- Ogbodo Ikechukwu Ogbodo, Nwaogaidu Simeon Obinna, Egbonwonu Emmanuel livinus, Asanya Onyebuchi Nduka
- DOI: 10.5281/zenodo.21387666
- SSR Journal of Engineering and Technology (SSRJET)
The Nigerian 330 kV transmission network
plays a critical role in bulk electric power delivery across the country, yet
it continues to experience operational challenges such as weak voltage
profiles, excessive transmission losses, congestion on key corridors, and
limited loadability. These issues reduce the efficiency, reliability, and
stability of the national grid. This study presents the optimal placement and
sizing of Flexible Alternating Current Transmission System (FACTS) devices,
namely the Static Var Compensator (SVC), Thyristor Controlled Series Capacitor
(TCSC), and Unified Power Flow Controller (UPFC), in the Nigerian 330 kV 48-bus
power system using Particle Swarm Optimization (PSO). The objective was to
minimize voltage drop, reduce real power losses, and improve network performance
through intelligent compensation planning. A base-case load flow analysis was
carried out in MATLAB/PSAT to determine voltage magnitudes, line loading
conditions, and weak buses in the network. Results identified Jos, Ugwuaji, and
New Haven buses as the most voltage-deficient locations and were selected for
SVC placement. The Ugwuaji–New Haven and Jos–Markurdi transmission lines were
identified as suitable locations for TCSC installation, while UPFC devices were
placed at the midpoint of the same lines. PSO was then applied to determine the
optimal compensation size subject to network operating constraints. The
optimization process converged successfully with a best objective function
value of -5974.45942 and produced optimal decision variables of
. The corresponding equivalent FACTS
impedance obtained was 37.5546 Ω. Comparative analysis showed that PSO-based
placement significantly outperformed random placement, reducing transmission
losses from 182.4 MW in the uncompensated system to 121.5 MW under optimized
compensation. Compensation sensitivity analysis further showed that increasing
compensation level from 0% to 60% progressively reduced losses, with 60%
compensation providing the best operating condition within the tested range. Among
the devices studied, the UPFC produced the best overall technical performance
due to its simultaneous control of voltage magnitude, transmission impedance,
and active/reactive power flow. The study concludes that PSO is a reliable and
computationally efficient tool for solving the nonlinear FACTS placement and
sizing problem. Strategic deployment of optimally sized FACTS devices offers a
practical and cost-effective approach for improving the performance of the
Nigerian 330 kV grid and reducing the need for immediate transmission expansion.
Keywords: Nigerian 330 kV
grid, FACTS devices, Particle Swarm Optimization, SVC, TCSC, UPFC, transmission
loss reduction, voltage stability, power system optimization.
