OBJECTIVES: In 1999, Cherrie carried out a series of mathematical simulations to investigate dispersion of pollutants through two indoor zones: the near-field (NF) and the far-field (FF). The results of these simulations were used to derive modifying factors for use in exposure modeling. However, in the original simulations, no account was taken of deposition on surfaces, either from sedimentation of aerosols or other mechanisms or the potential effects of intermittent or short duration sources. These factors may affect pollutant dispersion, particularly the relationship between NF and FF levels. The Advanced REACH Tool (ART) is based on a two-zone dispersion paradigm. Further simulations have been carried out to help ensure that the ART realistically reflects pollutant dispersion. METHODS: Pollutant dispersion has been simulated using a two-compartment well-mixed box model to represent the NF and the FF. Simulations were repeated for a range of room sizes and ventilation conditions. Intermittent sources (e.g. batch processes) were simulated by having the source active for 1 h followed by a 1-h gap, while short duration work emissions were set to last for 10 min, 30 min, 1 h, or 4 h, within the working day. Deposition was modeled by adding an equivalent air exchange rate based on published research data. Simulations were undertaken for non-volatile, monodisperse aerosols of aerodynamic diameter: 0.3, 1, 3, 10, 30, and 100 μm and the results were then interpreted in terms of typical polydisperse industrial aerosols. RESULTS: Room size and general ventilation strongly influenced dispersion from the NF to the FF as Cherrie had originally found. When varying the duration of the simulation, the biggest difference from continuous work was seen in small poorly ventilated rooms, with the ratio of the NF to FF concentration for 1-h work in the smallest room and lowest air exchange rate being a fifth of that calculated for continuous work. For large rooms and high general ventilation rates, the duration of the activity made little difference to dispersion. The results suggest that for the purposes of dispersion intermittent batch work is equivalent to continuous work. For typical simulated poly-disperse aerosols, the main effect of aerosol deposition was to reduce the predicted high concentrations compared to vapours when working in confined spaces. CONCLUSIONS: Both short duration of source emissions and deposition of aerosols have an important effect on dispersion, and the results from this study have been reflected in the ART model.
OBJECTIVES: In 1999, Cherrie carried out a series of mathematical simulations to investigate dispersion of pollutants through two indoor zones: the near-field (NF) and the far-field (FF). The results of these simulations were used to derive modifying factors for use in exposure modeling. However, in the original simulations, no account was taken of deposition on surfaces, either from sedimentation of aerosols or other mechanisms or the potential effects of intermittent or short duration sources. These factors may affect pollutant dispersion, particularly the relationship between NF and FF levels. The Advanced REACH Tool (ART) is based on a two-zone dispersion paradigm. Further simulations have been carried out to help ensure that the ART realistically reflects pollutant dispersion. METHODS: Pollutant dispersion has been simulated using a two-compartment well-mixed box model to represent the NF and the FF. Simulations were repeated for a range of room sizes and ventilation conditions. Intermittent sources (e.g. batch processes) were simulated by having the source active for 1 h followed by a 1-h gap, while short duration work emissions were set to last for 10 min, 30 min, 1 h, or 4 h, within the working day. Deposition was modeled by adding an equivalent air exchange rate based on published research data. Simulations were undertaken for non-volatile, monodisperse aerosols of aerodynamic diameter: 0.3, 1, 3, 10, 30, and 100 μm and the results were then interpreted in terms of typical polydisperse industrial aerosols. RESULTS: Room size and general ventilation strongly influenced dispersion from the NF to the FF as Cherrie had originally found. When varying the duration of the simulation, the biggest difference from continuous work was seen in small poorly ventilated rooms, with the ratio of the NF to FF concentration for 1-h work in the smallest room and lowest air exchange rate being a fifth of that calculated for continuous work. For large rooms and high general ventilation rates, the duration of the activity made little difference to dispersion. The results suggest that for the purposes of dispersion intermittent batch work is equivalent to continuous work. For typical simulated poly-disperse aerosols, the main effect of aerosol deposition was to reduce the predicted high concentrations compared to vapours when working in confined spaces. CONCLUSIONS: Both short duration of source emissions and deposition of aerosols have an important effect on dispersion, and the results from this study have been reflected in the ART model.
Authors: Eun Gyung Lee; Judith Lamb; Nenad Savic; Ioannis Basinas; Bojan Gasic; Christian Jung; Michael L Kashon; Jongwoon Kim; Martin Tischer; Martie van Tongeren; David Vernez; Martin Harper Journal: Ann Work Expo Health Date: 2019-02-16 Impact factor: 2.179
Authors: María Fernanda Cely-García; Frank C Curriero; Mauricio Sánchez-Silva; Patrick N Breysse; Margarita Giraldo; Lorena Méndez; Carlos Torres-Duque; Mauricio Durán; Mauricio González-García; Patricia Parada; Juan Pablo Ramos-Bonilla Journal: J Expo Sci Environ Epidemiol Date: 2016-12-14 Impact factor: 5.563
Authors: John William Cherrie; Wouter Fransman; Gerardus Antonius Henrikus Heussen; Dorothea Koppisch; Keld Alstrup Jensen Journal: Int J Environ Res Public Health Date: 2020-01-07 Impact factor: 3.390
Authors: Mónica López-Alonso; Beatriz Díaz-Soler; María Martínez-Rojas; Carlos Fito-López; María Dolores Martínez-Aires Journal: Int J Environ Res Public Health Date: 2020-12-09 Impact factor: 3.390
Authors: Urs Schlüter; Susan Arnold; Francesca Borghi; John Cherrie; Wouter Fransman; Henri Heussen; Michael Jayjock; Keld Alstrup Jensen; Joonas Koivisto; Dorothea Koppisch; Jessica Meyer; Andrea Spinazzè; Celia Tanarro; Steven Verpaele; Natalie von Goetz Journal: Int J Environ Res Public Health Date: 2022-01-22 Impact factor: 3.390
Authors: Kevin McNally; Nicholas Warren; Wouter Fransman; Rinke Klein Entink; Jody Schinkel; Martie van Tongeren; John W Cherrie; Hans Kromhout; Thomas Schneider; Erik Tielemans Journal: Ann Occup Hyg Date: 2014-03-24