1. 1 Novel Capabilities of Power Quality Monitoring at the Smart Grid Netzah Calamaro, Yuval Beck, Doron Shmilovitz Israel Electric Company, TAU energy conversion lab, HIT

2. 2 Grid event location Existing array of power quality monitors and meters

3. 3 innovative software tools for smart grid diagnostics and control Software that analyzes grid through waveform monitoring. Modern electric energy transport theories significantly contribute to this Periodic averaged theories, instantaneous theories re-investigated Hardware infrastructure already exists

4. 4 Current’s Physical Components theory The way it’s done Current decomposition into physical components Power decomposition into physical components All components are orthogonal Orthogonal = independent = separate

5. 5 Current’s Physical Components theory Advantages Energy measurement active/reactive load characterization grid monitoring and control load identification Disadvantages requires Fast Fourier Transform (FFT) X 8 channels Minimal response time: half a cycle For active filter requires storage components (explain what is a filter)

6. 6 Current’s Physical Components theory Components: Active Reactive Scattered Unbalanced Backward Orthogonality: Physical decomposition:

7. 7 Current’s Physical Components theory Voltage and current harmonic representation (FFT)

8. 8 Current’s Physical Components theory Decomposition Algorithm Back to grid monitoring and control

9. 9 Instantaneous p-q theory p – active, q- reactive Significantly different from periodic averaged theories (CPC) Instead of periodic averaged powers, it’s instantaneous powers Power components are completely different physical meaning than CPC

10. 10 Instantaneous p-q theory Advantages Grid monitoring and control Active filtering, power conditioning Not require storage components Latency: instantaneous, immediate Disadvantages Not characterize active/reactive load correctly Why? Recognition of active/reactive requires a period and not an instant. Less suitable for energy measurement

11. 11 Instantaneous p-q theory The way it’s done Physical meaning of powers Back to grid monitoring and control

12. 12 Instantaneous p-q theory Decomposition algorithm To filter

13. 13 Instantaneous p-q theory Clark Transformation

14. 14 Grid monitoring and control application - CPC

15. 15 Grid monitoring and control application – p-q

16. 16 Instantaneous p-q theory Novel application: Microscope, telescope To microscope To telescope

17. 17 Instantaneous p-q theory Novel application: Microscope, telescope Telescope: To schematic

18. 18 Instantaneous p-q theory Microscope, telescope Microscope: To slide 16

19. 19 Instantaneous p-q theory Active Power quality through active filtering To schematic To constant power

20. 20 Instantaneous p-q theory Active Power quality through active filtering – constant power To slide 11

21. 21 (d) Fig. 9: (a) Group delay spectra of active+ scattered. (b) Phase delay spectra of active+ scattered. (c) Magnitude response spectra of active+ scattered. (d) Phase response spectra of active+ scattered. Current’s Physical Components theory PC farm Load identification To flow diagram

22. 22 (c) Current’s Physical Components theory AC motor Load identification To flow diagram

23. 23 Current’s Physical Components theory - dimmer Load identification To flow diagram

24. 24 Current’s Physical Components theory algorithm To pc farm To AC motor To dimmer

25. 25 Conclusion: Over existing infrastructure of power quality monitors Using only software located at the MDM (Meter Data Management) Additional grid power quality data is obtained over EN 50160 is obtained It requires modern electric energy transport theories knowledge

26. 26 Conclusion: Novel applications presented: Telescope, microscope – for grid movement between branches Grid monitoring and control Grid active filtering Power flow –energy flow optimization

27. 27 Questions