Please use this identifier to cite or link to this item: https://hdl.handle.net/10321/3748
Title: Optimization of distribution static compensator for mitigation of power quality issues in grid-tied photovoltaic systems
Authors: Adebiyi, Abayomi Aduragba 
Issue Date: 1-Dec-2021
Abstract: 
The global energy demand is rising above the all-time average, and fossil fuel
reserves, which power a large chunk of the existing power generation plants, are
being depleted. Hence, Renewable Energy Technologies (RET) have become the
alternative to meet demand and provide sustainable power. Solar photovoltaic (PV)
energy, an essential aspect of RET, which generates emission-free power, is one of
the world's emerging resources. Rooftop PV technology installation is advanced in
residential and commercial applications due to government subsidies, lower
investment costs, and feed-in tariffs.
The rapid penetration of PV systems into conventional distribution grids has created
some power quality and power stability issues. Power quality (PQ) distortion is the
most critical problem in distribution grids. The literature studied revealed that the
several nonlinear loads and PV systems power electronic-based inverters that
penetrate the grid and contribute to poor power quality issues, i.e., voltage rise,
voltage dip, voltage unbalance, flicker, and harmonics. Also, the PV system
maximum power point (MPP) controller's performance was investigated since the
current-voltage (I-V) characteristic of PV panels is nonlinear and dependent on
variables such as solar radiation and temperature. A comparative analysis conducted
showed that the incremental conductance tracks the maximum power point better
than the perturb and observe method for better power generation.
MATLAB/Simulink system model simulations were run for several case studies to
analyze the maximum power point tracking (MPPT) algorithm's performance under
varied solar irradiation. The results obtained suggested a course to the
implementation of the proposed incremental conductance MPPT algorithm. Selected
power quality problems in a grid-tied PV system were analyzed via simulations and
enhanced with the application of conventional proportional-integral (PI) controlled DSTATCOM. Also, field measurement-based experiments were conducted to
determine system performance in a typical grid-tied PV system. The real-life 110 kW
grid-tied PV system installed at the Durban University of Technology (DUT), Steve
Biko campus, was used for the fieldwork. Taken into consideration was the impact of
solar radiation dynamic variation on the field study. According to the results obtained, the 110 kW PV system's voltage quality data were
within the limits of the local and internationally defined standards. The concept of DSTATCOM was implemented with an Enhanced Jaya (E-Jaya) optimization
algorithm to mitigate specific power quality issues, such as voltage rise, voltage dip,
voltage unbalance, and current harmonics. The precision with which the DSTATCOM reference compensation current is selected is vital to the device's
performance. The synchronous reference frame theory of phase lock loop (PLL) for
a three-phase system is described in this thesis. The objective was to keep the
source current THD below 5% to comply with the recommended limits of the IEEE519 Standard harmonic limits. The implemented novel E-Jaya control optimization
algorithm-based D-STATCOM provided continuous and adequate voltage regulation
and harmonic compensation to mitigate power quality issues in the grid-tied PV
distribution system. Simulation comparative analysis results of the developed control
method with Artificial Bee Colony (ABC) and Jaya optimization algorithm indicated
that the developed novel E-Jaya optimization algorithm enhanced the grid-tied PV
system's performance by providing superior voltage regulation and source current
THD compensation significantly declined to 1.01% from 31.93%.
Description: 
A thesis submitted in fulfilment of the requirements for the degree of Doctor of Engineering in Electrical Power Engineering, Department of Electrical Power Engineering, Faculty of Engineering and the Built Environment at the Durban University of Technology, 2021.
URI: https://hdl.handle.net/10321/3748
DOI: https://doi.org/10.51415/10321/3748
Appears in Collections:Theses and dissertations (Engineering and Built Environment)

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