Thermal Comfort and Internal Conditions Testing of Standard Relief Tents in cold Climates

Rawan A.Fayyad; Issam   M. Ali Aljubury

doi:10.22153/kej.2025.08.004

Authors

Rawan A.Fayyad Department of Mechanical Engineering, College of Engineering, University of Baghdad, Baghdad, Iraq
Issam M. Ali Aljubury Department of Mechanical Engineering, College of Engineering, University of Baghdad, Baghdad, Iraq

DOI:

https://doi.org/10.22153/kej.2025.08.004

Keywords:

temporary shelter; thermal comfort; CBE MRT; CBE Thermal Comfort tools; PMV; PPD

Abstract

To assist decision-makers in selecting the best solutions and arriving at better solutions for temporary shelter and to identify key issues related to temporary shelter methods and provide some principles and recommendations, this study presented a theoretical investigation into the measurement of thermal comfort in standard relief tents in cold climates. The results were analysed and compared using the CBE MRT and CBE Thermal Comfort tools based on field-measured values inside a tent from December 2024 to February 2025. The results on 11, 13, 14 and 18 December 2024, were selected to avoid repetition. Thermal comfort is a key factor in the design and use of tents in cold regions because of its direct impact on the safety and well-being of occupants. Factors affecting the thermal comfort of tents in cold weather include insulation, ventilation, clothing and heating. This study was applied in nature and was conducted using a descriptive analytical approach. Data were collected using library and documentation methods. This study provides important indicators in the field of thermal comfort, particularly in the design of heating, ventilation and air conditioning systems. These environmental and individual factors influence the relationship between the predicted population mean vote and the predicted dissatisfaction rate. On the basis of these factors, the study helps measure human indoor thermal comfort and determine the influencing factors in each case to reach the desired conclusions while emphasising that the tents did not provide suitable thermal conditions for their inhabitants until they were treated using an experimental model.

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References

[1] ASHRAE, Standard 55-2004: Thermal Environmental Conditions for Human Occupancy. American Society of Heating, Refrigeration and Air-Conditioning Engineers, Atlanta, 2004.

[2] ISO 7730, Ergonomics of the Thermal Environment — Analytical Determination and Interpretation of Thermal Comfort Using Calculation of PMV and PPD Indices, 2005.

[3] A. Boerstra, “EN 16798-1:2019,” REHVA Journal, vol. 56, no. 4, 2019.

[4] K. Cao, M. Lan, H. Wang, Y. Li, and X. Liu, “The thermal environment and thermal comfort of disaster relief tents in high-temperature composite environment,” Case Studies in Thermal Engineering, vol. 50, 2023, Art. no. 103453.

[5] A. Ullal, S. Aguacil, and R. Vannucci, “Comparing thermal performance of standard humanitarian tents,” Energy and Buildings, vol. 264, pp. 1–11, 2022.

[6] L. Zhang, Y. Yu, L. Xu, W. Zhang, and Q. Shen, “Experimental study on indoor air thermal equilibrium model of the tent,” International Journal of Low-Carbon Technologies, vol. 12, pp. 36–42, 2017.

[7] T. Stegmaier et al., “Energy-efficient textile building with transparent thermal insulation for the solar thermal use according to the model of the polar bear’s fur,” Innovative Energy & Research, 2018, doi:10.4172/2576-1463.1000218.

[8] J. Liu, Y. Jiang, Z. Gong, and H. Yang, “Experiment research on shading to improve the thermal environment of tents,” MATEC Web of Conferences, vol. 61, 2016.

[9] K. Cena, N. Davey, and T. Erlandson, “Thermal comfort and clothing insulation of resting tent occupants at high altitude,” Applied Ergonomics, vol. 34, pp. 543–550, 2003.

[10] S. W. Lee, C. H. Lim, and E. I. Salleh, “Reflective thermal insulation systems in buildings: A review on radiant barrier and reflective insulation,” Renewable and Sustainable Energy Reviews, vol. 65, pp. 643–661, 2016.

[11] L. Zhang, X. Meng, F. Liu, L. Xu, and E. Long, “Effect of retro-reflective materials on temperature environment in tents,” Case Studies in Thermal Engineering, vol. 9, pp. 122–127, 2017.

[12] A. Ujma and N. Umnyakova, “Thermal efficiency of the building envelope with the air layer and reflective coatings,” E3S Web of Conferences, vol. 100, 2019.

[13] J. Jura, “Budowlane materiały izolacyjne,” Construction of Optimized Energy Potential, vol. 2, pp. 39–44, 2015.

[14] A. Kysiak and A. Ujma, “Ocena prawidłowości rozliczania kosztów ogrzewania…,” Construction of Optimized Energy Potential, vol. 7, pp. 103–110, 2018.

[15] V. Bradshaw, The Building Environment: Active and Passive Control Systems. John Wiley & Sons, 2010.

[16] P. O. Fanger, Thermal Comfort: Analysis and Applications in Environmental Engineering. McGraw-Hill, 1970.

[17] R. de Dear and G. Brager, “Developing an adaptive model of thermal comfort and preference,” ASHRAE Transactions, vol. 104, no. 1, pp. 145–167, 1998.

[18] J. Szabo and L. Kajtar, “Thermal comfort analysis in office buildings with different air conditioning systems,” International Review of Applied Sciences and Engineering, vol. 9, no. 1, pp. 59–63, 2018.

[19] P. Fanger, Thermal Comfort: Analysis and Applications in Environmental Engineering. Danish Technical Press, Copenhagen, 1970.

[20] Better Shelter Organization. [Online]. Available: www.bettershelter.org

[21] A. Haiqal, M. Hasyim, and H. Syafruddin, “The thermal comfort performance in an Indonesian refugee tent,” International Journal of Thermofluid Environment, vol. 14, no. 2, pp. 112–123, 2025.

[22] A. Eltaweel, M. Elsayed, and A. Mohamed, “A parametric thermal analysis of refugees’ shelters using incremental design and affordable construction material,” Journal of Building Performance Simulation, vol. 16, no. 1, pp. 78–95, 2023.

[23] H. Ibrahim, T. Ahmad, and M. El-Shafie, “Energy use and indoor environment performance in sustainably designed refugee shelters,” Energy and Buildings, vol. 288, 112987, 2023.

[24] R. F. Rupp, N. G. Vásquez, and R. Lamberts, “A review of human thermal comfort in the built environment,” Energy and Buildings, 2021.

[25] C. Croitoru, I. Nastase, F. Bode, A. Meslem, and A. Dogeanu, “Thermal comfort models for indoor spaces and vehicles—Current capabilities and future perspectives,” Renewable and Sustainable Energy Reviews, vol. 44, pp. 304–318, 2015.