Open AccessDual‐loop SFC scheme for BTB‐VSC‐HVDC interconnecting asynchronous AC grids
Author(s) -
Zeng Lingkang,
Li Dahu,
Yao Wei,
Sun Jianbo,
Wen Jinyu
Publication year - 2019
Publication title -
the journal of engineering
Language(s) - English
Resource type - Journals
ISSN - 2051-3305
DOI - 10.1049/joe.2018.8528
Subject(s) - transient (computer programming) , control theory (sociology) , frequency grid , dual loop , grid , automatic frequency control , inertia , computer science , voltage source , dual (grammatical number) , ac power , loop (graph theory) , asynchronous communication , power (physics) , transient response , voltage , physics , electrical engineering , engineering , mathematics , control (management) , telecommunications , art , geometry , literature , classical mechanics , combinatorics , artificial intelligence , quantum mechanics , operating system
This study proposes a dual‐loop supplementary frequency control (SFC) scheme for back‐to‐back voltage source converter high‐voltage DC (BTB‐VSC‐HVDC) interconnecting asynchronous AC grids, to provide frequency support for each other after a large disturbance. The proposed dual‐loop SFC consists of the frequency‐active power ( f–P ) loop and the frequency‐reactive power ( f–Q ) loop. The former deployed on the P ‐loop of VSC‐HVDC can provide frequency support for the disturbed grid during the primary frequency regulation and improve the steady‐state characteristics of the frequency response, while the latter attached to the Q ‐loop of VSC‐HVDC supports virtual inertia to ameliorate the transient characteristics of the frequency response. Simulation studies are conducted based on the equivalently simplified model of Southwest Power Grid and Hubei Power Grid interconnected by Chongqing‐Hubei BTB‐VSC‐HVDC. Simulation results show that the proposed SFC scheme can effectively improve the transient and steady‐state characteristics of the system frequency response under a wide range of operating condition.