Particle Swarm Optimization for Optimal Frequency Response with High Penetration of Photovoltaic and Wind Generation

Alvarez-Alvarado, Manuel S.; Rengifo, Johnny; Gallegos-Núñez, Rommel M.; Rivera-Mora, José G.; Noriega, Holguer H.; Velasquez, W.; Donaldson, Daniel L.; Rodríguez-Gallegos, Carlos D.

doi:10.3390/en15228565

Cited by 4 publications

(4 citation statements)

References 46 publications

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“…Therefore, the cost function denoted by f is formulated as presented in (14). Then, the optimization problem focuses on minimizing the total cost of the system based on the optimal number and power of diesel generators, solar panels, and batteries, as indicated in (15). The system constraints are defined by Equations ( 4), (10), (11), ( 13), (16), and (17).…”

Section: Optimization Problem Formulationmentioning

confidence: 99%

“…A challenge in this context is to optimize the distribution of energy from different sources to meet the islands' electricity demands while ensuring a stable and reliable energy supply. A hybrid renewable energy system typically includes multiple sources of power, such as solar, wind, and diesel generators, which are integrated and controlled to provide electricity to the grid, and their design can be further optimized to achieve the best results [15][16][17]. The challenge lies in balancing the contribution of each energy source to meet the islands' energy demand while ensuring a stable and reliable supply of electricity.…”

Section: Introductionmentioning

confidence: 99%

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Optimal Design of a Hybrid Solar–Battery–Diesel System: A Case Study of Galapagos Islands

Garces-Palacios,

Rodríguez-Gallegos,

Vaca-Urbano

et al. 2024

Solar

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In this study, the sizing problem of hybrid diesel–photovoltaic–battery systems was determined using a particle swarm optimization approach. The goal was to optimize the number of solar panels and batteries that could be installed to reduce the overall cost of an isolated grid system, originally powered by diesel generators, located on Isabela Island in the Galapagos, Ecuador. In this study, real solar radiation and temperature profiles were used, as well as the load demand and electrical distribution system relative to this island. The results reveal that the total cost for the proposed approach is lower as it reaches the global optimal solution. It also highlights the advantage of a hybrid diesel–photovoltaic–battery (DG-PV-BAT) system compared to conventional systems operated exclusively by diesel generators (DGs) and systems made up of DGs and PV panels; compared to them, a reduction in diesel consumption and total cost (71% and 56%, respectively) is achieved. The DG-PV-BAT system also considerably improves environmental factors and the quality of the power line. This study demonstrates the advantages of hybridizing systems isolated from the network through the proposed approach.

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Section: Optimization Problem Formulationmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Optimal Design of a Hybrid Solar–Battery–Diesel System: A Case Study of Galapagos Islands

Garces-Palacios,

Rodríguez-Gallegos,

Vaca-Urbano

et al. 2024

Solar

Self Cite

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“…Such is the case of the Institute of Electrical and Electronics Engineers (IEEE), which provides users with model networks for implementation or study to obtain results applicable to future electrical network designs. In the literature, there are many studies that have used IEEE test feeders for their research: Scheneider et al (2018) analyzed the different IEEE test feeders, Alvarez-Alvarado et al (2022) used IEEE 39-node test feeder and DIgSILENT PowerFactory® to optimize the location and size of new solar and wind power plants by meeting frequency requirements in a distribution network, Alzahrani et al (2020) verified the optimization of the location of battery energy storage systems in distribution networks with photovoltaics minimizing losses in the IEEE 37-node test feeder, Kaur et al (2010) optimized generation economically to meet the operating requirements of the 30-node IEEE test feeder, Yadav et al (2019) used DIgSILENT PowerFactory® in the IEEE 39-node test feeder in the transmission network of India for the classification of events in networks with integration of renewables, Montoya-Bueno et al (2016) used the IEEE 34-node test feeder to test a new approach to manage uncertainty in distribution networks with integration of renewables minimizing distribution costs.…”

Section: Introductionmentioning

confidence: 99%

Análisis De Flujo De Carga De La Red Ieee 34 Nudos Con Integración De Energías Renovables

2023

Proceedings From the International Congress on Project Management and Engineering

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Honrubia Escribano, Andrés (1) (1) UCLM, (2) E2F INGENIERÍA Nowadays, the commitments made by governments worldwide on the reduction of greenhouse gas emissions, as well as the war situation that arose between Ukraine and Russia, which seriously affects Europe from the energy point of view, has motivated a great development of renewable energies. In order not to limit their expansion, grids must be prepared for the installation of these renewable energy sources and their impact on the electricity system in general. To analyze this impact, the "IEEE 34 Node Test Feeder" network is modelled and simulated in DIgSILENT PowerFactory®, because it is a network comparable to urban distribution networks where a massive implementation of generation system from renewable sources for self-consumption is taking place. Once the base grid has been modelled and simulated, renewable generation, wind and photovoltaic facilities are introduced along the network, with the aim of evaluating their technical-economic performance.

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“…Renewable energy sources, in particular wind farms, are becoming more popular every year. According to IRENA, by 2040 many countries plan to completely switch to the use of alternative energy sources [1]. Today, wind energy has become so popular in many countries of the world that it competes with traditional energy sources.…”

Section: Introductionmentioning

confidence: 99%

Development of a Control Unit for the Angle of Attack of a Vertically Axial Wind Turbine

et al. 2023

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This article presents the possibility of increasing the efficiency of a vertical-axis wind generator through the introduction of an automatic control system for the angle of attack of the blades. The calculation of the optimal position of the wind turbine blades for the maximum generation of electrical energy is given, and a developed scheme for controlling the blades using the sensors of the angular speed of rotation of the wind wheel by the anemometer and the current position of the blades is presented. The automatic control system implies the use of a PD controller. A comparison is made of two laboratory experimental models of vertical-axis wind turbines with and without the developed control system. This article focuses on optimizing the angle of attack and developing an automatic control system for vertical-axis wind turbines to increase their efficiency in generating electrical energy.

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Particle Swarm Optimization for Optimal Frequency Response with High Penetration of Photovoltaic and Wind Generation

Cited by 4 publications

References 46 publications

Optimal Design of a Hybrid Solar–Battery–Diesel System: A Case Study of Galapagos Islands

Optimal Design of a Hybrid Solar–Battery–Diesel System: A Case Study of Galapagos Islands

Análisis De Flujo De Carga De La Red Ieee 34 Nudos Con Integración De Energías Renovables

Development of a Control Unit for the Angle of Attack of a Vertically Axial Wind Turbine

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