1. IMPACT OF WIND POWER GENERATION ON DISTRIBUTION SYSTEMS�
2. Until Public Utility Regulatory Policies Act (PURPA) in 1978, U.S. utilities were not required to interconnect with small generators.
- Started DG
- Beckwith gets into the interconnection protection business
- Hot until late 1980’s when tax incentive terminated
Late 1990’s DG again hot
- Driven by high utility rates and de-regulation
- DGs can generator cheaper at source of consumption
+ Peak Shaving and Load Following
- Hot until early 2000’s when natural gas prices increased
Late 2000’s Green Power drives resurgence of DGs
- Regulates require utilities to generator a portion of their
power from green sources.
- Set high buy back rate – key driver for Distribution Wind Installations
Brief DG History
3. Types of Wind Power Generators Induction
Asynchronous
Four Types of Wind Generator Design
4. Induction Wind 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
5. DG Interconnection Protection
6. DG Interconnection Protection
9. Ferroresonance can take place between an induction machine and pole top capacitors after utility disconnection from feeder. Ferroresonance can also occur on Synchronous Generators! �
Generator is excited by pole top capacitors if the reactive components of the generator and aggregate capacitors are close. �
This interplay produces non-sinusoidal waveforms with high voltage peaks. This causes transformers to saturate, the non-linearities exacerbate the detection problem
10. FERRORESONANCE�NEW YORK FIELD TESTS –1989�FIELD TEST CIRCUIT
11. FERRORESONANCE�NEW YORK FIELD TESTS -1989�50KW Induction DG, 9KW load, 100KVAR Capacitance and �Wye-Delta Interconnection Transformer�A=2.74 pu B=2.34 pu C=2.92 pu�
12. 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
13. FERRORESONANCE�NEW YORK FIELD TESTS -1989�50KW Induction 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)
14. Asynchronous Generator
16. DG Interconnection Protection
17. DG Interconnection Protection
18. DG Interconnection Protection
19. Ungrounded Primary Transformer Winding
Overvoltage may be caused by Wind Generator when ungrounded primary transformer windings are applied (no ground source) and the Wind Generator backfeeds once utility disconnects
Grounded Primary Transformer Winding
Ground fault current contribution caused by Wind Generator grounded primary transformer windings during utility faults
Source feeder relaying and reclosers responding to secondary ground faults within the Wind Generator facility
20. Ungrounded Interconnection Transformers
21. Grounded Primary Interconnection Transformers
25. CONCLUSIONS 1. Wind Power Generation Interconnected on Distributions Systems Present Significant Technical Problems and Potential Harzards
2. There are No “Standard” Solutions Only Choices with
Undersirable Drawbacks.
3. Over-Voltage 59I is Key Element to Detect Ferroresonance
4. When Developing Wind Interconnection Protection the Technical Issues Raised in this Paper Need to be Addresses
26. THE END
