Design of load optimal control algorithm for smart grid based on demand response in different scenarios

Wang, Cheng-Liang; Cao, Minjian; Lucas, Raquel Martínez

doi:10.1515/phys-2018-0125

Cited by 6 publications

(6 citation statements)

References 14 publications

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“…The primary level can be designed through different strategies; for instance, impedance control. The primary control reference signal is calculated employing the secondary control system [26,27]. Table 1 shows the system parameters.…”

Section: Methodsmentioning

confidence: 99%

Optimal Hierarchical Control for Smart Grid Inverters Using Stability Margin Evaluating Transient Voltage for Photovoltaic System

et al. 2023

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This research proposed an optimal control approach for a smart grid electrical system with photovoltaic generation, where the control variables are voltage and frequency, which aims to improve the performance through addressing the need for a balance between the minimization of error and the operational cost. The proposed control scheme incorporates the latest advancements in heuristics and hierarchical control strategies to provide an efficient and effective solution for the smart grid electrical system control. Implementing the optimal control scheme in a smart power grid is expected to bring significant benefits, such as the reduced impact of renewable energy sources, improved stability, reliability and efficiency of the power grid, and enhanced overall performance. The optimal coefficient values are found by minimizing the cost functions, which leads to a more efficient system performance. The voltage output response of the system in a steady state is over-damped, with no overshoot, but with a 5% oscillation around the target voltage level that remains consistent. Despite the complexity of nonlinear elements’ behavior and multiple system interactions, the response time is fast and the settling time is less than 0.4 s. This means that even with an increase in load, the system output still meets the power and voltage requirements of the system, ensuring efficient and effective performance of the smart grid electrical systems.

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Section: Methodsmentioning

confidence: 99%

Optimal Hierarchical Control for Smart Grid Inverters Using Stability Margin Evaluating Transient Voltage for Photovoltaic System

et al. 2023

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“…In recent years, significant research progress has been made in the field of intelligent industrial applications, with numerous scholars providing substantial contributions [8][9][10][11][12][13][14][15][16][17][18][19]. For instance, Aristova et al [8] have extensively investigated the widespread application of industrial robots and automation systems in the manufacturing sector, resulting in enhanced production efficiency and quality.…”

Section: Intelligent Industrial Applicationsmentioning

confidence: 99%

Digital-Twin-Based Monitoring System for Slab Production Process

Fu,

Li,

Shi

et al. 2024

Future Internet

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The growing demand for high-quality steel across various industries has led to an increasing need for superior-grade steel. The quality of slab ingots is a pivotal factor influencing the final quality of steel production. However, the current level of intelligence in the steelmaking industry’s processes is relatively insufficient. Consequently, slab ingot quality inspection is characterized by high-temperature risks and imprecision. The positional accuracy of quality detection is inadequate, and the precise quantification of slab ingot production and quality remains challenging. This paper proposes a digital twin (DT)-based monitoring system for the slab ingot production process that integrates DT technology with slab ingot process detection. A neural network is introduced for defect identification to ensure precise defect localization and efficient recognition. Concurrently, environmental production factors are considered, leading to the introduction of a defect prediction module. The effectiveness of this system is validated through experimental verification.

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“…The uncertain change of the loading condition may damage the voltage and frequency profile and increase the load-shedding by decreasing the resiliency of the power system. 146 Again, the variable nature of the environment is responsible to change the power demand differently in different countries at different times. During summer, the loading in the south area largely increases as compared to the north while during winter, the loading condition is inversed.…”

Section: Energy Storage and Different Load Issuementioning

confidence: 99%

“…The increasing rate of the end user's load produces an adverse effect on the supply‐to‐demand ratio by making the DSM difficult and complex. The uncertain change of the loading condition may damage the voltage and frequency profile and increase the load‐shedding by decreasing the resiliency of the power system 146 …”

Section: Smart Grid Evolutionmentioning

confidence: 99%

“…Again, the variable nature of the environment is responsible to change the power demand differently in different countries at different times. During summer, the loading in the south area largely increases as compared to the north while during winter, the loading condition is inversed 146 . Again, different load characteristic such as consumer, inductive, synchronous, harmonic, nonlinear, and dynamic load are responsible to inject harmonics into the system and requires different control algorithm to stable the performance of the SG.…”

Section: Smart Grid Evolutionmentioning

confidence: 99%

See 1 more Smart Citation

Microgrid to smart grid's evolution: Technical challenges, current solutions, and future scopes

Badal

Sarker

Nayem

et al. 2022

Energy Science & Engineering

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Renewable energy (RE) sources play an important role that not only reduces the pressure on fossil fuels but also produces safe and clean energy by developing the microgrid (MG) technology that fulfills the excess demand for power throughout the world. The technological development and the blessing of information and communication technology converts the MG technology to a smarter one, termed as smart grid (SG) and virtual power plant, by establishing a two‐way communication between the consumers and service provider with the aid of smart metering infrastructure, dynamic pricing scheme, energy management system, smart transmission and distribution system. The transformation of the traditional power system to SG enhances the efficiency, flexibility, resiliency, and robustness of the power system due to the increasing level of cyber security and automation. A directional pathway from conventional to smart power system has been carried out in this paper by addressing the present status of the power system, challenges during the operations, and possible solutions. Initially, the control operation of MG with RE and energy storage system has been investigated which is essential to understand the operation complexity and challenges due to the variable nature of the RE, load dynamics, and uncertainties. But the facilities of end‐user feedback, dynamic pricing scheme, cyber security, and smart metering system are not present in MG technology that hampers the proper regulation of controlling operation, generating and distributing energy as well as energy losses. The development of SG with smart technologies overcomes these problems by proper controlling of power usage. Finally, this paper provides a path to move the MG toward SG by analyzing the technical and critical challenges of smart devices, equipment integration, and their control issues and provides possible solutions to overcome the integration and control challenges for a reliable and sustainable operation.

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Design of load optimal control algorithm for smart grid based on demand response in different scenarios

Cited by 6 publications

References 14 publications

Optimal Hierarchical Control for Smart Grid Inverters Using Stability Margin Evaluating Transient Voltage for Photovoltaic System

Optimal Hierarchical Control for Smart Grid Inverters Using Stability Margin Evaluating Transient Voltage for Photovoltaic System

Digital-Twin-Based Monitoring System for Slab Production Process

Microgrid to smart grid's evolution: Technical challenges, current solutions, and future scopes

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