Wind Research
Aerodynamics Research To Improve Large Wind Turbine Performance and Reliability

Aerodynamics Research To Improve Large Wind Turbine Performance and Reliability

NREL's Aerodynamics of Large Turbines (ALTius, which is Greek for “higher”) project is driving knowledge of aerodynamics of large turbines higher.

As part of ALTius, NREL is providing up to $6.25 million to industry and academia to generate scientific data that can enable the design and development of cost-effective, high-performance large commercial wind turbines.

Important Dates

Jan. 17, 2025: Request for proposals opened

April 7, 2025 (extended from March 17, 2025): Proposal submissions due

Spring 2025: Selections announced

Modern offshore wind turbines are the largest rotating machines ever built by humankind. As these turbines grow larger to capture more wind energy (beyond 10 MW of capacity), they offer significant opportunities for cost reduction but also expose knowledge gaps that increase the risk to their performance and reliability.

To address these challenges in the field of aerodynamics, NREL, on behalf of the U.S. Department of Energy's Wind Energy Technologies Office, has issued a request for proposals (RFP) from industry and academia to advance necessary data and tools that can accelerate the development of cost-effective, high-performance large commercial turbines. The RFP will offer up to $6.25 million in funding to eligible entities.

The Focus of This Research

The research targets two key knowledge gaps:

Understanding aerodynamics at large scales
Large wind turbines of 10–15 MW and beyond—such as those being deployed offshore today—operate in unique aerodynamic conditions (high Reynolds numbers). The current lack of high-quality, open-source experimental data to characterize the behavior of airfoils (the curved surface of a wind turbine blade) and validate the tools used to design and analyze them creates uncertainties. Generating these data will improve the accuracy of design tools, leading to the development of more reliable and efficient turbines.
Addressing loads in nonoperational conditions.
Large turbine blades can face significant stress from vibrations when turbines are in nonoperational states (when idling or parked), such as during installation, maintenance, or in extreme weather events. Current simulation techniques struggle to predict unsteady, three-dimensional (3D) aerodynamic and aeroelastic effects, leading to over-designed and costly blades or designs that are vulnerable to damage under certain conditions.

By providing validation-quality, open test data to the wind R&D community, the selected projects will:

Enhance the reliability and aerodynamic performance of large wind turbines
Accelerate and assure the reduction of the levelized cost of wind energy by enabling the design of turbines that can reliably and cost-effectively avoid or withstand excessive loads and vibrations.

Funding Details and Eligibility

NREL will award up to $6.25 million to U.S.-based research teams from industry and academia, with funding distributed across two topic areas. This initiative represents a significant investment in the aerodynamics of large-scale wind turbine technology, fostering innovation and collaboration between industry and academia to overcome technical barriers.

Eligible teams must be a domestic institution for higher education, a for-profit or nonprofit entity, a state or local governmental entity, or a Tribal Nation.

Topic Areas

Topic Area 1: High Reynolds Number Airfoil Aerodynamics Validation Datasets

Applicants will design and carry out experiments to generate and disseminate high-quality data about how airfoils perform at a specific range of conditions that match those experienced by large wind turbines. Key aspects include:

Primary testing: The main testing will take place at a national research facility, capable of providing crucial data to validate, develop, or improve computer models that can predict aerodynamic performance, scaling, and robustness accurately.
Secondary testing: Conducted in lower Reynolds number, even ‘quieter’, wind tunnels to expand the datasets, these tests will cover sensitivity to turbulence, wind hitting the airfoils at extreme angles, and any other experiments that could improve understanding of relevant flow physics.
Funding: The total funding for this topic is $4.75 million to the applicant, with an additional approximately $3 million from DOE directly supporting the national test facility's (the National Full-Scale Aerodynamics Complex’s of NFAC's) operations.

Topic Area 2: Aerodynamic Characterization of Nonoperational Loads Phenomena

Applicants will conduct experiments to characterize how wind turbine blades behave aerodynamically and produce publicly available validation-quality datasets that improve or develop computer models for predicting how blades behave when idling, parked, and/or in extreme weather. Key aspects include:

Testing scenarios: Experiments can use blades that are scaled down or full size, rigid or aero-elastically representative. Tests will need to capture the unsteady (changing) 3D aerodynamics of the blades in relevant situations and provide complete descriptions of all boundary and initial conditions. Additional tests on airfoil sections may also be designed to replicate the key conditions causing these vibrations.
Funding: Approximately $1.5 million is allocated for this topic, with one award expected.

Learn more about the topic areas and solicitation process in the latest version of the request for proposals document.

Frequently Asked Questions

The following are a few examples of general FAQ. For additional answers to FAQ, please see Amendment No. 1 of the RFP or use the contact information below.

What is the limitation on participation in multiple proposals for a given institution?
Proposals for the two topic areas will be treated independently.

Can this be a single principal investigator effort or do I have to be a part of a team? If a team, do I need to use the Teaming Partner List or form the team myself?
Team composition is the applicant’s responsibility. A single organization proposal is as valid as a multi-organization one.

Although education is not a priority for this solicitation, are we permitted to involve graduate student(s)?
Yes. It will be the applicant’s responsibility to account for constraints in terms of access and presence in testing activities at U.S. government facilities.

The following are a few examples of Topic Area 1 FAQ. For additional answers to FAQ, please see Amendment No. 1 of the RFP or use the contact information below.

Who will own the NFAC models after the test and therefore be responsible for their disposal/storage?
NREL.

Is the secondary test mandatory? If yes, is it necessary to test all three airfoils or just one?
Yes, and yes. Secondary testing for the two modern airfoils is mandatory.

What administrative and/or logistical support can we expect from NREL in the test at NFAC?
An NREL-led team will provide program oversight and limited technical consulting assistance but no direct logistical support (e.g., building or transporting test articles).

The following are a few examples of Topic Area 2 FAQ. For additional answers to FAQ, please see Amendment No. 1 of the RFP or use the contact information below.

How many awards are expected for Topic Area 2?
One.

How will the collected data be used to improve industry design codes?
These open datasets will be used in validation of a range of (government-, academia-, and industry-developed) modeling and simulation tools to improve their fundamental physics capture capabilities.

Is there a specific person (e.g., another email or a phone number) who I can contact in regard to NFAC facility cost estimates, availability, and installation details for Topic Area 2?
Please reach out to Joe Sacco, NFAC Deputy Director.

Contact

Contact ALTius with further questions about the ALTius RFP.

Industry and academic organizations interested in forming teams and looking for partners can put their names into a Microsoft form teaming list. For a current list of teams looking for partners, please contact ALTius. We expect applicants generally to bring expertise in and, hence, select for themselves appropriate roles in:

Aerodynamic instrumentation and testing (wind tunnels)
Test system integration and management
Aerodynamic design analysis
Aerodynamics/aeroelasticity of wind turbines
Physics-based model development and validation.