Particle deposition from turbulent flow: Review of published research and its applicability to ventilation ducts in commercial buildings

Sippola, Mark R.; Nazaroff, William W.

doi:10.2172/815478

Cited by 41 publications

(28 citation statements)

References 128 publications

(277 reference statements)

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“…Experimental data for the deposition velocity (Davies, 1966;Fan & Ahmadi, 1993;Johansen, 1991;Liu & Agarwal, 1974;Sippola & Nazaroff, 2002;Wood, 1981a) are limited, mainly, to measurements in small-diameter pipes, paths of physical facilities or ventilation ducts. As a rule, these measurements are taken only for a small roughness parameter, in the range of hundreds of micrometers.…”

Section: Models Of Deposition Onto Vertical Wallsmentioning

confidence: 99%

“…distance to the surface (wall) y + dimensionless distance to the surface (wall) y + = yu * / z 0 surface roughness parameter , u d pollutant dry deposition velocity air molecular path air dynamic viscosity air kinematic (molecular) viscosity = / t air turbulent viscosity air density p particle density p characteristic time of particle relaxation (deceleration) p = u s /g L Lagrangian timescale of turbulence + dimensionless relaxation time + = p u * 2 / Numerous papers (Davies, 1966;Fan & Ahmadi, 1993;Johansen, 1991;Kharchenko, 1997;Liu & Agarwal, 1974;Nho-Kim, Michou, and Peuch, 2004;Sehmel, 1973Sehmel, , 1980Sehmel & Hodgson, 1978;Sippola & Nazaroff, 2002;Slinn, 1978Slinn, , 1982Valentine and Smith, 2005;Wood, 1981aWood, , 1981bZaichik and Alipchenkov, 2007) describe semiempirical relations for the velocities of deposition onto vertical and horizontal walls. These were determined mainly from experimental data on turbulent deposition in ducts and channels.…”

Section: Introductionmentioning

confidence: 99%

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Parameterization of aerosol dry deposition velocities onto smooth and rough surfaces

Piskunov¹

2009

Journal of Aerosol Science

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Section: Models Of Deposition Onto Vertical Wallsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Parameterization of aerosol dry deposition velocities onto smooth and rough surfaces

Piskunov¹

2009

Journal of Aerosol Science

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“…Markedly, one of the relevant conclusions was the significance of the 2-7 μm particle size for airborne contamination of ventilation ducts with non-fully developed regime [54]. Previous studies have reported comparable observations with these particle sizes but for nonindustrial HVAC systems [47,[56][57][58].…”

Section: Diagnosis Of Hvac Systems Under Real Industrial Situationsmentioning

confidence: 97%

“…Sippola and Nazaroff [56,57] substantially reviewed these data and pointed out widely scattered results. Thus, Sippola and Nazaroff [65,66] conducted new experiments with steel and internally insulated rectangular ducts at air speeds typically found in ventilation ducts, 2-9 m s À1 .…”

Section: Experimental Approaches For Particle Depositionmentioning

confidence: 99%

Preventing Indoor Bioaerosol Contamination in Food Processing Environments and HVAC Systems: Assessment of Particle Deposition for Hygienic Design Purposes

Gehin

Havet

et al. 2014

Environment, Energy and Climate Change I

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This chapter deals with airborne particle contamination in food processing indoor environments and particularly within heating, ventilation, and air-conditioning (HVAC) systems in food factory buildings. The major types of bioaerosols encountered in the food manufacturing sector as well as the bioaerosol sampling methods are firstly introduced. Secondly, some features of air handling systems such as zoning, cleanrooms, localized air handling systems, and HVAC systems are presented. Besides, the study of particle deposition to duct surfaces from turbulent airflow is reviewed and discussed. Substantially, an original work combining industrial diagnosis and experiments at factory scale with experiments at laboratory scale is then proposed through the case study of the CleanAirNet project. The CleanAirNet project (Hygienic Design of Ventilation Duct Networks in Food Factories) aimed at producing new knowledge, models, and techniques to help control the safety of the food products through a better control of aerosol particle transport and deposition in the ventilation networks of the food industry. The different work packages of the project are presented relatively to the state-of-theart particle deposition on duct surfaces. The methodological findings and relevant applications (e.g., a newly patented particle trapping device for air handling systems) for food industries are exposed. The

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“…A comprehensive literature review (Sippola, 2002) revealed that considerable experimental data regarding particle deposition from turbulent flows has been collected using a range of techniques of varying quality (Sippola and Nazaroff, 2002). According to the authors, models can capture broad trends seen in experiments, but modeled results can deviate markedly from observations.…”

Section: Introductionmentioning

confidence: 99%

Transport efficiency and deposition velocity of fluidized spores in ventilation ducts

Krauter

Biermann

Larsen³

2005

Aerobiologia

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Experiments with dry, fluidized spores were conducted in a test apparatus to delineate the extent of spore contamination and deposition behavior under normal airflow conditions within a ventilation system. The surrogate biological warfare agent used in experiments was the spore-forming bacterium Bacillus atrophaeus. Viable-spore-counting methods were used in the study because they provide the most important number for estimating human health effects. Three common ventilation duct materials were evaluated: flexible plastic, galvanized steel, and internally insulated fiberglass. Transport efficiency ranged from 9 to 13% in steel and fiberglass ducts; transport efficiency was far less (0.1-4%) in plastic duct. Results showed that the deposition of surrogate biological warfare agent was significantly different in the three duct materials evaluated. All experimentally determined, dimensionless deposition velocities were in the range of theoretical predictions for dimensionless roughness, k + =10. All were 10-100 times greater than the velocities predicted for ducts with smoother surfaces, k + =0.1. For plastic duct, greater dimensionless deposition velocities were likely the result of charge forces between spores and surface. However, for the steel duct, a relatively large dimensionless deposition velocity was unexpected. These findings imply that building contamination will likely vary, depending on the specific type of duct material used throughout an affected area. Results of this study may aid in refining existing particle-transport models and remediation activities.

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Particle deposition from turbulent flow: Review of published research and its applicability to ventilation ducts in commercial buildings

Cited by 41 publications

References 128 publications

Parameterization of aerosol dry deposition velocities onto smooth and rough surfaces

Parameterization of aerosol dry deposition velocities onto smooth and rough surfaces

Preventing Indoor Bioaerosol Contamination in Food Processing Environments and HVAC Systems: Assessment of Particle Deposition for Hygienic Design Purposes

Transport efficiency and deposition velocity of fluidized spores in ventilation ducts

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