Stress Mohr
description
Transcript of Stress Mohr
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Load, Stress and Strain
When I am working on a problem, I never thinkabout beauty. I only think of how to solve theproblem. But when I have finished, if the solutionis not beautiful, I know it is wrong.
Richard Buckminster Fuller
Image: A dragline lifts a large load in a mining operation.
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A Simple Crane
Figure 2.1 A simple crane and forces acting on it. (a) Assembly drawing; (b) free-body diagram of forces acting on the beam.
text reference: Figure 2.1, page 30
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Load Classification
text reference: Figure 2.2, page 31
Figure 2.2 Load classified as to location and method of application. (a) Normal, tensile (b) normal, compressive; (c) shear; (d) bending; (e) torsion; (f) combined
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Sign Convention
Figure 2.3 Sign convention used in bending. (a) y coordinate upward; (b) y coordinate downward.
text reference: Figure 2.3, page 32
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Lever Assembly
Figure 2.4 Lever assembly and results. (a) Lever assembly; (b) results showning (1) normal, tensile, (2) shear, (3) bending, (4) torsion on section B of lever assembly.
text reference: Figure 2.4, page 33
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Supports and Reactions
Table 2.1: Four types of support with their corresponding reactions.
text reference: Table 2.1, page 35
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Ladder Free Body Diagram
Figure 2.5: Ladder having contact with the house and the ground while having a painter on the ladder. Used in Example 2.4. The ladder length is l.
text reference: Figure 2.5, page 36
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External Rim Brake and Forces
Figure 2.6 External rim brake and forces acting on it. (a) External rim brake; (b) external rim brake with forces acting on each part. (Linear dimensions are in millimeters.)
text reference: Figure 2.6, page 38
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Sphere and Forces
Figure 2.7 Sphere and forces acting on it. (a) Sphere supported with wires from top and a spring at the bottom; (b) free-body diagram of forces acting on the sphere. Figure used in Example 2.6.
text reference: Figure 2.7, page 38
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Beam Supports
Figure 2.8 Three types of beam support. (a) Simply supported; (b) cantilevered; (c) overhanging.
text reference: Figure 2.8, page 39
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Simply Supported Bar
Figure 2.9 Simply supported bar with (a) midlength load and reactions; (b) free-body diagram for 0
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Singularity Functions (Part 1)
Table 2.2 Six singularity and load intensity functions with corresponding graphs and expressions.
text reference: Table 2.2, page 43
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Singularity Functions (Part 2)
Table 2.2 Six singularity and load intensity functions with corresponding graphs and expressions.
text reference: Table 2.2, page 43
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Shear and Moment Diagrams
Figure 2.10 (a) Shear and (b) moment diagrams for Example 2.8.
text reference: Figure 2.10, page 44
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Simply Supported Beam
Figure 2.11 Simply supported beam. (a) Forces acting on beam when P1=8kN, P2=5kN; w0=4kN/m; l=12m; (b) free-body diagram showing resulting forces; (c) shear and (d) moment diagrams of Example 2.9.
text reference: Figure 2.11, page 46
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Example 2.10
Figure 2.12 Figures used in Example 2.10. (a) Load assembly drawing; (b) free-body diagram.
text reference: Figure 2.12, page 48
10mm
6mm
25mm
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Example
text reference: Figure 2.12, page 48
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General State of Stress
Figure 2.13 Stress element showing general state of three-dimensional stress with origin placed in center of element.
text reference: Figure 2.13, page 49
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2-D State of Stress
Figure 2.14 Stress element showing two-dimensional state of stress. (a) Three dimensional view; (b) plane view.
text reference: Figure 2.14, page 51
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Equivalent Stresses
Figure 2.15 Illustration of equivalent stresss states; (a) Stress element oriented in the direction of applied stress. (b) stress element oriented in different (arbitrary) direction.
text reference: Figure 2.15, page 52
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Stresses in Oblique Plane
Figure 2.16 Stresses in oblique plane at angle .text reference: Figure 2.16, page 52
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Mohrs Circle
Figure 2.17 Mohrs circle diagram of Eqs. (2.13) and (2.14).
text reference: Figure 2.17, page 55
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Results from Example 2.13
Figure 2.18 Results from Example 2.13 (a) Mohrs circle diagram; (b) stress element for principal normal stresses shown in x-y coordinates; (c) stress element for principal stresses shown in x-y coordinates.
text reference: Figure 2.18, page 57
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Mohrs Circle for Triaxial Stress State
Figure 2.19 Mohrs circle for triaxial stress state. (a) Mohrs circle representation; (b) principal stresses on two planes.
text reference: Figure 2.19, page 59
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Example 3.5
Figure 2.20 Mohrs circle diagram for Example 3.5. (a) Triaxial stress state when 1=23.43 ksi, 2=4.57 ksi, and 3=0; (b) biaxial stress state when 1=30.76 ksi and 2=-2.760 ksi; (c) triaxial stress state when 1=30.76 ksi, 2=0, and 3=-2.76 ksi.
text reference: Figure 2.20, page 60
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Stresses on Octahedral Planes
Figure 2.21 Stresses acting on octahedral planes. (a) General state of stress. (b) normal stress; (c) octahedral shear stress.
text reference: Figure 2.21, page 61
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Normal Strain
Figure 2.22 Normal strain of cubic element subjected to uniform tension in x direction. (a) Three dimensional view; (b) two-dimensional (or plane) view.
text reference: Figure 2.21, page 64
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Shear Strain
Figure 2.23 Shear strain of cubic element subjected to shear stress. (a) Three dimensional view; (b) two-dimensional (or plane) view.
text reference: Figure 2.23, page 65
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Plain Strain
Figure 2.24 Graphical depiction of plane strain element. (a) Normal strain x; (b) normal strain y; and (c) shear strain xy.
text reference: Figure 2.24, page 66
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Circular Bar with Tensile Load
Figure 4.10 Circular bar with tensile load applied.
text reference: Figure 4.10, page 149
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Twisting due to Applied Torque
Figure 4.11 Twisting of member due to applied torque.
text reference: Figure 4.11, page 152
lr
Hipotesis de Coulomb: secciones transversales circulares, permanecen planas.
Principio de Saint Venant: secciones transversales no circulares.
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Bending of a Bar
Figure 4.12 Bar made of elastomeric material to illustrate effect of bending. (a) Undeformed bar; (b) deformed bar.
text reference: Figure 4.12, page 156
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Bending in Cantilevered Bar
Figure 4.13 Bending occurring in cantilevered bar, showing neutral surface.
text reference: Figure 4.13, page 157
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Figure 4.14 Undeformed and deformed elements in bending.
text reference: Figure 4.14, page 157
Elements in Bending
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Bending Stress Distribution
Figure 4.15 Profile view of bending stress variation.
text reference: Figure 4.15, page 158
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Example 4.10
Figure 4.16 U-shaped cross section experiencing bending moment, used in Example 4.10.
text reference: Figure 4.16, page 159
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Curved Member in Bending
text reference: Figure 4.17, page 161
rdrr n )(
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Curved Member in Bending
0)( dAr rrEddA A nA
rdrrEE n )(
r
drr n )(
Condicin: sumatorio de esfuerzos en el rn=0
A
nA
n
rdAAr
rdArA 0
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Curved Member in Bending
dArA
rA 1_
rdrrEE n )(
)(_
nrre
A
n
rdAAr
AerMc
rrEAerM
n
AeEdArrdAEdr
dArArArrdAEd
dAr
rrrrEddArrrEddArrM
An
Annn
A
nn
A
n
An
2
222 )2()())((
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Cross Section of Curved Member
Figure 4.18 Rectangular cross section of curved member.
text reference: Figure 4.18, page 162
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Example: Cross Section of Curved Member
Una seccin transversal rectangular de un elemento curvo, tiene las dimensiones:
b= 1 y h=r0-ri=3, sometida a un momento de flexin puro de 20000lbf-pulg.
Hallar:
a) Elemento recto.
b) Elemento curvo. r=15.
c) Elemento curvo. r=3.
text reference: Figure 4.18, page 162
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Tabla de Ganchos
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Example: Cross Section of Curved Member
Una seccin trapezoidal de un elemento curvo, tiene las dimensiones:
ri=10 cm
F= 125 kg
Tadm=1380 Kg/cm2
Hallar: valor de a.
text reference: Figure 4.18, page 162
01
01 23 bb
bbhrr in
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Development of Transverse Shear
Figure 4.19 How transverse shear is developed.
text reference: Figure 4.19, page 165
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Deformation due to Transverse Shear
Figure 4.20 Cantilevered bar made of highly deformable material and marked with horizontal and vertical grid lines to show deformation due to transverse shear. (a) Undeformed; (b) deformed.
text reference: Figure 4.20, page 166
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Moments and Stresses on Elements
Figure 4.21 Three-dimensional and profile views of moments and stresses associated with shaded top segment of element that has been sectioned at y about neutral axis. (a) Three-dimensional view; (b) profile view.
text reference: Figure 4.21, page 166
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Maximum Shear Stress
Table 4.3 Maximum shear stress for different beam cross sections.
text reference: Table 4.3, page 168
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Strain Gage Rosette
Figure 2.25 Strain gage rosette used in Example 2.17.
text reference: Figure 2.25, page 68
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BIBLIOGRAFIAde referencia
Bernard J. Hamrock, Elementos de mquinas. Ed. Mc Graw Hill.
Robert L. Norton, Diseo de mquinas. Ed. Prentice Hall.
Shigley, Diseo en Ingeniera Mecnica, Ed. Mc Graw-Hill