A demand side controller of electrolytic aluminum industrial microgrids considering wind power fluctuations

Ding, Xin; Xu, Jie; Sun, Yang; Liao, Siyang; Zheng, Jingwen

doi:10.1186/s41601-022-00270-x

Cited by 6 publications

(2 citation statements)

References 24 publications

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“…However, the DR's regulation function is usually neglected in the above literature, which may lead to an unreasonable DG allocation scheme. Actually, DR can shave the peak, and fill the valley of the load, and then promote the accommodation of renewable energy [13,14]. In this situation, the DG allocation scheme can also be affected.…”

Section: Introductionmentioning

confidence: 99%

Optimal Allocation Stochastic Model of Distributed Generation Considering Demand Response

He,

Liu

2024

Energies

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Demand response (DR) can improve the accommodation of renewable energy and further affect the distributed generation (DG) allocation strategy. In this context, this paper proposes a stochastic optimal allocation model of DG, considering DR. Firstly, to address the uncertainty of wind and solar power outputs, a large number of scenarios of wind and solar power are generated based on the scenario method, which are then clustered into 10 typical scenarios by the k-means method. Secondly, with the goal of maximizing the total cost, the DR cost and corresponding constraints are introduced. Then, the stochastic planning model for DG is established, where the planning level aims to minimize the investment cost while the operation level minimizes the total operation expectation cost. For the non-linear term in the DR cost and power flow constraint, the Taylor expansion method and second-order conic relaxation method are both adopted to transform the original mixed-integer non-linear model to the mixed-integer second-order conic planning model. Finally, the whole planning model for DG is solved by CPLEX 12.6.0. The results show that DR can reduce the total cost and improve the accommodation of renewable energy in the DG planning process, which should be paid more attention to in the DG planning model.

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Section: Introductionmentioning

confidence: 99%

Optimal Allocation Stochastic Model of Distributed Generation Considering Demand Response

He,

Liu

2024

Energies

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“…In response to the growing energy crisis and environmental pollution problems, increasing the share of renewable energy resources has become a roadmap for many nations (Ding et al, 2022;Han et al, 2022). However, with the large-scale integration of wind energy resources, the variability and uncertainty of the wind power output seriously affect the secure operation of the system (Khoshjahan et al, 2019;Park et al, 2022).…”

Section: Introductionmentioning

confidence: 99%

Tight power balance multi-time scale disposal strategy for wind integrated system considering electric vehicle charging station

2023

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High wind power penetration and peak load pose significant challenges to the power system in maintaining the power supply–demand balance. Once the power supply–demand balance is disrupted, system load shedding and wind spillage become inevitable. In this study, the aforementioned problem is defined as the tight power balance (TPB) problem. The accuracy of wind power and load forecasting increases with a decrease in the forecasting timescale. Based on the aforementioned characteristics, a TPB multi-timescale disposal strategy for wind-integrated power systems considering electric vehicle (EV) charging stations is established to address the TPB problem at different timescales. First, the operation model of an electric vehicle charging station offering flexible ramping capacity is established. Second, a multi-timescale disposal strategy, which includes an intra-day 4-h plan, an intra-day 1-h plan, and a real-time 15-min plan, is presented by quantifying the flexible demand at different timescales. Finally, the proposed strategy is verified using a modified IEEE 118-bus system. The analysis results show that the proposed TPB multi-timescale disposal strategy effectively promotes the disposal level of the TPB problem.

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Asynchronous distributed optimal power control for fatigue load minimization in wind farms

Bai,

Feng,

Huang

et al. 2024

International Journal of Electrical Power & Energy Systems

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A demand side controller of electrolytic aluminum industrial microgrids considering wind power fluctuations

Cited by 6 publications

References 24 publications

Optimal Allocation Stochastic Model of Distributed Generation Considering Demand Response

Optimal Allocation Stochastic Model of Distributed Generation Considering Demand Response

Tight power balance multi-time scale disposal strategy for wind integrated system considering electric vehicle charging station

Asynchronous distributed optimal power control for fatigue load minimization in wind farms

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