Thermal impedance spectroscopy method as applied for road bearing layer structure thermoelectric parameters determination

International Journal of Civil Engineering

© 2017 by SSRG - IJCE Journal

Volume 4 Issue 8

Year of Publication : 2017

Authors : Youssou Traore, Alassane Ba, CheikhThiam, M. S. Ould Brahim, Moussa Dieng, Ould Mohamed Bah, Issa Diagne, Gregoire Sissoko

10.14445/23488352/IJCE-V4I8P106

How to Cite?

Youssou Traore, Alassane Ba, CheikhThiam, M. S. Ould Brahim, Moussa Dieng, Ould Mohamed Bah, Issa Diagne, Gregoire Sissoko, "Thermal impedance spectroscopy method as applied for road bearing layer structure thermoelectric parameters determination," SSRG International Journal of Civil Engineering, vol. 4,  no. 8, pp. 38-44, 2017. Crossref, https://doi.org/10.14445/23488352/IJCE-V4I8P106

Abstract:

In this article, we propose to determine by thermal electric- analogy of the thermoelectric parameters of a road bearing layer structure from the thermal impedance spectroscopy method. When the road surface is submitted to thermal constraints, a heat exchange phenomenon appears to be characterized by the radiation thermal exchange coefficient and the convection thermal exchange coefficient. The influenceof one of these coefficients compared with the other one on the road depends on its environment (shade or illumination). The determination of the thermal electric parameters allow the valid bearing layer thermal stability. The method used is the thermal impedance spectroscopy method.

Keywords:

Road- thermal impedance spectroscopy- convection thermal exchange coefficient- radiation thermal exchange coefficient.

References:

[1]A.Mammeri, L.Ulmet ,C.Petit , A.Mokhtari Modélisation d’un corps de chaussée rigide sous sollicitations thermiques en régime transitoire XXX e Rencontres Universitaires de Génie Civil. Chambéry, 6 au 8 juin 2012.
[2] Bissada, F., Asphalt pavement temperature related to Kuwait climate. Highway Research Record 404, Transportation Research Board, Washington, D.C., 1972, pp. 71-85.
[3] Al-Abdul, H.I., Balghunaim, F.A., Asphalt pavement temperature related to arid Saudi environment. Journal of Material in Civil Engineering, Volume 6, Issue 1, February 1994, pages 1-14.
[4] BECQUART F., « Caractérisation du comportement mécanique d’un mâchefer dans la perspective d’une méthologie de dimensionnement adaptée aux structures de chaussées. », XXIVème Rencontres Universitaires de Génie Civil –3ème Prix du Concours Jeunes Chercheurs, 2006.
[5] Adolphe KimbonguilaManounou, Frédéric Becquart, Nor-EdineAbriakMéthode de dimensionnement des structures de chaussées : quelle(s) adaptabilité(s) pour les matériaux granulaires alternatifs ?33èmes Rencontres de l’AUGC, ISABTP/UPPA, Anglet, 27 au 29 mai 2015
[6] FAKHARI TEHRANI F., ABSI J., ALLOU F., PETIT C., « Heterogeneous Numerical Modeling of Asphalt Concrete through Use of a Biphasic Approach: Porous Matrix/inclusions », Computational Materials Science, vol. 69, 2013, p. 186-196.
[7] MO L.T., HUURMAN M., WU S.P., MOLENAAR A., « Investigation into Stress States in Porous Asphalt Concrete on the Basis of FE-Modelling », Finite Elements in Analysis and Design, vol. 43, n° 4, 2007, p. 333-343.
[8] BONNOT, J., “La détermination des propriétés des matériaux en vue du dimensionnement des chaussées”. Bulletin de liaison des laboratoires des ponts et chaussées, janvier-février 1973, n°63, pp.73-82.
[9] Rezqallah H. Ramadhan* Hamad I. Al-abdulwahhab., (1997) Temperature variation of flexible and rigid pavement in Eastern audi Arabia. Building and environment, Vol.32,No. 4, pp. 367-373,
[10] Williamson, R. H., (1977) Effect of environment on pavement temperature. Proceedings of Third International Conference on Structural of Asphalt Pavements, Michigan, vol. 1, pp. 144-157
[11] I. Demir, H.M. Zbib, et M. Khaleel. (2001) Microscopic analysis of crack propagation for multiple cracks, inclusions and voids. Theoretical and Apllied fracture mechanics, 36:147–164.
[12] G.N King, H.W King, W. Arand O. Harders, et J.P. Planche. (1993) Influence of asphalt grade and polymer concentration on the low temperature performance of polymer modified asphalt. J.Assoc. Asphalt Paving Techn., 62:1–18.
[13] Solaimanian M, Kennedy TW. Prediction maximum pavement surface temperature using maximum air temperature and hourly solar radiation. Transport Res Rec: J Tranport Res Board 1993; 1417:1-11.
[14] Rezqallah H. Ramadhan* Hamad I. Al-abdulwahhab., Temperature variation of flexible and rigid pavement in Eastern Saudi Arabia. Building and environment, Vol. 32, No. 4, pp. 367-373, 1997. 
[15] Williamson, R. H., Effect of environment on pavement temperature. Proceedings of Third International Conference on Structural of Asphalt Pavements, Michigan, 1977, volume 1, pp. 144-157. 
[16]Youssou TRAORE, Séni TAMBA, Alassane DIENE, Khatry OULD CHEIKH, Moussa DIENG, El HadjiBalaMoussaNyakhaté, Issa DIAGNE, and Grégoire SISSOKO Etude du transfert de chaleur à travers une chaussée en régime dynamique fréquentiel : l’influence des paramètres extrinsèques International Journal of Innovation and AppliedStudies ISSN 2028-9324 Vol. 20 No. 2 May. 2017, pp. 616-623 
[17]Moussa WONE, (1995) Contribution A La Modélisation Du Comportement Hydrique Et Mécanique Des Remblais Routiers En Matériaux Fins, thèse, l'Ecole Nationale des Ponts et Chaussées, spécialité : géotechnique,pp-148-150 
[18] Defer D., Bellatar S, B. Duthoit, «Non destructive in situ inspection of a wall by thermal impedance » Materials and Structure, 26, 3-7, 1993. 
[19] I. Gaye, A. Corréa, A. L. Ndiaye, E. Nanéma, M. Adj, G. Sissoko.“Impedance parameters determination of silicon solar cell using the one diode model in transient study”. Renewable Energy, Vol 3, pp. 1598-1601, 1996.
[20] R. Anil Kumar, M.S. Suresh and J. Nagaraju. “Measurement of AC parameters of Gallium Arsenide (GaAs/Ge) solar cell by impedance spectroscopy”, IEEE Transactions on Electron Devices, Vol.48, No.9, pp 2177-2179, September 2001. 
[21]Xuan Y. and Roetzel W. 2000. Conceptions for heat transfer correlation of nanofluids. International Journal of Heat and Mass Transfer. 43: 3701-3707. 
[22]Duangthongsuk W. and Wongwises S. 2010. An experimental study on the heat transfer performance and pressure drop of TiO2-water nanofluids flowing under a turbulent flow regime. International Journal of Heat and Mass Transfer. 53: 334-344.
[23]Hinojosa, J. F., Estrada, C. A., Cabanillas, R. E., and Alvarez, G. 2005. Numerical study of transient and steady-state natural convection and surface thermal radiation in a horizontal square open cavity, Numerical Heat Transfer A, vol. 48, 179-196. 
[24]Hinojosa, J. F., Estrada, C. A., Cabanillas, R. E., and Alvarez, G. 2005. Nusselt number for the natural convection and surface thermal radiation in a square tilted open cavity, Int. Com. InHear and Mass Transfer, vol. 32, 1184-1192. 
[25] PROTEAU M., PAQUIN Y., « Contribution de différents bitumes purs et bitumes modifiés par ajout de polymères à la résistance à l’orniérage », Routes et Aérodromes, N°793, 2001, p. 34-39. 
[26] N. B. Guttman, J. D. Matthews, Computation of extraterrestrial solar radiation, solar elevation angle and true solar time of sunrise and sunset, SOLMET Vol. 2- Final report, National Climatic Center, U.S. Departement of Commerce (1979), 49-52.
[27] J. Schmetz, Relationship between solar net radiative fluxes at the top of the atmosphere and at the surface, Journal of the Atmospheric Sciences, 50-8 (1993), 1125.
[28] Turgut A., Tavman I., Chirtoc M., Schuchmann H. P., Sauter C. and Tavman S. 2009. Thermal conductivity and viscosity measurements of water-based TiO2 nanofluids. International Journal of Thermophysics. 30: 1213-1226. 
[29] Buongiorno J., Venerus D. C., Prabhat N. and McKrell T. 2009. A benchmark study on the thermal conductivity of nanofluids. Journal of Applied Physics. 106: 094312.
[30] Murshed S. M. S., Leong K. C. and Yang C. 2005. Enhanced thermal conductivity of TiO2-water based nanofluids. International Journal of Thermal Sciences 44: 367-373.
[31] A.J. Steckl and S.P. Sheu (1979) The a.c. admittance of the p-n PbS Si heterojunction Solid-State Electronics Vol.23, pp. 715 – 720 
[32]R. Anil Kumar, M.S. Suresh and J. Nagaraju Measurement of AC parameters for Gallium Arsenide (GaAs/Ge) solar cell by impedance spectroscopy IEEE Transactions on Electron Devices, Vol.48, No.9, September 2001. 
[33] I. Diagne, B Fleur, M. O Sidya, S. Gaye, G. SISSOKO (2008) Détermination de Paramètres Thermiques d’un Matériau en Régime Dynamique Fréquentiel à Partir de Diagrammes de Bode et de Représentation de Nyquist Journal des Sciences, Vol. 8, N°2 pp88-98
[34]K. OuldCheikh, I. Diagne, M. L. Sow, M. S. OuldBrahim, A. Diouf, K. Diallo, M. Dieng and G. Sissoko, 2013 Interpretation of the Phenomena of Heat Transfer from Representations of Nyquist and Bode Plots Research Journal of Applied Sciences, Engineering and Technology 5(4): 1118-1122.