AI Chat Paper
Note: Please note that the following content is generated by AMiner AI. SciOpen does not take any responsibility related to this content.
{{lang === 'zh_CN' ? '文章概述' : 'Summary'}}
{{lang === 'en_US' ? '中' : 'Eng'}}
Chat more with AI
Powered by AMiner. Clicking this button will take you away from SciOpen.
Home Building Simulation Article
Article Link
Cite
EndNote(RIS) BibTeX
Collect
Submit Manuscript
Show Outline
Outline
Show full outline
Hide outline
Outline
Show full outline
Hide outline
Research Article

CFD simulation of pumping ventilation in a three-story isolated building with internal partitioning: Effects of partition widths, heights and locations

Huai-Yu Zhong1,2( )Jie Sun1Chao Lin4Song-Heng Wu2Jin Shang3Hideki Kikumoto4Fu-Ping Qian1Carlos Jimenez-Bescos5Fu-Yun Zhao3
School of Energy and Environment, Anhui University of Technology, Ma-An-Shan, Anhui Province, 243002, China
State Key Laboratory of Green Building in Western China, Xi’an University of Architecture & Technology, Xi’an, Shaanxi Province, China
School of Power and Mechanical Engineering, Wuhan University, Wuhan, Hubei Province, 430072, China
Institute of Industrial Science, The University of Tokyo, 4-6-1 Komaba, Meguro-ku, Tokyo, 153-8505, Japan
School of Built and Natural Environment, University of Derby, Derby, UK
Show Author Information

Abstract

Pumping ventilation (PV), a special single-sided ventilation (SSV), has been certified as an effective strategy to improve the air exchange rate of SSV. However, most studies targeted on the single space, and few studies have been focused on the effect of internal partitioning on PV. This paper aims to evaluate the ventilation performance of PV influenced by different configurations of internal partitioning. Computational fluid dynamics (CFD) simulation was used to predict the flow fields and ventilation rates. The width (w/H), height (h/H) and location (d/H) are the three main internal partition parameters considered in this study. The simulation results showed that the total, mean and fluctuating ventilation rates all decrease with wider internal partitions. The normalized total ventilation rate decreases by 7.6% when w/H is increased from 50% to 75%. However, the reduction rate is only 0.23% between w/H = 0 and 25%, and only 0.61% between w/H = 25% and 50%. The ventilation rate is hardly reduced by increasing the partition width when w/H < 50%, whereas greatly reduced by wider partition for w/H > 50%. Increasing the partition height will reduce the mean ventilation rate but promote the fluctuating and total ventilation rate in some cases. An increase of total ventilation rate by 1.4% is observed from h/H = 50% to 75%. The ventilation rate is larger when the internal partition is attached to the leeward or windward wall. The total, mean and fluctuating ventilation rates for d/H = 50% are relatively higher than d/H = 0 by 1.5%, 3.1% and 0.8%, respectively. Hence the internal partition should be mounted attached to the windward wall so as to obtain the greatest pumping ventilation rate. The periodicity of pumping flow oscillation and pumping frequency are independent of the partition configurations. The peak power of pumping flow is the lowest for the widest internal partition and is negatively affected by the partition height, but it generally has a positive correlation with the distance between the partition and leeward wall. Present research will help to understand pumping ventilation mechanism in real buildings with internal partitioning and provide theoretical basis for developing unsteady natural ventilation technology in low-carbon buildings.

Keywords

ventilation ratesingle-sided ventilationpumping ventilationinternal partitioningperiodic oscillation

References

 

Albuquerque DP, Sandberg M, Linden PF, et al. (2020). Experimental and numerical investigation of pumping ventilation on the leeward side of a cubic building. Building and Environment, 179: 106897.
Crossref Google Scholar
 

Allocca C, Chen Q, Glicksman LR (2003). Design analysis of single-sided natural ventilation. Energy and Buildings, 35: 785–795.
Crossref Google Scholar
 

Carrilho da Graça G, Albuquerque DP, Sandberg M, et al. (2021). Pumping ventilation of corner and single sided rooms with two openings. Building and Environment, 205: 108171.
Crossref Google Scholar
 

Chu C-R, Chiu Y-H, Wang Y-W (2010). An experimental study of wind-driven cross ventilation in partitioned buildings. Energy and Buildings, 42: 667–673.
Crossref Google Scholar
 

Chu C-R, Chiang B-F (2013). Wind-driven cross ventilation with internal obstacles. Energy and Buildings, 67: 201–209.
Crossref Google Scholar
 

Chu C-R, Chiu Y-H, Tsai Y-T, et al. (2015). Wind-driven natural ventilation for buildings with two openings on the same external wall. Energy and Buildings, 108: 365–372.
Crossref Google Scholar
 

Daish NC, Carrilho da Graça G, Linden PF, et al. (2016). Impact of aperture separation on wind-driven single-sided natural ventilation. Building and Environment, 108: 122–134.
Crossref Google Scholar
 
Franke J, Hellsten A, Schlünzen H, et al. (2007). Best Practice Guideline for the CFD Simulation of Flows in the Urban Environment. COST Action 732: Quality assurance and improvement of microscale meteorological models. Brussels: COST Office.
 

Goricsán I, Balczo M, Balogh M, et al. (2011). Simulation of flow in an idealised city using various CFD codes. International Journal of Environment and Pollution, 44: 359.
Crossref Google Scholar
 

Guyot G, Ferlay J, Gonze E, et al. (2016). Multizone air leakage measurements and interactions with ventilation flows in low-energy homes. Building and Environment, 107: 52–63.
Crossref Google Scholar
 

Guyot G, Geoffroy H, Ondarts M, et al. (2019). Modelling the impact of multizone airleakage on ventilation performance and indoor air quality in low-energy homes. Building Simulation, 12: 1141–1159.
Crossref Google Scholar
 

Hanna S, Chang J (2012). Acceptance criteria for urban dispersion model evaluation. Meteorology and Atmospheric Physics, 116: 133–146.
Crossref Google Scholar
 

Lee H, Awbi HB (2004a). Effect of internal partitioning on indoor air quality of rooms with mixing ventilation—Basic study. Building and Environment, 39: 127–141.
Crossref Google Scholar
 

Lee H, Awbi HB (2004b). Effect of internal partitioning on room air quality with mixing ventilation—Statistical analysis. Renewable Energy, 29: 1721–1732.
Crossref Google Scholar
 

Lin Z, Chow TT, Tsang CF, et al. (2009). Effect of internal partitions on the performance of under floor air supply ventilation in a typical office environment. Building and Environment, 44: 534–545.
Crossref Google Scholar
 

Liu X, Wu X, Chen L, et al. (2018). Effects of internal partitions on flow field and air contaminant distribution under different ventilation modes. International Journal of Environmental Research and Public Health, 15: 2603.
Crossref Google Scholar
 

Luo T, Tan Y, Langston C, et al. (2019). Mapping the knowledge roadmap of low carbon building: A scientometric analysis. Energy and Buildings, 194: 163–176.
Crossref Google Scholar
 

Menter FR (1994). Two-equation eddy-viscosity turbulence models for engineering applications. AIAA Journal, 32: 1598–1605.
Crossref Google Scholar
 

Moonen P, Allegrini J (2015). Employing statistical model emulation as a surrogate for CFD. Environmental Modelling & Software, 72: 77–91.
Crossref Google Scholar
 

Murakami S, Mochida A (1995). On turbulent vortex shedding flow past 2D square cylinder predicted by CFD. Journal of Wind Engineering and Industrial Aerodynamics, 54–55: 191–211.
Crossref Google Scholar
 
Nielsen PV, Hoff L, Pedersen LG (1988). Displacement ventilation by different types of diffusers. In: Proceedings of the 9th AIVC Conference on Effective Ventilation, Gent, Belgium.
 

Pérez-Lombard L, Ortiz J, Pout C (2008). A review on buildings energy consumption information. Energy and Buildings, 40: 394–398.
Crossref Google Scholar
 

Ramponi R, Blocken B (2012). CFD simulation of cross-ventilation for a generic isolated building: Impact of computational parameters. Building and Environment, 53: 34–48.
Crossref Google Scholar
 

Richards PJ, Norris SE (2011). Appropriate boundary conditions for computational wind engineering models revisited. Journal of Wind Engineering and Industrial Aerodynamics, 99: 257–266.
Crossref Google Scholar
 

Roache PJ (1997). Quantification of uncertainty in computational fluid dynamics. Annual Review of Fluid Mechanics, 29: 123–160.
Crossref Google Scholar
 
Straw MP (2000). Computation and measurement of wind induced ventilation. PhD Thesis, University of Nottingham, UK.
 

Tominaga Y, Mochida A, Yoshie R, et al. (2008). AIJ guidelines for practical applications of CFD to pedestrian wind environment around buildings. Journal of Wind Engineering and Industrial Aerodynamics, 96: 1749–1761.
Crossref Google Scholar
 

Zhang X, Weerasuriya AU, Wang J, et al. (2022). Cross-ventilation of a generic building with various configurations of external and internal openings. Building and Environment, 207: 108447.
Crossref Google Scholar
 

Zhong H-Y, Zhang D, Liu D, et al. (2018). Two-dimensional numerical simulation of wind driven ventilation across a building enclosure with two free apertures on the rear side: Vortex shedding and “pumping flow mechanism”. Journal of Wind Engineering and Industrial Aerodynamics, 179: 449–462.
Crossref Google Scholar
 

Zhong H-Y, Zhang D, Liu Y, et al. (2019). Wind driven “pumping” fluid flow and turbulent mean oscillation across high-rise building enclosures with multiple naturally ventilated apertures. Sustainable Cities and Society, 50: 101619.
Crossref Google Scholar
 

Zhong H-Y, Lin C, Sun Y, et al. (2021). Boundary layer wind tunnel modeling experiments on pumping ventilation through a three-story reduce-scaled building with two openings. Building and Environment, 202: 108043.
Crossref Google Scholar
 

Zhong H-Y, Sun Y, Shang J, et al. (2022). Single-sided natural ventilation in buildings: A critical literature review. Building and Environment, 212: 108797.
Crossref Google Scholar
Building Simulation
Volume 17 Issue 2,
February 2024
Pages 267-284
DOI: 10.1007/s12273-023-1068-3
Cite this article:
Zhong H-Y, Sun J, Lin C, et al. CFD simulation of pumping ventilation in a three-story isolated building with internal partitioning: Effects of partition widths, heights and locations. Building Simulation, 2024, 17(2): 267-284. https://doi.org/10.1007/s12273-023-1068-3

239

Views

1

Crossref

4

Web of Science

2

Scopus

0

CSCD

Altmetrics
Received: 30 May 2023
Revised: 06 July 2023
Accepted: 01 August 2023
Published: 22 August 2023
© Tsinghua University Press 2023
Return