An Assessment of Indoor Air Quality and Thermal Comfort in Educational Spaces (Case Study: Girls' High Schools in Arak, Iran)
Subject Areas : Built EnvironmentAzin Velashjerdi Farahani 1 , Mansoureh Tahbaz 2 , Shahram Delfani 3
1 - M.A., Shahid Beheshti University,School of Architecture and Urban Design, Shahid Beheshti University,
2 - Associate Professor, Shahid Beheshti University, School of Architecture, Department of Construction, Tehran, Iran
3 - Associate professor, Road, Housing and Urban Development Research Center (BHRC), Tehran, Iran.
Keywords: educational spaces, Natural ventilation, Indoor air quality, Thermal Comfort,
Abstract :
As students spend one-third of their time at school, their health, comfort, and productivity are mostly influenced by thermal condition and indoor air quality of classrooms. Regarding that manual window-opening is a common way for providing fresh air in classes and students aren't allowed to change their uniform, position or control the windows during the lesson hours, providing thermal comfort in winters may cause a lack of fresh air and therefore, dissatisfaction. This article is trying to evaluate the indoor air quality, and thermal condition of the classrooms, in two typical classrooms for 15-16-year-old girls in Arak, Iran. The overall study objective is to compare indoor microclimate measured parameters, with (1) students' subjective judgment, collected through a questionnaire, and (2) standards and to investigate the effects of microclimate on the indoor environmental condition of classrooms. According to the results, the thermal sensation of the students depends on their clothing rate and their understanding of the thermal state. In contrast, their thermal satisfaction is affected by the amount of fresh air provided. In winter, because of closed windows, students are mostly dissatisfied with the air quality and, therefore, thermal comfort, while in spring that the indoor environmental conditions meet the standards; the students feel satisfied with the conditions. The results of this research show that the indoor environment of the classrooms is mainly influenced by internal loads; consequently, its thermal condition is not a defining parameter.
Ali, H. H., & Al-Hashlamun, R. (2019). Assessment of indoor thermal environment in different prototypical school buildings in Jordan. Alexandria Engineering Journal, 58(2), 699-711.
ASHRAE 55 (2010) ASHRAE Standard 55-2010. Thermal Environmental Conditions for Human Occupancy. American Society of Heating, Refrigerating and Air-Conditioning Engineers, Atlanta.
ASHRAE Standard 62.1 (ANSI/ASHRAE). (2010). Ventilation for acceptable indoor air quality. American Society of Heating, Refrigerating, and Air-Conditioning Engineers, Inc.: Atlanta, GA.
CBE Thermal Comfort Tool. (2018). Retrieved from: https://comfort.cbe.berkeley.edu/
Pereira, L. D., Raimondo, D., Corgnati, S. P., & da Silva, M. G. (2014). Assessment of indoor air quality and thermal comfort in Portuguese secondary classrooms: Methodology and results. Building and Environment, 81, 69-80.
El-Darwish, I. I., & El-Gendy, R. A. (2018). Post occupancy evaluation of thermal comfort in higher educational buildings in a hot arid climate. Alexandria engineering journal, 57(4), 3167-3177.
Givoni, B. (1992). Comfort, climate analysis and building design guidelines. Energy and buildings, 18(1), 11-23.
He, Y., Li, N., Peng, J., Zhang, W., & Li, Y. (2016). Field study on adaptive comfort in air conditioned dormitories of university with hot-humid climate in summer. Energy and Buildings, 119, 1-12.
Heracleous, C., & Michael, A. (2019). Experimental assessment of the impact of natural ventilation on indoor air quality and thermal comfort conditions of educational buildings in the Eastern Mediterranean region during the heating period. Journal of Building Engineering, 26, 100917.
Iran Meteorological Organization Data Center. (2018). Retrieved from: Https://Data.Irimo.Ir/," n.d.
Johnson, D. L., Lynch, R. A., Floyd, E. L., Wang, J., & Bartels, J. N. (2018). Indoor air quality in classrooms: Environmental measures and effective ventilation rate modeling in urban elementary schools. Building and Environment, 136, 185-197.
Liu, J., Yang, X., Jiang, Q., Qiu, J., & Liu, Y. (2019). Occupants’ thermal comfort and perceived air quality in natural ventilated classrooms during cold days. Building and Environment, 158, 73-82.
Merabtine, A., Maalouf, C., Hawila, A. A. W., Martaj, N., & Polidori, G. (2018). Building energy audit, thermal comfort, and IAQ assessment of a school building: A case study. Building and Environment, 145, 62-76.
Orosa, J. A., & Oliveira, A. C. (2012). Passive methods as a solution for improving indoor environments. Springer Science & Business Media.
Ricciardi, P., & Buratti, C. (2018). Environmental quality of university classrooms: Subjective and objective evaluation of the thermal, acoustic, and lighting comfort conditions. Building and Environment, 127, 23-36.
Singh, M. K., Kumar, S., Ooka, R., Rijal, H. B., Gupta, G., & Kumar, A. (2018). Status of thermal comfort in naturally ventilated classrooms during the summer season in the composite climate of India. Building and Environment, 128, 287-304.
Strøm‐Tejsen, P., Zukowska, D., Wargocki, P., & Wyon, D. P. (2016). The effects of bedroom air quality on sleep and next‐day performance. Indoor Air, 26(5), 679-686.
Elshafei, G., Negm, A., Bady, M., Suzuki, M., & Ibrahim, M. G. (2017). Numerical and experimental investigations of the impacts of window parameters on indoor natural ventilation in a residential building. Energy and Buildings, 141, 321-332.
Tahbaz, M. (2013). A method for microclimate observation and thermal analysis-tropical condition of Kuala Lumpur. Iran University of Science & Technology, 23(1), 1-16.
Zar, J. H. (1974). Probabilities for Spearman rank correlation coefficients. Behavior Research Methods & Instrumentation, 6(3), 357-357.
Zuhaib, S., Manton, R., Griffin, C., Hajdukiewicz, M., Keane, M. M., & Goggins, J. (2018). An Indoor Environmental Quality (IEQ) assessment of a partially-retrofitted university building. Building and Environment, 139, 69-85.