Indoor Air Quality Monitoring and Characterization of Airborne Workstations Pollutants Within Detergent Production Plant

Overview

Journal Toxics

Date 2022 Jul 27

PMID 35893852

Authors

John Stephen Gushit

Salamatu Uba Mohammed

Haruna Musa Moda

Affiliations

Soon will be listed here.

Abstract

The indoor air quality (IAQ) of five workstations within a detergent production unit was monitored. Particulate matter (PM) was measured using a gravitational settlement method, and later characterized. To ascertain the quality of indoor air within the workstations, which could directly or indirectly affect the health and performance of the workers, a physical inspection of the plant premises was undertaken. The mean value of the following air-quality parameters; particulate matter(PM), particulate matter (PM), formaldehyde (HCHO), volatile organic compounds (VOCs), carbon dioxide (CO), temperature (T) and percent relative humidity (%RH) were obtained within the range of 24.5-48.5 µg/m, 26.75-61.75 µg/m, 0.0-0.012 mg/m, 0.09-1.35 mg/m, 1137-1265 ppm, 25.65-28.15 °C and 20.13-23.8%, respectively. Of the particulate matter components characterized, sodium oxide (NaO)-25.30 mg/m, aluminum oxide (AlO)-22.93 mg/m, silicon dioxide (SiO)-34.17 mg/m, sulfur trioxide (SO)-41.57 mg/m, calcium oxide (CaO)-10.94 mg/m and iron III oxide (FeO)-19.23 mg/m, were of significance. These results, compared with international standards for industrial indoor air quality, suggest that indoor air contamination emanating from the chemicals used in production workstations is traced to the design of the plant structures and the activities carried out within the workstations.

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