@pec.paavai.edu.in/electrical-and-electronics-engineering
Professor and Electrical and Electronics Engineering
Paavai Engineering College
was born in Tamil Nadu, India, on May 20, 1975. He received his UG degree B.E in Electrical and Electronics Engineering from Madras University, in 1997. He completed his M.E Power Electronics and Drives from Anna University of technology in 2010.He has done his research work in wind energy under the title “Wind Energy Conversion System Using Nozzle Augmented Wind Turbine and Power Converters”. He completed his Ph.D from Anna University, Chennai in 2016.
With 22 years of teaching experience, he has published more than 15 papers in national and international conferences. In national and international journals he has published more than 25 journals. He has published 6 patents in various field of innovations such as Electronics, Mechanical, Physics etc. He received more than lakhs funds from various communities like AICTE- MODROB, STTP, CSIR etc. He is a dynamic member in various professional bodies like ISTE, IE, IAENG, IFERP.
Ph.D. in Electrical Engineering, Renewable Energy, Anna university Year of 2016
M.E - Power Electronics & Drives K.S R College of Technology Year of 2010
B.E - Electrical and Electronics Engineering Hindustan College of Engineering, Year of 1997
Renewable Power Conversion Systems, Pulse Width Modulation Techniques, Small Signal Modeling of Power Converters, AC Drives and Control and Networking.
Scopus Publications
Scholar Citations
Scholar h-index
Scholar i10-index
R.Johnnie Hepziba, G. Balaji, R. Muralikrishna, and S. Rathinavel
Elsevier BV
R. Muthukumar, G. Balaji, and S. Vadivel
Elsevier BV
Thangaraj Nandagopal and Govindan Balaji
Wiley
A facile one‐pot hydrothermal method is provided for synthesis of the reduced graphene oxide‐cobalt tungstate (rGO@CoWO4) nanocomposites with the enhanced electrochemical performances for supercapacitors (SCs). The resulting nanocomposites are comprised of CoWO4 nanospheres that are well anchored on graphene sheets by in situ reducing. The BET‐specific surface area of CoWO4, rGO@CoWO4 nanocomposites are 101 and 167 m2 g−1, respectively. The electrochemical evaluations are carried out in a 1 M KOH solution as the electrolyte. The hybrid electrode shows excellent specific capacitance of 1145 F g−1 at a current density of 1 A g−1 with superior rate capability and satisfactory cycling stability (97.2% capacitance preserved after 10 000 cycles). The good electrochemical performance can be attributed to the increased electrical conductivity and the creation of new active sites due to the synergetic effect of rGO and CoWO4 nanospheres. Moreover, the cyclic stability tests demonstrat capacitance retention of about 97.2% after 10 000 cycles, suggesting the potential application of rGO@CoWO4 nanocomposites in energy storage devices. The asymmetric SCs assembled with rGO@CoWO4 and activated carbon exhibit high energy density (39.1 Wh kg−1) and power density (631.2 W kg−1 at 1 A g−1), with remarkable cycle life (96.7% over 10 000 cycles) while still maintaining 24.5 Wh kg−1 at an even higher power density of 5098 W kg−1. The above results indicate that the hybrid rGO@CoWO4 electrodes synthesized by this approach would be a promising candidate for practical application of high‐performance SCs.
Johnnie Hepziba R and Balaji G
Informa UK Limited
T. Nandagopal, G. Balaji, and S. Vadivel
Elsevier BV
S. Suganya, G. Balaji, and S. Vadivel
Elsevier BV
R. Muthukumar, G. Balaji, and S. Vadivel
Elsevier BV
T. Nandagopal, G. Balaji, and S. Vadivel
Elsevier BV
R. Muthukumar, G. Balaji, and S. Vadivel
Elsevier BV
R. Ramaprabha, Anjana Ethirajan, G. Balaji, N. Abhishek, and R. Aswinkumar
IEEE
As grid transmission difficulties is increased in rural areas so the standalone PV system has become a better option to power smaller rural areas. The main contribution of standalone PV system is the energy storage system (ESS) which reduces the intermittency effects at the solar farm. Though, batteries are the commonly used ESS, they are susceptible to low lifetime with increased maintenance cost. In such case, supercapacitors are considered for the better alternative. The role of capacitors in the standalone PV system have been investigated in this paper using Matlab/Simulink and hardware. It is observed that the supercapacitors help to improve the battery lifecycle.
G. Balaji, S. Rathinavel, and S. Vadivel
Elsevier BV
S. Rathinavel, G. Balaji, and S. Vadivel
Elsevier BV
S. Rathinavel, S. Vadivel, and G. Balaji
Elsevier BV
S. Vadivel, G. Balaji, and S. Rathinavel
Elsevier BV
G. Balaji, A. Rathinam, and S. Vadivel
Springer Science and Business Media LLC
A. Rathinam, G. Balaji, and S. Vadivel
Springer Science and Business Media LLC
G. Balaji, R. Sivakami, M. Sridharan, and K. Jeyadheepan
Elsevier BV
Gnanambal, , G. Balaji, M. Abinaya, , and
International Hellenic University
This paper proposes adaptive Maximum Power Point Tracking (MPPT) controller for Permanent Magnet Synchronous Generator (PMSG) wind turbine and direct power control for grid side inverter for transformer less integration of wind energy. PMSG wind turbine with two back to back voltage source converters are considered more efficient, used to make real and reactive power control. The optimal control strategy has introduced for integrated control of PMSG Maximum Power Extraction, DC link voltage control and grid voltage support controls. Simulation model using MATLAB Simulink has developed to investigate the performance of proposed control techniques for PMSG wind turbine steady and variable wind conditions. This paper shows that the direct driven grid connected PMSG system has excellent performances and confirms the feasibility of the proposed techniques. While the wind turbine market continues to be dominated by conventional gear-driven wind turbine systems, the direct drive is attracting attention. PM machines are more attractive and superior with higher efficiency and energy yield, higher reliability, and power-to-weight ratio compared with electricity-excited machines.
G. Balaji, , I. Gnanambal, C. Gowrishankar, , and
International Hellenic University
Thispaper deals with the analysis, modeling and control system for permanent magnet synchronous generator (PMSG) based wind turbine connected to the grid. A wind energy conversion using DC-DC Buck- Boost Converter for permanent magnet synchronous generator (PMSG) based variable speed wind energy conversion system (WECS) has been proposed which is integrated with grid using five-level diode clamped multilevel (DCMLI) inverter. In this work the instantaneous values of input side current and voltage of DC-DC buck-boost converter are utilized for implementing the PID controller. The proposed work is verified by the simulation in Powersim.
G.Balaji, I.Ganambal, & M.Thenmoli “Improvement Technique of the Power Quality for Three Phase Grid Connected System using Wind Energy” International Journal of Systems, Algorithms & Applications (IJ S A A), Volume 2, Issue ICRAET12, May 2012, .
G. Balaji, I. Gnanambal& P. Gajendran “Fuzzy Logic Controller Based Wind Energy Conversion System” International Journal of Electrical and Electronics Engineering Research (IJEEER), Vol. 3, Issue 1, Mar 2013, .
G.Balaji, & S.Suganya “Power Converter Topology for Permanent Magnet Wind Generator System” IOSR Journal of Engineering (IOSRJEN), Vol. 3, Issue 2 (Feb. 2013), PP 43-51. (UGC Approval)
G. Balaji, “Isolated Wind–Hydro Hybrid System using Permanent Magnet Synchronous Generators and Battery Storage with Fuzzy Logic Controller” IJEDR, Volume 2, Issue 1, ISSN: 2321-9939. (UGC Approval)
Gnanambal, G. Balaji& M. Abinaya “Adaptive Controller for Drive System PMSG in Wind Turbine” Middle-East Journal of Scientific Research 21 (7): 2014, pp. 1119-1129. (Scoups, Impact
G.Balaji, I.Gnanambal “Wind Power Generator Using Horizontal Axis Wind Turbine with Convergent Nozzle” Published in Journal of Scientific & Industrial Research in India (NATL INST SCIENCE COMMUNICATION) Volume 73, June 2014, Page(s):375-380. (Scoups, Impact
G. Balaji, I. Gnanambal “Multilevel inverters for permanent magnet synchronous generator using wind power generation system” Energy Education Scie