Thermal Performance Analysis of Functional Parameters of the Floor Heating System in Africa

Safaa Oubenmoh; Afaf Charraou; Rachid Saadani; Miloud Rahmoune; Abdelouahad Ait msaad; Abdelmajid Jamil; El hassan Sebbar

doi:10.19139/soic-2310-5070-1551

Safaa Oubenmoh Laboratory of Advanced Materials and Applications Studies, FS - EST Meknes, Moulay Ismail University.
Afaf Charraou Laboratory of Advanced Materials and Applications Studies, FS - EST Meknes, Moulay Ismail University, BP 11201, Meknes, Morocco.
Rachid Saadani Laboratory of Advanced Materials and Applications Studies, FS - EST Meknes, Moulay Ismail University, BP 11201, Meknes, Morocco.
Miloud Rahmoune Laboratory of Advanced Materials and Applications Studies, FS - EST Meknes, Moulay Ismail University, BP 11201, Meknes, Morocco.
Abdelouahad Ait msaad Higher School of Technology of Fez, U.S.M.B.A, Imouzzer Road BP 2427, Fez, Morocco.
Abdelmajid Jamil Higher School of Technology of Fez, U.S.M.B.A, Imouzzer Road BP 2427, Fez, Morocco.
El hassan Sebbar 3Engineering Sciences Laboratory, Polydisciplinary Faculty of Taza, U.S.M.B.A, BP 1223, Taza, Morocco.

DOI: https://doi.org/10.19139/soic-2310-5070-1551

Keywords: Functional parameters, Floor heating system, Supply water temperature, Surface temperature, Transient simulation, Parametric study

Abstract

Buildings frequently utilize radiant heating floors because they offer benefits including effective use of space and homogeneous temperature distribution, which results in increased thermal comfort. The present work aims to investigate the perfect use of floor heating systems analytically and numerically with improved thermal performance to prove their efffficiency in various African climates. The evaluation depends on the functional parameters of the heating system and particularly focuses on floor surface temperature to acquire the desired heat flux and the perfect supply water temperature. According to results, It is desirable to use floor coverings with low thermal resistance and should not exceed R = 0.15 m2 . K/W since it has considerable influence on the thermal efffficiency of the underfloor heating components. The pipe diameter is suggested to be about 20 mm. By comparing pipe spacings of 15 mm and 30 mm, the difference in supply water temperature is approximately 7.4 C. The smaller the pipe spacing, the more energy it delivers and makes the floor much warmer while reducing heating time. Regarding the effect of pipe materials, PE-X is chosen for this study because of its low cost and resistance to corrosion and scaling. As the influence of these studied parameters on floor heating is remarkable, there is also the impact of the ambient temperature of each city on the floor heating efffficiency. The proposed model can be applied and considered potentially beneficial and helpful to the control, and design of floor heating systems, and choosing the right heating source.

References

G. Baldinelli, F. Bianchi, A. Rotili, and A. Presciutti, Transient Heat Transfer in Radiant Floors: A Comparative Analysis between the Lumped Capacitance Method and Infrared Thermography Measurements, Journal of Imaging , vol. 2, no. 3, pp. 22,juill, 2016.

W. Fu, T. zou, X. Lian, S. Wang, X. Gao, Z. Zhang and Y. Fang Preparation and properties of phase change temperature-tuned composite phase change material based on sodium acetate trihydrate–urea/fumed silica for radiant floor heating system, Applied Thermal Engineering, vol. 162, p. 114253,nov, 2019.

N. Nguyen Modeling snow-free concrete surfaces using hydronic radiant heat, Colorado State University, 2018.

S. Oubenmoh. A.Allouhi, E.H.Sebbar, R.Sadaani, A.Jamil, A.Ait Msaad, M.Rahmoune, M.Bentaleb, Energy Assessment and Economic Study of Solar Floor Heating System in Different Climates in Morocco, Journal of Solar Energy Engineering, vol. 42, no 1, p. 011005, févr. 2023.

R. M. S. F. Almeida,R.S.Vicente,A.Ventura-Gouveia, A.Figueiredo, F.Rebelo, E.Roque, V.M.Ferreira, Experimental and Numerical Simulation of a Radiant Floor System: The Impact of Different Screed Mortars and Floor Finishings, Materials, vol. 15, no 3, p. 1015, janv. 2022.

D. Wang, Y. Liu, Y. Wang, and J. Liu, Numerical and experimental analysis of floor heat storage and release during an intermittent in-slab floor heating process, Applied Thermal Engineering, vol. 62, no 2, p. 398‑406, janv, 2014.

S. Sattari and B. Farhanieh„ A parametric study on radiant floor heating system performance, Renewable Energy, vol. 31, no 10, p. 1617‑1626, août, 2006.

A. Laafer, D. Semmar, A. Hamid, and M. Bourouis, Thermal and Surface Radiosity Analysis of an Underfloor Heating System in a Bioclimatic Habitat, Energies, vol. 14, no 13, p. 3880, 2021.

Q. Li, C. Chen, Y. Zhang, J. Lin, and H. Ling, Simplified thermal calculation method for floor structure in radiant floor cooling system, Energy and Buildings, vol. 74, p. 182‑190, mai, 2014.

S. Oubenmoh, A. Allouhi, A. Ait Mssad, R. Saadani, T. Kousksou, M. Rahmoune and M. Bentaleb, Some particular design considerations for optimum utilization of under floor heating systems, Case Studies in Thermal Engineering, vol. 12, p. 423‑432, sept, 2018.

A. Handbook, HVAC Systems and Equipment (I-P): I-P Edition (includes CD in Dual Units), American Society of Heating, Refrigerating & Air-Conditioning Engineers, Incorporated, 2008