New Data Compilation Illustrates the Maturity and Declining Cost of Wind Energy

The Lawrence Berkeley National Laboratory announces the release of its Wind Energy Technology Data Update: 2020 Edition. The release provides an updated overview of data and trends in land-based wind energy in the U.S., in the form of a briefing slide deck, a data file, and a series of data visualizations. Highlights this year include:

  • Wind comprises a growing share of electricity supply: More than 9 gigawatts of new wind power capacity, representing an investment of $13 billion, was installed in the U.S. in 2019. Wind energy output rose to more than 7% of the entire nation's electricity supply, more than 10% in fourteen states, and more than 40% in two of those states-Iowa and Kansas. At least 225 gigawatts of wind are seeking transmission interconnection, 5% of which are paired with storage.
  • Wind project performance has increased over time: The average 2019 capacity factor among projects built from 2014 through 2018 was 41%, compared to an average of 31% among projects built from 2004 to 2012 and 25% among projects built from 1998 to 2001.

 

  • Turbines continue to get larger: Improved plant performance has been driven, in part, by larger turbines mounted on taller towers and featuring longer blades. The area swept by the average wind turbine rotor has more than doubled since 2010, compared to a 42% increase in average turbine capacity and a 13% increase in average hub height. Project applications submitted to the FAA suggest that total turbine height (tower plus blade length) will continue to rise in the years ahead.

 

  • Low wind turbine pricing continues to push down installed project costs: Wind turbine prices have fallen to $700-$850/kW. The average installed cost of wind projects in 2019 was $1,440/kW, down more than 40 percent since the peak in 2009 and 2010.

 

 

  • Wind energy prices are below 2 ¢/kWh, on average: After topping out at 7 ¢/kWh for power purchase agreements (PPAs) executed in 2009, the national average price of wind PPAs has dropped to below 2 ¢/kWh-though this nationwide average is dominated by projects that hail from the low-priced interior of the country, where the wind resource is strongest. This sub-2 ¢/kWh average, which is possible in part due to federal tax support, falls below the projected future fuel costs of gas-fired generation. Utility-scale solar PPA prices have also declined precipitously, pressuring wind's competitive position.
  • The levelized cost of wind energy is down 60% from a decade ago: The levelized cost of wind energy, which does not reflect the federal production tax credit, was in the mid-$30/MWh range in 2019, down from the $85-90/MWh range seen a decade ago.
  • The grid-system value of wind varies by location: The value of wind in wholesale power markets is affected by the location of wind plants, their hourly output profiles, and how those characteristics correlate with real-time electricity prices and capacity markets. The market value of wind in 2019 was lowest in the Southwest Power Pool and ERCOT (averaging $15/MWh and $16/MWh, respectively) whereas the highest-value market was CAISO (at $37/MWh). Wind energy PPA prices are generally competitive with these value estimates.
  • The domestic supply chain for wind equipment is diverse: For wind projects recently installed in the U.S., domestically manufactured content is highest for nacelle assembly (>90%), towers (65-85%), and blades and hubs (40-70%), but is much lower for most components internal to the nacelle.
  • Notwithstanding the COVID-19 pandemic, independent analysts forecast continued wind energy growth: With federal tax incentives still available, various forecasts for the domestic market show expected wind power capacity additions of more than 10 gigawatts in 2020, with some contraction anticipated in the years ahead as those tax incentives are phased out.

The briefing slide deck, an Excel-based data file, and a series of data visualizations can all be found at: windreport.lbl.gov