Power Enhancement With Grid Stabilization of Renewable Energy-Based Generation System Using UPQC-FLC-EVA Technique

Sarita, Kumari; Kumar, S. Senthil; Vardhan, Aanchal Singh S.; Elavarasan, Rajvikram Madurai; Saket, R. K.; Shafiullah, GM; Hossain, Eklas

doi:10.1109/access.2020.3038313

Cited by 88 publications

(30 citation statements)

References 58 publications

(39 reference statements)

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“…It has been proposed that neural networks can manage damping in uniform energy flow control units in order to mitigate low-frequency oscillations in power systems [78]. The improved power performance of a renewable energy-based power system through grid optimization using a unified power quality conditioner (UPQC) with fuzzy logic controller (FLC) method is based on the results of the study [79]. Fuzzy logic is used in UPFC controllers to control the shunts and series converters through the implementation of control converters [80].…”

Section: -Artificial Intelligent Control Of Hvdc Systemmentioning

confidence: 99%

Artificial Intelligence-based Control Techniques for HVDC Systems

Abdulwahid

2023

Emerg Sci J

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The electrical energy industry depends, among other things, on the ability of networks to deal with uncertainties from several directions. Smart-grid systems in high-voltage direct current (HVDC) networks, being an application of artificial intelligence (AI), are a reliable way to achieve this goal as they solve complex problems in power system engineering using AI algorithms. Due to their distinctive characteristics, they are usually effective approaches for optimization problems. They have been successfully applied to HVDC systems. This paper presents a number of issues in HVDC transmission systems. It reviews AI applications such as HVDC transmission system controllers and power flow control within DC grids in multi-terminal HVDC systems. Advancements in HVDC systems enable better performance under varying conditions to obtain the optimal dynamic response in practical settings. However, they also pose difficulties in mathematical modeling as they are non-linear and complex. ANN-based controllers have replaced traditional PI controllers in the rectifier of the HVDC link. Moreover, the combination of ANN and fuzzy logic has proven to be a powerful strategy for controlling excessively non-linear loads. Future research can focus on developing AI algorithms for an advanced control scheme for UPFC devices. Also, there is a need for a comprehensive analysis of power fluctuations or steady-state errors that can be eliminated by the quick response of this control scheme. This survey was informed by the need to develop adaptive AI controllers to enhance the performance of HVDC systems based on their promising results in the control of power systems. Doi: 10.28991/ESJ-2023-07-02-024 Full Text: PDF

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Section: -Artificial Intelligent Control Of Hvdc Systemmentioning

confidence: 99%

Artificial Intelligence-based Control Techniques for HVDC Systems

Abdulwahid

2023

Emerg Sci J

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“…The destabilization of the power grid takes place if the challenge of PQ is not addressed appropriately. Some of the commonly employed techniques for enhancement of PQ includesStatic Var Compensator (SVC) [12], Dynamic Voltage Restorer (DVR) [13], Static synchronous Compensator (STATCOM) [14], Active Power Filtering (APF) [15], Static Var Generator (SVG) [16] and Thyristor-Controlled Series Capacitor (TCSC) [17].All these aforementioned techniques solely focusseson the compensation of a particular PQ issue.As a result, UPQC [18][19][20][21][22] is becoming a more popular option owing to its excellent performance in compensating both voltage and current PQ issues, resulting in the overall improvement of the PQ of both load voltage and grid current.In [23], a considerable amount of advancement is seen in tackling the issues of reactive power, harmonics, short interruptions and voltage swells/sags by integrating UPQC with PV.A configuration of PV-UPQC is presented in [24] for tackling voltage and current distortions, while in [25] the modelling, verification and simulation of a 3Φ PV-UPQC is addressed.Although this study field has been experiencing rampant growth, the attempts to integrate UPQC with PV is in initial stages, and there remain certain problems that still needs to be resolved. For instance, the dc-bus voltage stability control issue is directly associated to the PV array's output power along with the compensation capability of the UPQC.…”

Section: Introductionmentioning

confidence: 99%

Power Quality Improvement in Distribution System Using Solar Fed Cuk Integrated Boost Converter

Joseph

et al. 2023

Preprint

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Recently, Power Quality (PQ) issues have emerged to be acritical problem faced by the distributed power system on account of its several forms and frequencies of occurrence. Thereby, the integration of the distributed generation of Photovoltaic (PV) with Unified Power Quality Conditioner (UPQC) is recommended in this work with the intension towards improvement of quality of power delivered to the customers. Also leading to the development of a novel grid tied PV design that avoids any unfavourable voltage or current situation in distributed power system. The series compensator of the UPQC addresses voltage-related challenges, while the shunt compensator of the UPQC handles current-related challenges. The interfacing of the PV to the UPQC is accomplished using the Cuk Integrated Boost Converter (CIBC)and the optimum extraction of PV power is ensured with the application of Cascaded Type-2 Fuzzy Logic Controller (CT2FLC) based Maximum Power Point Tracking (MPPT) technique. The control of the UPQC is done using Fuzzy tuned Adaptive PI controller in addition to Convolution Neural Network (CNN) assisted DQ theory. The dynamic nature of the presented approach in terms of compensation capability and dc-bus stability is assessed through MATLAB simulation and experimental verification.

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“…Inspite of several advantages, the solar PV system has a major disadvantage which is the unpredictable nature of solar energy supply owing to the earth's rotation and environmental factors like temperature variations, cloud formation, changing weather conditons, etc. [1,2]. The power output from PV fluctuates and develops several peaks because of partial shading condition non-uniform irradiance.…”

Section: Introductionmentioning

confidence: 99%

Design of Intelligent Controller based High Gain DC-DC Converter for Microgrid applications

2022

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The major objective of this research is to develop a hybrid Maximum Power Point Tracking (MPPT) technique to provide the grid with unceasing supply of power from PV system and to improve the dependability of the Battery Energy Storage System (BESS). The ANN controller manages the discharging and charging process of the BESS. The Maximum Power Point (MPP) is tracked using an Adaptive Neuro Fuzzy Inference System -Particle Swarm Optimization (ANFIS-PSO) based MPPT approach in order to maximize the power extraction from the PV system. The DC-DC boost converter boosts the voltage output obtained from the PV system and feeds it to the 3 φ Voltage Source Inverter (VSI). The interfacing of the inverter to the 3 φ grid is achieved via an LC filter which performs effective harmonics mitigation. The Proportional Integral (PI) controller is used in synchronous (dq) reference frame for accomplishing effective grid voltage synchronization. The proposed system's performance is evaluated using Matlab/Simulink.

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Power Enhancement With Grid Stabilization of Renewable Energy-Based Generation System Using UPQC-FLC-EVA Technique

Cited by 88 publications

References 58 publications

Artificial Intelligence-based Control Techniques for HVDC Systems

Artificial Intelligence-based Control Techniques for HVDC Systems

Power Quality Improvement in Distribution System Using Solar Fed Cuk Integrated Boost Converter

Design of Intelligent Controller based High Gain DC-DC Converter for Microgrid applications

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