Evolution of Modern Wind Turbine Rotors · 2011. 1. 13. · Evolution of Modern Wind Turbine Rotors...
Transcript of Evolution of Modern Wind Turbine Rotors · 2011. 1. 13. · Evolution of Modern Wind Turbine Rotors...
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Evolution of Modern Wind Turbine Rotors
Peter JamiesonFebruary 2004
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Personal History
• In wind industry since 1980.
• With Garrad Hassan (GH) since 1991 – foundermember of their Scottish office.
• Previously with James Howden of Glasgow who manufactured wind turbines from 1980 – 1988.
• Currently heading “Special Projects” department inGH with involvement in innovative designs of windturbine and component developments. Alsoinvolved in technology review for government, windindustry and commercial organisations.
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Overview
1. Evolution of blade design
2. Blades in the context of machine design
3. Future
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Evolution
1. Size
2. Materials and processes
3. Structure and aerodynamics
4. Testing and certification
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Blade Length, 3.5 m 1980 → 54 m 2004
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Growth of Commercial Wind Turbines
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1980 1985 1990 1995 2000 2005
year
diam
eter
[m] Year Turbine
Power Rating [kW]
Diameter [m]
1981 Vestas V15 55 151986 Vestas V19 90 191990 Vestas V36 500 361996 Enercon E66 1500 661998 Jacobs MD70 1500 701999 Tacke 1.5sl 1500 772000 Vestas V80 2000 802002 GEWind 3.6MW 3600 1042003 Enercon E112 4500 114
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Materials and Processes
• glass polyester, wet, hand lay-up
• wood epoxy
• glass epoxy resin infusion
• glass epoxy prepregs
• carbon reinforcement
• carbon spar
• carbon blades
• thermoplastics
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Ecological performanceMaterialMaterial DescriptionDescription DensityDensity EnergyEnergy Flexural Flexural Energy per Energy per
StrengthStrength unit load unit load kg/mkg/m33 kWh/kg kWh/kg MPaMPa kWh/NkWh/N
Aluminium Extrusions 2700 60 290 559
Concrete Walls (compressive 2200 0.33 30 24loads only)
Reinforced Concrete Beams 2400 0.7 30 56
Timber Glulam, temperate softwood 500 1.33 14 48
Steel Grade 43 sections 7850 11.5 275 328
GRP Glass/Polyester 1:1 1950 26.4 150 343
CFRP 1900 60 600 190Source: Chris Hornzee-Jones
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Blade Manufacture at NEG Micon
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Blade Manufacture at Bonus
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Structure and Aerodynamics
• Which comes first? Design democracy overdue.
• High lift and low lift aerofoils
• Cylinder versus aerofoil
• Aeroelastic design
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Rotor Blade “Add-ons”
• Stall strips
• Vortex generators
• Gurney flaps
• Edgewise vibration dampers
• Dinotails
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Testing and Certification• Testing – absolutely vital, an obvious but slowly learned truth
• Certification – development of industry standards reflectsmaturing of the industry
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Blade Testing at LM
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Blades in the Wind Turbine Design Context
1. Cost of Energy
2. Up-scaling
3. Structural flexibility
4. Control of loads
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Cost of Energy Context
• Blades are about 18% of wind turbine ex works cost
• The turbine is about 55% of lifetime capital cost
• Hence blades amount to about 10% of total lifetime cost
• Thus 1% energy gain trades with 10% blade cost reduction
• It may pay to introduce more intelligence and actuator capability into blades rather than simply to pursuemanufacturing cost reduction
• This means – larger rotors with better system load management,possibly through added rotor cost and complexity
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Blade Mass Scaling – All Sources
y = 0.3742x2.2898
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0.0 20.0 40.0 60.0 80.0 100.0
rotor diameter [m]
blad
e m
ass [
kg]
AbekingAerolamNOIATVPolymarinEurosLMPower (LM)
NOI 2.05ATV 3.07Polymarin 2.76Euros 2.92LM 2.30
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Blade Mass Scaling – Big Blades Only
M = 0.0000561D2.943
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Rotor Diameter [m]
Bla
de M
ass [
tonn
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Shaft Mass Scaling
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rotor diameter [m]
shaf
t mas
s [kg
]
Ms = 0.01698D3
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Hub Mass Scaling
Mhub = 0.0057x3.45
05000
100001500020000250003000035000
0 20 40 60 80 100
diameter [m]
norm
alise
d m
ass [
kg]
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Scaling of Turbine Price/kW
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0 20 40 60 80 100diameter [m]
spec
ific
cost
[$/k
W]
land based designs
offshore, higher tip speed
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Significance of Scaling Trends
• Increasing cost/kW both for blades and complete turbinesystem points to economic limits for up-scaling
• Blades up-scale with geometric similarity and hence cubicallybecause of a match between the designing aerodynamicloading and structural section modulus
• Self weight loading must not be allowed to become a driver orup-scaling economics will be yet worse
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Structural Flexibility
• Has been a “holy grail” of wind turbine cost reduction
• Myth of the Carter wind turbine design
• Lessons and insights
• Natural path to more flexible blades
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Structural Flexibility – Impact on Tower Top Mass
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0 10 20 30 40rotor diameter [m]
norm
alis
edm
ass
[kg]
AOC
Carter
AWT
AOC
AOC
Carter
AWT
AOCtrend line of European data
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Carter 300 and WEG MS4 Wind Turbine
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Carter Design Concepts
• Stimulated interest in routes to lower mass and lower costrotors and turbines
• Not the most commercially successful wind turbine but way out front in – engineering discussion hours/rated kW
• Widespread confusion about the influence of structural flexibility on system mass
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More Flexible Blades
• Useful potential cost reduction in downwind flexible rotorsbut easily overestimated
• Popular fallacy that free yaw saves significant cost in theyaw system
• Avoid cost centre of “extreme” flexibility which requiresCarter-like solutions of spar/shell composite hinge
• Glass is an automatic choice for flexible blades because of its high strain capability but, surprisingly, carbon may be themore logical material for very flexible downwind rotors
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Future
1. Bigger blades but only if offshore market growsas predicted
2. More carbon – but in what form?
3. More adaptable rotors