A Modified Droop Control for Grid-Connected Inverters With Improved Stability in the Fluctuation of Grid Frequency and Voltage Magnitude

Geng, Yiwen; Zhu, Lin; Song, Xuanfeng; Wang, Kai; Li, Xiaoqiang

doi:10.1109/access.2019.2920312

Cited by 18 publications

(19 citation statements)

References 30 publications

(40 reference statements)

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“…The benefits of coordinated photovoltaic (PV) inverter control with centralised coordination of PV active power curtailment, when compared to autonomous droop control, were presented in [9], in order to increase PV hosting capacity and reduce network losses. Lastly, in [10] a modified droop control strategy was proposed to mitigate the frequency and voltage oscillation impacts on the power system's stability.…”

Section: A Local Der Control Methodsmentioning

confidence: 99%

Flexibility Services Provision by Frequency-Dependent Control of On-Load Tap-Changer and Distributed Energy Resources

et al. 2021

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Distribution network connected distributed energy resources (DER) are able to provide various flexibility services for distribution system operators (DSOs) and transmission system operators (TSOs). These local and system-wide flexibility services offered by DER can support the frequency (f) and voltage (U) management of a future power system with large amounts of weather-dependent renewable generation and electric vehicles. Depending on the magnitude of frequency deviation, other active network management-based frequency control services for TSOs could also be provided by DSOs in coordination with adaptive control of DER. This paper proposes utilisation of demand response based on frequencydependent HV/MV transformer on-load tap-changer (OLTC) operation in case of larger frequency deviations. The main principle underlying the proposed scheme lies in the voltage dependency of the distribution network connected loads. In this paper, it is also proposed to, simultaneously with frequencydependent OLTC control, utilise reverse reactive power-voltage (QU)-and adaptive active power-voltage (PU)-droops with distribution network connected DER units during these larger frequency deviations, in order to enable better frequency support service for TSOs from DSO networks. The effectivity and potential of the proposed schemes are shown through PSCAD simulations. In addition, this paper also presents a holistic and collaborative view of potential future frequency control services which are provided by DSO network-connected resources for TSOs at different frequency deviation levels.

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Section: A Local Der Control Methodsmentioning

confidence: 99%

Flexibility Services Provision by Frequency-Dependent Control of On-Load Tap-Changer and Distributed Energy Resources

et al. 2021

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“…In general, grid-connected power electronic converters (PECs) are operated by nested control loops, which are an inner current control loop and an outer voltage control loop. The reference voltage for the outer control loop is generated by a droop controller, while the reference current vector is generated by voltage controller [2]- [4]. The reference current is typically limited based on the power ratings of the PEC, in order to avoid saturation of the current control loop.…”

Section: B Droop Control For Grid-connected Pecsmentioning

confidence: 99%

“…The reference current is typically limited based on the power ratings of the PEC, in order to avoid saturation of the current control loop. The saturation in the current control loop can be a result of grid-side frequency dynamics [4]. A small signal state space model of a gridconnected PEC has been developed, and has been used to design various current/voltage controllers without employing droop FIGURE 1.…”

Section: B Droop Control For Grid-connected Pecsmentioning

confidence: 99%

Parameter Adjustment for the Droop Control Operating a Discharge PEC in PMG-Based WECSs With Generator-Charged Battery Units

Saleh

Ahshan

2021

IEEE Access

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Permanent magnet generator (PMG)-based wind energy conversion systems (WECSs) with battery units, have become a popular class of distributed generation units. These distributed generation units are typically operated using various types of controllers, including droop controllers. Existing droop controllers are designed to operate grid-side dc-ac power electronic converters (PEC) to ensure stable and reliable power production by a PMG-based WECS. The employment of battery storage units (to mitigate fluctuations in the power produced by a PMG-based WECS) introduces additional considerations for the design of droop controllers. Such considerations are due to the power available from battery units that is dependent on the state-of-charge (SOC). This paper proposes adjustments in the parameters (droop constants) of the droop control (operate the the discharge PEC) based on the SOC of the battery units. These adjustments are made to further support stable and reliable power delivery of the PMG-based WECS into the point-of-common-coupling (PCC). The proposed adjustments of droop constants are evaluated using a 7.5 kW grid-connected PMG-based WECS with 3.52 kW generator-charged battery storage units. Performance tests are carried out for step changes in the active and reactive power demands, changes in the wind speed, and grid-side disturbances. Test results show that the proposed correction of the droop constants is critical for maintaining a stable, effective, and accurate power delivery by the battery units, thus supporting the voltage/frequency stability at the PCC under different operating conditions.INDEX TERMS permanent magnet generators, wind energy conversion systems, battery storage systems, droop control, and distributed generation

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“…, and 1 N be an N dimensional column vector with every entry being one. Then (14) and (15) can be rewritten into the following compact forṁ=…”

Section: Closed-loop Dynamics Wrt (9) and (10a)mentioning

confidence: 99%

“…The droop control method was applied for microgrids in grid-connected mode. [13][14][15][16] Note that the key to the success of droop control lies in that there is no dominating frequency or voltage magnitude in the system when the droop characteristics are applied for power sharing. However, for grid-connected mode, the frequency and voltage magnitude of the microgrid at the point of common coupling are clamped by the stiff main grid.…”

Section: Introductionmentioning

confidence: 99%

A unified distributed robust control framework for power sharing of grid‐connected dispatchable distributed generator cluster

Su¹,

Tu²,

Cai

2020

Adv Control Appl

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Summary In this paper, a unified distributed robust control framework is proposed to address the power sharing problem for a cluster of dispatchable distributed generators (DDGs) within a grid‐connected AC microgrid. In contrast to the existing results, the advantages of the proposed control design are threefold. First, the unified design can directly handle the dynamics of the closed‐loop system by Lyapunov analysis without the assumption on time scale separation. Second, the canonical internal model is adopted so that the controller is able to undertake arbitrarily large parametric uncertainties. Last not least, the associated control gains can be obtained once and for all following the standard procedure. Comprehensive numerical simulations are provided for performance validation.

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A Modified Droop Control for Grid-Connected Inverters With Improved Stability in the Fluctuation of Grid Frequency and Voltage Magnitude

Cited by 18 publications

References 30 publications

Flexibility Services Provision by Frequency-Dependent Control of On-Load Tap-Changer and Distributed Energy Resources

Flexibility Services Provision by Frequency-Dependent Control of On-Load Tap-Changer and Distributed Energy Resources

Parameter Adjustment for the Droop Control Operating a Discharge PEC in PMG-Based WECSs With Generator-Charged Battery Units

A unified distributed robust control framework for power sharing of grid‐connected dispatchable distributed generator cluster

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