A review of advanced air distribution methods - theory, practice, limitations and solutions

Yang, Bin; Melikov, Arsen Krikor; Kabanshi, Alan; Zhang, Chen; Bauman, Fred; Cao, Guangyu; Awbi, Hazim; Wigö, Hans; Niu, Jianlei; Cheong, David; Tham, Kwok Wai; Sandberg, Mats; Nielsen, Peter; Kosonen, Risto; Yao, Runming; Kato, Shinsuke; Sekhar, S. Chandra; Schiavon, Stefano; Karimipanah, Taghi; Li, X.; Lin, Zhang

doi:10.1016/j.enbuild.2019.109359

Cited by 185 publications

(92 citation statements)

References 157 publications

(159 reference statements)

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“…In the convective type of localized systems, personalized ventilation in conjunction with mixing ventilation or displacement ventilation would provide a higher thermal comfort and a better perceived air quality compared with that could be provided by the total volume system. 30 According to the EN ISO 7730:2005, 68 how the increased air movement could enhance thermal comfort, e.g. by using desk fans is prescribed.…”

Section: Discussionmentioning

confidence: 99%

Experimental comparison of local low velocity unit combined with radiant panel and diffuse ceiling ventilation systems

Zhao

Kilpeläinen

Kosonen

et al. 2020

Indoor and Built Environment

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In this study, the performance of a micro-environment system was analysed and compared with diffused ceiling ventilation. In the analysed micro-environment low velocity radiant panel system, two low velocity units and radiant panels were installed above workstations to supply directly clean air to occupants and to cover the cooling power required. With diffused ceiling ventilation, all cooling demand is covered with air and thus, the airflow rate required is higher than with low velocity radiant panel system. The varied heat gain from 40 to 80 W/m2 consists of two seated dummies, laptops, monitors and simulated solar gain. The results show that with perimeter exhaust and local supply air, 8–13% reduction of the total cooling load required is possible, in comparison to the standard mixing systems. The average exhaust temperature was 0.7–1.9°C higher than average room air temperature at the workstation. Moreover, the mean air temperature with the low velocity radiant panel system at the occupied zone was 0.6°C lower than with diffused ceiling ventilation. With low velocity radiant panel system, the air velocity was less than 0.12 m/s in the occupied zone. Also, the draught rate was less than 10%. Furthermore, the air change efficiency with the low velocity radiant panel system was over 70% which is better than 44–49% efficiency with diffused ceiling ventilation.

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Section: Discussionmentioning

confidence: 99%

Experimental comparison of local low velocity unit combined with radiant panel and diffuse ceiling ventilation systems

Zhao

Kilpeläinen

Kosonen

et al. 2020

Indoor and Built Environment

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“…The copyright holder for this this version posted October 6, 2020. ; https://doi.org/10.1101/2020.10.03.20206391 doi: medRxiv preprint is served with displacement ventilation that the conditioned air is supplied near the floor level (S1-S14) (with the supply air temperature around 20°C and supply airflow rate around ACH) and exhausted from the ceiling (E1-E3). Displacement ventilation has an airflow pattern with high contaminant removal efficiency at the breathing level [13]. SF6 (released from the mouth of the infector in Figure 1) is used as the tracer gas to represent the airborne contaminants [31][32][33].…”

Section: Benchmark With Rebreathed-fraction Model Under Well-mixed Anmentioning

confidence: 99%

Dilution-based Evaluation of Airborne Infection Risk - Thorough Expansion of Wells-Riley Model

Zhang

Lin

2020

Preprint

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Evaluation of airborne infection risk with spatial and temporal resolutions is indispensable for the design of proper interventions fighting infectious respiratory diseases (e.g., COVID-19), because the distribution of aerosol contagions is both spatially and temporally non-uniform. However, the well-recognized Wells-Riley model and modified Wells-Riley model (i.e., the rebreathed-fraction model) are limited to the well-mixed condition and unable to evaluate airborne infection risk spatially and temporally, which could result in overestimation or underestimation of airborne infection risk. This study proposes a dilution-based evaluation method for airborne infection risk. The method proposed is benchmarked by the Wells-Riley model and modified Wells-Riley model, which indicates that the method proposed is a thorough expansion of the Wells-Riley model for evaluation of airborne infection risk with both spatial and temporal resolutions. Experiments in a mock hospital ward also demonstrate that the method proposed effectively evaluates the airborne infection risk both spatially and temporally.

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“…There are many different air distribution modes for built environments [27] . The general principles for AIIRs are to achieve and maintain a directional air distribution from a clean area to a less clean area [28] , [29] and to position exhaust vents as close to contaminant sources as possible [12] .…”

Section: Introductionmentioning

confidence: 99%

Adaptive Wall-Based Attachment Ventilation: A Comparative Study on Its Effectiveness in Airborne Infection Isolation Rooms with Negative Pressure

Zhang

Han

et al. 2022

Engineering

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A review of advanced air distribution methods - theory, practice, limitations and solutions

Cited by 185 publications

References 157 publications

Experimental comparison of local low velocity unit combined with radiant panel and diffuse ceiling ventilation systems

Experimental comparison of local low velocity unit combined with radiant panel and diffuse ceiling ventilation systems

Dilution-based Evaluation of Airborne Infection Risk - Thorough Expansion of Wells-Riley Model

Adaptive Wall-Based Attachment Ventilation: A Comparative Study on Its Effectiveness in Airborne Infection Isolation Rooms with Negative Pressure

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