Effect of cross beam in Vortex-Induced vibration and flutter analysis at large attack angle for the twin-deck bridges Puja Haldar and Somnath Karmakar
Abstract; Full Text (4958K) .	pages 395-409.	DOI: 10.12989/was.2024.39.6.395

Abstract
Twin deck bridges are often required to construct, particularly for large spans and one-way movement of vehicles. The gap between the two decks is the most critical in the combined deck/bridge response. Nevertheless, this twin deck is vulnerable to vortex-induced vibration because the central slot modifies the flow profile surrounding a bridge girder. In addition, the large spans are also susceptible to the flutter effects of wind. Therefore, the study uses computational fluid dynamics to explore the impact of twin decks with cross beams on aerodynamic coefficients, flutter instability, and vortex-induced vibration. The features of vortex characteristics have been investigated and inferred in the current study for two structures: with and without cross beams at various effective angles. The research findings reveal that the vibrating frequency at the lock-in region is identical for installing cross beams. However, in the structure where the cross beam has not been used, the vibrating frequency exceeds the lock-in frequency at every effective angle. Still, the flow that passes through the cross beam extracts considerable energy from the flow field. The research findings revealed that the vibrating frequency at the lock-in region is identical for installing cross beams. This installation also beats the flutter instability by increasing critical flutter, which makes it a popular idea for mitigation purposes. Therefore, in these regards, the framework and solution are sustainable for bridge responses under vortex and flutter domains.

Key Words
computational fluid dynamics; flutter; twin-deck; vortex-induced vibration

Address
Puja Haldar: Department of Civil Engineering, National Institute of Technology Durgapur, West Bengal 713209, India

Somnath Karmakar: Department of Civil Engineering, National Institute of Technology Durgapur, West Bengal 713209, India

Impact of wind on high-rise: A review on wind induced vibrations, aerodynamic design, pedestrian level wind effects Vinayak Gautam and Neelam Rani
Abstract; Full Text (3069K) .	pages 411-433.	DOI: 10.12989/was.2024.39.6.411

Abstract
The rise in the construction of high-rise buildings can be attributed to a number of factors, including the economic rise of nations, the substantial rural-to-urban migration trend, and innovative technological breakthroughs in construction that facilitate the growth of high-rise construction. All these factors have contributed to the upward trajectory of high-rise building construction. However, increase in height of buildings make it susceptible to the undesired effects of high-speed winds. Different aerodynamic modifications are used to mitigate the aerodynamic oscillations that are caused by the wind. This article aims to provide a review on different modes of wind induced vibrations in high-rise buildings, aerodynamic modifications in high-rise buildings to mitigate wind induced loads and pedestrian level wind studies. The effectiveness of these modifications varies with the degree of modification applied. Helical buildings and tapered buildings show improved wind resistance with increase in angle of twist and tapering ratio. Small corner modifications up to 10% are more effective than larger corner modifications. Aerodynamic modifications also improve the pedestrian level wind environment around high-rise buildings with corner modifications reducing the shear layers and thus subsequently reducing the high wind speed regions whereas setbacks have exhibited reduction in wind velocities by up to 28-30% in front of them.

Key Words
aerodynamic modifications; high-rise; pedestrian level wind; wind induced vibration

Address
Vinayak Gautam: Department of Civil Engineering, Dr. B.R. Ambedkar National Institute of Technology, Jalandhar, Punjab, 144008, India

Neelam Rani: Department of Civil Engineering, Dr. B.R. Ambedkar National Institute of Technology, Jalandhar, Punjab, 144008, India

Enhanced wind velocity imputation near building structures using advanced machine learning techniques Istiak Ahammed, Sujeen Song, Gang Hu, Jinwoo An and Bubryur Kim
Abstract; Full Text (4075K) .	pages 435-451.	DOI: 10.12989/was.2024.39.6.435

Abstract
The evaluation of instantaneous wind flow patterns nearest to building architecture is crucial to ensuring structural stability, architectural integrity, and pedestrian safety. Particle image velocimetry (PIV), a technique for studying fluid flow by tracing particles, provides accurate predictions of instantaneous wind velocities (IWV). However, PIV encounters challenges in specific regions due to laser light-based experimentation, leading to missing data. Consequently, investigating the wind circulation pattern around buildings becomes more challenging. Numerous ML techniques have been employed to impute missing wind velocities at random building locations with minimal structural impact. This paper focuses on addressing this concern by utilizing a machine learning (ML) approach that focuses on estimating unmeasured values in critical areas near buildings. We employ three distinct ML models: the generative adversarial imputation network (GAIN), multiple imputations by chained equations (MICE), and neighbor distance imputation (NDI) to estimate missing values around building structures. Our results indicate that the GAIN technique achieves a remarkable balance, displaying the lowest average mean square error of 0.073 and the highest average R-squared error of 0.965. Furthermore, it effectively captures the distribution of measured values and provides reliable data for evaluating aerodynamic characteristics and ensuring structural safety.

Key Words
deep learning; generative adversarial imputation network; machine learning; structural safety; urban wind flow analysis; wind velocity imputation

Address
Istiak Ahammed:Department of Robot and Smart System Engineering, Kyungpook National University, 80, Daehak-ro, Buk-gu, Daegu, 41566, South Korea

Sujeen Song:Earth Turbine, 36 Dongdeok ro 40 gil, Jung gu, Daegu, 41905, South Korea

Gang Hu:School of Civil and Environmental Engineering, Harbin Institute of Technology, Shenzhen 518055, China

Jinwoo An:Department of Civil Engineering, College of Engineering and Computer Science,
The University of Texas Rio Grande Valley, Edinburg, Texas 78539, USA

Bubryur Kim:School of Space Engineering Sciences, Kyungpook National University, 80, Daehak-ro, Buk-gu, Daegu, 41566, South Korea

Effect of wrinkling deformation on the wind-induced responses of inflated membranes Xiaofeng Wang, Xujing Cao and Qingshan Yang
Abstract; Full Text (4927K) .	pages 453-467.	DOI: 10.12989/was.2024.39.6.453

Abstract
Inflated membranes are a kind of flexible structure very sensitive to wind load. The enveloping membrane is prone to be wrinkled under compression with very small stiffness and stresses in the direction perpendicular to wrinkles, resulting in a significant change in the wind-induced responses of the inflated membrane. This paper studies the effect of wrinkling deformation on the dynamic behavior of inflated membranes under wind. A thin shell model with random imperfection is developed based on the stability theory to consider the wrinkling deformation of the enveloping membrane. The internal air is treated as a kind of potential-based fluid to consider the air-membrane interaction. The governing equations of inflated membranes are discretized with the finite element method. Square ETFE cushions under the time history of wind pressure provided by the TPU database are analyzed with the developed finite element model for different initial internal pressures and wind speeds to investigate the effect of wrinkling deformation. The results indicate that: a) Effect of the wrinkling deformation is larger on the windward side and smaller on the leeward side with largest magnitudes on the corners; b) The wrinkling deformation has a larger effect on the stresses with more sensitivity to the varying initial internal pressure and wind speed on the windward side; and c) Effect of the wrinkling deformation decreases with the increasing initial internal pressure and increases with the growing wind speed. The present research is helpful to the understanding of the effect of wrinkling deformation on the dynamic behavior of inflated membranes under wind for their rational design and reliable engineering application.

Key Words
finite element method; inflated membranes; stability theory of plates and shells; wind-induced responses; wrinkling deformation

Address
Xiaofeng Wang: Xiaofeng Wang, Xujing Cao and Qingshan Yang

Xujing Cao: Xiaofeng Wang, Xujing Cao and Qingshan Yang

Qingshan Yang: School of Civil Engineering, Chongqing University, No.174 Shazhengjie, Shapingba, Chongqing, 400044, China

Static wind pressure and force effect on Y-Plan building in presence of adjacent buildings Faiz Akram, Shanku Mandal and Sujit Kumar Dalui
Abstract; Full Text (5611K) .	pages 469-484.	DOI: 10.12989/was.2024.39.6.469

Abstract
The regions where wind velocity is high, large lateral loads occur on asymmetric and tall buildings. A detailed wind analysis has been presented in this document on the principal Y-Plan building interfered by two square plan buildings put in a Lshape pattern. Moreover, 0° to 180° at a step size of 15° wind angles have been considered. It is revealed by the results that presence of interfering buildings imposed significant fluctuations in force and wind pressure. For the windward side and the leeward side, wind flow profile is same but for faces A, G, H and I i.e., faces receiving the blockage of wind by interfering buildings, it is different. Increasing angle of attack (AOA) increased the velocity to 2.95 m/s in interference case as compared to velocity of 1.37 m/s in isolated case for 60° wind angle because of blockage of wind and generation of wake region is more in interference case by the presence of interfering buildings. The highest positive value of interference factor (I.F.) is for Face H and Face I with values of 2.019 and 2.454 respectively for 0° AOA of wind while the most negative value is for Face B with value of -1.702 for 0° AOA. Most of the faces have the values of interference factor near about 1 indicating that interfering buildings on these faces do not produce much effect on the principal building.

Key Words
asymmetric; interference; leeward; numerical analysis; wind angle; windward

Address
Faiz Akram:Department of Civil Engineering, Indian Institute of Engineering Science and Technology, Shibpur, Howrah, India

Shanku Mandal:Department of Civil Engineering, Indian Institute of Engineering Science and Technology, Shibpur, Howrah, India

Sujit Kumar Dalui:Department of Civil Engineering, Indian Institute of Engineering Science and Technology, Shibpur, Howrah, India