Natural ventilation in buildings with concave elements (H and C)
A review
DOI:
https://doi.org/10.46421/entac.v20i1.5720Keywords:
Natural ventilation, Air quality, Concave geometry, “H” floor-plan, “C” floor-planAbstract
Concave elements in floor plan are common in architecture; their larger perimeter, allows more openings to the outside. “C” and “H” shaped buildings are examples of design with concave elements, the second being the most recurrent in Brazil and widely used for multifamily social housing. However, many of them do not have good natural ventilation, which is a recommended strategy to improve thermal comfort and air quality in hot climates. In this regard, it was conducted a systematic review of the literature on natural ventilation of buildings with concave bay (“H” and “C”) to understand the behavior of wind flow around these buildings and the impact of their shape on ventilation. In syntheses, results indicate that the “C” shape was less efficient than a rectangular in removing pollutants. It is recommended to design low-rise windward. Finally, it was identified that dense neighborhoods composed of "H" shaped buildings have greater wind resistance, causing a decrease in the leeward ventilation in those buildings.
References
SANKETH, P.; RAO, B. D. V. C. M. Effect of Symmetrical Floor Plan Shapes with Re-Entrant Corners on Seismic Behavior of RC Buildings. i-manager’s Journal on Structural Engineering, v. 4, n. 2, p. 15–21, 2015a.
TEIXEIRA, C. A. et al. Levantamento das características de edifícios residenciais brasileiros- Labeee. Florianopolis: Centro Brasileiro de Eficiência Energética em Edificações (CB3e), 2015b.
MONTES, M. A. T. Abordagem Integrada No Ciclo De Vida De Habitação De Interesse Social Considerando Mudanças Climáticas. Florianópolis: Universidade Federal de Santa Catarina, 2016c.
SECRETARIA NACIONAL DA HABITAÇÃO. Sistema de Gerenciamento da Habitação: Dados Abertos da SNH. Disponível em: <http://sishab.mdr.gov.br/dados_abertos/sistema_habitacao>. Acesso em: 19 dez. 2022d.
KOURY, ANA PAULA ; BONDUKI, NABIL ; MANOEL, S. K. Análise Tipológica da Produção de Habitação Econômica no Brasil ( 1930-1964 ). 5o Seminário DOCOMOMO Brasil. Anais...São Carlos: DOCOMOMO Brasil, 2003e. Disponível em: https://docomomobrasil.com/wp-content/uploads/2016/01/115R.pdf>
MORAIS, J. M. S. C.; LABAKI, L. C. Ventilação natural em edificios multifamiliares do “Programa Minha Casa Minha Vida”. Campinas: Unicamp, 2013f.
CAIXA ECONÔMICA FEDERAL. Cartilha Minha Casa Minha Vida - Moradia para as famílias Renda para os trabalhadores Desenvolvimento para o Brasil. [s.l.] Caixa Econômica Federal, 2009g.
ORTIZ, H.; BAVARESCO, M. Metodologia para Elaboração do “Mapa de Tipologias e Sistemas Construtivos”. Bonn, Alemanha: Secretaria Nacional de Habitação (SNH), Deutsche Gesellschaft für Internationale Zusammenarbeit (GIZ), 2019h. Disponível em: <https://antigo.mdr.gov.br/images/biblioteca_snh/P2_GIZ-EEDUS_Metodologia-Mapa-Tipologias_Relatorio-Final_V0.pdf>.
MORAIS, J. M. DA S. C.; LABAKI, L. C. CFD como ferramenta para simular ventilação natural interna por ação dos ventos: estudos de caso em tipologias verticais do “Programa Minha Casa, Minha Vida”. Ambiente Construído, v. 17, n. 1, p. 223–244, mar. 2017i.
ASHRAE. Energy-Efficient Design of Low-Rise Residential Buildings. USAASHRAE, , 2018j.
CHENG, C. K. C. et al. Wind-induced natural ventilation of re-entrant bays in a high-rise building. Journal of Wind Engineering and Industrial Aerodynamics, v. 99, n. 2–3, p. 79–90, 1 fev. 2011k.
HONG KONG GOVERNMENT. Outbreak at the Amoy Garden.: Report of the Select Committee to inquire into the handling of the Severe Acute Respiratory Syndrome outbreak by the Government and the Hospital Authority. Hong Kong: Legislative Council of Hong Kong, 2004l. Disponível em: <https://www.legco.gov.hk/yr03-04/english/sc/sc_sars/reports/sars_rpt.htm>.
GÖTTING, J. et al. Dispersion of a passive pollutant in the vicinity of a U-shaped building. International Journal of Environment and Pollution, v. 8, n. 3–6, p. 718–726, 1997m.
WANG, D. et al. A combination method to generate fluctuating boundary conditions for large eddy simulation. Wind and Structures, v. 20, n. 4, p. 579–607, 25 abr. 2015n.
KLEIN, P. et al. Concentration estimation around point sources located in the vicinity of U-shape buildings. (P. Baldasano, JM; Brebbia, CA; Power, H; Zannetti, Ed.)International Conference on Air Pollution II. Anais...BARCELONA, SPAIN: IT Transactions on Ecology and the Environment, 1994o.
WANG, D. Y. et al. Numerical Prediction of Wind Flow Around Irregular Models. Journal of Fluids Engineering, v. 134, n. 7, 1 jul. 2012p.
ABNT. NBR 15220: Desempenho Térmico de Edificações -Parte 1 : Definições , símbolos e unidades. Rio de Janeiro, BrasilABNT, , 2003q.
RIVERO, R. Arquitetura e clima. Porto Alegre: D. C. Luzzatto, 1986r.
LAMBERTS, R.; DUTRA, L.; PEREIRA, F. O. R. Eficiência Energética na Arquitetura. Rio de Janeiro: ELETROBRAS/PROCEL, 2014s.
RUDNICK, S. N.; MILTON, D. K. Risk of indoor airborne infection transmission estimated from carbon dioxide concentration. Indoor Air, v. 13, n. 3, p. 237–245, 2003t.
WONG, S. Y. Y.; LAM, K. M. M. Effect of recessed cavities on wind-induced loading and dynamic responses of a tall building. Journal of Wind Engineering and Industrial Aerodynamics. Anais...Elsevier, mar. 2013u. Disponível em: <https://linkinghub.elsevier.com/retrieve/pii/S0167610513000044>. Acesso em: 13 out. 2023
LI, Y.-G. Y. Y. et al. Wind loads characteristics of irregular shaped high-rise buildings. Advances in Structural Engineering, v. 26, n. 1, p. 3–16, 12 jan. 2022v.
CHENG, L.; LAM, K. M.; WONG, S. Y. POD analysis of crosswind forces on a tall building with square and H-shaped cross sections. Wind and Structures, v. 21, n. 1, p. 63–84, 25 jul. 2015w.
MANDAL, S.; DALUI, S. K.; BHATTACHARJYA, S. Influence of Side Ratio on Wind Induced Responses of U Plan Shape Tall Building. In: Lecture Notes in Civil Engineering. [s.l: s.n.]. v. 274p. 345–355.
PADILLA-MARCOS, M. Á.; FEIJÓ-MUÑOZ, J.; MEISS, A. Wind velocity effects on the quality and efficiency of ventilation in the modelling of outdoor spaces. Case studies. Building Services Engineering Research and Technology, v. 37, n. 1, p. 33–50, 28 jan. 2016y.
GUNAYDIN, T. I. Numerical Study of Wind induced Pressures on Irregular Plan Shapes. ICONARP INTERNATIONAL JOURNAL OF ARCHITECTURE AND PLANNING, v. 9, n. 2, p. 646–679, dez. 2021z.
LI, B.; LIU, J.; GAO, J. Surface wind pressure tests on buildings with various non-uniformity morphological parameters. Journal of Wind Engineering and Industrial Aerodynamics, v. 137, p. 14–24, 1 fev. 2015aa.
LI, B. et al. Wind tunnel pressure measurement of drag force effects of non-uniform buildings. Tianjin Daxue Xuebao (Ziran Kexue yu Gongcheng Jishu Ban)/Journal of Tianjin University Science and Technology, v. 47, n. 2, p. 180–188, 2014ab.
LI, B. et al. Wind tunnel study on influences of morphological parameters on drag coefficient of horizontal non-uniform buildings. Building and Environment, v. 207, p. 108412, 1 jan. 2022ac.
LI, B.; LIU, J.; LI, M. Wind tunnel study on the morphological parameterization of building non-uniformity. Journal of Wind Engineering and Industrial Aerodynamics, v. 121, p. 60–69, out. 2013ad.
LI, B. et al. Drag distributions of non-uniform buildings from surface pressure measurements in wind tunnel. Building and Environment, v. 143, n. March, p. 618–631, 1 out. 2018ae.
NAGAR, S. K.; RAJ, R.; DEV, N. Experimental study of wind-induced pressures on tall buildings of different shapes. Wind and Structures, An International Journal, v. 31, n. 5, p. 441–453, 2020af.