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1. Optimal design in wind engineering using cyber-physical systems and non-stochastic search algorithms

   Whiteman, M.L.; Fernández-Cabán, P.L.; Phillips, B.M.; Masters, F.J.; Bridge, J.A.; and Davis, J.R. (July 2018, Structures Conference 2018: Blast, Impact Loading, and Response; and Research and Education)

   This paper explores a cyber-physical systems (CPS) approach to optimize the design of rigid, low-rise structures subjected to wind loading. The approach combines the accuracy of physical wind tunnel testing with the ability to efficiently explore a solution space using numerical optimization algorithms. The approach is fully automated, with experiments executed in a boundary layer wind tunnel (BLWT), sensor feedback monitored by a computer, and actuators used to generate physical changes to a mechatronic structural model. The approach was demonstrated for a low-rise structure with a parapet wall of variable height. A non-stochastic optimization algorithm was implemented to search along the domain of parapet heights to minimize both positive and negative pressures on the roof a of a 1:18 length scale low-rise building model. Experiments were conducted at the University of Florida Experimental Facility (UFEF) of the National Science Foundation’s (NSF) Natural Hazard Engineering Research Infrastructure (NHERI) program. 

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2. The Aerodynamic Behavior of Tall Buildings with Various Side and Corner Modifications under Different Terrain Conditions in a Boundary Layer Wind Tunnel:Subtitle

   https://doi.org/10.17603/ds2-hz4t-rd93  

   Lu, Wei-Ting; Phillips, Brian M; Jiang, Zhaoshuo (January 2025, Designsafe-CI)

   This study investigates the complementary effects of side and corner modification strategies for the aerodynamic performance of tall buildings. A total of 81 doubly symmetric models were examined. High-frequency force balance (HFFB) wind tunnel testing was conducted at the University of Florida’s (UF) boundary layer wind tunnel (BLWT), an NSF-sponsored Natural Hazard Engineering Research Infrastructure (NHERI) Experimental Facility. The 81 models were examined under two approach flow conditions, which are suburban and open terrains. For each flow condition, the models were tested under 10 different wind angles from 0° to 45°. The base responses were recorded using a 6-axis load cell. A total of 1620 tests (81 models × 2 flow conditions × 10 wind angles) were performed in the BLWT at UF. Details are provided in the report document. 

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3. Flow characteristics over flat building roof with different edge configurations for wind energy harvesting: A wind tunnel study

   https://doi.org/10.1016/j.enbuild.2024.114789  

   Li, Shaopeng; Lu, Wei-Ting; Phillips, Brian M; Jiang, Zhaoshuo (November 2024, Energy and Buildings)

   The impact of climate change and global warming makes it imperative to seek sustainable solutions for the built environment. To facilitate the design of future sustainable buildings, wind tunnel tests are conducted in this study to investigate the flow characteristics and wind energy potential over a flat building roof with different edge configurations. Specifically, this study addresses the effect of parapet walls and roof edge-mounted solar panels on the wind flow over a flat-roof tall building. The results show that parapet walls generally slow down the wind speed and increase turbulence intensity as well as skewness angle, which compromises the efficiency of traditional turbine-based wind energy harvesting. On the other hand, the presence of solar panels on the roof edge (or on the top of the parapet wall) further alters flow separation and has the potential to enhance wind energy harvesting over the roof, especially for the solar panel inclined at 30°. In addition to providing valuable data for validating computational fluid dynamics (CFD) simulations, this study could also help to guide the design of wind energy harvesting devices on the building roof and explore the promising synergy with solar panels. 

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4. Automated large-scale and terrain-induced turbulence modulation of atmospheric surface layer flows in a large wind tunnel

   https://doi.org/10.1007/s00348-023-03739-z  

   Mokhtar, Nasreldin O; Fernández-Cabán, Pedro L; Catarelli, Ryan A (January 2024, Experiments in Fluids)

   Longmire, Ellen K; Westerweel, Jerry (Ed.)

   This study leverages a novel multi-fan flow-control instrument and a mechanized roughness element grid to simulate large- and small-scale turbulent features of atmospheric flows in a large boundary layer wind tunnel (BLWT). The flow-control instrument, termed the flow field modulator (FFM), is a computer-controlled 3 m × 6 m (2D) fan array located at the University of Florida (UF) Natural Hazard Engineering Research Infrastructure (NHERI) Experimental Facility. The system comprises 319 modular hexagonal aluminum cells, each equipped with shrouded three-blade corotating propellers. The FFM enables the active generation of large-scale turbulent structures by replicating user-specified velocity time signals to inject low-frequency fluctuations into BLWT flows. In the present work, the FFM operated in conjunction with a mechanized roughness element grid, called the Terraformer, located downstream of the FFM array. The Terraformer aided in the production of near-wall turbulent mixing through precise adjustment of the height of the roughness elements. A series of BLWT velocity profile measurement experiments were carried out at the UF BLWT test section for a set of turbulence intensity and integral length scale regimes. Input commands to the FFM and Terraformer were iteratively updated via a governing convergence algorithm (GCA) to achieve user-specified mean and turbulent flow statistics. Results demonstrate the capabilities of the FFM for significantly increasing the longitudinal integral length scales compared to conventional BLWT approaches (i.e., no active large-scale turbulence generation). The study also highlights the efficacy of the GCA scheme for attaining prescribed target mean and turbulent flow conditions at the measurement location. 

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5. Wind Tunnel Pressure Measurements on a 1:20 TTU-WERFL Building Model Tested under Actively Generated Large-Scale Turbulent Flows:Subtitle

   https://doi.org/10.17603/ds2-2egh-ey26  

   Mokhtar, Nasreldin; Fernández-Cabán, Pedro; Catarelli, Ryan (January 2025, Designsafe-CI)

   This dataset comprises surface pressure and 3D flow velocity data collected in a large boundary layer wind tunnel (BLWT) at the University of Florida (UF) Natural Hazard Engineering Research Infrastructure (NHERI) Experimental Facility (EF). Wind pressures were monitored on the surface of a 1:20 scale model of the Texas Tech University (TTU) Wind Engineering Research Field Laboratory (WERFL) experimental building. The TTU building model was immersed in a wide range of turbulent boundary layer flows with prescribed turbulence intensity and integral length scales. Control of large-scale turbulent scales was enabled by an active multi-fan flow control instrument system termed Flow Field Modulator (FFM). The FFM system enabled the injection of slowly varying (low frequency) turbulent gust structures to achieve significantly greater integral length scales than traditional BLWT approaches. The dataset complies with DesignSafe-CI's best practices for collection and data level curation. Additional documentation and data processing procedures applied to the data are available in the report. 

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