Designing of SPVWM Inverter Controlled System by Using Suitable Architecture of Power Quality Enhancement Device for Driving Mixed Loads

Authors

  • Rakesh Kumar M.Tech. Scholar, Corporate Institute of Science and Technology, Bhopal, M.P, India
  • Mr Anurage Khare Assistant Professor, Corporate Institute of Science and Technology, Bhopal, M.P, India

DOI:

https://doi.org/10.24113/ijoscience.v6i1.256

Abstract

The stability of a power system is the ability of a power system to restore an operating state of equilibrium for a given initial operating condition after it has been subjected to a physical disturbance, most of the variables of the system being limited so that almost the entire system remains intact. Designing of a SPVWM controlled inverter that has to be made available for efficient power supply to the load of different types. The control of inverter has to be designed in order to enhance the system power supply. To achieve this a space vector pulse width modulation technique has been designed which is then used to provide pulses to the three leg inverter. To design a power quality enhancement device with a simplified architecture such that it will accommodate for the reactive power supply along with an improvement in the active power available at the load terminals. Thus it can be drawn from this work that while designing an inverter with SPVWM control strategy the proposed power quality enhancement device can serve the purpose with better results in terms of power and efficiency. This architecture can also be used in hybrid systems thus making it more reliable controlling method. The system designed is also fitted to feed different types of load like nonlinear load, balanced load and unbalanced load.

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References

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Published

01/08/2020

How to Cite

Kumar, R., & Khare, M. A. (2020). Designing of SPVWM Inverter Controlled System by Using Suitable Architecture of Power Quality Enhancement Device for Driving Mixed Loads. SMART MOVES JOURNAL IJOSCIENCE, 6(1), 10–18. https://doi.org/10.24113/ijoscience.v6i1.256