Robust decentralized control for effective load sharing and bus voltage regulation of DC microgrid based on optimal droop parameters

The energy internet (EI) is a wide area power network that efficiently combines new energy technology and information technology, resulting in bidirectional on-demand power transmission and rational utilization of distributed energy resources (DERs). Since the stability of local network is a prerequisite for the normal operation of the entire EI, the direct current (DC) bus voltage stabilization for each individual DC microgrid (MG) is a core issue. In this paper, the dynamics of the EI system is modeled with a continuous stochastic system, which simultaneously considers related time-varying delays and norm-bounded modeling uncertainty. Meanwhile, the voltage stabilization issue is converted into a robust H ∞ control problem solved via a linear matrix inequality approach. To avoid the situation of over-control, constraints are set in controllers. The problem of finding a balance between voltage regulation performance and constraints for the controllers was also extensively investigated. Finally, the efficacy of the proposed methods is evaluated with numerical simulations.

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Multi-level bus voltage compensation of droop control with enhanced load-sharing capability for DC microgrid

The Journal of Engineering ◽

10.1049/joe.2018.8419 ◽

2019 ◽

Vol 2019 (16) ◽

pp. 3056-3061 ◽

Cited By ~ 1

Author(s):

Sucheng Liu ◽

Zhongpeng Li ◽

Wenjie Liu ◽

Xiaodong Liu

Keyword(s):

Load Sharing ◽

Droop Control ◽

Dc Microgrid ◽

Voltage Compensation ◽

Multi Level ◽

Bus Voltage

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The Hierarchical Control Algorithm for DC Microgrid Based on the Improved Droop Control of Fuzzy Logic

Energies ◽

10.3390/en12152995 ◽

2019 ◽

Vol 12 (15) ◽

pp. 2995 ◽

Cited By ~ 4

Author(s):

Liang Zhang ◽

Kang Chen ◽

Shengbin Chi ◽

Ling Lyu ◽

Guowei Cai

Keyword(s):

Fuzzy Logic ◽

Control Algorithm ◽

Voltage Drop ◽

Hierarchical Control ◽

Voltage Regulation ◽

Droop Control ◽

Dc Microgrid ◽

Current Sharing ◽

The Difference ◽

Bus Voltage

In the direct current (DC) microgrid composed of multiple distributed generations, due to the different distances between various converters and the DC bus in the system, the difference of the line resistance will reduce the current sharing accuracy of the system. The droop control was widely used in the operation control of the DC microgrid. It was necessary to select a large droop coefficient to improve the current sharing accuracy, but a too large droop coefficient will lead to a serious bus voltage drop and affect the power quality. In view of the contradiction between the voltage regulation and load current sharing in the traditional droop control, a hierarchical control algorithm based on the improved droop control of the fuzzy logic was proposed in this paper. By improving the droop curve, the problems of voltage regulation and current sharing were solved simultaneously. The effectiveness of the algorithm was verified by simulation.

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Secondary Control Method for Standalone DC Microgrid with Improved Voltage Regulation, Load Sharing, and Line Loss

2020 IEEE Power & Energy Society General Meeting (PESGM) ◽

10.1109/pesgm41954.2020.9282164 ◽

2020 ◽

Author(s):

Rajneesh Kumar Yadav ◽

Souradip De ◽

Soumya Ranjan Sahoo ◽

Saikat Chakrabarti

Keyword(s):

Control Method ◽

Load Sharing ◽

Voltage Regulation ◽

Secondary Control ◽

Dc Microgrid ◽

Line Loss

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Barrier Function Based Adaptive Sliding Mode Controller for a Hybrid AC/DC Microgrid Involving Multiple Renewables

Applied Sciences ◽

10.3390/app11188672 ◽

2021 ◽

Vol 11 (18) ◽

pp. 8672

Author(s):

Ammar Armghan ◽

Mudasser Hassan ◽

Hammad Armghan ◽

Ming Yang ◽

Fayadh Alenezi ◽

...

Keyword(s):

Barrier Function ◽

Sliding Mode ◽

Renewable Energy Sources ◽

Energy System ◽

Voltage Regulation ◽

Sliding Mode Controller ◽

Dc Microgrid ◽

Adaptive Sliding Mode ◽

Adaptive Sliding Mode Controller ◽

Bus Voltage

Conventional electricity generation methods are under the major revolution, and microgrids established on renewable energy sources are playing a vital role in this power generation transformation. This study proposes a hybrid AC/DC microgrid with a barrier function-based adaptive sliding mode controller, in which 8 kW wind energy system and 4.5 kW photovoltaic energy system perform as the hybrid RESs, and 33 Ah of battery works as the energy storage system. Barrier function-based adaptive sliding mode controller ensures the convergence of the system’s output variable independent of the knowledge of the upper bound of the disturbances. Firstly, global mathematical modeling of the suggested system is ensured. Then, the control laws are defined, providing the DC bus voltage regulation during islanding mode and AC/DC link bus voltage regulation during the grid-connected mode. The proposed barrier function-based adaptive sliding mode controller technique is analyzed through 20 s simulations on MATLAB/Simulink, which validates the controller’s robustness and effectiveness. Furthermore, a comparison of the proposed controller is made with the proportional integral derivative controller, Lyapunov controller, and sliding mode controller. In the end, hardware-in-loop tests are performed using C2000 Delfino MCU F28379D LaunchPad, showing the proposed structure’s real-time performance.

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