Stress Analysis of Laminated Cylinders Subject to the Thermomechanical Loads
In this study, thermo elastic stress analysis is performed on a cylinder made of laminated isotropic materials under thermomechanical loads. Laminated cylinders have many applications such as aerospace, automotive and nuclear plant in the
industry. These cylinders generally performed under thermomechanical loads. Stress and displacement distribution of the laminated cylinders are determined using by analytical method both thermal and mechanical loads. Based on the results, materials combination plays an important role on the stresses distribution along the radius. Variation of the stresses and displacements along the radius are presented as graphs. Calculations program are prepared using MATLAB® by authors.
[1] B. Krstic, B. Rasuo, D. Trifkovic, I.Radisavljevic, Z. Rajic, M.
Dinulovic, "An investigation of the repetitive failure in an aircraft
engine cylinder head”, Engineering Failure Analysis, vol. 34, pp.
335–349, 2013.
[2] A. Kawasaki, R. Watanabe, "Concept and P/M fabrication of
functionally gradient materials”, Ceramics International, vol. 23,
pp. 73–83, 1997.
[3] C. Zhang, S. V. Hoa, "A limit-based approach to the stress analysis
of cylindrically orthotropic composite cylinders (0/90) subjected to
pure bending”, Composite Structures, vol. 94, pp. 2610–2619,
2012.
[4] Y. V. Tokovyy, C. C. Ma, "Analysis of residual stresses in a long
hollow cylinder”, International Journal of Pressure Vessels and
Piping”, vol. 88, pp. 248-255, 2011.
[5] R. W. Zimmerman, M. P. Lutz, "Thermal stresses and thermal
expansion in a uniformly heated functionally graded cylinder”,
Journal of Thermal Stresses, vol. 22, pp. 177–188, 1999.
[6] Y. J. Liu, H. M. Yin "Elastic thermal stresses in a hollow circular
overlay/substrate system”, Mechanics Research Communications,
vol. 55, pp. 10–17, 2014.
[7] N. H. Zhang, J. Z. Chen, "An alternative model for elastic thermal
stresses in two materials joined by a graded layer”, Composites
Part B: Engineering, vol. 41, pp. 375–379, 2010.
[8] C. L. Tan, Y. C. Shiah, C. Y. Wang, "Boundary element elastic
stress analysis of 3D generally anisotropic solids using
fundamental solutions based on Fourier series”, International
Journal of Solids and Structures, vol. 50, pp. 2701–2711, 2013.
[9] M. Serati, H. Alehossein, D. J. Williamsa, "Elastic stress analysis
of partially loaded hollow discs”, International Journal of
Engineering Science, vol. 53, pp. 19–37, 2012.
[10] S. P. Hong, J.H. An, Y.J. Kim, K. Nikbin, P. J. Budden,
"Approximate elastic stress estimates for elbows under internal
pressure”, International Journal of Mechanical Sciences, vol. 53,
pp. 526–535, 2011.
[11] A. M. Malik, E. M. Qureshi, N. U. Dar, I. Khan, "Analysis of
circumferentially arc welded thin-walled cylinders to investigate
the residual stress fields”, Thin-Walled Structures, vol. 46, pp.
1391– 1401, 2008.
[12] Z.S. Shao, G.W. Ma, "Thermo-mechanical stresses in functionally
graded circularhollow cylinder with linearly increasing boundary
temperature”, Composite Structures, vol. 83, pp. 259–265, 2008.
[13] A. Ozturk, M. Gulgec, "Elastic–plastic stress analysis in a long
functionally graded solid cylinder with fixed ends subjected to
uniform heat generation”, International Journal of Engineering
Science, vol. 49, pp. 1047–1061, 2011.
[14] O. Sayman, "Analysis of multi-layered composite cylinders under
hygrothermal loading”, Composites: Part A, vol. 36, pp. 923–933,
2005.
[15] M. Jabbari, S. Sohrabpour, M. R. Eslami, "Mechanical and thermal
stresses in a functionally graded hollow cylinder due to radially
symmetric loads”, International Journal of Pressure Vessels and
Piping, vol. 79, pp. 493-497, 2002.
[16] Timoshenko SP, Goodier JN. Theory of elasticity. New York:
McGraw-Hill; 1970.
[1] B. Krstic, B. Rasuo, D. Trifkovic, I.Radisavljevic, Z. Rajic, M.
Dinulovic, "An investigation of the repetitive failure in an aircraft
engine cylinder head”, Engineering Failure Analysis, vol. 34, pp.
335–349, 2013.
[2] A. Kawasaki, R. Watanabe, "Concept and P/M fabrication of
functionally gradient materials”, Ceramics International, vol. 23,
pp. 73–83, 1997.
[3] C. Zhang, S. V. Hoa, "A limit-based approach to the stress analysis
of cylindrically orthotropic composite cylinders (0/90) subjected to
pure bending”, Composite Structures, vol. 94, pp. 2610–2619,
2012.
[4] Y. V. Tokovyy, C. C. Ma, "Analysis of residual stresses in a long
hollow cylinder”, International Journal of Pressure Vessels and
Piping”, vol. 88, pp. 248-255, 2011.
[5] R. W. Zimmerman, M. P. Lutz, "Thermal stresses and thermal
expansion in a uniformly heated functionally graded cylinder”,
Journal of Thermal Stresses, vol. 22, pp. 177–188, 1999.
[6] Y. J. Liu, H. M. Yin "Elastic thermal stresses in a hollow circular
overlay/substrate system”, Mechanics Research Communications,
vol. 55, pp. 10–17, 2014.
[7] N. H. Zhang, J. Z. Chen, "An alternative model for elastic thermal
stresses in two materials joined by a graded layer”, Composites
Part B: Engineering, vol. 41, pp. 375–379, 2010.
[8] C. L. Tan, Y. C. Shiah, C. Y. Wang, "Boundary element elastic
stress analysis of 3D generally anisotropic solids using
fundamental solutions based on Fourier series”, International
Journal of Solids and Structures, vol. 50, pp. 2701–2711, 2013.
[9] M. Serati, H. Alehossein, D. J. Williamsa, "Elastic stress analysis
of partially loaded hollow discs”, International Journal of
Engineering Science, vol. 53, pp. 19–37, 2012.
[10] S. P. Hong, J.H. An, Y.J. Kim, K. Nikbin, P. J. Budden,
"Approximate elastic stress estimates for elbows under internal
pressure”, International Journal of Mechanical Sciences, vol. 53,
pp. 526–535, 2011.
[11] A. M. Malik, E. M. Qureshi, N. U. Dar, I. Khan, "Analysis of
circumferentially arc welded thin-walled cylinders to investigate
the residual stress fields”, Thin-Walled Structures, vol. 46, pp.
1391– 1401, 2008.
[12] Z.S. Shao, G.W. Ma, "Thermo-mechanical stresses in functionally
graded circularhollow cylinder with linearly increasing boundary
temperature”, Composite Structures, vol. 83, pp. 259–265, 2008.
[13] A. Ozturk, M. Gulgec, "Elastic–plastic stress analysis in a long
functionally graded solid cylinder with fixed ends subjected to
uniform heat generation”, International Journal of Engineering
Science, vol. 49, pp. 1047–1061, 2011.
[14] O. Sayman, "Analysis of multi-layered composite cylinders under
hygrothermal loading”, Composites: Part A, vol. 36, pp. 923–933,
2005.
[15] M. Jabbari, S. Sohrabpour, M. R. Eslami, "Mechanical and thermal
stresses in a functionally graded hollow cylinder due to radially
symmetric loads”, International Journal of Pressure Vessels and
Piping, vol. 79, pp. 493-497, 2002.
[16] Timoshenko SP, Goodier JN. Theory of elasticity. New York:
McGraw-Hill; 1970.
@article{"International Journal of Mechanical, Industrial and Aerospace Sciences:66337", author = "Ş. Aksoy and A. Kurşun and E. Çetin and M. R. Haboğlu", title = "Stress Analysis of Laminated Cylinders Subject to the Thermomechanical Loads", abstract = "In this study, thermo elastic stress analysis is performed on a cylinder made of laminated isotropic materials under thermomechanical loads. Laminated cylinders have many applications such as aerospace, automotive and nuclear plant in the
industry. These cylinders generally performed under thermomechanical loads. Stress and displacement distribution of the laminated cylinders are determined using by analytical method both thermal and mechanical loads. Based on the results, materials combination plays an important role on the stresses distribution along the radius. Variation of the stresses and displacements along the radius are presented as graphs. Calculations program are prepared using MATLAB® by authors.
", keywords = "Isotropic materials, laminated cylinders,
thermoelastic stress, thermomechanical load.", volume = "8", number = "2", pages = "240-6", }