wind Farms Connected With Diode Rectifier-Based HVDC System

et al. 2020

IEEE Trans. Power Delivery

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This paper analyzes the control and operation of offshore wind farms connected with diode rectifier based HVDC (DR-HVDC) system. A small-signal state-space model of the offshore wind turbines (WTs) connected with DR-HVDC system is developed to design the WT Q-f droop control. The use of WT P-V and Q-f control during individual WT active power variation is clearly clarified. In order to reduce the interaction between WT active power and reactive power, an angle feedforward control is proposed where an additional phase shift is directly added to the WT output voltage based on the WT's active power output. The effectiveness of the proposed control on improving dynamic response and reducing active and reactive power interaction is verified by frequency-domain analysis and time-domain simulations in PSCAD/EMTDC. Index Terms-diode rectifier based HVDC, interaction of WT active and reactive power, small-signal analysis, wind turbine control This work was supported by the European Union's Horizon 2020 research and innovation programme under Grant 691714.

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Section: Analysis Of the Wt Q-f Controlmentioning

confidence: 99%

Analysis and Control of Offshore Wind Farms Connected With Diode Rectifier-Based HVDC System

et al. 2020

IEEE Trans. Power Delivery

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“…Based on the properties exhibited by (14) and (15), the equivalent sequence network for a phase-to-phase AC fault is drawn as shown in Fig. 6.…”

Section: B Phase-to-phase Ac Faultsmentioning

confidence: 99%

“…Further investigation conducted in [12] reveals that the reactive current injection during faults curtails the delivered active power and the ability to mitigate the oscillating term from DC side, while only has limited impact on the offshore grid voltage during faults. Due to serval constraints posed by the converters, the characterization of negative sequence current for offshore AC grid fault behaviors becomes increasingly important, particularly from the 2 protection point of view [1,13,14]. Unlike two-level VSCs, several studies on the behavior of modular multilevel converters (MMCs) under asymmetric AC faults reveal that a well-controlled MMC does not inject even harmonic currents into DC side thus exhibits no even harmonic voltage ripples in the DC link voltage when it operates with balanced or unbalanced AC currents and voltages [15][16][17].…”

Section: Introductionmentioning

confidence: 99%

Control of Offshore MMC During Asymmetric Offshore AC Faults for Wind Power Transmission

Shi

Adam

et al. 2020

IEEE J. Emerg. Sel. Topics Power Electron.

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“…As DRU can only convert AC to DC [128], a hybrid topology combining DRU and VSC/LCC must be used, introducing the DRU as the offshore rectifier and the LCC/VSC as the onshore converter [129]. The main advantages of DRU-HVDC compared to LCC-HVDC and VSC-HVDC are [130][131][132][133]:…”

Section: Diode Rectifier Unitmentioning

confidence: 99%

Offshore Wind Power Integration into Future Power Systems: Overview and Trends

Fernández‐Guillamón

Das

Cutululis

et al. 2019

JMSE

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Nowadays, wind is considered as a remarkable renewable energy source to be implemented in power systems. Most wind power plant experiences have been based on onshore installations, as they are considered as a mature technological solution by the electricity sector. However, future power scenarios and roadmaps promote offshore power plants as an alternative and additional power generation source, especially in some regions such as the North and Baltic seas. According to this framework, the present paper discusses and reviews trends and perspectives of offshore wind power plants for massive offshore wind power integration into future power systems. Different offshore trends, including turbine capacity, wind power plant capacity as well as water depth and distance from the shore, are discussed. In addition, electrical transmission high voltage alternating current (HVAC) and high voltage direct current (HVDC) solutions are described by considering the advantages and technical limitations of these alternatives. Several future advancements focused on increasing the offshore wind energy capacity currently under analysis are also included in the paper.

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Offshore AC Fault Protection of Diode Rectifier Unit-Based HVdc System for Wind Energy Transmission

Cited by 48 publications

References 41 publications

Analysis and Control of Offshore Wind Farms Connected With Diode Rectifier-Based HVDC System

Analysis and Control of Offshore Wind Farms Connected With Diode Rectifier-Based HVDC System

Control of Offshore MMC During Asymmetric Offshore AC Faults for Wind Power Transmission

Offshore Wind Power Integration into Future Power Systems: Overview and Trends

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