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DIGITAL LIBRARY: SAMPE 2024 | LONG BEACH, CA | MAY 20-23

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New Ideas for Tall Composite Wind Turbine Towers: Adapting to a Sustainable Future

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Title: New Ideas for Tall Composite Wind Turbine Towers: Adapting to a Sustainable Future

Authors: Clement (Clem) Hiel

DOI: 10.33599/nasampe/s.24.0283

Abstract: "Placing a wind turbine on a short tower is akin to positioning a solar panel in the shade. Currently, most towers are monopoles constructed primarily from steel or concrete, or both. However, as wind turbine towers grow taller, they encounter significant challenges related to transporting the more massive tower components. Moreover, the concrete tower foundation constitutes a substantial portion—75%—of the entire onshore wind turbine’s weight, thereby contributing significantly to global CO2 pollution, which should be included into the decarbonization algebra. While offshore towers are more transport-friendly, they still require massive steel substructures, with a substantial part of the associated technology remaining untested for deep waters. This paper aims to resurrect a 130-year-old steel tower construction technology pioneered by the legendary Ukrainian genius Shukov (1858-1939). Specifically, it focuses on hyperboloid-type towers, many of which were installed in the former Soviet Union as water towers and electrical transmission towers. These towers demanded a skilled labor force for installation but never gained popularity in the West. The West favored structurally heavier and more buckling prone steel lattice towers, which had fewer skill requirements. Revisiting and adapting hyperboloid tower technology for composites has revealed new and significant advantages in construction, ease of assembly, and greatly reduced foundation requirements for both onshore and offshore wind turbines. The type of advanced composites construction that is elucidated in this paper goes a long way to meet the performance and sustainability criteria that are called for in the DOE Earthshots and Windshots programs."

References: [1] Carrara, S. et al., “Raw Materials Demand for Wind and Solar PV Technologies in the Transition Towards a Decarbonized Energy System. Luxembourg Publication Office of the European Union, 2020. [2] Walt Musical, Offshore Wind Technology 101, NREL Webinar Series, April 7, 2021 [3] Land-Based Wind Market Report: 2023 Edition, U.S. Department of Energy-Office of Energy Efficiency & Renewable Energy, 2023. [4] Eric Smith, Keystone Tower Systems, “Next Generation Tower for the Next Generation of Wind power.” WESE Workshop, August 31, 2022. [5] Levine, Aaron and Cook, Jeff, “Transportation of Large Wind Components: a permitting and regulatory review,” Technical Report NREL/TP-6A20-66998, 2016. [6] Brian Ti and Matt Johnson, “A Variety of Solutions is Currently Available for Todays Common Wind-Turbine Foundation Challenges, with more Solutions on the Horizon,” Wind Systems, August 2023. [7] NREL, “Large Scale Wind Power in the United States-Assessment of opportunities and Barriers, September 2010. [8] Paul Dvorak, “An Old Twist to New Tower Construction,” Wind power Engineering Development, Oct 7, 2014. [9] BFT International, “Innovative Precast Concrete Component Concept with Optimized Joint Design for Especially Tall Wind Turbines. [9] Eric Smith, “On-Site Tall Towers for Low-Cost Wind power.” [10] Ramona du Houx, “#100 million Investment gives Maine’s Floating Offshore Wind Turbine Project a Second Wind, August 1, 2020. [11] Matthias Beckh, “Hyperbolische Stabtragwerke-Suchov’s Gitterturme als Wegweiser in Den Modernen Leichtbau,” Edition Detail, 2012 [12] Belles, A.A. and Soare, Mica, “Les Paraboloides Elliptique et Hyperbolique dans les Constructions, Dunod, 1967.

Conference: SAMPE 2024

Publication Date: 2024/05/20

SKU: TP24-0000000283

Pages: 26

Price: $52.00

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