1. IMPACT OF GREEN POWER GENERATION ON DISTRIBUTION SYSTEMS�
2. Not Green
Burn conventional fuel
Gas
Diesel, oil, gasoline�
Green
Use renewable sources to reduce reliance of fossil fuels:
Solar
Methane (from decomposition)
Wind
Hydro
Biomass (burn it)
Tidal
3. Typical Interconnection Protection Disconnects the generator when it is no longer operating in parallel with the utility.
Protects the utility system from damage caused by connection of the generator (fault current and overvoltage).
Protects the DG generator from damage from the utility system, especially through automatic reclosing.
4. Typical Generator Protection Generator internal short circuits.
Abnormal operating conditions (loss of field, reverse power, overexcitation and unbalance currents).
5. Types of Green Power Generators Induction
Synchronous
Asynchronous
6. Induction Generator Induction
Excitation provided externally
Start up like a motor�(no sync. equipment needed)
Less costly than synchronous machines
Limited in size to 500 KVA
7. Synchronous Generator
8. Asynchronous Generator
9. IEEE 1547 SAYS�A DG SHALL:
Not Cause Overvoltages or Loss of Utility Relay Coordination
Disconnect When No Longer Operating in Parallel With the Utility.
+ Only Discusses 81O/U and 27, 59
Not Energize the Utility when it is De-energized
Not Create an Unintentional Islands
Use “Utility Grade” Relays
Not Cause Objectionable Harmonics
Not Cause Loss of Synchronism That Results in Objectionable Flicker
10. Greatly complicates restoration
Requires synchronizing at utility substation
Inhibits automatic reclosing
Power quality issue
DG may not be able to maintain voltage, frequency and harmonics within acceptable levels.
11. Feeder deenergizes when utility opens feeder
Restoration responsibility on the DG
Requires synchronizing to utility
Inhibits automatic reclosing
12. OVERVOLTAGE AND LOSS OF COORDINATION Two Sources of Overvoltage
+Choice of Delta Interconnection Transformer
Primary Winding
+ Ferroresonance
Loss of Coordination
+Choice of Grounded Interconnection
Transformer Primary Winding.
14. Ungrounded Interconnection Transformers
15. Grounded Primary Interconnection Transformers
16. FERRORESONANCE�NEW YORK FIELD TESTS –1989�FIELD TEST CIRCUIT
17. FERRORESONANCE�NEW YORK FIELD TESTS -1989�50KW Synchronous DG, 9KW load, 100KVAR Capacitance and �Wye-Delta Interconnection Transformer�A=2.74 pu B=2.34 pu C=2.92 pu�
18. FERRORESONANCE�NEW YORK FIELD TESTS -1989�50KW Synchronous DG, 9KW load, 100KVAR Capacitance and �Wye-Delta Interconnection Transformer�A=2.74 pu B=2.34 pu C=2.92 pu��PROTECTION SOLUTION: MEASURE PEAK OVERVOLTAGE� NOT RMS (59I)
19. CONDITIONS FOR FERRORESONANCE DG Must be Separated From the Utility System (islanded condition)
KW Load in the Island Must be Less than 3 Times DG Rating
Capacitance Must be Greater Than 25 and Less Than 500 Percent of DG Rating
There Must be a Transformer in the Circuit to Provide Nonlinearity
20. PROTECTION FUNCTION BEYOND �81O/U,27 AND 59 Total Interconnect Package
Loss of Parallel
Fault backfeed removal
Damaging conditions
Abnormal power flow
Restoration
21. TYPICAL INTERCONNECTION PROTECTION FOR WYE-GROUNDED (PRI.) INTERCONNECTION TRANSFORMER
22. TYPICAL INTERCONNECTION PROTECTION FOR UNGROUNDED (PRI.) INTERCONNECTION TRANSFORMER
23. CONCLUSIONS 1. Green Power DGs Interconnected on Distributions Systems Present Significant Technical Problems and Potential Harzards
2. There are No “Standard” Solutions Only Choices with
Undersirable Drawbacks
3. IEEE 1547 Provides Limited Real Guidance – Simply Cites
Obvious Requirements
4. When Developing DG Interconnection Protection the Technical Issues Raised in this Paper Need to be Addresses
24. THE END
