Transcript Slide 1

Overview OF MULTI Mega
Watt WIND TURBINES and
wind parks
CONTENTS
 Introduction
 Wind Turbine System Overview
a. Conventional Generators
b. Control systems
c. Energy storage and power
smoothing
 Power-Converter Topologies
 Park Connection Systems
 Grid Connection Issues
 Conclusion
 References
INTRODUCTION
 Energy crisis
 Importance of renewable energy resources like
 Electricity can be produced from wind energy by Multi MW
wind turbines
 Wind turbines can be constructed offshore or onshore
 High wind energy potential of offshore wind parks
conventional generators
 Doubly Fed Induction Generators (DFIG)
 Squirrel Cage Induction Generators (SCIG)
 Synchronous Generators (SG)
Doubly Fed Induction Generators
 Widely used for variable speed generation
 Reduced power converters rated 30% of nominal power
 Stator is directly connected to the grid
 Speed range is limited and slip rings are required to connect
the converter
 Gearbox combined mechanism is required
 Fault handling capacity is poor
Squirrel Cage Induction Generators
 SCIGs are of robust construction and mechanically stable
 Rotor consist of metallic bars, resistant to dirt and vibration
 Two full scale power converters are required
 Fault current is limited by grid side converter
 Variable speed operation cannot be obtained using reduced
size power converters
 Cannot be used in direct-driven WECS
Synchronous Generators
 Most efficient Synchronous Generator is direct drive PMSG
 They have lesser power losses
 Noise reduction is achieved as gear boxes are eliminated
 For offshore applications increased oil spills from gear boxes
are eliminated
 More reliable
 Cost , weight and size is more than DFIGs
CONTROL System
 Electrical control system
• Supply of active/reactive power to the grid
• Overload protection
 Mechanical Control System
• Power limitation with pitch adjustment
• Maximum energy capture
• Speed limitation
• Reduction of acoustical noise
ENERGY STORAGE & POWER
SMOOTHING
 Wind speed variability produce unacceptable variations
on the power
 Power smoothing is done by supplying a compensating
power
Pc from an energy storage system
 Pgrid = Pw + Pc
 Energy storage may be based on flywheels, super
capacitors, lead acid batteries etc..
POWER Converter topologies
POWER CONVERTORS FOR DFIG
A back to back converter with converter bridges are used
CONVERTERS FOR OTHER GENERATORS
Full power converters or full scale converters are used.
A parallel array of Converter modules are used for
reliable power output
PARK CONNECTION SYSTEM
1) Parallel Connection
2) Series Connection
3) Cluster Connection
Parallel connection of turbines
Figure shows a parallel connected offshore wind park in
which a high voltage power converter is employed
 Conventional scheme in which turbines are connected to
a low voltage grid
 A high power transformer is needed to increase voltage
to transmission level
 High voltage DC transmission is employed with the help
of converters
 Advantages :
• More reliable
• Can be used for both DC and AC offshore grids
 Drawbacks :
• Weight is more and thus offshore platforms needed
• Investment cost is high
• Lesser efficiency due to losses in low voltage
offshore grid
 Introduction of medium voltage power conversion
systems in WT can eliminate transformers and increase
efficiency.
SERIES CONNECTION OF
TURBINES
The figure shows a series connected offshore WECS which
employs HVDC transmission
 Output of each wind turbine is converted to DC and
then connected in series via HVDC(High Voltage DC)
cables
 Advantages :
• Requires lesser cables and investment cost
• High power transformers are not needed
• Least losses in transmission lines and offshore grid
since HVDC is transmitted
 Drawbacks :
• Losses in power electronic converters
• Variation in wind velocity will cause variation in output
• Less reliable
Cluster connection of wind turbines
Figure shows the cluster connection of wind turbines which
holds the advantages of both series and parallel arrays
compromising between reliability and efficiency.
GRID CONNECTION ISSUES
1. HARMONICS
 At control level modulation techniques and harmonic
controllers are used
 At hardware level filters are used
 Introduction of filters may cause stability problems
2.FAULTS/UNBALANCES
 May create negative sequence components in voltages or
currents
 Reduces life span of generation system
 Controlled by connecting generator stator to grid using full
power converters
CONCLUSION
 Most adopted generator system is DFIG equipped with
a back to back converter since less weight and cost
 For large wind energy systems, direct drive PMSGs are
preferred due to better reliability and efficiency
 Full power converters can reduce the effects of grid
voltage unbalances in the generator
 For offshore wind parks, cluster connection combines
the advantages of both series and parallel connections
References
•A.Mogstad, M.Molinas, P.Olsen and R.Nilsen, “A Power
Conversion System for offshore wind parks”, IEEE transactions on
Industrial Electronics, vol 58, no.4, Nov 2008
•Kaigui Xie, Zefu Jiang and Wenyuan Li, “Effect of Wind Speed on
Turbine Power Converter Reliability Wind”, IEEE transactions on
Industrial Electronics, vol 27, no.1, March 2012
•B.Rabelo and W.Hofman, “Control of an Optimised power flow in
wind power plants with doubly fed induction generators”, IEEE on
Power Electronics, June 2003