Consensus control of electric spring using back-to-back converter for voltage regulation with ultra-high renewable penetration

Zheng, Yongjun; Zhang, Congchong; Hill, David J.; Meng, Ke

doi:10.1007/s40565-017-0338-4

Cited by 16 publications

(10 citation statements)

References 23 publications

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“…In [55], a two-level voltage management scheme with load tap changer and capacitor banks at the upper level and ES at the lower level is demonstrated using consensus control allowing different voltage regulation devices to work together to maintain the voltage of critical buses by sharing the responsibility. Reference [71] also uses a consensus algorithm to coordinate multiple ESs for maintaining critical bus voltage in distribution systems with ultra-high renewable penetration. This yields similar voltage suppression capability as the conventional ES but better voltage support with the ESs sharing the burden using limited communication.…”

Section: B Voltage Regulation 1 Distribution Networkmentioning

confidence: 99%

Electric Spring and Smart Load: Technology, System-Level Impact, and Opportunities

Lee

Liu

Tan

et al. 2021

IEEE J. Emerg. Sel. Topics Power Electron.

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Increasing use of renewable energy sources to combat climate change comes with the challenge of power imbalance and instability issues in emerging power grids. To mitigate power fluctuation arising from the intermittent nature of renewables, electric spring has been proposed as a fast demandside management technology. Since its original conceptualization in 2011, many versions and variants of electric springs have emerged and industrial evaluations have begun. This paper provides an update of existing electric spring topologies, their associated control methodologies, and studies from the device level to the power system level. Future trends of electric springs in large-scale infrastructures are also addressed.

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Section: B Voltage Regulation 1 Distribution Networkmentioning

confidence: 99%

Electric Spring and Smart Load: Technology, System-Level Impact, and Opportunities

Lee

Liu

Tan

et al. 2021

IEEE J. Emerg. Sel. Topics Power Electron.

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“…Therefore, the ES‐3 does not provide a direct effect on P SL . These stable‐state models have been used to implement collaborative control schemes that allow improving the PQ in distribution systems [50] and study the joint operation of ESs with distributed generation and dynamic loads that represent the behaviour of electric vehicles [40].…”

Section: Es Hardware Structuresmentioning

confidence: 99%

“…On the other hand, consensus control is another voltage regulation control scheme for multiple ESs [50, 55, 56]. It is based on graph theory and is suitable to operate with sparse topologies and limited local communication.…”

Section: Control Schemes and Their Applications In Epdsmentioning

confidence: 99%

“…A case study presented in [55] shows that the behaviour of a set of ES‐1 operating in an IEEE‐34 node test feeder achieves cooperation in sharing reactive power and voltage regulation during fault conditions. The study case implemented in [50] is based on a set of ES‐3 operating as agents and an IEEE‐15 bus distribution system. Transient response, communication sensitivity, and voltage regulation are analysed.…”

Section: Control Schemes and Their Applications In Epdsmentioning

confidence: 99%

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Hardware structures, control strategies, and applications of electric springs: a state‐of‐the‐art review

Tapia-Tinoco

García-Pérez

Granados-Lieberman

et al. 2020

IET Generation, Transmission & Distribution

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“…After reformulating (15) and (16) in per-unit (p.u.) system with the base of P nom , the capacity limit of smart load can be derived as…”

Section: A Operating Regionsmentioning

confidence: 99%

Hybrid Electric Springs for Grid-Tied Power Control and Storage Reduction in AC Microgrids

Wang

Tan

Hui

2019

IEEE Trans. Power Electron.

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The renewable generations (RGs) are conventionally interfaced with the utility grid through battery energy storage systems (BESS). In this cascaded configuration of the gridconnected inverter, battery and RG, the power of the battery is passively governed by the power difference between the RG and the grid. This compromises the state-of-charge (SoC) control of the battery and increases the storage capacity. To address this issue, a hybrid electric spring (HES), which is integrated with the RG and non-critical load (NCL), is proposed in this paper for the grid-tied power control and reduction of battery storage capacity in AC microgrids. Such an integrated configuration enables a flexible control of the power flow among battery, NCL and grid. On top of that, the proposed HES can achieve an extended operating region of grid-tied power control compared with the conventional BESS and the existing electric springs (ES). The operating principle, steady-state analysis and control design of the HES are discussed. The functions of the grid-tied power control and battery SoC control are verified experimentally and through simulations.

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Consensus control of electric spring using back-to-back converter for voltage regulation with ultra-high renewable penetration

Cited by 16 publications

References 23 publications

Electric Spring and Smart Load: Technology, System-Level Impact, and Opportunities

Electric Spring and Smart Load: Technology, System-Level Impact, and Opportunities

Hardware structures, control strategies, and applications of electric springs: a state‐of‐the‐art review

Hybrid Electric Springs for Grid-Tied Power Control and Storage Reduction in AC Microgrids

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