A Survey of Application of Static Synchronous Compensator on Nigerian Longitudinal Transmission System
Abstract
The quest to improve system voltage profile appreciably as well as to significantly reduce network system loss is the growing desire of power system engineers. Flexible alternating current transmission system (FACTS) devices are the emerging technologies for achieving these objectives. One of the famous members of shunt-connected FACTS controller is static synchronous compensator (STATCOM). The motivation for choice of STATCOM for critical review on Nigerian longitudinal transmission systems among other members of advanced voltage source converter (VSC) is connected to enhanced rapid usage of STATCOM in power system simulators across the globe during the last few decades. Published literatures on this concept were carefully x-rayed and presented in chronologically order. The popularity of artificial intelligence (AI) for optimal sizing and placement of STATCOM is still at abysmal level. This suggests the need for power systems researchers to switch to the use of AI techniques most especially the meta-heuristics, population-based optimisation algorithms.
Downloads
References
Aborisade, D. O., Adebayo, I. G., & Oyesina, K. A. (2014). A comparison of the voltage enhancement and loss reduction capabilities of STATCOM and SSSC FACTS Controllers. American Journal of Engineering Research, 3(1): 96-105.
Adepoju, G. A., Akangbe, S. A., & Oni, J. O. (2016). Power flow analysis of longitudinal electrical power system incorporating generalised unified power flow controller. American Journal of Electrical Power and Energy Systems, 5(6): 59-66.
Adepoju, G. A., Komolafe, O. A., & Aborisade, D. O. (2011). Power flow analysis of the Nigerian transmission system incorporating FACTS controllers. International Journal of Applied Science and Technology, 1(5): 187-200.
Akter, S., Saha, A., & Das, P. (2012). Modelling, simulation and comparison of various FACTS devices in power system. International Journal of Engineering Research and Technology, 1(8): 1-13.
Ali, S. M., & Reza, E. (2015). Presenting an innovative method to determine the optimal size of STATCOM to improve the static voltage stability in the power systems. Indian Journal of Fundamental and Applied Life Sciences, 5(1): 2373-2382.
Ambafi, J. G., Nwohu, M. N., Ohize, H. O., & Tola, O. J. (2012). Performance evaluation of PSS and STATCOM on oscillation dumping of North-Central power network of Nigeria grid system. International Journal of Engineering and Technology, 2(2): 209-219.
Anumaka, M. C. (2012). Analysis of technical losses in electrical power system (Nigerian 330kV network as a case study). International Journal of Research and Review in Applied Sciences, 12(2): 320-327.
Aribi, F., & Nwohu, M. N. (2014). Optimal location of STATCOM in Nigerian 330kV network using ant colony optimisation meta-heutistic. Global Journal Research in Engineering, 14(3): 45-50.
Aribi, F., Nwohu, M. N., Sadiq, A. A., & Ambafi, J. G. (2015), Voltage profile enhancement of the Nigerian North-East 330kV power network using STATCOM. International Journal of Advanced Research in Science, Engineering and Technology, 2(1): 332-337.
Choudhary, G., Singhal, N., & Sajan, K. S. (2016). Optimal placement of STATCOM for improving voltage profile and reducing losses using crow search algorithm, International Conference on Control, Computing, Communication and Materials.
Eseosa, O. & Odiase, F. O. (2012). Efficiency improvement of Nigeria 330kV network using flexible alternating current transmission system devices. International Journal of Advances in Engineering and Technology, 4(1): 26-41.
Firas, M. T., Yasser, N. A., & Hassan, A. A. S. (2015). Optimal location of STATCOM for IEEE, 5-bus standard system using GA. Journal of Engineering, 21(7): 72-84.
Fuerte-Esquivel, C. R. (1997). Steady state modelling and analysis of flexible AC transmission systems, PhD thesis, Department of Electronics and Electrical Engineering, University of Glasgow, Glasgow.
Jokojeje, R. A., Adejumobi, A. A., Mustapha, A. O., & Adebisi, O. I. (2015). Application of static synchronous compensator in improving power system performance: A case study of the Nigeria 330kV electricity grid. Nigerian Journal of Technology, 34(3): 564-572.
Makoju, J. (2002). Nigeria transmission development project (distribution and transmission). Report no. PID9541.
Mbunwe, M. J., Nwohu, M. N., & Madueme, V. C. (2015). Minimising power losses and enhancing voltage profile of a multi-machine power network using static synchronous compensator device. Proceedings of the World Congress on Engineering and Computer Science 2015, October 21-23, 2015, San Fransisco, USA.
Muhammad, S., Sohail, Q., Liaqat, A., Sakhi, R., & Nasrullah, K. (2016). STATCOM controller (design and assessment) for transmission and distribution system problems. Innovative Systems Design and Engineering, 7(8): 30-45.
Ogbuefi, U. C., & Madueme, T. C. (2015). A power flow analysis of the Nigerian 330kV electronic power system. IOSR Journal of Electrical and Electronic Engineering, 10(1): 46-57.
Okakwu, I. K., Olabode, E. O., & Okundamiya, M. S. (2018). Voltage profile improvement of the Nigerian 330-kV transmission network using STATCOM. Journal of Engineering Science and Applications, 11(2): 19-27.
Omorogiuwa, E., & Ike, S. A. (2015). Stability studies of the Nigerian 330kV integrated power systems. Journal of Electrical and Electronic Systems, 4(1): 1-11.
Pandey, R., & Kori, A. K. (2012). Real and reactive power flow control using FACTS connected to a transmission line: A power injection concept. International Journal of Advanced Research in Computer Engineering and Technology, 1(6): 252-256.
PHCN National Control Centre Oshogbo, (2005). Generation and transmission grid operations. Oshogbo, Nigeria: Annual Technical Report for 2004.
Prakash, S., Verma, K. P., & Singh, B. (2013). Total harmonic distortion reduction by using SSSC with and without BVSI. International Journal of Power System Operation and Energy Management, 3(2): 17-27.
Prashant, K. A. (2015). Analysis of FACTS Controllers in transmission lines. International Journal for Research in Applied Science and Engineering Technology, 3(7): 209-217.
Rahul, D., Shishir, D., & Ganga, A. (2014). Optimal placement of shunt FACTS devices using heuristic optimisation techniques: an overview. Communication Systems and Network Technologies, IEEE, 518-523.
Raju, J., & Kowslaya, M. (2014). Evolve the controller for SSSC based on control strategy of sen transformer. International Journal of Power Electronics and Drive System, 4(1): 127-136.
Samrajyam, K., & Prakash, R. B. R. (2012). Optimal location of STATCOM for reducing voltage fluctuations. International Journal of Modern Engineering Research, 2(3):834-839.
Usman, R., Sigalo, M. B., & McDonald, S. (2016). Analysis of the effect of FACTS on the Nigerian 330kV transmission network using MATLAB/SIMULINK. European Journal of Engineering and Technology, 4(3): 18-34.
Wei, X., Chow, J. H., Fardanesh, B., & Edris, A. A. (2004). A Common modelling framework of voltage sourced converters for power flow, sensitivity, and dispatch analysis, IEEE Transactions Power on System. 19, 934-941.
Yilu, L., Ribeiro, P. F., & Aysen, A. (2000), Transmission power quality benefits realised by SMES-FACTS controller. Ninth International Conference on Harmonics and Quality of Power Proceedings, IEEE, 1, 307-312.
Zhiping, Y., Chen, S., Maresa, L. C., & Lingli, Z. (2000). Improved STATCOM model for power flow analysis, Proceedings of IEEE Canadian Conference of Electrical and Computer Engineering, 2, 1121-1126.
Copyright (c) 2018 O. E. Olabode, Ignatius K Okakwu, O. O. Ade-Ikuesan, I. D. Fajuke
This work is licensed under a Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.
