Please use this identifier to cite or link to this item: https://hdl.handle.net/10321/4870
Title: Power loss minimization and voltage profile improvement in transmission networks using a network modification algorithm
Authors: Ntombela, Mlungisi 
Keywords: Power system losses;Voltage profiles;Distributed generator
Issue Date: May-2023
Abstract: 
A number of algorithms that aim to reduce power system losses and improve voltage profiles by
optimizing distributed generator (DG) location and size have already been proposed, but they are
still subject to several limitations. Hence, new algorithms can be developed or existing ones can
be improved so that this important issue can be addressed much more appropriately and effectively.
In their formulations, the majority of algorithms focused only on real power loss minimization.
Power systems operate with reactive power controller installed at various locations, which are
essential to their operation. Therefore, the effect of reactive power control must be taken into
consideration when optimizing DG allocation for voltage profile improvement. State-of-the-art
optimization algorithms can be used to improve the effectiveness of the existing one in taking into
account the effect of reactive power control. This study proposed a modification methodology
based on a hybrid optimization algorithm, consisting of a combination of the genetic algorithm
(GA) and the improved particle swam optimization (IPSO) algorithm m for minimizing active
power loss and maintaining the voltage magnitude at about 1 p.u. The buses at which DGs should
be injected were identified based on optimal real power loss and reactive power limit. When
applying the proposed optimization algorithm for DGs allocation in power systems, the search
space or number of iterations was reduced, increasing its convergence rate. The proposed
modification methodology was tested in an IEEE-30 bus electrical network system with DGs
allocations and the simulations were conducted using MATLAB software. The hybrid GA and
IPSO (HGAIPSO) method has less iterations and is more effective at solving optimization issues
than other optimization algorithms like GA, PSO, and IPSO. An IEEE-30 bus network system
with DGs allocations was used to evaluate the effectiveness of the proposed HGAIPSO, and the
test results were compared to those from alternative techniques (i.e. GA, PSO and IPSO). The
outcomes of the simulation demonstrate that the suggested HGAIPSO can be an effective and
promising optimization technique for issues with transmission network modification. IEEE-30 bus
test system with DGs included at various locations, Type 1, Type 2, and Type 3 DGs allocation,
respectively, showed decreases in overall real power loss of 40.7040%, 36.2403%, and 42.9406%.
For the IEEE-30 bus, the highest bus voltage profiles are up to 1.01pu.
Description: 
Dissertation submitted in fulfillment of the requirements for the degree of Master of Engineering: Electrical Power Engineering, Durban University of Technology, Durban, South Africa, 2022.
URI: https://hdl.handle.net/10321/4870
DOI: https://doi.org/10.51415/10321/4870
Appears in Collections:Theses and dissertations (Engineering and Built Environment)

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