TY - JOUR
T1 - Transition from electromechanical dynamics to quasi-electromechanical dynamics caused by participation of full converter-based wind power generation
AU - Luo, Jianqiang
AU - Bu, Siqi
AU - Zhu, Jiebei
N1 - Funding Information:
Funding: This research was funded by National Natural Science Foundation of China grant number (51807171), Guangdong Science and Technology Department grant number (2019A1515011226), Hong Kong Research Grant Council grant number (25203917), (15200418) and (15219619), and Department of Electrical Engineering, The Hong Kong Polytechnic University grant number (1-ZE68). The APC was funded by TPS Scheme of Hong Kong Polytechnic University.
Funding Information:
Acknowledgments: The authors would like to acknowledge the support from the National Natural Science Foundation of China for the Research Project (51807171), the Guangdong Science and Technology Department for the Research Project (2019A1515011226), the Hong Kong Research Grant Council for the Research Projects (25203917), (15200418) and (15219619), the Department of Electrical Engineering, and the Hong Kong Polytechnic University for the Start-up Fund Research Project (1-ZE68).
Publisher Copyright:
© 2020 by the authors. Licensee MDPI, Basel, Switzerland.
PY - 2020/12/1
Y1 - 2020/12/1
N2 - Previous studies generally consider that the full converter-based wind power generation (FCWG) is a “decoupled” power source from the grid, which hardly participates in electromechanical oscillations. However, it was found recently that strong interaction could be induced which might incur severe resonance incidents in the electromechanical dynamic timescale. In this paper, the participation of FCWG in electromechanical dynamics is extensively investigated, and particularly, an unusual transition of the electromechanical oscillation mode (EOM) is uncovered for the first time. The detailed mathematical models of the open-loop and closed-loop power systems are firstly established, and modal analysis is employed to quantify the FCWG participation in electromechanical dynamics, with two new mode identification criteria, i.e., FCWG dynamics correlation ratio (FDCR) and quasi-electromechanical loop correlation ratio (QELCR). On this basis, the impact of different wind penetration levels and controller parameter settings on the participation of FCWG is investigated. It is revealed that if an FCWG oscillation mode (FOM) has a similar oscillation frequency to the system EOMs, there is a high possibility to induce strong interactions between FCWG dynamics and system electromechanical dynamics of the external power systems. In this circumstance, an interesting phenomenon may occur that an EOM may be dominated by FCWG dynamics, and hence is transformed into a quasi-EOM, which actively involves the participation of FCWG quasi-electromechanical state variables.
AB - Previous studies generally consider that the full converter-based wind power generation (FCWG) is a “decoupled” power source from the grid, which hardly participates in electromechanical oscillations. However, it was found recently that strong interaction could be induced which might incur severe resonance incidents in the electromechanical dynamic timescale. In this paper, the participation of FCWG in electromechanical dynamics is extensively investigated, and particularly, an unusual transition of the electromechanical oscillation mode (EOM) is uncovered for the first time. The detailed mathematical models of the open-loop and closed-loop power systems are firstly established, and modal analysis is employed to quantify the FCWG participation in electromechanical dynamics, with two new mode identification criteria, i.e., FCWG dynamics correlation ratio (FDCR) and quasi-electromechanical loop correlation ratio (QELCR). On this basis, the impact of different wind penetration levels and controller parameter settings on the participation of FCWG is investigated. It is revealed that if an FCWG oscillation mode (FOM) has a similar oscillation frequency to the system EOMs, there is a high possibility to induce strong interactions between FCWG dynamics and system electromechanical dynamics of the external power systems. In this circumstance, an interesting phenomenon may occur that an EOM may be dominated by FCWG dynamics, and hence is transformed into a quasi-EOM, which actively involves the participation of FCWG quasi-electromechanical state variables.
KW - Electromechanical dynamics
KW - Electromechanical loop correlation ratio (ELCR)
KW - FCWG dynamic correlation ratio (FDCR)
KW - FCWG dynamics
KW - Quasi- electromechanical loop correlation ratio (QELCR)
KW - Strong interaction
UR - http://www.scopus.com/inward/record.url?scp=85106646612&partnerID=8YFLogxK
U2 - 10.3390/en13236270
DO - 10.3390/en13236270
M3 - Journal article
AN - SCOPUS:85106646612
SN - 1996-1073
VL - 13
JO - Energies
JF - Energies
IS - 23
M1 - 6270
ER -