CFD Simulation Analysis of Building Density on Residential Wind Environment

Hu, Kaihua; Cheng, Shidan; Qian, Yi

doi:10.25103/jestr.111.05

Cited by 15 publications

(11 citation statements)

References 8 publications

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“…However, these studies have mainly focused on urban morphology, mesoscale layout, and microscopic details of buildings. On the basis of CFD simulation of the wind environment in residential districts, Hu Kaihua et al [8] analyzed the quantitative relationship between building density and wind environment. They indicated that building density has a negative linear relationship with the average outdoor wind speed ratio (WSR) in residential districts, but it shows a positive linear relationship with the average air age.…”

Section: State Of the Artmentioning

confidence: 99%

CFD Simulation Analysis of the Influence of Floor Area Ratio on the Wind Environment in Residential Districts

Li¹,

Yang²,

Qian³

2018

JESTR

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The floor area ratio (FAR) in residential districts in China has been expanding continuously as a response to the rapid urbanization and increasing demands for buildings. Consequently, the wind environment in residential districts begins to affect the outdoor comfort of residents. Simulation cases of residential buildings with different FARs were presented in this study to disclose the relationship between FAR and the wind environment in residential districts. First, the wind environment characteristics of residential districts with different FARs were established via computer numerical simulation. Second, wind speed ratio (WSR) and air age distribution were calculated at pedestrian height. Finally, the quantitative relationship between outdoor wind environment and FAR in residential districts was concluded. Results demonstrate a negative linear relationship between FAR and the average WSR (AWSR) in outdoor environment but a positive linear relationship between FAR and average air age. The AWSR in residential areas is decreased by 0.18 and the average air of age is increased by 53.38 s when FAR is increased from 0.63 to 2.32. In other words, increasing FAR in residential areas can decrease the AWSR but increase the average air age, thereby influencing the outdoor comfort of residents. This study provides references to improving wind environment and planning layout in residential districts with high FARs.

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Section: State Of the Artmentioning

confidence: 99%

CFD Simulation Analysis of the Influence of Floor Area Ratio on the Wind Environment in Residential Districts

Li¹,

Yang²,

Qian³

2018

JESTR

Self Cite

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“…The results showed that the wind speed ratios of open spaces and lane entrances are higher than those of other places [49]. The simulation results of Hu et al indicated that when the residential BD increases from 0.18 to 0.32, the mean wind speed ratio of the residential area decreases by 0.18 [50]. Guo et al considered that there was a negative correlation between ventilation efficiency and BD in Dalian City, and proposed measures such as using ventilation channels and increasing building height to improve urban ventilation performance [18].…”

Section: Discussionmentioning

confidence: 96%

Optimization Strategy of Traditional Block Form Based on Field Investigation—A Case Study of Xi’an Baxian’an, China

Feng

Ding

Yin³

et al. 2021

IJERPH

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Rapid urbanization has caused environmental problems such as the urban heat island and air pollution, which are unfavorable to residents. Urban traditional blocks are facing the dual challenges of restoration and protection. This paper proposes adaptive transformation strategies for improving the microclimate of traditional areas. We selected Baxian’an Block in Xi’an city, simulated the air temperature and wind speed during summer and winter using ENVI-met, and studied the correlationship between morphological parameters (average building height, building density, enclosure degree, height fall, aspect ratio, and sky view factor) and air temperature and wind speed ratio. The case study revealed that the wind speed ratio of Baxian’an is relatively different in summer, reaching a maximum of 0.61, meaning that the ventilation capacity is significantly affected by the architectural form of the block. Finally, suggestions for the optimal design of the block’s form are provided: the building density should be less than 50%, the average building height should be more than 50 m, the enclosure degree should be less than 0.2, the height fall should be more than 41.7 m, and the sky view factor should be less than 0.5. This study can provide data and support for improving the planning and design standards of traditional residential areas.

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“…Hadavi and Pasdarshahri quantified the effects of the wind velocity, urban planning district density, and urban form on the infiltration rate via CFD simulations, and concluded that building tightness enhancement could reduce the infiltration rate and augment the exfiltration rate [20]. Hu et al analyzed the relationship between the residential building density and wind environment and reported that when the residential building density increases from 0.18 to 0.32, the outdoor average wind velocity ratio decreases by 0.18 and the average air age increases by 58.63 s [21]. Hong and Lin compared the wind environments of several residential areas with different layout patterns and tree arrangements and concluded that orienting the long facades of buildings parallel to the prevailing wind direction can yield satisfactory thermal comfort [22].…”

Section: Introductionmentioning

confidence: 99%

Impact of Enclosure Boundary Patterns and Lift-Up Design on Optimization of Summer Pedestrian Wind Environment in High-Density Residential Districts

Jiang

Gao

2021

Energies

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A comfortable wind environment favors the sustainable development of urban residential districts and public health. However, the rapid growth of high-rise urban residential districts leads to low wind velocity environments in summer. This study examines the influence of enclosure boundary patterns and lift-up design on the wind environment and proposes an optimization strategy to improve the low wind velocity environment in residential districts in summer. A typical residential district in Hangzhou was selected; the average wind velocity, calm wind zone ratio and comfortable wind zone ratio were selected as the evaluation indexes. The wind environment for different enclosure boundary patterns and lift-up designs were obtained via computational fluid dynamics (CFD) simulations. The results indicate that the pedestrian wind environment is greatly improved in residential districts by reducing the height/width of the enclosure boundary, increasing the permeability rate and adopting a lift-up design in all buildings within residential districts. A combination of permeable railings and lift-up design is recommended; this can increase the average wind velocity and the ratio of comfortable wind zones by 70% and 200%, respectively. This study provides practical guidelines for the optimization of a low wind velocity environment in Chinese high-density residential districts in summer.

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CFD Simulation Analysis of Building Density on Residential Wind Environment

Cited by 15 publications

References 8 publications

CFD Simulation Analysis of the Influence of Floor Area Ratio on the Wind Environment in Residential Districts

CFD Simulation Analysis of the Influence of Floor Area Ratio on the Wind Environment in Residential Districts

Optimization Strategy of Traditional Block Form Based on Field Investigation—A Case Study of Xi’an Baxian’an, China

Impact of Enclosure Boundary Patterns and Lift-Up Design on Optimization of Summer Pedestrian Wind Environment in High-Density Residential Districts

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