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Voltage Stability Improvement of Transmission Systems Using a Novel Shunt Capacitor Control

  • Masahiro Furukakoi EMAIL logo , Mir Sayed Shah Danish , Abdul Motin Howlader and Tomonobu Senjyu
Published/Copyright: February 3, 2018
International Journal of Emerging Electric Power Systems
From the journal International Journal of Emerging Electric Power Systems Volume 19 Issue 1

Abstract

This paper proposes a novel shunt capacitor (SC) based voltage stability method for a power system operation. The integration of distributed generators e.g. wind and PV powers to the grid, and fluctuations nature of load power cause the attention of voltage stability management for a power system operation and planning. The SC based proposed method improves the voltage stability by using the flow of active and reactive powers in the transmission line. The Voltagestability index (VSI) is utilized for the voltage stability analysis. The SC is installed at the load bus so that it can inject a proper amount of reactive power for ensuring the voltage stability of power system. The proposed method is investigated in the IEEE-14 bus test system. Simulation results are compared with the non-SC based method. Extensive simulation analyses have been done by the MATLAB/Simulink software.

Keywords: voltage stability; voltage collapse; shunt capacitor

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Received: 2016-8-19
Accepted: 2018-1-10
Published Online: 2018-2-3

© 2018 Walter de Gruyter GmbH, Berlin/Boston

Articles in the same Issue

  2. Evaluation of Partial Discharge Signatures Using Inductive Coupling at On-Site Measuring for Instrument Transformers
  3. Decoupled AC/DC Power Flow Strategy for Multiterminal HVDC Systems
  4. Accurate Location of Evolving Faults on Transmission Lines Using Sparse Wide Area Measurements
  5. Techno-economic Analysis of Wind Turbines in Algeria
  6. Comparative Analysis of Sliding Mode Controller and Hysteresis Controller for Active Power Filtering in a Grid connected PV System
  7. Transient Stability by means of Generator Tripping, Under Frequency Load Shedding and a Hybrid Control Scheme
  8. Influence of Moment of Inertia on Dynamic Characteristics of Permanent Magnet Brushless DC Motor
  9. Risk Assessment of Power System Transmission Network Based on Cascading Failure Chains
  10. Development of a Low Cost Power Meter Based on A Digital Signal Controller
  11. Voltage Stability Improvement of Transmission Systems Using a Novel Shunt Capacitor Control
  12. Smart Demand Response Management of Islanded Microgrid using Voltage-Current Droop Mechanism
  13. Mathematical Model of Multi-Phase Power Converter for Parallel Computation
https://doi.org/10.1515/ijeeps-2017-0112
Keywords for this article
voltage stability; voltage collapse; shunt capacitor

Articles in the same Issue

  2. Evaluation of Partial Discharge Signatures Using Inductive Coupling at On-Site Measuring for Instrument Transformers
  3. Decoupled AC/DC Power Flow Strategy for Multiterminal HVDC Systems
  4. Accurate Location of Evolving Faults on Transmission Lines Using Sparse Wide Area Measurements
  5. Techno-economic Analysis of Wind Turbines in Algeria
  6. Comparative Analysis of Sliding Mode Controller and Hysteresis Controller for Active Power Filtering in a Grid connected PV System
  7. Transient Stability by means of Generator Tripping, Under Frequency Load Shedding and a Hybrid Control Scheme
  8. Influence of Moment of Inertia on Dynamic Characteristics of Permanent Magnet Brushless DC Motor
  9. Risk Assessment of Power System Transmission Network Based on Cascading Failure Chains
  10. Development of a Low Cost Power Meter Based on A Digital Signal Controller
  11. Voltage Stability Improvement of Transmission Systems Using a Novel Shunt Capacitor Control
  12. Smart Demand Response Management of Islanded Microgrid using Voltage-Current Droop Mechanism
  13. Mathematical Model of Multi-Phase Power Converter for Parallel Computation
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