Assessing the Peak-Period Thermal Conditions of Large Places of Worship in Ahmadu Bello University Main Campus Zaria, Nigeria
DOI:
https://doi.org/10.5281/zenodo.13895587Keywords:
Religious Buildings, Thermal comfort, Thermal Comfort indicators, Comfort zoneAbstract
One of the most gruelling challenges for the users of places of worship in the tropical hot regions is the extreme thermal discomfort during the peak activity periods. This study investigated the thermal comfort conditions of mosques and churches of ABU Zaria main campus. To fully understand the occupants’ experience, the study applied an empirical field observations method to obtain primary data that was subsequently subjected to comparative analysis against the stipulated comfort zones for the location from a set of validated thermal comfort standards. The results show that the combined impact of air temperature, relative humidity and wind speed provided a comprehensive deduction that thermal comfort is such a great challenge to attain in the places of worship throughout the survey period. The average cases of temperature profile on a typical day of the hottest week recorded a temperature difference of +2.85 °C from the outdoor temperature in the ITN mosque, which is the highest record, while the lowest was +2.15°C on ABU Chapel. Worse cases were observed to be +4.50 °C in the hottest moments during Friday prayer in the ITN Mosque and +4.10 °C during the Sunday mass in OLQPP chapel. The study concludes that the design of crowded worship spaces requires a holistic approach of balancing the comfort indices with adequate natural ventilation and supplementary augmentation with mechanical systems.
References
Abdullah, I. A., Salisu, A. S., & Dahiru, A. (2023). Determining the Adaptive Thermal
Comfort and Preference Votes of Children in Public Primary Schools in the Hot
Semi-arid Climatic Zone of Nigeria. Journal of Human Centered Technology, 2(2), 1-10.
Abubakar, R., & Ibrahim, R. H. (2019). Assessing the Role of Double Skin Facade In
Improving The Thermal Comfort Condition of Microfinance Bank; Ahmadu Bello
University, Zaria; Nigeria. Issn 2735-993x, 305.
Abubakar, R., & Ibrahim, R. H. (2019). Assessing the Role of Double Skin Facade In
Improving The Thermal Comfort Condition of Microfinance Bank; Ahmadu Bello University, Zaria; Nigeria. Issn 2735-993x, 305.
Al Touma, A., & Ouahrani, D. (2017). Enhanced thermal performance of mosques in Qatar.
In IOP Conference Series: Earth and Environmental Science (Vol. 104, No. 1, p. 012012). IOP Publishing. Retrieved from doi:10.1088/1755-1315/104/1/012012 on 20/8/23
Aryal, A., Chaiwiwatworakul, P., Chirarattananon, S., & Wattanakit, S. (2021). A field
survey of thermal comfort in air-conditioned space in Songkhla’s hot humid climate. Engineering Journal, 25(2), 235-244.
ASHRAE, (2020). ASHRAE Standard 55-2020. Thermal Environmental Conditions for
Human Occupancy. American Society of Heating, Refrigerating and Air-Conditioning Engineers.
Azmi, N. A., Baharun, A., Arıcı, M., & Ibrahim, S. H. (2023). Improving thermal comfort in
mosques of hot-humid climates through passive and low-energy design strategies. Frontiers of Architectural Research, 12(2), 361-385. Retrieved on 08/08/23 FROM https://doi.org/10.1016/j.foar.2022.07.001
Chen, G., Hua, J., Shi, Y., & Ren, C. (2023). Constructing air temperature and relative
humidity-based hourly thermal comfort dataset for a high-density city using machine learning. Urban Climate, 47, 101400.
Chiguchi, M., Yamaguchi, H., Higashino, T., & Shimoda, Y. (2016). Human thermal comfort
estimation in indoor space by crowd sensing. In 2016 IEEE International Conference on Smart Grid Communications (SmartGridComm) (pp. 45-50). IEEE.
Garba. A. (2011). An Analysis Of Thermal Comfort Indices Based On The Temperature –
Humidity Index Of Zaria, Kaduna State, Nigeria A Thesis Submitted To The School Of Postgraduate Studies, Ahmadu Bello University, Zaria In Partial Fulfillment Of The Requirements For The Award Of Master Degree In Geography Department Of Geography, Faculty Of Science Ahmadu Bello University, Zaria, Nigeria
ISO 7730 (2005) Ergonomics of the Thermal Environment. Analytical Determination and
Interpretation of Thermal Comfort Using Calculation of the PMV and PPD Indices and Local Thermal Comfort Criteria. CEN (European Committee for Standardization). Geneva.
Kazman, R., and Klein, M. (2002). Making Architecture Design Decisions: An Economic
Approach. Carnegie Mellon University
Malgwi, E. M., & Sagada, M. L. (2014). An evaluation of thermal comfort conditions in an
urban entertainment centre in the hot-dry climate of Nigeria. International Journal of Energy and Environmental Research, 2(1), 55-74.
Ministry Of New And Renewable Energy (MNRE), 2020. Water and Energy International,
(8), 6-8.
Moossavi, S. M. (2014). Adaptive Thermal Comfort Model. GREENARCS–Green
Architecture and Arts Online Magazine; International Conference and Exhibition on Green Buildings and Built Environment 10th Edition. Retrieved from https://www.researchgate.net/publication/343153355
Ogunsote, O.O. (1991). Introduction to Building Climatology; A Basic Course for
Architecture Students. First Edition. Ahmadu Bello University Press, Nigeria
Ogunsote, O. O. and Prucnal-Ogunsote, B. (2002). Comfort Limits for the Effective
Temperature Index in the Tropics: A Nigerian Case Study. Architectural Science
Review, 45:2, 125- 132, Sydney, Australia.
Olanipekun E.A. (2017).Thermal comfort and occupant behaviour in a naturally ventilated
hostel in warm-humid climateof Ile-Ife, Nigeria. Civil and Environmental Research,2017,9(7): 44–60.
Olesen, B. W., & Parsons, K. C. (2002). Introduction to thermal comfort standards and the
proposed a new version of EN ISO 7730. Energy and buildings, 34(6), 537-548.
Schellen, L., van Marken Lichtenbelt, W. D.; Loomans, M. G.; Toftum, J.; de Wit, M.H.
Differences between young adults and elderly in thermal comfort, productivity, and thermal Physiology in response to moderate temperature drift and a steady-state condition. Indoor Air, 2010 Aug; 20(4):273-83.
Szokolay, V.S. (2008). Introduction to Architectural Science: The Basis of Sustainable
Design Second edition. Oxford, Elsevier
Vella, R. C., Martinez, F. J. R., Yousif, C., & Gatt, D. (2020). A study of thermal comfort in
naturally ventilated churches in a Mediterranean climate. Energy and buildings, 213, 109843. Retrieved on 18/08/23 from https://doi.org/10.1016/j.enbuild.2020.109843
Wargocki, P., Sundell, J., Bischof, W., Brundrett, G., Fanger, P. O., Gyntelberg, F., ... &
Wouters, P. (2002). Ventilation and health in non-industrial indoor environments: report from a European multidisciplinary scientific consensus meeting (EUROVEN). Indoor air, 12(2), 113-128.
Wu, Y., Fan, J., & Cao, B. (2023). Comparison among different modelling approaches for
personalized thermal comfort prediction when using personal comfort systems. Energy and Buildings, 285, 112873.
Wu, Y., Liu, H., Li, B., Kosonen, R., Kong, D., Zhou, S., & Yao, R. (2019). Thermal
adaptation of the elderly during summer in a hot humid area: Psychological, behavioural, and physiological responses. Energy and Buildings, 203, 109450.
Youssef, A., Hamid, A., & Vatopoulos, K. (2017). Reuse of ablution water for mosque air-
conditioning using Indirect Direct Evaporative Cooling (IDEC) technology in Saudi Arabia. ASHRAE Transactions, 123(1).
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