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1. Surrogate-based cyber-physical aerodynamic shape optimization of high-rise buildings using wind tunnel testing

   https://doi.org/10.1016/j.jweia.2023.105586  

   Lu, Wei-Ting; Phillips, Brian M.; Jiang, Zhaoshuo (November 2023, Journal of Wind Engineering and Industrial Aerodynamics)

   This study proposes a surrogate-based cyber-physical aerodynamic shape optimization (SB-CP-ASO) approach for high-rise buildings under wind loading. Three components are developed in the SB-CP-ASO procedure: (1) an adaptive subtractive manufacturing technique, (2) a high-throughput wind tunnel testing procedure, and (3) a flexible infilling strategy. The downtime of the procedure is minimized through a parallel manufacturing and testing (llM&T) technique. An unexplored double-section setback strategy with various cross-sections and transitions positions is used to demonstrate the performance of the proposed procedure. A total of 173 physical specimens were evaluated to reach the optimization convergence within the reserved testing window. Further analysis of promising shapes considering multiple design wind speeds is suggested to achieve target performance objectives at various hazard levels. Practical information on setback and cross-section modification strategies is discussed based on the optimization results. In comparison with a square benchmark model, the roof drifts for promising candidates with similar building volumes are reduced by more than 70% at wind speeds higher than 50 m/s. This procedure is expected to provide an efficient platform between owners, architects, and structural engineers to identify ideal candidates within a defined design space for real-world applications of high-rise buildings. 

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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. Cyber-physical systems approach to optimization in wind engineering: parapet wall design

   Whiteman, Michael L; Phillips, Brian M; Fernández Cabán, Pedro L; Masters, Forrest J; Rice, Jennifer A; Davis, Justin R. (May 2017, The 13th Americas Conference on Wind Engineering (13ACWE))

   ABSTRACT: This paper explores the use of cyber-physical systems (CPS) for optimal design in wind engineering. 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 high-performance computer, and actuators used to bring about physical changes in the BLWT. Because the model is undergoing physical change as it approaches the optimal solution, this approach is given the name “loop-in-the-model” testing. The building selected for this study is a low-rise structure with a parapet wall of variable height. Parapet walls alter the location of the roof corner vortices, alleviating large suction loads on the windward facing roof corner and edges and setting up an interesting optimal design problem. In the BLWT, the model parapet height is adjusted using servo-motors to achieve a particular design. The model surface is instrumented with pressure taps to measure the envelope pressure loading. The taps are densely spaced on the roof to provide sufficient resolution to capture the change in roof corner vortex formation. Experiments are conducted using a boundary BLWT located at the University of Florida Natural Hazard Engineering Research Infrastructure (NHERI) Experimental Facility. The proposed CPS approach enables the optimal solution to be found quicker than brute force methods, in particular for complex structures with many design variables. The parapet wall provides a proof-of-concept study with a single design variable that has a non-monotonic influence on a structure’s wind load. This study focuses on envelope load effects, seeking the parapet height that minimizes roof and parapet wall suction loading. Implications are significant for more complex structures where the optimal solution may not be obvious and cannot be reasonably determined with traditional experimental or computational methods. KEYWORDS: Cyber-physical systems, optimization, boundary-layer wind tunnel, parapet wall, NHERI 

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4. 1:100 Scaled Buildings with Perpendicular Surfaces:Subtitle

   https://doi.org/10.17603/ds2-j7cj-hk03  

   Mohammadjani, Chia; Zisis, Ioannis (January 2024, Designsafe-CI)

   This dataset includes files from an extensive wind tunnel study of stepped-roof buildings conducted at the Wall of Wind facility at Florida International University. The aim of the study was to clarify the key factors that affect aerodynamic forces on complex architectural shapes. While ASCE7-22 offers a guideline for wind loads on building components and roofs, it falls short of providing the detailed data needed by engineers to calculate wind loads on the surfaces of stepped-roof buildings. This study fills that gap. The main subject under investigation was the impact of wind loads on different building geometries such as stepped roofs, U-shaped buildings, podium structures, and low-rise buildings with carport extensions. This involved a detailed examination of how various structural features influenced wind pressure distribution, with a specific emphasis on understanding the behavior of wind forces on these models. The outcomes include a series of detailed findings on wind pressure coefficients for each building model. These results offer insights into the wind load characteristics for different architectural forms, contributing to a better understanding of structural behavior under wind forces. The study findings will furnish additional data to enable engineers and scholars to more accurately assess and comprehend wind loads on buildings with multi-level roofs. The dataset includes diagrams of each model’s geometry and wind pressure data. The data highlighted key areas where wind pressures were most significant and how different building features either mitigated or exacerbated these pressures. The data gathered from this study can be reused in multiple ways. It can serve as a reference for designing wind-resilient buildings, particularly in regions susceptible to strong winds or hurricanes. The empirical data can also aid in validating and refining computational models for predicting wind loads on buildings. Additionally, it can be used in academic research for further exploration into wind engineering, urban planning, and architectural design, potentially leading to innovations in building safety standards and construction practices. 

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5. Methodologies to mitigate wind-induced vibration of tall buildings: A state-of-the-art review

   https://doi.org/10.1016/j.jobe.2020.101582  

   Jafari, M; Alipour, A. (July 2020, Journal of building engineering)

   This paper reviews the state-of-the-art and –practice on various methodologies developed to control the wind-induced vibration of tall buildings. Tall buildings experience wind-induced vibration in the along- and across-wind directions depending on the wind direction, building shape, height, and structural properties. It is possible to control the wind response of buildings through passive, active, and semi-active systems. Damping systems, which are widely used to reduce the structural vibrations, are reviewed, and their performance in alleviating the building vibration is discussed. It was found that the application of conventional dampers needs to be reassessed to ensure their efficiency in dissipating the energy, especially caused by wind loads. Specific attention has been given to the aerodynamic modification of building shapes considering their effectiveness and high popularity within the wind engineering community. A comprehensive review of the existing wind tunnel experiment and Computational Fluid Dynamics (CFD) studies are conducted here to present the past and recent achievements on the response mitigation of tall buildings. A comparative study on the performance of different systems has been provided that can provide a commencing point for future studies. The existing challenges and their solutions are explained, and suggestions for future studies are proposed. It is expected that the information provided in this paper will facilitate further research in the area of wind-induced vibration mitigation approaches of tall buildings. 

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