Review of approaches, opportunities, and future directions for improving aerodynamics of tall buildings with smart facades

Abstract The demand for tall buildings has increased over the past decades for cultural, financial, and technological reasons. Such slender structures are more flexible and vulnerable to wind-induced vibrations. Additionally, wind speed exponentially increases with height, resulting in larger wind loading on higher levels and complex turbulent regimes. Such effects call for more innovative approaches to enhance the resilience of tall buildings while accounting for the sustainability implications. Current methodologies to control the vibrations using auxiliary dampers are typically limited in their applicable bandwidth. The aerodynamic modifications are specific to a particular wind direction and characteristics and cannot adapt to the changing climate or that of flow regimes due to the new construction in the proximity of the target building. There have been major advances in using secondary facades to achieve sustainability through ventilation and energy-saving applications around the world. These advances have resulted in the development of adaptive facades for architectural and energy applications. This review paper discusses the available approaches and potential opportunities to utilize the existing adaptive facade system capabilities (for energy applications) to alter building aerodynamics. For this purpose, the paper concisely discusses aerodynamic modification, surface roughness effects, available bio-inspired approaches, and potential morphing material capabilities to provide valuable insights into understanding the flow-control mechanism of such systems, potentially leading to innovative designs of facade systems. Opportunities have been identified to combine this concept with smart technologies to develop smart facades with the aerodynamic performance that leads to mitigating wind-induced vibration in tall buildings. The review of existing research on this topic opens up opportunities for enhancing the use of facades as active, dynamic, and smart systems that not only enhance the performance of the tall buildings under wind-induced vibrations but also can result in long term energy saving, leading to more resilient and sustainable communities.

[1]  Nader Sadegh,et al.  Real-time optimization of a double-skin facade based on lumped modeling and occupant preference , 2004 .

[2]  Simon Laflamme,et al.  Performance-based design with life-cycle cost assessment for damping systems integrated in wind excited tall buildings , 2019, Engineering Structures.

[3]  Dong Li,et al.  Numerical analysis on thermal performance of naturally ventilated roofs with different influencing parameters , 2016 .

[4]  Kevin R. Cooper,et al.  Unsteady aerodynamic force measurements on a super-tall building with a tapered cross section , 1997 .

[5]  Elham Mehrinejad Khotbehsara,et al.  Study on wind aerodynamic and flow characteristics of triangular-shaped tall buildings and CFD simulation in order to assess drag coefficient , 2019, Ain Shams Engineering Journal.

[6]  Per Heiselberg Expert Guide: Part 1 Responsive Building Concepts , 2010 .

[7]  Peter Lund,et al.  Daylight optimization of multifunctional solar facades , 2000 .

[8]  Ming Gu,et al.  Across-wind loads of typical tall buildings , 2004 .

[9]  Jianlei Niu,et al.  CFD simulation of the wind environment around an isolated high-rise building: An evaluation of SRANS, LES and DES models , 2016 .

[10]  Yi Luo,et al.  Wind-rain erosion of Fujian Tulou Hakka Earth Buildings , 2019, Sustainable Cities and Society.

[11]  Amlan Kumar Bairagi,et al.  Comparison of aerodynamic coefficients of setback tall buildings due to wind load , 2018 .

[12]  Yingzheng Liu,et al.  The effects of cactus inspired spines on the aerodynamics of a cylinder , 2013 .

[13]  Michael Amitay,et al.  Bio-mimicry inspired tall buildings: The response of cactus-like buildings to wind action at Reynolds Number of 104 , 2016 .

[14]  B. Samali,et al.  Wind-induced response reduction of a tall building with an innovative façade system , 2014 .

[15]  Ashraf A. El Damatty,et al.  LES evaluation of wind-induced responses for an isolated and a surrounded tall building , 2016 .

[16]  Stephen Selkowitz,et al.  Advanced Interactive Facades - Critical Elements for Future GreenBuildings? , 2003 .

[17]  Yue Zhang,et al.  Predicting wind-induced vibrations of high-rise buildings using unsteady CFD and modal analysis , 2015 .

[18]  S. C. Luo,et al.  Effects of incidence and afterbody shape on flow past bluff cylinders , 1994 .

[19]  I. G. Capeluto,et al.  Advice tool for early design stages of intelligent facades based on energy and visual comfort approach , 2009 .

[20]  Yuanlin Yu,et al.  A new inflow turbulence generator for large eddy simulation evaluation of wind effects on a standard high-rise building , 2018, Building and Environment.

[21]  Yukio Tamura,et al.  Response characteristics of super-tall buildings – Effects of number of sides and helical angle , 2015 .

[22]  Ning Lin,et al.  Experimental and zonal modeling for wind pressures on double-skin facades of a tall building , 2012 .

[23]  Zoltán Szalay Drags on several polygon cylinders , 1989 .

[24]  Wafaa Karaki,et al.  Particle Image Velocimetry Measurements in the Wake of a Cactus-Shaped Cylinder , 2011 .

[25]  Jing-Jong Jang,et al.  A Study of Geometric Properties And Shape Factors For Design of Wind Turbine Tower , 2009 .

[26]  Alice Alipour,et al.  Surrogate models for high performance control systems in wind-excited tall buildings , 2020, Appl. Soft Comput..

[27]  C. Mannini,et al.  Two-dimensional study of a rectangular cylinder with a forebody airtight screen at a small distance , 2019, Journal of Wind Engineering and Industrial Aerodynamics.

[28]  Jlm Jan Hensen,et al.  Dynamic sensitivity analysis for performance-based building design and operation , 2013 .

[29]  H. Montazeri,et al.  CFD simulations of wind flow and mean surface pressure for buildings with balconies: Comparison of RANS and LES , 2020 .

[30]  Amos Darko,et al.  Sensitivity analysis of wind pressure coefficients on CAARC standard tall buildings in CFD simulations , 2018 .

[31]  Young-Moon Kim,et al.  Across-wind responses of an aeroelastic tapered tall building , 2008 .

[32]  H. J. Gerhardt,et al.  Wind loads on wind permeable facades , 1994 .

[33]  Ashraf A. El Damatty,et al.  Consistent inflow turbulence generator for LES evaluation of wind-induced responses for tall buildings , 2015 .

[34]  Abd Halid Abdullah,et al.  Design and low energy ventilation solutions for atria in the tropics , 2012 .

[35]  Yukio Tamura,et al.  Experimental investigation of aerodynamic forces and wind pressures acting on tall buildings with various unconventional configurations , 2012 .

[36]  Kenny C. S Kwok,et al.  Sopite syndrome in wind-excited buildings: productivity and wellbeing impacts , 2017 .

[37]  Bijan Samali,et al.  Control of wind-induced motion of mid-rise buildings using smart facade systems , 2014 .

[38]  Qiusheng Li,et al.  Aerodynamic treatments for reduction of wind loads on high-rise buildings , 2018 .

[39]  Andrea Freda,et al.  Experimental investigation on the aerodynamic behavior of square cylinders with rounded corners , 2014 .

[40]  Y. Tominaga Flow around a high-rise building using steady and unsteady RANS CFD: Effect of large-scale fluctuations on the velocity statistics , 2015 .

[41]  Mohammad Jafari,et al.  Methodologies to mitigate wind-induced vibration of tall buildings: A state-of-the-art review , 2021 .

[42]  Krishnan Mahesh,et al.  Aerodynamic loads on cactus-shaped cylinders at low Reynolds numbers , 2008 .

[43]  J. M. Blanco,et al.  Assessment of the influence of façade location and orientation in indoor environment of double-skin building envelopes with perforated metal sheets , 2019, Building and Environment.

[44]  Fabio Favoino,et al.  Experimental analysis of the energy performance of an ACTive, RESponsive and Solar (ACTRESS) façade module , 2016 .

[45]  Ming Gu,et al.  Across-wind loads and effects of super-tall buildings and structures , 2011 .

[46]  E. D. Obasaju Measurement of forces and base overturning moments on the CAARC tall building model in a simulated atmospheric boundary layer , 1992 .

[47]  Xu Xu,et al.  Evaluation of an Active Building Envelope window-system , 2008 .

[48]  Tahsin Başaran,et al.  Experimental investigation of the pressure loss through a double skin facade by using perforated plates , 2016 .

[49]  K. Kwok,et al.  The effects of a double-skin façade on the cladding pressure around a tall building , 2019, Journal of Wind Engineering and Industrial Aerodynamics.

[50]  Rolando E. Vega,et al.  Cladding Performance of High-Rise Buildings in the Houston CBD during Hurricane Ike , 2009 .

[51]  Kyoung Sun Moon Tall Building Motion Control Using Double Skin Façades , 2009 .

[52]  Jun Kanda,et al.  Characteristics of aerodynamic forces and pressures on square plan buildings with height variations , 2010 .

[53]  Ahsan Kareem,et al.  Aerodynamic Loads on Tall Buildings: Interactive Database , 2003 .

[54]  Shen Guohui Wind tunnel test study on mean wind pressure distribution for double-skin facade , 2009 .

[55]  M. Glória Gomes,et al.  Gap inner pressures in multi-storey double skin facades , 2008 .

[56]  Anders Hjelm,et al.  Recent Advances in Electrochromics for Smart Windows Applications , 1998, Optical Interference Coatings.

[57]  Feng Qian,et al.  Summertime thermal and energy performance of a double-skin green facade: A case study in Shanghai , 2018 .

[58]  Zhengqing Chen,et al.  Characteristics of aerodynamic forces on high-rise buildings with various façade appurtenances , 2019, Journal of Wind Engineering and Industrial Aerodynamics.

[59]  A.L.S. Chan,et al.  Pedestrian level wind environment assessment around group of high-rise cross-shaped buildings: Effect of building shape, separation and orientation , 2016, Building and Environment.

[60]  D. Fletcher,et al.  Potential application of double skin façade incorporating aerodynamic modifications for wind energy harvesting , 2018 .

[61]  Andrea Freda,et al.  Effects of free-stream turbulence and corner shape on the galloping instability of square cylinders , 2013 .

[62]  Kenny C. S Kwok,et al.  Effect of edge configuration on wind-induced response of tall buildings , 1988 .

[63]  Z. Zhai,et al.  A new double-skin façade system integrated with TiO2 plates for decomposing BTEX , 2020, Building and Environment.

[64]  Yi Hui,et al.  Effects of facade appurtenances on the local pressure of high-rise building , 2018, Journal of Wind Engineering and Industrial Aerodynamics.

[65]  Jun Kanda,et al.  Effects of taper and set-back on wind force and wind-induced response of tall buildings , 2010 .

[66]  S. Laflamme,et al.  Life‐cycle cost optimization of wind‐excited tall buildings using surrogate models , 2021, The Structural Design of Tall and Special Buildings.

[67]  Sung-Ah Kim,et al.  Interactive Decision Making Environment for the Design Optimization of Climate Adaptive Building Shells , 2013, CDVE.

[68]  Lo Beltrán,et al.  From Static to Kinetic : A Review of Acclimated Kinetic Building Envelopes , 2012 .

[69]  Simon Laflamme,et al.  Performance-Based Design for Wind-Excited Tall Buildings Equipped with High Performance Control Systems , 2018 .

[70]  B. L. H. Hasselaar,et al.  Climate Adaptive Skins:Towards The New Energy-efficient Façade , 2006 .

[71]  Mohamed S. Fadl,et al.  CFD Simulation for Wind Comfort and Safety in Urban Area: A Case Study of Coventry University Central Campus , 2013 .

[72]  Ting Deng,et al.  Aerodynamic measurements of across-wind loads and responses of tapered super high-rise buildings , 2015 .

[73]  Kenny C. S Kwok,et al.  Wind-induced responses of a tall building with a double-skin façade system , 2017 .

[74]  Kenny C. S Kwok,et al.  Utilizing cavity flow within double skin façade for wind energy harvesting in buildings , 2017 .

[75]  Michael Amitay,et al.  Improving aerodynamic performance of tall buildings using Fluid based Aerodynamic Modification , 2014 .

[76]  Alice Alipour,et al.  Multiple-Surrogate Models for Probabilistic Performance Assessment of Wind-Excited Tall Buildings under Uncertainties , 2020 .

[77]  P Pieter-Jan Hoes,et al.  Performance prediction of buildings with responsive building elements challenges and solutions , 2014 .

[78]  Tetsuro Tamura,et al.  The effect of turbulence on aerodynamic forces on a square cylinder with various corner shapes , 1999 .

[79]  Klaus Fichter,et al.  Dye solar modules for facade applications: Recent results from project ColorSol , 2009 .

[80]  H Hamid Montazeri,et al.  CFD simulation of wind-induced pressure coefficients on buildings with and without balconies: Validation and sensitivity analysis , 2013 .

[81]  Marco Perino,et al.  Towards an active, responsive and solar building envelope , 2010 .

[82]  A. Alipour,et al.  A smart façade system controller for optimized wind-induced vibration mitigation in tall buildings , 2021 .

[83]  Kenny C. S Kwok,et al.  Aerodynamic Devices for Tall Buildings and Structures , 1987 .

[84]  Daniel T. Levin,et al.  Motion interference effects while performing and viewing actions with hand-held objects , 2010 .

[85]  Y. Eom,et al.  Numerical analysis of PM2.5 particle collection efficiency of an electrostatic precipitator integrated with double skin façade in a residential home , 2019, Building and Environment.

[86]  H. J. Gerhardt,et al.  Wind loads on wind-permeable building facades , 1983 .

[87]  Youming Chen,et al.  Energy performance and applicability of naturally ventilated double skin façade with Venetian blinds in Yangtze River Area , 2020 .

[88]  Luca Caracoglia,et al.  Examination of experimental variability in HFFB testing of a tall building under multi-directional winds , 2017 .

[89]  Kenny C. S Kwok,et al.  Economic perspectives of aerodynamic treatments of square tall buildings , 2009 .

[90]  Fabio Favoino,et al.  Review of current status, requirements and opportunities for building performance simulation of adaptive facades† , 2017 .

[91]  A. Zasso,et al.  Experimental assessment of the effects of a porous double skin façade system on cladding loads , 2020, Journal of Wind Engineering and Industrial Aerodynamics.

[92]  Li Huan-long Wind tunnel test study on wind pressure distribution on double-skin facades of high-rise buildings with typical shapes , 2008 .

[93]  Yukio Tamura,et al.  Experimental investigation on aerodynamic characteristics of various triangular-section high-rise buildings , 2013 .

[94]  Yukio Tamura,et al.  Wind-induced responses of super-tall buildings with various atypical building shapes , 2014 .

[95]  Poul Henning Kirkegaard,et al.  Development and Evaluation of a Responsive Building Envelope , 2011 .

[96]  Yukio Tamura,et al.  Wind-induced response of high-rise buildings Effects of corner cuts or openings in square buildings , 1993 .

[97]  Yue Wu,et al.  Wind-induced responses of tall buildings under combined aerodynamic control , 2018, Engineering Structures.

[98]  Ming Zhao,et al.  Performance assessment of a special Double Skin Façade system for wind energy harvesting and a case study , 2018 .

[99]  Ming Gu,et al.  Experimental study of across‐wind aerodynamic damping of super high‐rise buildings with aerodynamically modified square cross‐sections , 2014 .

[100]  Prageeth Jayathissa,et al.  The Adaptive Solar Facade: From concept to prototypes , 2016 .

[101]  Yoshiteru Iwasa,et al.  Aerodynamic shape effects of tall building for vortex induced vibration , 1990 .

[102]  Peter A. Irwin,et al.  Bluff body aerodynamics in wind engineering , 2008 .

[103]  John C. Mauro,et al.  Structure of boroaluminosilicate glasses: Impact of [Al2O3]/[SiO2] ratio on the structural role of sodium , 2012 .

[104]  Yang Liu,et al.  Wind driven “pumping” fluid flow and turbulent mean oscillation across high-rise building enclosures with multiple naturally ventilated apertures , 2019, Sustainable Cities and Society.

[105]  H Hamid Montazeri,et al.  CFD evaluation of new second-skin facade concept for wind comfort on building balconies : case-study for the Park Tower in Antwerp , 2013 .

[106]  Satu Paiho,et al.  An energetic analysis of a multifunctional facade system for energy efficient retrofitting of residential buildings in cold climates of Finland and Russia , 2015 .

[107]  David Chow,et al.  Heat transfer and air movement behaviour in a double-skin façade , 2014 .

[108]  Yoichi Yamagishi,et al.  Effect of the number of grooves on flow characteristics around a circular cylinder with triangular grooves , 2005, J. Vis..

[109]  Dirk Saelens,et al.  Potential of structural thermal mass for demand-side management in dwellings , 2013 .

[110]  Peter A. Irwin,et al.  Wind engineering challenges of the new generation of super-tall buildings , 2009 .

[111]  Yukio Tamura,et al.  Wind-induced coupled motion of tall buildings with varying square plan with height , 2011 .

[112]  T. Tamura,et al.  Numerical prediction of unsteady pressures on a square cylinder with various corner shapes , 1998 .

[113]  Alexandre de Macêdo Wahrhaftig,et al.  Using computational fluid dynamics to improve the drag coefficient estimates for tall buildings under wind loading , 2018 .

[114]  K. Kwok,et al.  A Hybrid RANS and Kinematic Simulation of Wind Load Effects on Full-Scale Tall Buildings , 2011 .

[115]  Jlm Jan Hensen,et al.  Simulation-based support for product development of innovative building envelope components , 2014 .

[116]  S. Laflamme,et al.  Data-Driven Risk-Based Assessment of Wind-Excited Tall Buildings , 2019, Structures Congress 2019.

[117]  Jun Kanda,et al.  Wind pressures on tapered and set-back tall buildings , 2013 .

[118]  S. Setunge,et al.  Greenhouse gas emissions during timber and concrete building construction —A scenario based comparative case study , 2018 .

[119]  Jan Van der Spiegel,et al.  A Low-Power Multifunctional CMOS Sensor Node for an Electronic Facade , 2014, IEEE Transactions on Circuits and Systems I: Regular Papers.

[120]  A. Alipour,et al.  Aerodynamic shape optimization of rectangular and elliptical double-skin façades to mitigate wind-induced effects on tall buildings , 2021, Journal of Wind Engineering and Industrial Aerodynamics.

[121]  P. K. Bhargava,et al.  Effect of balconies on ventilation inducing aeromotive force on low-rise buildings , 1998 .

[122]  Alice Alipour,et al.  Life-Cycle Cost Evaluation Strategy for High-Performance Control Systems under Uncertainties , 2020 .

[124]  Makoto Kanda,et al.  Effects on surface roughness for wind pressure on glass and cladding of buildings , 1998 .

[125]  L. E. M. Lignarolo,et al.  Shape morphing wind-responsive facade systems realized with smart materials , 2011 .

[126]  Young-Moon Kim,et al.  Dynamic responses of a tapered tall building to wind loads , 2001 .

[127]  Lou Wenjuan Wind tunnel test study on wind load characteristics for double-skin facade building with rectangular shape , 2005 .

[128]  Tamotsu Igarashi Drag reduction of a square prism by flow control using a small rod , 1997 .

[129]  Christ Glorieux,et al.  Assessment of sound insulation of naturally ventilated double skin facades , 2016 .

[130]  Richard J. Jackson,et al.  Active materials for adaptive architectural envelopes based on plant adaptation principles , 2015 .

[131]  N. Isyumov,et al.  Reduction of tall building motion by aerodynamic treatments , 1990 .

[132]  Yao-Chun Zhang,et al.  Computational Fluid Dynamics study on the performance and mechanism of suction control over a high‐rise building , 2012 .

[133]  H. Kawai,et al.  Effect of corner modifications on aeroelastic instabilities of tall buildings , 1998 .

[134]  Yi Min Xie,et al.  Numerical simulations of wind drags on straight and twisted polygonal buildings , 2013 .

[135]  Valentina Serra,et al.  Experimental assessment of the energy performance of an advanced responsive multifunctional façade module , 2012 .

[136]  Kenneth Ip,et al.  Perspectives of double skin façades for naturally ventilated buildings: A review , 2014 .

[137]  Italo Meroni,et al.  Energy efficiency of a dynamic glazing system , 2010 .

[138]  F. Hou,et al.  Investigation approaches to quantify wind-induced load and response of tall buildings: A review , 2020 .

[139]  Simon Elias Bibri,et al.  Smart sustainable cities of the future: An extensive interdisciplinary literature review , 2017 .

[140]  Hiromichi Shirato,et al.  ON AERODYNAMIC STABILITY EFFECTS FOR BLUFF RECTANGULAR CYLINDERS BY THEIR CORNER-CUT , 1988 .

[141]  T. Stathopoulos,et al.  Wind pressures on buildings with stepped roofs , 1990 .

[142]  Jlm Jan Hensen,et al.  Climate adaptive building shells: state-of-the-art and future challenges , 2013 .