Neural Network-Based Demand-Side Management in a Stand-Alone Solar PV-Battery Microgrid Using Load-Shifting and Peak-Clipping

Philipo, Godiana Hagile; Kakande, Josephine Nakato; Krauter, Stefan

doi:10.3390/en15145215

Cited by 12 publications

(5 citation statements)

References 54 publications

(66 reference statements)

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“…Recently, other approaches to solving the problem of power control have also become widespread, in particular, those that apply the neural-fuzzy principle in building control systems. Moreover, artificial neural networks are mainly used to predict power consumption [24,25] in a hybrid system, and fuzzy logic [26,27] is used to regulate the power receiver capacity or to decide whether to disconnect it from the power grid or reconnect it to it.…”

Section: Electrical Complexes and Systemsmentioning

confidence: 99%

Heuristic control of power consumption by up to 1000 V electrical loads at mining enterprises

Sinchuk,

Rogoza,

Mykhailenko

et al. 2024

Nauk. visn. nat. hirn. univ.

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Purpose. To develop a method for synthesizing the structure and algorithm of the system for automated control of power consumption by up to 1000 V electrical receivers at mining enterprises with iron ore underground mining methods. This enables direct control of the load connection to the industrial power grid to ensure minimum power costs depending on its cost per day ahead. Methodology. The problem of controlling power consumption of electrical receivers at iron ore underground mines is formalized as a binary form of mixed integer programming. To solve it, a binary implementation of the heuristic genetic algorithm is used. The mathematical modeling method analyzes the impact of genetic algorithm settings, such as the number of phenotypes in the population, the number of elite phenotypes that pass unchanged to the next generation, and the method of phenotype crossover on its quality. Findings. As a result of the research, it is found that the most effective way to control the process of power consumption based on an evolutionary genetic algorithm is to use the Laplace crossover function and keep the percentage of elite phenotypes in the population at 10 %. Moreover, at the smallest population size, the best accuracy is observed when using the Laplace function, while at one- and two-point crossover functions, it worsens, but not significantly (no more than 0.2 %). However, as the number of elite phenotypes increases, the duration of the evolutionary search in the control process is reduced by almost a factor of two in the case of one- and two-point crossovers. Originality. For the first time, the structure of a heuristic system for automated control of power consumption by underground electrical receivers with a supply voltage of up to 1000 V at iron ore underground mines has been developed on the basis of an evolutionary genetic algorithm. Depending on the designed volumes of ore production and the daily power cost per day, this allows determining the optimal power load schedule of underground distribution substations in advance, which, subject to the accepted limits on hourly and daily power, minimizes the cost of purchasing power, and thus reduces the cost of the final product. Practical value. The architecture of a heuristic system for controlling power consumption by electrical receivers with a voltage of up to 1000 V based on an evolutionary genetic algorithm is developed and recommended when optimizing the power load schedule of transformer substations of mining and metallurgical enterprises, in particular, of iron ore underground mines operating in this voltage class.

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Section: Electrical Complexes and Systemsmentioning

confidence: 99%

Heuristic control of power consumption by up to 1000 V electrical loads at mining enterprises

Sinchuk,

Rogoza,

Mykhailenko

et al. 2024

Nauk. visn. nat. hirn. univ.

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“…G.H. Philipo et al [169] suggest a DSM strategy involving load shifting and peak clipping implemented in MATLAB/Simulink and fine-tuned through ANN optimization. Simulations were conducted to evaluate the model's performance in a stand-alone PV-battery MG located in East Africa.…”

Section: Demand Side Management (Dsm)mentioning

confidence: 99%

Technological Elements behind the Renewable Energy Community: Current Status, Existing Gap, Necessity, and Future Perspective—Overview

Ahmed,

Ali,

Ciocia

et al. 2024

Energies

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The Renewable Energy Community (REC) in Europe promotes renewable energy sources (RESs), offering social, economic, and environmental benefits. This new entity could alter consumer energy relationships, requiring self-consumption, energy sharing, and full utilization of RESs. Modernizing energy systems within the REC requires addressing self-consumption, energy sharing, demand response, and energy management system initiatives. The paper discusses the role of decentralized energy systems, the scenarios of the REC concept and key aspects, and activities involving energy generation, energy consumption, energy storage systems, energy sharing, and EV technologies. Moreover, the present work highlights the research gap in the existing literature and the necessity of addressing the technological elements. It also highlights that there is no uniform architecture or model for the REC, like in the case of microgrids. Additionally, the present work emphasizes the role and importance of technological elements in RECs, suggesting future recommendations for EMS, DSM, data monitoring and analytics, communication systems, and the software or tools to ensure reliability, efficiency, economic, and environmental measures. The authors also highlight the crucial role of policymakers and relevant policies, which could help in implementing these technological elements and show the importance of the RECs for a sustainable energy shift and transition.

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“…Incorporating variable renewable energy sources such as solar and wind power into the power grid poses significant challenges. Renewables are not always available, and their power output can fluctuate rapidly due to weather conditions [14]. The study [25] proposes a scheme that utilizes probabilistic techniques to model the uncertainties associated with renewable energy sources, load forecasting errors, and other stochastic factors.…”

Section: Challenges In Power Distribution and Demand-side Managementmentioning

confidence: 99%

“…The study [13] developed a heuristic peak load management method based on generated electricity and anticipated market clearing prices that considers the unpredictable characteristics of spontaneous resources and load demand. In the existing literature, heuristic algorithms have been proposed as a means of addressing the challenge of load scheduling in order to meet various client objectives [14]. Article [15] outlines a home energy management (HEM) system that uses equipment management to minimize overall energy usage and peak demand, benefiting both the utility and consumers.…”

Section: Introductionmentioning

confidence: 99%

Categorization of Loads in Educational Institutions to Effectively Manage Peak Demand and Minimize Energy Cost Using an Intelligent Load Management Technique

Ramu

Gangatharan

Rangasamy³

et al. 2023

Sustainability

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The inclusion of photovoltaics (PV) in electric power supply systems continues to be a significant factor in global interest. However, solar power exhibits intermittent uncertainty and is further unpredictable. Accurate solar generation prediction and efficient utilization are mandatory for power distribution management and demand-side management. Peak demand management and reducing energy costs can be effectively tackled through the implementation of a reliable solar power forecasting system and its efficient utilization. In this regard, the proposed work is related to efficiently managing solar PV power and optimizing power distribution using an enhanced reinforced binary particle swarm optimization (RBPSO) technique. This DSM (demand-side management) strategy involves utilizing a forecast of solar PV generation for the upcoming day and adjusting the consumption schedule of the load to decrease the highest energy demand. The proposed approach improves user comfort by adjusting the non-interruptible and flexible institutional load through clipping and shifting techniques. To evaluate the effectiveness of this approach, its performance is assessed by analyzing the peak demand range and PAR (peak-to-average ratio). It is then compared to the conventional genetic algorithm to determine its effectiveness. Simulation results obtained using MATLAB show that the PAR peak demand before DSM was found to be 1.8602 kW and 378.06 kW, and after DSM, it was reduced to 0.7211 kW and 266.54 kW. This indicates a 29% reduction in Peak demand and performance compared to the conventional genetic algorithm (GA).

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Neural Network-Based Demand-Side Management in a Stand-Alone Solar PV-Battery Microgrid Using Load-Shifting and Peak-Clipping

Cited by 12 publications

References 54 publications

Heuristic control of power consumption by up to 1000 V electrical loads at mining enterprises

Heuristic control of power consumption by up to 1000 V electrical loads at mining enterprises

Technological Elements behind the Renewable Energy Community: Current Status, Existing Gap, Necessity, and Future Perspective—Overview

Categorization of Loads in Educational Institutions to Effectively Manage Peak Demand and Minimize Energy Cost Using an Intelligent Load Management Technique

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