Research Article
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Year 2018, , 202 - 212, 04.12.2018
https://doi.org/10.5541/ijot.434180

Abstract

References

  • [1] S. Tang, Thermal stresses in temperature dependent isotropic plates, Journal of spacecrafts and rockets, 5, 987-990, 1968.
  • [2] T. Hata, “Thermal stresses in a nonhomogeneous thick plate under steady distribution of temperature”, Journal of Thermal Stresses, 5, 1-11, 1982.
  • [3] N. Noda, “Thermal stresses in materials with temperature dependent properties”, Thermal Stresses I, Taylor & Francis, North Holland, Amsterdam, 391-483, 1986.
  • [4] Y. Obata and N. Noda, "Unsteady thermal stresses in functionally gradient Material Plate (influence of heating and cooling conditions on unsteady thermal stresses)", Trans. JSME A, 59, 1097–1103, 1993.
  • [5] V.S. Popovych and G.Yu. Garmatii, “Analytic-numerical methods of constructing solutions of heat-conduction problems for thermosensitive bodies with convective heat transfer” [in Ukrainian], Ukrainian Academy of Sciences, Pidstrigach Institute for Applied Problems of Mechanics and Mathematics, L'viv, Ukraine, Preprint, 13-93, 1993.
  • [6] V.S. Popovych and B.N. Fedai, The axisymmetric problem of thermoelasticity of a multilayer thermosensitive tube, Journal of Mathematical Sciences, 86, 2605-2610, 1997.
  • [7] N. Noda, “Thermal stresses in functionally graded materials”, Journal of Thermal Stresses, 22, 477-512, 1999.
  • [8] Y. Miyamoto, W.A. Kaysser, B.H. Rabin, B.H., A. Kawasaki, and R.G. Ford, R.G., “Functionally Graded Materials: Design, Processing and Applications”, Kluwer Academic, Boston, 1999.
  • [9] H. Awaji, H. Takenaka, S. Honda and T. Nishikawa, “Temperature/Stress distributions in a stress-relief-type plate of functionally graded materials under thermal shock”, JSME Int. J., 44, 37-44, 2001.
  • [10] A. Kawasaki and R. Watanabe, "Thermal fracture behavior of metal/ceramic functionally graded materials", Eng. Fract. Mech., 69, 1713–1728, 2002.
  • [11] M. Al-Hajri and S.L. Kalla, “On an integral transform involving Bessel functions”, Proceedings of the international conference on Mathematics and its applications, Kuwait, April 5-7, 2004.
  • [12] R. Kushnir and V.S. Popovych, Thermoelasticity of thermosensitive solids, SPOLOM, Lviv, 2009.
  • [13] Li-C. Guo and N. Noda, "An analytical method for thermal stresses of a functionally graded material cylindrical shell under a thermal shock", Acta Mechanica, 214, 71-78, 2010.
  • [14] G.D. Kedar and K.C. Deshmukh, “Estimation of temperature distribution and thermal stresses in a thick circular plate”, African Journal of Mathematics and Computer Science Research, 4, 389-395, 2011.
  • [15] R. Kushnir and V.S. Popovych, Heat conduction problems of thermosensitive solids under complex heat exchange, INTECH, 2011.
  • [16] R.M. Mahamood, E.T. Akinlabi, M. Shukla, and S. Pityana, “Functionally Graded Material: An Overview”, Proceedings of the World Congress on Engineering 2012, Vol III, July 4 - 6, London, U.K, 2012.
  • [17] J.N. Sharma, D. Sharma, and S. Kumar, "Stress and strain analysis of rotating FGM thermoelastic circular disk by using FEM", International Journal of Pure and Applied Mathematics, 74, 339-352, 2012.
  • [18] A. Moosaie, Axisymmetric steady temperature field in FGM cylindrical shells with temperature-dependent heat conductivity and arbitrary linear boundary conditions, Arch. Mech., 67, 233–251, 2015.
  • [19] A.M. Nikolarakis, E.E. Theotokoglou, Transient stresses of a functionally graded profile with temperature-dependent materials under thermal shock, 8th GRACM International Congress on Computational Mechanics, Volos, 2015.
  • [20] A.N. Eraslan and T. Apatay, “Analytical solution to thermal loading and unloading of a cylinder subjected to periodic surface heating”, Journal of Thermal Stresses, 39, 928-941, 2016.
  • [21] V.R. Manthena, N.K. Lamba, G.D. Kedar and K.C. Deshmukh, “Effects of stress resultants on thermal stresses in a functionally graded rectangular plate due to temperature dependent material properties”, International Journal of Thermodynamics, 19, 235-242, 2016.
  • [22] I. Rakocha and V.S. Popovych, “The mathematical modeling and investigation of the stress-strain state of the three-layer thermosensitive hollow cylinder”, Acta Mechanica et Automatica, 10, 181–188, 2016.
  • [23] V.R. Manthena, N.K. Lamba, and G.D. Kedar, Springbackward phenomenon of a transversely isotropic functionally graded composite cylindrical shell, Journal of Applied and Computational Mechanics, 2, 134-143, 2016.
  • [24] R. Kumar, V.R. Manthena, N.K. Lamba and G.D. Kedar, “Generalized thermoelastic axi-symmetric deformation problem in a thick circular plate with dual phase lags and two temperatures”, Material Physics and Mechanics, 32, 123-132, 2017.
  • [25] P. Bhad, V. Varghese and L. Khalsa, "Transient thermal stresses of annulus elliptical plate with mixed-type boundary conditions", International Journal of Thermodynamics, 20, 26-34, 2017.
  • [26] A.K. Surana, K.J. Samuel, S. Harshit, U. Kumar and R.T.K. Raj, "Numerical investigation of shell and tube heat exchanger using Al2O3 nanofluid", International Journal of Thermodynamics, 20, 59-68, 2017.
  • [27] J.J.Tripathi, K.C. Deshmukh and J. Verma, "Fractional order generalized thermoelastic problem in a thick circular plate with periodically varying heat source", International Journal of Thermodynamics, 20, 132-138, 2017.
  • [28] V.R. Manthena, N.K. Lamba, and G.D. Kedar, “Transient thermoelastic problem of a nonhomogeneous rectangular plate”, Journal of Thermal Stresses, 40, 627-640, 2017.
  • [29] U. Köbler, "On the thermal conductivity of metals and of insulators", International Journal of Thermodynamics, 20, 210-218, 2017.
  • [30] V.R. Manthena, N.K. Lamba, and G.D. Kedar, “Thermal stress analysis in a functionally graded hollow elliptic-cylinder subjected to uniform temperature distribution”, Applications and Applied Mathematics, 12, 613-632, 2017.
  • [31] V.R. Manthena and G.D. Kedar, “Transient thermal stress analysis of a functionally graded thick hollow cylinder with temperature dependent material properties”, Journal of Thermal Stresses, 41, 568–582, 2018.

Mathematical Modeling of Thermoelastic State of a Functionally Graded Thermally Sensitive Thick Hollow Cylinder With Internal Heat Generation

Year 2018, , 202 - 212, 04.12.2018
https://doi.org/10.5541/ijot.434180

Abstract

In this paper, the effect of internal heat generation has been studied in a functionally graded thick hollow cylinder in context with thermosensitive thermoelastic properties. Initially, the cylinder is kept at reference temperature and the radial boundary surface under consideration dissipates heat by convection according to Newton’s law of cooling, heat flux is applied at the lower surface, while the upper surface is insulated. The heat conduction equation due to internal heat generation is solved by integral transform technique and Kirchhoff’s variable transformation is used to deal with the nonlinearity of the heat conduction equation. A mathematical model has been constructed for a nonhomogenous material in which the material properties are assumed to be dependent on both temperature and spatial variable z. A ceramic-metal-based FGM is considered in which alumina is selected as ceramic and nickel as metal. The results obtained are illustrated graphically.


References

  • [1] S. Tang, Thermal stresses in temperature dependent isotropic plates, Journal of spacecrafts and rockets, 5, 987-990, 1968.
  • [2] T. Hata, “Thermal stresses in a nonhomogeneous thick plate under steady distribution of temperature”, Journal of Thermal Stresses, 5, 1-11, 1982.
  • [3] N. Noda, “Thermal stresses in materials with temperature dependent properties”, Thermal Stresses I, Taylor & Francis, North Holland, Amsterdam, 391-483, 1986.
  • [4] Y. Obata and N. Noda, "Unsteady thermal stresses in functionally gradient Material Plate (influence of heating and cooling conditions on unsteady thermal stresses)", Trans. JSME A, 59, 1097–1103, 1993.
  • [5] V.S. Popovych and G.Yu. Garmatii, “Analytic-numerical methods of constructing solutions of heat-conduction problems for thermosensitive bodies with convective heat transfer” [in Ukrainian], Ukrainian Academy of Sciences, Pidstrigach Institute for Applied Problems of Mechanics and Mathematics, L'viv, Ukraine, Preprint, 13-93, 1993.
  • [6] V.S. Popovych and B.N. Fedai, The axisymmetric problem of thermoelasticity of a multilayer thermosensitive tube, Journal of Mathematical Sciences, 86, 2605-2610, 1997.
  • [7] N. Noda, “Thermal stresses in functionally graded materials”, Journal of Thermal Stresses, 22, 477-512, 1999.
  • [8] Y. Miyamoto, W.A. Kaysser, B.H. Rabin, B.H., A. Kawasaki, and R.G. Ford, R.G., “Functionally Graded Materials: Design, Processing and Applications”, Kluwer Academic, Boston, 1999.
  • [9] H. Awaji, H. Takenaka, S. Honda and T. Nishikawa, “Temperature/Stress distributions in a stress-relief-type plate of functionally graded materials under thermal shock”, JSME Int. J., 44, 37-44, 2001.
  • [10] A. Kawasaki and R. Watanabe, "Thermal fracture behavior of metal/ceramic functionally graded materials", Eng. Fract. Mech., 69, 1713–1728, 2002.
  • [11] M. Al-Hajri and S.L. Kalla, “On an integral transform involving Bessel functions”, Proceedings of the international conference on Mathematics and its applications, Kuwait, April 5-7, 2004.
  • [12] R. Kushnir and V.S. Popovych, Thermoelasticity of thermosensitive solids, SPOLOM, Lviv, 2009.
  • [13] Li-C. Guo and N. Noda, "An analytical method for thermal stresses of a functionally graded material cylindrical shell under a thermal shock", Acta Mechanica, 214, 71-78, 2010.
  • [14] G.D. Kedar and K.C. Deshmukh, “Estimation of temperature distribution and thermal stresses in a thick circular plate”, African Journal of Mathematics and Computer Science Research, 4, 389-395, 2011.
  • [15] R. Kushnir and V.S. Popovych, Heat conduction problems of thermosensitive solids under complex heat exchange, INTECH, 2011.
  • [16] R.M. Mahamood, E.T. Akinlabi, M. Shukla, and S. Pityana, “Functionally Graded Material: An Overview”, Proceedings of the World Congress on Engineering 2012, Vol III, July 4 - 6, London, U.K, 2012.
  • [17] J.N. Sharma, D. Sharma, and S. Kumar, "Stress and strain analysis of rotating FGM thermoelastic circular disk by using FEM", International Journal of Pure and Applied Mathematics, 74, 339-352, 2012.
  • [18] A. Moosaie, Axisymmetric steady temperature field in FGM cylindrical shells with temperature-dependent heat conductivity and arbitrary linear boundary conditions, Arch. Mech., 67, 233–251, 2015.
  • [19] A.M. Nikolarakis, E.E. Theotokoglou, Transient stresses of a functionally graded profile with temperature-dependent materials under thermal shock, 8th GRACM International Congress on Computational Mechanics, Volos, 2015.
  • [20] A.N. Eraslan and T. Apatay, “Analytical solution to thermal loading and unloading of a cylinder subjected to periodic surface heating”, Journal of Thermal Stresses, 39, 928-941, 2016.
  • [21] V.R. Manthena, N.K. Lamba, G.D. Kedar and K.C. Deshmukh, “Effects of stress resultants on thermal stresses in a functionally graded rectangular plate due to temperature dependent material properties”, International Journal of Thermodynamics, 19, 235-242, 2016.
  • [22] I. Rakocha and V.S. Popovych, “The mathematical modeling and investigation of the stress-strain state of the three-layer thermosensitive hollow cylinder”, Acta Mechanica et Automatica, 10, 181–188, 2016.
  • [23] V.R. Manthena, N.K. Lamba, and G.D. Kedar, Springbackward phenomenon of a transversely isotropic functionally graded composite cylindrical shell, Journal of Applied and Computational Mechanics, 2, 134-143, 2016.
  • [24] R. Kumar, V.R. Manthena, N.K. Lamba and G.D. Kedar, “Generalized thermoelastic axi-symmetric deformation problem in a thick circular plate with dual phase lags and two temperatures”, Material Physics and Mechanics, 32, 123-132, 2017.
  • [25] P. Bhad, V. Varghese and L. Khalsa, "Transient thermal stresses of annulus elliptical plate with mixed-type boundary conditions", International Journal of Thermodynamics, 20, 26-34, 2017.
  • [26] A.K. Surana, K.J. Samuel, S. Harshit, U. Kumar and R.T.K. Raj, "Numerical investigation of shell and tube heat exchanger using Al2O3 nanofluid", International Journal of Thermodynamics, 20, 59-68, 2017.
  • [27] J.J.Tripathi, K.C. Deshmukh and J. Verma, "Fractional order generalized thermoelastic problem in a thick circular plate with periodically varying heat source", International Journal of Thermodynamics, 20, 132-138, 2017.
  • [28] V.R. Manthena, N.K. Lamba, and G.D. Kedar, “Transient thermoelastic problem of a nonhomogeneous rectangular plate”, Journal of Thermal Stresses, 40, 627-640, 2017.
  • [29] U. Köbler, "On the thermal conductivity of metals and of insulators", International Journal of Thermodynamics, 20, 210-218, 2017.
  • [30] V.R. Manthena, N.K. Lamba, and G.D. Kedar, “Thermal stress analysis in a functionally graded hollow elliptic-cylinder subjected to uniform temperature distribution”, Applications and Applied Mathematics, 12, 613-632, 2017.
  • [31] V.R. Manthena and G.D. Kedar, “Transient thermal stress analysis of a functionally graded thick hollow cylinder with temperature dependent material properties”, Journal of Thermal Stresses, 41, 568–582, 2018.
There are 31 citations in total.

Details

Primary Language English
Subjects Engineering
Journal Section Regular Original Research Article
Authors

V R Manthena

G D Kedar This is me

Publication Date December 4, 2018
Published in Issue Year 2018

Cite

APA Manthena, V. R., & Kedar, G. D. (2018). Mathematical Modeling of Thermoelastic State of a Functionally Graded Thermally Sensitive Thick Hollow Cylinder With Internal Heat Generation. International Journal of Thermodynamics, 21(4), 202-212. https://doi.org/10.5541/ijot.434180
AMA Manthena VR, Kedar GD. Mathematical Modeling of Thermoelastic State of a Functionally Graded Thermally Sensitive Thick Hollow Cylinder With Internal Heat Generation. International Journal of Thermodynamics. December 2018;21(4):202-212. doi:10.5541/ijot.434180
Chicago Manthena, V R, and G D Kedar. “Mathematical Modeling of Thermoelastic State of a Functionally Graded Thermally Sensitive Thick Hollow Cylinder With Internal Heat Generation”. International Journal of Thermodynamics 21, no. 4 (December 2018): 202-12. https://doi.org/10.5541/ijot.434180.
EndNote Manthena VR, Kedar GD (December 1, 2018) Mathematical Modeling of Thermoelastic State of a Functionally Graded Thermally Sensitive Thick Hollow Cylinder With Internal Heat Generation. International Journal of Thermodynamics 21 4 202–212.
IEEE V. R. Manthena and G. D. Kedar, “Mathematical Modeling of Thermoelastic State of a Functionally Graded Thermally Sensitive Thick Hollow Cylinder With Internal Heat Generation”, International Journal of Thermodynamics, vol. 21, no. 4, pp. 202–212, 2018, doi: 10.5541/ijot.434180.
ISNAD Manthena, V R - Kedar, G D. “Mathematical Modeling of Thermoelastic State of a Functionally Graded Thermally Sensitive Thick Hollow Cylinder With Internal Heat Generation”. International Journal of Thermodynamics 21/4 (December 2018), 202-212. https://doi.org/10.5541/ijot.434180.
JAMA Manthena VR, Kedar GD. Mathematical Modeling of Thermoelastic State of a Functionally Graded Thermally Sensitive Thick Hollow Cylinder With Internal Heat Generation. International Journal of Thermodynamics. 2018;21:202–212.
MLA Manthena, V R and G D Kedar. “Mathematical Modeling of Thermoelastic State of a Functionally Graded Thermally Sensitive Thick Hollow Cylinder With Internal Heat Generation”. International Journal of Thermodynamics, vol. 21, no. 4, 2018, pp. 202-1, doi:10.5541/ijot.434180.
Vancouver Manthena VR, Kedar GD. Mathematical Modeling of Thermoelastic State of a Functionally Graded Thermally Sensitive Thick Hollow Cylinder With Internal Heat Generation. International Journal of Thermodynamics. 2018;21(4):202-1.