1. 2014 CIGRE ParisIñigo Ferrero 1 Process Bus Implementation on IEDs: Development Considerations

2. 2014 CIGRE ParisIñigo Ferrero 2 Overview Conventional / Process Bus Substations Topology example Development of the IED SV time alignment Sampling frequency change Frequency tracking Estimation of lost SV

3. 2014 CIGRE ParisIñigo Ferrero 3 Conventional Substation

4. 2014 CIGRE ParisIñigo Ferrero 4 Process Bus Substation

5. 2014 CIGRE ParisIñigo Ferrero 5 Process Bus Substation

6. 2014 CIGRE ParisIñigo Ferrero Network Topology Example Merging Unit IEC 61850-8-1 IEC 61850-9-2LE / IEC61869-9 Merging Unit Telecontrol. WAN Maintenance Management Protection Management Subestation Bus Process Bus IEC 61850-8-1 LEVEL 1 (Bay Position) LEVEL 2 (Substation) LEVEL 0 (Switchgear)

7. 2014 CIGRE ParisIñigo Ferrero 7 Currents and Voltages can be measured by several MU Each SV has a Sample Counter (smpCnt) used by the IED that receives the frames to make the alignment: 50 Hz: 0 – 3999 60 Hz: 0 - 4799 MU are synchronized (IRIG-B, PPS, IEEE1588). Reception on PPS signal forces the sample number 0, the rest are based on the internal MU clock SV from different MU can arrive at different times. Delays due to: MU processing time Communication network SV Alignment MU works with 80samples/cycledelay must be considered

8. 2014 CIGRE ParisIñigo Ferrero 8 SV Alignment

9. 2014 CIGRE ParisIñigo Ferrero Sampling Frequency Change Two options to convert a conventional IED into process bus: Adapt the filters to work with the new sampling frequency Change the sample frequency and use the same filters Frequency tracking Protection algorithms MU: 80 s/c IED: 32 s/c

10. 2014 CIGRE ParisIñigo Ferrero 10 Frequency Tracking Sampling frequency of the MU is fixed (80 samples per 50 / 60 Hz cycle) without changing with the frequency Frequency tracking: if SV are directly used, errors during off-nominal frequencies will appear. The samples must span exactly one cycle. Harmonic influence must be also taken into account Frequency tracking: algorithm that modifies the time between samples based on the frequency measurement to make the DFT window expand exactly one cycle

11. 2014 CIGRE ParisIñigo Ferrero 11 Estimation of Lost SV SV can be lost Lost SV can generate phasor errors during one cycle Blocking will delay the operation for too long Estimation on SV

12. 2014 CIGRE ParisIñigo Ferrero 12 Estimation of Lost SV SV is consider as lost: Delay time Quality invalid Synchronized flag FALSE Estimation. Replaced by: Zeros Value of last SV New SV after lost SV Interpolation

13. 2014 CIGRE ParisIñigo Ferrero 13 A time delay must be considered when time alignment is performed Decision between Changing from the MU sampling rate to the conventional relay sampling (allows maintaining the digital filters and protection algorithms) Work with the MU sampling rate Frequency tracking is needed because of the fixed sampling rate of the MU. Harmonics influence must be taken into account. Estimation of lost SV is a must. It should be developed to support SV lost also under harmonics presence. Conclusions

14. 2014 CIGRE ParisIñigo Ferrero 14 Thank you Iñigo Ferrero inigo.ferrero@cggloblal.com