| Title: | Comprehensive assessment of the indoor air quality in a chlorinated Olympic-size swimming pool |
| Author(s): | Felgueiras F; Mourao Z; Morais C; Santos H; Gabriel MF; De Oliveira Fernandes E; |
| Address: | "INEGI, Institute of Science and Innovation in Mechanical and Industrial Engineering, Porto, Portugal. INEGI, Institute of Science and Innovation in Mechanical and Industrial Engineering, Porto, Portugal. Electronic address: mgabriel20023@gmail.com. Faculty of Engineering, University of Porto, Porto, Portugal" |
| DOI: | 10.1016/j.envint.2019.105401 |
| ISSN/ISBN: | 1873-6750 (Electronic) 0160-4120 (Linking) |
| Abstract: | "Elite swimmers and swimming pool employees are likely to be at greater health risk due to their regular and intense exposure to air stressors in the indoor swimming pool environment. Since data on the real long-term exposure is limited, a long-term monitoring and sampling plan (22 non-consecutive days, from March to July 2017) was carried out in an indoor Olympic-size pool with a chlorine-based disinfection method to characterize indoor environments to which people involved in elite swimming and maintenance staff may be exposed to. A comprehensive set of parameters related with comfort and environmental conditions (temperature, relative humidity (RH), carbon dioxide (CO(2)) and monoxide and ultrafine particles (UFP)) were monitored both indoors and outdoors in order to determine indoor-to-outdoor (I/O) ratios. Additionally, an analysis of volatile organic compounds (VOC) concentration and its dynamics was implemented in three 1-hr periods: early morning, evening elite swimmers training session and late evening. Samplings were simultaneously carried out in the air layer above the water surface and in the air surrounding the pool, selected to be representative of swimmers and coaches/employees' breathing zones, respectively. The results of this work showed that the indoor climate was very stable in terms of air temperature, RH and CO(2). In terms of the other measured parameters, mean indoor UFP number concentrations (5158 pt/cm(3)) were about 50% of those measured outdoors whereas chloroform was the predominant substance detected in all samples collected indoors (13.0-369.3 microg/m(3)), among a varied list of chemical compounds. An I/O non-trihalomethanes (THM) VOC concentration ratio of 2.7 was also found, suggesting that, beyond THM, other potentially hazardous VOC have also their source(s) indoors. THM and non-THM VOC concentration were found to increase consistently during the evening training session and exhibited a significant seasonal pattern. Compared to their coaches, elite swimmers seemed to be exposed via inhalation to significantly higher total THM levels, but to similar concentrations of non-THM VOC, during routine training activities. Regarding swimming employees, the exposure to THM and other VOC appeared to be significantly minimized during the early morning period. The air/water temperature ratio and RH were identified as important parameters that are likely to trigger the transfer processes of volatile substances from water to air and of their accumulation in the indoor environment of the swimming pool, respectively" |
| Keywords: | "*Air Pollutants *Air Pollution, Indoor Environmental Monitoring Humans Particulate Matter Swimming *Swimming Pools Trihalomethanes *Volatile Organic Compounds Disinfection by-products Exposure assessment Indoor air quality Indoor swimming pool Ultrafine p;" |
| Notes: | "MedlineFelgueiras, Fatima Mourao, Zenaida Morais, Catarina Santos, Hugo Gabriel, Marta Fonseca de Oliveira Fernandes, Eduardo eng Research Support, Non-U.S. Gov't Netherlands 2019/12/31 Environ Int. 2020 Mar; 136:105401. doi: 10.1016/j.envint.2019.105401. Epub 2019 Dec 26" |
