Modern approaches to estimation of power quality

One of the most important properties of the electric power system is its observability. Ensuring observability is relevant not only for power flows and reliability indicators of power supply, but also for power quality indicators, in particular, the non-sinusoidal shape of the supply voltage. Increasingly, the use of elements of power electronics in intelligent power systems, and its application will grow in the future. This leads to the appearance of harmonic components of higher orders of current and voltage. The objects of the power system can be either sources or receivers of harmonics. In this regard, the actual task is to assess the impact of individual objects on the quality of electrical energy in the power system. The observability of Проблемы энергетики, 2017, том 19, № 7-8 86 power systems can be realized by the application of the phasor measurement units (PMU). In this paper, the authors suggest using a distributed system for monitoring the power quality by using the existing PMU infrastructure. This will allow for continuous monitoring of the level of harmonic oscillations in different sections of the power system. Especially this event should be used for isolated power supply systems.

1. Smirnov S.S. High harmonics in high voltage networks / S.S.Smirnov. Novosibirsk: Nauka, 2010. 327 p.

2. Mudiraj A.N. Improvement of Power Quality by mitigating harmonics in single phase AC distribution/ A.N.Mudiraj //2016 International Conference on Automatic Control and Dynamic Optimization Techniques (ICACDOT). 2016. P. 83 – 88.

3. Shashikumar K. Automatic sequential reactive power compensation and harmonic suppression at loads using appliance clustering and power quality monitoring / K.Shashikumar, C.Venkataseshaiah, K.S.Sim. // 2016 International Conference on Robotics, Automation and Sciences (ICORAS) 2016 P.1 – 6.

4. Arrillaga J. Power system harmonics / J. Arrillaga. Chichester: Wiley, 2003. 670 p.

5. Jaipradidtham C. Energy conservation with TCSC controller of electric arc furnace for harmonic analysis in power quality disturbance using continuous wavelet transform / C. Jaipradidtham, // 2016 IEEE Region 10 Conference (TENCON) - 2016 P. 2905 – 2908.

6. Rajasekhar A.N.V.V. Harmonics reduction and power quality improvement by using DPFC / A.N.V.V.Rajasekhar, M.N.Babu. - 2016 International Conference on Electrical, Electronics, and Optimization Techniques (ICEEOT). 2016 P. 1754 – 1758.

7. Suslov K.V. A principle of power quality control in the intelligent distribution networks / K.V.Suslov, N.N.Solonina, V.S.Stepanov // International Symposium on Smart Electric Distribution Systems and Technologies EDST. 2015. P. 131–137.

8. Smirnov A.S. Separate measurement of fundamental and high harmonic energy at consumer inlet - a way to enhancement of electricity use efficiency / K.V.Suslov, N.N.Solonina, A.S.Smirnov // International Conference on Power System Technology PowerCon 2010. P.1 – 6.

9. Wu Z. Simultaneous transmission line parameter and PMU measurement calibration / Z.Wu, L.T.Zora, A.G.Phadke // Power & Energy Society General Meeting IEEE. 2015. P.450–458.

10. Nuthalapati S. Managing the Grid: Using Synchrophasor Technology / S.Nuthalapati, A.Phadke // Power and Energy Magazine, IEEE. 2015. Vol. 13/-Issue. 5- P.340–348.

11. Suslov K.V. Distributed filtering of high harmonics in Smart Grid / K.V.Suslov, N.N.Solonina, A.S.Smirnov // CIGRE Bologna Symposium - The Electric Power System of the Future: Integrating Supergrids and Microgrids. - 2011. P.230–238.

12. Sood V.K. HVDC and FACTS Controllers. Applications of Static Converters in Power Systems /

13. V. K Sood - Springer, 2004. 450p.

14. Suslov K.V. The program for calculating and controlling the level of harmonic components in the power supply network. / K.S. Suslov, N.N.Solonina, Y.D. Gerasimov, Certificate of state registration of the computer program No. 2016613995. date of state registration 12.12.2016.