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Wind Turbine LabMuseum of Science, Boston
APA National ConferenceUrban Wind April 10, 2011
Marian TomusiakWind Turbine Lab Analyst
Museum of Science, Boston
Proven
Windspire
Swift
Skystream
AVX1000s
Why are Wind Turbines on the Museum of Science Roof?
• Wind energy was one option explored as part of our
Green Initiative, which includes conservation, recycling, and other renewable energy sources.
• Site, wind and structural assessment showed it was impractical to scale wind turbines for Museum’s electrical load (9GWh/year)
• Little data on small-scale wind turbines are available from the built environment
Project became a Consumer Test Lab
• Testing a variety of commercially available small-scale wind turbines roof-mounted in our urban environment
• Serving as a community resource for both professionals and the general public– A lesson in critical thinking about energy technology– A practical demonstration and laboratory; experience; data
• An experiential part of a new Museum exhibit
• A landmark for Boston, Cambridge, New England
• A statement about the importance of renewable energy
Complex Site
WIND
WIND
VIEWS
VIE
WS
VIE
WS
VIEWS
PUBLIC SAFETY
STRUCTURE
But wait, there’s more!
Boston
Cambridge DCR Land
Wetland
FAA / hospital / military flywayHistoric District
(MA, Boston & Cambridge)
Birds? Bats? Endangered species?
Neighbors
Implementation
2006 2007 2008 2009 2010
Design & Permitting
Str. Eng.Test l
ab concept
Con-tracts
Ph. I
Ph. II
Commissioning
Wind Study
Windspire Energy
Windspire 1.2kW @11m/s 10 m tall
Cascade Engineering
Swift 1kW @11m/s 2.1 m diameter
Southwest Windpower
Skystream 3.72.4kW @13m/s 3.7 m diameter
Proven Energy
Proven 6 6kW @12m/s 5.5 m diameter
AeroVironment
AVX1000 5 x 1kW @13m/s 1.8 m diameter
The Turbines
Five different types of small-scale wind turbines installed on the roof of the Museum in 2009 Feeds into our
Catching the Wind
Exhibit
A consumer test lab for both professionals and the general public. Data is recorded and shared.
The Lab
2010 Update
• In 2010, the wind turbines produced
4,409 kWh of clean electricity
for the Museum.– 60% of average MA home (2009 figures)
– Museum requires > 1,000 times MA house
• No issues with noise, vibration, ice throw, flicker, birds, bats, other environment problems*. Our neighbors like them, too. (*Update April 12, 2011 –one bird strike in 2-year Lab history.)
• Not cost effective at this site – Roof installation costs were high
– The Museum does not have a good wind regime
– Some turbines underperforming; investigation continues
Overall production (2010)
Low cut-out speed; out of service for 4 months out of 12
2%1743.123.4Windspire
Directional. Improved after repairs, but underperforming
5%3393.726.7AVX1000
Poor site; unable to evaluate true behavior
2%1152.933.0Swift
More energy than the others combined, but underperforming
31%22592.695.1Proven
As expected in this wind profile21%15223.0141.6Skystream
NotesMA Home
(7416 kWh)
Total Usable Energy
kWh
AvgWind
Speed (m/s)
Energy/ Swept
Area
kWh/m2
TURBINE
Skystream Power Curves
Actual vs. Manufacturer’s
Of the wind turbines installed at the Museum, Skystream is the closest to “plug and play.”
Southwest Windpower’s new model will be Skystream 600.
It’s
not s
o w
indy
muc
h of
the
time.
We
get o
ur p
ower
whe
n it’
s w
indy
.
kWh
%
Time
0%
1%
2%
3%
4%
5%
6%
7%
8%
Percent Elapsed Time
Skystream Wind DistributionLower and Higher Wind Buckets
0 - 10 MPH
10 - 20+ MPH
0
50
100
150
200
250
Energy kWh
Skystream Energy per MonthAvg 127 kWh/Month; Total 1525 kWh
Proven Power Curves
Actual vs. Manufacturer’s
Proven has the largest generator and rotor of the Museum turbines.
It produces more energy than all the others combined, yet it is underperforming expectations.
Investigation of system components continues.
Swift Power Curves
Actual vs. Manufacturer’s
Swift is poorly sited for prevailing southern winds.
Significant increase in energy generation in strong north winds.
Evaluating increase of tower height.
TRC/Ansys Computational Flow Model
Wind
AVX1000 Power Curves5 Units
Actual vs. Manufacturer’s
Reoccurring inverter faults throughout 2010.
Tail shroud repaired May19; power turned off by mistake until June 3
Inverter down mid-November to mid-January.
April 2011 Update:
Inverter settings changed January 2011; fix has eliminated inverter faults. Turbines still underperforming.
Windspire Power Curves
Actual vs. Manufacturer’s
Cut-out logic reduces access to high energy wind.
Due to inverter issues, Windspire shut down Jan, Feb, most of Aug, half of Sep, end of Dec.
April 2011 Update:Will soon replace with Windspire High Wind model with improved inverter and generator.
Cost Breakdown ($350K total)
• Hidden costs associated with being “ground breaking,”coping with surprises in permitting, engineering, installation, commissioning
• Maintenance is not expensive, our regular facilities people can handle most of the operations (do it themselves or coordinate with vendors)
Summarizing Issues
• Wind regime (generally & different locations that were suboptimal)
• Bugs (Windspire inverter, Swift braking problem)
• “Features” (Windspire high-wind shutdown)
• Installation errors (Proven anemometer, AVX inverter settings)
• Location/failure to account for building effects (Swift)
• Unknowns (Proven power curve, AVX power curve)
• Lab vs. single installation (complexity, conservative foundations)
Evaluating Wind Turbines
• “Rated Power” tells you about size of generator and rotor, not how much energy you can expect. Wind speed at rated power is not yet standardized across market.
• Energy produced depends most strongly on wind speed (cubed)– How fast, how often: Detailed anemometer study at hub height– Building effects: CFD analysis may be wise
• Return on Investment relies heavily on installation costs and project scale.– At MoS cost of structural steel was single largest capital cost – almost
one quarter of entire $350K project cost• Federal & state financial incentives are available.
– Consider scale of expected energy wrt your building electrical load.• Consider expected future costs of electricity generated from fossil
fuels
Actionable items
• Be clear and realistic about your goals (Energy? Economics? EcoBling? Green?)
• Carefully investigate wind/building interaction
• Take care with structure and public safety
• Be aware of the cost of building integration (even with new construction)
• Carefully think through your plan for vibration risk management and other uncertainties.
• Evaluate Scale …
– Wind speed generally increases with height
• Roof space?
• Ground installation?
– Large buildings mean high electricity needs
View from Museum of Science Garage Roof One Science Park, Boston MA
Proven
Windspire
Swift
Skystream
AVX1000s
mos.org/WindTurbineLabmtomusiak@mos.org
Additional Slides
The TeamMuseum of ScienceDavid Rabkin, Director for Current Science and TechnologyPaul Ippolito, Director, FacilitiesSteve Nichols, Project Manager, IITMarian Tomusiak, Wind Turbine Lab Analyst
Boreal Renewable Energy DevelopmentBob Shatten, PrincipalTom Michelman, PrincipalAlex Weck, PrincipalMichael Alexis, Principal
ANSYS/TRCValerio Viti, Sr. Fluids SpecialistChris DesAutels, Sr. MeteorologistLloyd Schulman, Sr. Meteorologist
Apterra TechnologiesTed Schwartz, Principal
Nexamp, Inc.Will Thompson, VP, Integration
Phelan EngineeringPaul Phelan, Jr., P.E.
Richard Gross, Inc.Richard Gross, P.E.
Rubin and Rudman, LLPKeren Schlomy, Partner
Shaw Welding CompanyRick Shaw, President/CEO
Titan Electric CorporationJohn Gill, President
Renewable Energy Trust / Mass CECDick Tinsman, now with Criterium Engineersrtinsman@criterium-engineers.com
Rapheal Herz, now with Johnson ControlsRaphael.Herz@jci.com
Jim Christo, now with Alteris Renewablesjchristo@alterisinc.com
Marybeth Campbell, now with the MassachusettsClean Energy Center
MCampbell@MassCEC.com
Christie Howe, Massachusetts Clean Energy Centerchowe@MassCEC.com
drabkin@mos.orgpippoloto@mos.orgsnichols@mos.org
mtomusiak@mos.org
bshatten@boreal-renewable.comtmichelman@boreal-renewable.com
aweck@boreal-renewable.commalexis@boreal-renewable.com
valerio.viti@ansys.comcdesautels@trcsolutions.comlschulman@trcsolutions.com
ted.schwartz@apterratech.com
wthompson@nexamp.com
paulphelan@comcast.net
rgross@ieee.org
kschlomy@green-mail.org
rick@shawwelding.com
jgill@titan-electric.com
Underwriters
Kresge Foundation
Cascade Energy
Museum of Science and its supporters
And the Extended Project Team
Wind Resource Assessment
• Multiple locations for measurement
– Parapets
– Tower
• 3-month study correlated local data to Logan to estimate local annual pattern
• Winds recorded for another 9 months
• Moved anemometer 1 to future Proven location
1
3 2
4
5
Data Collection
• Apterra Hawkeye samples data every 2-3 seconds, after
inverters, transformer
• Data recorded:
– Wind Direction
– Power & Energy for each turbine
– Wind Speed for each turbine’s anemometer
• Data aggregated into 10-minute intervals, includes wind speed and power averages, min, max, std dev
• Continuous data collection since 8Oct09
– Commissioning issues meant some inaccuracies over several weeks
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