THERMAL SCIENCE

International Scientific Journal

Thermal Science - Online First

online first only

An equivalent temperature model of three-dimensional steady heat conduction analysis for a fiber metal laminated plate coated with a thermal barrier

ABSTRACT
In this paper, an equivalent temperature model of three-dimensional steady heat conduction analysis for a fiber metal laminated plate coated with a thermal barrier (CFML) is presented. The separate variable method (SVM) and equivalent temperature (ET) method are applied comprehensively to solve the temperature field at the interface between the thermal barrier and top aluminum 2024-T3 layer for the fiber metal laminated (FML) structure firstly, and values of other layers' temperature and thermal contact resistance are obtained based on balance principle of heat flux between respective adjacent top and bottom layers subsequently. The aim of this research is to understand the influences of kinds of fiber species, numbers of FML layers, thickness ratio between total CFML structure and thermal barrier as well as temperature distributed function on the values of thermal contact resistance between respective adjacent layers and temperature distribution from top to bottom surfaces for the CFML structure. Especially, the ratio of thermal contact resistance between maximum and minimum values are about 5 times no matter considering one or two kinds of fiber species. Besides the present results (mainly geometrical and physical parameters' effect) could guide engineers designing the CFML structures to adapt to high-temperature environment especially aerospace temperature environment.
KEYWORDS
PAPER SUBMITTED: 2019-07-04
PAPER REVISED: 2019-11-10
PAPER ACCEPTED: 2019-11-21
PUBLISHED ONLINE: 2019-12-22
DOI REFERENCE: https://doi.org/10.2298/TSCI190704445G
REFERENCES
  1. Reyes, G.V. and Cantwell, W.J., The mechanical properties of fibre-metal laminates based on glass fibre reinforced polypropylene, Compos. Sci. Technol., 60 (2000), pp. 1085-1094
  2. Khalili, S.M.R., et al., A study of the mechanical properties of steel/ aluminum/GRP laminates, Mat. Sci. Eng. A-Struct., 412 (2005), pp. 137-140
  3. Jiang, H.J. and Dai, H.L., Analytical solutions for three-dimensional steady and transient heat conduction problems of a double-layer plate with a local heat source, Int. J. Heat Mass Transfer, 89 (2015), pp. 652-666
  4. Jiang, H.J., et al., Three-dimensional steady thermodynamic analysis for a double-layer plate with a local heat source and harmonic load, Appl. Therm. Eng. 106 (2016), pp. 161-173
  5. Bhowmick, S., et al., High temperature tribological behavior of tetrahedral amorphous carbon (taC) and fluorinated ta-C coatings against aluminum alloys, Surf. Coat. Tech., 284 (2015), pp. 14-25
  6. Esposito, S., et al., Optimization procedure and fabrication of highly efficient and thermally stable solar coating for receiver operating at high temperature, Sol. Energ. Mat. Sol. C., 157 (2016), pp. 429-437
  7. Liu, Y.L., et al., Thermal barrier coating debonding defects detection based on infrared thermal wave testing technology under linear frequency modulation heat excitation, Therm. Sci., 23 (2019), pp. 1607-1613
  8. da Costa, A.A., et al., The effect of thermal cycles on the mechanical properties of fiber-metal laminates, Mater. Design, 42 (2012), pp. 434-440
  9. Fu, Y.M. and Hu, S.M., Nonlinear transient response of fibre metal laminated shallow spherical shells with interfacial damage under unsteady temperature fields, Compos. Struct., 106 (2013), pp. 57-64
  10. Fu, Y.M., et al., Thermal postbuckling analysis of fiber-metal laminated plates including interfacial damage, Compos. Part B-Eng., 56 (2014), pp. 358-364
  11. Fu, Y.M., et al., Analysis of nonlinear dynamic response for delaminated fiber-metal laminated beam under unsteady temperature field, J. Sound Vib., 333 (2014), pp. 5803-5816
  12. Li, Y.L. and Fu, Y.M., A thermo-elasto-plastic model for a fiber-metal laminated beam with interfacial damage, Appl. Math. Model., 39 (2015), pp. 3317-3330
  13. Tao, C., et al., Nonlinear dynamic analysis of fiber metal laminated beams subjected to moving loads in thermal environment, Compos. Struct., 140 (2016), pp. 410-416
  14. Qiu, L., et al., Macro fluid analysis of laminated fabric permeability, Therm. Sci., 20 (2016), pp. 835-838
  15. Seifert, S., et al., Thermal resistance and apparent thermal conductivity of thin plasma-sprayed mullite coatings, Surf. Coat. Technol., 200 (2006), pp. 3404-3410
  16. Huang, H.M., and Xu X.L., Effects of surface morphology on thermal contact resistance, Therm. Sci., 15 (2011), pp. S33-S38
  17. Tsai, T.W. and Lee, Y.M., Analysis of microscale heat transfer and ultrafast thermoelasticity in a multi-layered metal film with nonlinear thermal boundary resistance, Int. J. Heat Mass Transfer, 62 (2013), pp. 87-98
  18. Patel, P.P. and Gajjar, P.N., Interface thermal resistance and thermal conductivity in composites-an abrupt junction thermal diode model, Phys. Lett. A, 378 (2014), pp. 2524-2528
  19. Zhao, Z., et al., Effects of pressure and temperature on thermal contact resistance between different materials, Therm. Sci., 19 (2015), pp. 1369-1372
  20. Sharifi, N., et al., The influence of thermal contact resistance on the relative performance of heat pipe-fin array systems, Appl. Therm. Eng., 105 (2016), pp. 46-55
  21. Araya, G. and Gutierrez, G., Analytical solution for a transient, three-dimensional temperature distribution due to a moving laser beam, Int. J. Heat Mass Transfer, 49 (21-22) (2006), pp. 4124-4131
  22. Jiang, H.J. and Dai, H.L., Effect of laser processing on three dimensional thermodynamic analysis for HSLA rectangular steel plates, Int. J. Heat Mass Transfer, 82 (2015), pp. 98-108
  23. Jiang, H.J., et al., Refined plate theory for bending analysis of a HSLA steel plate under 3D temperature field, Appl. Math. Comput., 250 (2015), pp. 497-513
  24. Zheng, X.P., et al., Experimental investigation of high temperature thermal contact resistance with interface material, Theor. Appl. Mech. Lett., 1 (2011), pp. 051009