Strength Of Materials: A Practical Approach (vol. I)Strength of Materials is a subject that deals with the behaviour, load carrying capacity (strength), rigidity and stability of isolated members such as bars, shafts, beams, arches, slabs and columns. The individual elements may form a part of structures, machines, automobiles, spacecrafts, towers or antenna dishes. Engineering students are expected to be trained in this subject, and to learn the rudiments of the theory as a part of the curriculum. Taught as Mechanics of soilds and structural mechanics in some courses, it forms part of the curriculum of all the streams of engineering at degree and diploma levels. |
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Page v
... Flexural analysis of beams 103 103 103 106 107 109 113 115 117 118 118 118 121 121 122 123 126 126 128 129 130 132 132 133 134 134 135 136 139 140 142 142 142 143 144 144 145 146 146 147 148 169 170 174 6.0 Introduction 6.1 Assumptions ...
... Flexural analysis of beams 103 103 103 106 107 109 113 115 117 118 118 118 121 121 122 123 126 126 128 129 130 132 132 133 134 134 135 136 139 140 142 142 142 143 144 144 145 146 146 147 148 169 170 174 6.0 Introduction 6.1 Assumptions ...
Page vi
... Flexural rigidity of beams 208 6.9 6.8 Flexural shear stresses 6.8.1 Shear stress analysis 6.8.2 Distribution of shear stresses 6.8.3 Transverse and longitudinal shear 6.8.4 Shear centre Section modulus 6.10 Radius of gyration and ...
... Flexural rigidity of beams 208 6.9 6.8 Flexural shear stresses 6.8.1 Shear stress analysis 6.8.2 Distribution of shear stresses 6.8.3 Transverse and longitudinal shear 6.8.4 Shear centre Section modulus 6.10 Radius of gyration and ...
Page vii
... Flexural direct stresses 344 350 350 350 350 9.6.1.2 Flexural shear stresses 9.6.2 Application of energy methods 9.6.3 Contents vii.
... Flexural direct stresses 344 350 350 350 350 9.6.1.2 Flexural shear stresses 9.6.2 Application of energy methods 9.6.3 Contents vii.
Page viii
Prakash D.S. Rao. 9.6.1.2 Flexural shear stresses 9.6.2 Application of energy methods 9.6.3 Limitations of the method 9.7 Reciprocal theorem 9.8 9.7.1 Maxwell's theorem 9.7.2 Maxwell - Betti's theorem Flexural and torsional effects 9.9 ...
Prakash D.S. Rao. 9.6.1.2 Flexural shear stresses 9.6.2 Application of energy methods 9.6.3 Limitations of the method 9.7 Reciprocal theorem 9.8 9.7.1 Maxwell's theorem 9.7.2 Maxwell - Betti's theorem Flexural and torsional effects 9.9 ...
Page 87
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Contents
External forces on a body | 7 |
Direct stresses | 19 |
19 | 48 |
26 | 56 |
Impact loading and strain energy | 71 |
Shear stresses | 87 |
Stress and strain analysis | 102 |
Analysis of beams | 142 |
Deflections in beams | 314 |
Statically indeterminate beams | 369 |
Determinate arches and frames | 410 |
Trusses | 434 |
Cylinders and spherical shells | 480 |
Columns and struts | 526 |
Springs | 568 |
Appendix A | 597 |
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Common terms and phrases
allowable stress analysis angle applied load arch assumed axial B.M. diagram bending body boundary conditions buckling cantilever centroid circular coefficients coiled column compatibility condition compressive computed conjugate beam cross section cylinder deflection profile deformation Determine the maximum diameter displacement eccentricity elongation equation yields equilibrium condition expressed factor of safety flange flexural free end given hinged hoop stresses horizontal Indian Standards joint length longitudinal material maximum shear stress maximum stress member forces method mild steel mm² Mohr's circle noted obtain P₁ parameters plane Poisson's ratio pressure principal stresses Problem R₁ radial rivets rotation segment shaft shear force shear strain shear stress sin² slope Solution span spring strain energy structural Students are advised subjected Substituting support reactions Taking moments tensile stress tension theorem theory thickness Tmax torque torsional truss tube vertical wire X₁ yield stress Young's modulus zero