Workplace Exposure to Nanoparticles during Thermal Spraying of Ceramic Coatings
Thermal spraying is widely used for industrial-scale application of ceramic coatings onto metallic surfaces. The particular process has implications for occupational health, as the high energy process generates high emissions of metal-bearing nanoparticles. Emissions and their impact on exposure were characterized during thermal spraying in a work environment, by monitoring size-resolved number and mass concentrations, lung-deposited surface area, particle morphology, and chemical composition. Along with exposure quantification, the modal analysis of the emissions assisted in distinguishing particles from different sources, while an inhalation model provided evidence regarding the potential deposition of particulate matter on human respiratory system. High particle number (>106 cm-3; 30-40 nm) and mass (60-600 µgPM1 m-3) concentrations were recorded inside the spraying booths, which impacted exposure in the worker area (104-105 cm-3, 40-65 nm; 44-87 µgPM1 m-3). Irregularly-shaped, metal-containing particles (Ni, Cr, W) were sampled from the worker area, as single particles and aggregates (5-200 nm). Energy dispersive X-ray analysis confirmed the presence of particles originated from the coating material, establishing a direct link between the spraying activity and exposure. In particle number count, 90% of the particles were between 26-90 nm. Inhaled dose rates, calculated from the exposure levels, resulted in particle number rates (n˙) between 353 × 106-1024 × 106 min-1, with 70% of deposition occurring in the alveolar region. The effectiveness of personal protective equipment (FPP3 masks) was tested under real working conditions. The proper sealing of the spraying booths was identified as a key element for exposure reduction. This study provides high time-resolved aerosol data which may be valuable for validating indoor aerosol models applied to risk assessment.
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dig-idaea-es-10261-2098772020-12-13T00:02:02Z Workplace Exposure to Nanoparticles during Thermal Spraying of Ceramic Coatings Salmatonidis, A. Ribalta, Carla Sanfélix, V. Bezantakos, S. Biskos, G. Vulpoi, A. Simion, S. Monfort, E. Viana, Mar Thermal spraying is widely used for industrial-scale application of ceramic coatings onto metallic surfaces. The particular process has implications for occupational health, as the high energy process generates high emissions of metal-bearing nanoparticles. Emissions and their impact on exposure were characterized during thermal spraying in a work environment, by monitoring size-resolved number and mass concentrations, lung-deposited surface area, particle morphology, and chemical composition. Along with exposure quantification, the modal analysis of the emissions assisted in distinguishing particles from different sources, while an inhalation model provided evidence regarding the potential deposition of particulate matter on human respiratory system. High particle number (>106 cm-3; 30-40 nm) and mass (60-600 µgPM1 m-3) concentrations were recorded inside the spraying booths, which impacted exposure in the worker area (104-105 cm-3, 40-65 nm; 44-87 µgPM1 m-3). Irregularly-shaped, metal-containing particles (Ni, Cr, W) were sampled from the worker area, as single particles and aggregates (5-200 nm). Energy dispersive X-ray analysis confirmed the presence of particles originated from the coating material, establishing a direct link between the spraying activity and exposure. In particle number count, 90% of the particles were between 26-90 nm. Inhaled dose rates, calculated from the exposure levels, resulted in particle number rates (n˙) between 353 × 106-1024 × 106 min-1, with 70% of deposition occurring in the alveolar region. The effectiveness of personal protective equipment (FPP3 masks) was tested under real working conditions. The proper sealing of the spraying booths was identified as a key element for exposure reduction. This study provides high time-resolved aerosol data which may be valuable for validating indoor aerosol models applied to risk assessment. 2020-04-30T15:39:03Z 2020-04-30T15:39:03Z 2019 2020-04-30T15:39:03Z artículo http://purl.org/coar/resource_type/c_6501 doi: 10.1093/annweh/wxy094 issn: 2398-7316 Annals of Work Exposures and Health 63: 91- 106 (2019) http://hdl.handle.net/10261/209877 10.1093/annweh/wxy094 Postprint http://dx.doi.org/10.1093/annweh/wxy094 Sí open |
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Thermal spraying is widely used for industrial-scale application of ceramic coatings onto metallic surfaces. The particular process has implications for occupational health, as the high energy process generates high emissions of metal-bearing nanoparticles. Emissions and their impact on exposure were characterized during thermal spraying in a work environment, by monitoring size-resolved number and mass concentrations, lung-deposited surface area, particle morphology, and chemical composition. Along with exposure quantification, the modal analysis of the emissions assisted in distinguishing particles from different sources, while an inhalation model provided evidence regarding the potential deposition of particulate matter on human respiratory system. High particle number (>106 cm-3; 30-40 nm) and mass (60-600 µgPM1 m-3) concentrations were recorded inside the spraying booths, which impacted exposure in the worker area (104-105 cm-3, 40-65 nm; 44-87 µgPM1 m-3). Irregularly-shaped, metal-containing particles (Ni, Cr, W) were sampled from the worker area, as single particles and aggregates (5-200 nm). Energy dispersive X-ray analysis confirmed the presence of particles originated from the coating material, establishing a direct link between the spraying activity and exposure. In particle number count, 90% of the particles were between 26-90 nm. Inhaled dose rates, calculated from the exposure levels, resulted in particle number rates (n˙) between 353 × 106-1024 × 106 min-1, with 70% of deposition occurring in the alveolar region. The effectiveness of personal protective equipment (FPP3 masks) was tested under real working conditions. The proper sealing of the spraying booths was identified as a key element for exposure reduction. This study provides high time-resolved aerosol data which may be valuable for validating indoor aerosol models applied to risk assessment. |
| format |
artículo |
| author |
Salmatonidis, A. Ribalta, Carla Sanfélix, V. Bezantakos, S. Biskos, G. Vulpoi, A. Simion, S. Monfort, E. Viana, Mar |
| spellingShingle |
Salmatonidis, A. Ribalta, Carla Sanfélix, V. Bezantakos, S. Biskos, G. Vulpoi, A. Simion, S. Monfort, E. Viana, Mar Workplace Exposure to Nanoparticles during Thermal Spraying of Ceramic Coatings |
| author_facet |
Salmatonidis, A. Ribalta, Carla Sanfélix, V. Bezantakos, S. Biskos, G. Vulpoi, A. Simion, S. Monfort, E. Viana, Mar |
| author_sort |
Salmatonidis, A. |
| title |
Workplace Exposure to Nanoparticles during Thermal Spraying of Ceramic Coatings |
| title_short |
Workplace Exposure to Nanoparticles during Thermal Spraying of Ceramic Coatings |
| title_full |
Workplace Exposure to Nanoparticles during Thermal Spraying of Ceramic Coatings |
| title_fullStr |
Workplace Exposure to Nanoparticles during Thermal Spraying of Ceramic Coatings |
| title_full_unstemmed |
Workplace Exposure to Nanoparticles during Thermal Spraying of Ceramic Coatings |
| title_sort |
workplace exposure to nanoparticles during thermal spraying of ceramic coatings |
| publishDate |
2019 |
| url |
http://hdl.handle.net/10261/209877 |
| work_keys_str_mv |
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