BENDING STRESSES IN BEAMS · 2021. 1. 20. · PURE BENDING or SIMPLE BENDING. Simple bending or...
Transcript of BENDING STRESSES IN BEAMS · 2021. 1. 20. · PURE BENDING or SIMPLE BENDING. Simple bending or...
• RAGHU ENGINEERING COLLEGE
(AUTONOMOUS)
DEPARTMENT OF MECHANICAL ENGINEERING
Mechanics of solids
UNIT-3 Flexural and Shear Stresses in Beams
Prepared by
Singuru Rajesh
Assistant Professor1
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CONTENTS:
Bending in Beams
Stresses due to bending
Simple Bending or Pure bending
Assumptions of theory of Simple Bending
Neutral Axis
Moment of Resistance
Bending of Flitched Beams
Shear stresses in beams
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FLEXURAL STRESSES: Theory of simple bending –
Assumptions – Derivation of bending equation: M/ I =f/y = E/R
Neutral axis – Determination bending stresses – section
modulus of rectangular and circular sections(Solid and Hollow),
I,T, Angle and Channel sections – Design of simple beam
sections.
SHEAR STRESSES: Derivation of formula – Shear stress
distribution across various beams sections like rectangular,
circular, triangular, I, T angle sections.
Bending in beams
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Stresses due to bending
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12/39
e
Bending
ee e
Compression
Tension
Shear
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WHAT THE LOADS DO????
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LC B
W KN
SFD
BMD
- Base Line
SFD and BMD for OVER
HANGING BEAM POINT
LOAD with Point Load
A𝐾𝑁
Base Line
a𝑅𝐴 𝑅𝐵
C
BA
CB
D
D+
-
KN
D
W KN
KNm KNm
A
a
PURE BENDING or SIMPLE BENDING
Simple bending or Pure bending
• When some external force acts on a beam, the shearforce and bending moments are set up at all thesections of the beam
• Due to shear force and bending moment, the beamundergoes deformation. The material of the beamoffers resistance to deformation.
• Stresses introduced by bending moment are knownas bending stresses.
• These Bending stresses are indirect normal stresses.
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Simple bending or Pure bending
• When some external force acts on a beam, the shearforce and bending moments are set up at all thesections of the beam
• Due to shear force and bending moment, the beamundergoes deformation. The material of the beamoffers resistance to deformation.
• Stresses introduced by bending moment are knownas bending stresses.
• These Bending stresses are indirect normal stresses.
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AssumptionsThe following are the assumptions of Simple Bending:
1. The material of the beam is isotropic and homogeneous. Ie ofsame density and elastic properties throughout.
2. The value of Young’s modulus of elasticity is the same in tensionand compression.
3. The transverse sections which were plane before bending, remainplane after bending also.
4. The beam is initially straight and all longitudinal filaments bendinto circular arcs with a common centre of curvature.
5. The radius of curvature is large compared with the dimensions ofthe cross-section.
6. Each layer of the beam is free to expand or contract,independently of the layer, above or below it.
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Theory of simple bending
AssumptionsThe following are the assumptions of Simple Bending:
1. The material of the beam is isotropic and homogeneous. Ie ofsame density and elastic properties throughout.
2. The value of Young’s modulus of elasticity is the same in tensionand compression.
3. The transverse sections which were plane before bending, remainplane after bending also.
4. The beam is initially straight and all longitudinal filaments bendinto circular arcs with a common centre of curvature.
5. The radius of curvature is large compared with the dimensions ofthe cross-section.
6. Each layer of the beam is free to expand or contract,independently of the layer, above or below it.
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Theory of simple bending
Theory of simple bending
• Consider a beam subjected to simple bending. Consider aninfinitesimal element of length dx which is a part of this beam.Consider two transverse sections AB and CD which are normalto the axis of the beam and parallel to each other.
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Theory of simple bending
• Due to the bending action the element ABCD is deformed toA’B’C’D’ (concave curve).
• The layers of the beam are not of the same length beforebending and after bending .
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• The layer AC is shortened to A’C’. Hence it is subjected tocompressive stress.
• The layer BD is elongated to B’D’. Hence it is subjected totensile stresses.
• Hence the amount of shortening decrease from the top layertowards bottom and the amount of elongation decreases fromthe bottom layer towards top.
• Therefore there is a layer in between which neither elongatesnor shortens. This layer is called neutral layer.
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Neutral Axis• For a beam subjected to a pure bending moment, the stresses
generated on the neutral layer is zero.
• Neutral axis is the line of intersection of neutral layer with thetransverse section
• Consider the cross section of a beam subjected to pure bending.The stress at a distance y from the neutral axis is given by σ/y=E/R
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Neutral Axis• For a beam subjected to a pure bending moment, the stresses
generated on the neutral layer is zero.
• Neutral axis is the line of intersection of neutral layer with thetransverse section
• Consider the cross section of a beam subjected to pure bending.The stress at a distance y from the neutral axis is given by σ/y=E/R
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REMEMBER POINT
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Moment of Resistance
• Due to the tensile and compressive stresses, forcesare exerted on the layers of a beam subjected tosimple bending.
• These forces will have moment about the neutralaxis. The total moment of these forces about theneutral axis is known as moment of resistance ofthat section.
• We have seen that force on a layer of cross sectionalarea dA at a distance y from the neutral axis,
dF= (E x y x dA)/R
Moment of force dF about the neutral axis= dF x y= (E x y x dA)/R x y= E/R x (y²dA).
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• Hence the total moment of force about theneutral axis=
Bending moment applied= ∫ E/R x (y²dA)= E/R x Ixx
• Ixx is the moment of area about the neutralaxis/centroidal axis.
Hence M = E/R x Ixx
Or M/Ixx=E/R
Hence M/Ixx=E/R = σb/y;
σb is also known as flexural stress (Fb).
Hence M/Ixx=E/R=Fb/y
• The above equation is known as bendingequation.
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Condition of Simple Bending
• Bending equation is applicable to a beam subjected topure/simple bending. Ie the bending moment acting onthe beam is constant and the shear stress is zero.
• However in practical applications, the bending momentvaries from section to section and the shear force is notzero.
• But in the section where bending moment is maximum,shear force (derivative of bending moment) is zero.
• Hence the bending equation is valid for the sectionwhere bending moment is maximum.
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Bending of fletched beams
• A beam made up of two or more different materialsassumed to be rigidly connected together and behavinglike a single piece is called a flitched beam or acomposite beam.
• Consider a wooden beam reinforced by steel plates. Let
E1= Modulus of elasticity of steel plate
E2= Modulus of elasticity of wooden beam
M1= Moment of resistance of steel plate
M2= Moment of resistance of wooden beam
I1= Moment of inertia of steel plate about neutral axis
I2= Moment of inertia of wooden beam about neutral axis.Singuru Rajesh Mechanics of Solids Mechanical Engineering REC 23
The bending stresses can be calculated using twoconditions.
• Strain developed on a layer at a particulardistance from the neutral axis is the same forboth the materials
• Moment of resistance of composite beam isequal to the sum of individual moment ofresistance of the members
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Using condition-1:
σ1/E1= σ2/E2;
σ1= σ2 x (E1/E2) or σ1 = σ 2 x m;
where m= E1/E2 is the modular ratio
between steel and wood
Using condition-2:
M=M1 + M2;
M1= σ1x I1/y
M1= σ2x I2/y
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• A beam is made up of two or more differentmaterials assumed to be rigidly connectedtogether and behaving like a single piece isknown as composite beam or wooden FlitchedBeam.
Flitched Beams or Composite Beams
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Problem 1
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Problem 1
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Problem 1 Continued….
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Section Modulus for Various Shapes or Beam Sections
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Section Modulus for Various Shapes or Beam Sections
d/2
d
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Problem 2
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Problem 3
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A steel plate of width 200mm and of thickness 50mm is bent into a circular arc of radius 20m. Determine the max stress induced and the bending moment which will produce the max stress. Take E= 2 x 10^5 N/mm^2.
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Problem 4
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Problem 4: Calculate the maximum stress induced in a cast iron pipe of external diameter 40mm, of internal diameter 20mm and of length 4m then the pipe is supported at its ends and carry a point load of 80N at its centre.
Soln:
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Problem 4: Calculate the maximum stress induced in a cast iron pipe of external diameter 40mm, of internal diameter 20mm and of length 4m then the pipe is supported at its ends and carry a point load of 80N at its centre.
Soln:
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6.
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Contd.
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9. Contd.
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9. Contd.
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Bending Stresses in Symmetrical Sections
• The Neutral Axis (N.A) of a symmetrical section (such as circular,rectangular or square) lies at a distance of d/2 from the section where dis the diameter (for a circular section) or depth (for a rectangular or asquare section). There is no stress at the neutral axis
• But the stress at a point is directly proportional to its distance from the neutral axis.
• The maximum stress takes place at the outer most layer• For SSB there is a compressive stress above the neutral axis and a tensile
stress below it.
Shear stresses in beams
The stresses induced by shear force at a section in a beam may be
analyzed as follows:
Consider an elemental length of a beam between the sections AA
and BB separated by a distance dx, as shown in the following
figure. Let the moments acting at AA and BB be M and M+ dM
respectively.
Let CD be a fibre of thickness dy at a distance y from the neutral
axis. Then bending stress at left side of the fibre CD = M y/I
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SHEAR STRESS IN A SECTION
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Shear stresses in beams Force on the left side of the layer CD =M y (b.dy)/I
and force on the right side of the layer CD =
(M+dM).y.(b.dy)/I
Therefore unbalanced force, towards right, on the layer CD
is = dM.y.b.dy/I
There are a number of such elements above the section CD.
Hence the unbalanced horizontal force above the section
CD =
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I∫y
dM.y.b.dy
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yt
This horizontal force is resisted by the resisting force
provided by shearing stresses acting horizontally on the
plane at CD.Let the intensity of shear stress be τ. Equating the
I
resisting force provided by the shearing stress to the
unbalanced horizontal force we have:
y t
dM .y . b. dy∫y
where da = b.dy is area of theelement .
where the term
y t
y
τ .b.dx =
∫y.da = ay = Moment of, area above the
fibre CD about the NA.
y t
1
dx I.by
or τ=dM . ∫ y.da
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But the term dM / dx = F, the shear force. Substituting in the
expression for τ, we obtain :
where :F a y
I bτ =
F = shear force at a section in a beam
a = area above or below a fibre (shaded area)
y = dist. from N.A. to the centroid of the shaded area
I = M.I. of the entire section about the N.A
b = breadth of the fibre.
Note :The above expression is for horizontal shear stress. From
The principle of complementary shear, this horizontal shear stress
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SHEAR STRESS DISTRIBUTION DIAGRAM
1.Rectangular section
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SHEAR STRESS DISTRIBUTION DIAGRAM
1.Rectangular section
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• Contd…
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Shear Stress Distribution in Circular Cross
Section
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𝝉 =
SHEAR STRESS DISTRIBUTION DIAGRAM
1.Rectangular section
2.Circular section
maxNA
maxNA
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3.Triangular section
4.Hollow circular section
h/2 max
avg
NA
maxNA
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5.Hollow Rectangular section
6. “I” section
maxNA
maxNA
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7. “C” section
8. “+” section
maxNA
maxNA
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9. “H” section
10. “T” section
maxNA
maxNA
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Shear Stress Distribution of ‘I’
Section
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