Applied Mathematics and Mechanics >
Saint-Venant torsion analysis of bars with rectangular cross-section and effective coating layers
Received date: 2015-03-18
Revised date: 2015-08-01
Online published: 2016-02-01
This paper investigates the torsion analysis of coated bars with a rectangular cross-section. Two opposite faces of a bar are coated by two isotropic layers with different materials of the original substrate that are perfectly bonded to the bar. With the Saint-Venant torsion theory, the governing equation of the problem in terms of the warping function is established and solved using the finite Fourier cosine transform. The state of stress on the cross-section, warping of the cross-section, and torsional rigidity of the bar are evaluated. Effects of thickness of the coating layers and material properties on these quantities are investigated. A set of graphs are provided that can be used to determine the coating thicknesses and material properties so as to keep the maximum von Mises stress on the cross-section below an allowable value for effective use of the coating layer.
H. TEIMOORI, R. T. FAAL, R. DAS . Saint-Venant torsion analysis of bars with rectangular cross-section and effective coating layers[J]. Applied Mathematics and Mechanics, 2016 , 37(2) : 237 -252 . DOI: 10.1007/s10483-016-2028-8
[1] Kazimi, S. M. A. Solid Mechanics, Tata McGraw-Hill, New Delhi (2001)
[2] Timoshenko, S. History of Strength of Materials: With a Brief Account of the History of Theory of Elasticity and Theory of Structures, Dover Publications, New York (1983)
[3] Sapountzakis, E. J. and Mokos, V. G. Nonuniform torsion of composite bars of variable thickness by BEM. International Journal of Solids and Structures, 41(7), 1753-1771(2004)
[4] Wang, C. Y. Torsion of tubes of arbitrary shape. International Journal of Solids and Structures, 35(7-8), 719-731(1998)
[5] Ecsedi, I. Elliptic cross section without warping under torsion. Mechanics Research Communica-tions, 31(2), 147-150(2004)
[6] Arghavan, S. and Hematiyan, M. R. Torsion of functionally graded hollow tubes. European Journal of Mechanics-A/Solids, 28(3), 551-559(2009)
[7] Hematiyan, M. R. and Doostfatemeh, A. Torsion of moderately thick hollow tubes with polygonal shapes. Mechanics Research Communications, 34(7-8), 528-537(2007)
[8] Leissa, A.W. and Brann, J. H. On the torsion of bars having symmetry axes. International Journal of Mechanical Sciences, 6(1), 45-50(1964)
[9] Chen, Y. Z. On the torsional rigidity for a hollow shaft with outer or inner keys. Computer Methods in Applied Mechanics and Engineering, 42(1), 107-118(1984)
[10] Hromadka, T. V., II. and Pardoen, G. C. Application of the CVBEM to non-uniform St. Venant torsion. Computer Methods in Applied Mechanics and Engineering, 53(2), 149-161(1985)
[11] Tuba, I. S. Elastic-plastic torsion of shafts with hyperbolic notches. International Journal of Mechanical Sciences, 8(11), 683-701(1966)
[12] Wang, C. Y. Torsion of a flattened tube. Meccanica, 30(2), 221-227(1995)
[13] Allam, M. N.M. and Ghaleb, A. F. Torsion of a composite, viscoelastic prismatic bar of rectangular cross-section. Applied Mathematical Modelling, 6(3), 197-201(1982)
[14] Xu, R. Q., He, J. S., and Chen,W. Q. Saint-Venant torsion of orthotropic bars with inhomogeneous rectangular cross section. Composite Structures, 92(6), 1449-1457(2010)
[15] Ecsedi, I. Some analytical solutions for Saint-Venant torsion of non-homogeneous cylindrical bars. European Journal of Mechanics-A/Solids, 28(5), 985-990(2009)
[16] Mindlin, R. D. Solution of St. Venant's torsion problem by power series. International Journal of Solids and Structures, 11(3), 321-328(1975)
[17] Zehetner, C. Compensation of torsion in rods by piezoelectric actuation. Archive of Applied Me-chanics, 78(12), 921-933(2008)
[18] Maleki, M., Naei, M. H., Hosseinian, E., and Babahaji, A. Exact three-dimensional analysis for static torsion of piezoelectric rods. International Journal of Solids and Structures, 48(2), 217-226(2011)
[19] Maleki, M., Naei, M. H., and Hosseinian, E. Exact three-dimensional interface stress and electrode-effect analysis of multilayer piezoelectric transducers under torsion. International Journal of Solids and Structures, 49(17), 2230-2238(2012)
[20] Barone, G., Pirrotta, A., Santoro, R. Comparison among three boundary element methods for torsion problems: CPM, CVBEM, LEM. Engineering Analysis with Boundary Elements, 35(7), 895-907(2011)
[21] Hromadka, T. V., II. and Guymon, G. Complex polynomial approximation of the Laplace equa-tion. Journal of Hydraulic Engineering, 110(3), 329-339(1984)
[22] Poler, A. C., Bohannon, A. W., Schowalter, S. J., and Hromadka, T. V., II. Using the complex polynomial method with Mathematica to model problems involving the Laplace and Poisson equations. Numerical Methods for Partial Differential Equations, 25(3), 657-667(2009)
[23] Hromadka, T. V., II. The complex variable boundary element method. Lecture Notes in Engineer-ing, 9, 101-161(1984)
[24] Hromadka, T. V., II. and Whitley, R. J. Advances in the Complex Variable Boundary Element Method, Springer, London (1998)
[25] Whitley, R. J. and Hromadka, T. V., II. Theoretical developments in the complex variable bound-ary element method. Engineering Analysis with Boundary Elements, 30(12), 1020-1024(2006)
[26] Di Paola, M., Pirrotta, A., and Santoro, R. Line element-less method (LEM) for beam torsion solution (truly no-mesh method). Acta Mechanica, 195(1-4), 349-364(2008)
[27] Shams-Ahmadi, M. and Chou, S. I. Complex variable boundary element method for torsion of composite shafts. International Journal for Numerical Methods in Engineering, 40(7), 1165-1179(1997)
[28] Santoro, R. The line element-less method analysis of orthotropic beam for the de Saint Venant torsion problem. International Journal of Mechanical Sciences, 52(1), 43-55(2010)
[29] Sapountzakis, E. J. Nonuniform torsion of multi-material composite bars by the boundary element method. Composite Structures, 79(32), 2805-2816(2001)
[30] Sapountzakis, E. J. and Mokos, V. G. Warping shear stresses in nonuniform torsion of composite bars by BEM. Computer Methods in Applied Mechanics and Engineering, 192(39-40), 4337-4353(2003)
[31] Rychlewski, J. Plastic torsion of a rectangular bar with jump non-homogeneity. International Journal of Solids and Structures, 1(3), 243-255(1965)
[32] Johnson, D. A cellular analogy for the elastic-plastic Saint-Venant torsion problem. International Journal of Solids and Structures, 24(3), 321-329(1988)
[33] Edelstein, W. S. On transient creep bounds and approximate solutions for the torsion of thin strips. International Journal of Solids and Structures, 16(12), 1053-1058(1980)
[34] Timoshenko, S. and Goodier, J. N. Theory of Elasticity, McGraw-Hill, New York (1969)
[35] Sadd, M. H. Elasticity: Theory, Applications, and Numerics, Elsevier Science, Amsterdam (2009)
/
| 〈 |
|
〉 |
Email Alert
RSS