strength of materials_2
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Dr. K.ChinnarajuAssociate Professor
Division of Structural EngineeringAnna University, Chennai 600 025
email: [email protected]
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COURSE GOALS
This course has two specificgoals:• (i) To introduce students to
concepts of stresses and strains;shearing force and bendingmoment; torsion and deflection of
different structural / machineelements: as well as analysis ofstresses in two dimensions
Dr.K.Chinnaraju, Associate Professor, Division of Structural Engineering, Anna University, Chennai - 600 025.
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COURSE OUTLINE
Unit -I Stress, strain and deformationof solids
Simple and compound bars, thermalstresses, Elastic constants and strainenergy
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course outline …..
Unit – II Beams – loads and stressesshear force and bending moments,theory of simple bending, bending andshear stresses
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course outline …. Unit – III Torsion
Torsion on circular bars, powertransmitted by solid and hollow shafts – springs
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course outline …. Unit – IV Deflection of beams and
column theoriesDouble integration method,Macaulay s method and area momentmethod.Columns – Euler s theory andRankine s formula
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course outline ….
Unit – V Stresses in two dimensions
Thin cylindrical and spherical shells,Principal stresses and planes – Mohr s circle
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UNIT -1STRESS, STRAIN AND
DEFORMATION OF SOLIDSDefinitions:Rigid Body: A rigid body is an idealizationof a solid body of finite size in whichdeformation is neglected.
In other words, the distance between anytwo given points of a rigid body remainsconstant in time regardless of external
forces exerted on it.Dr.K.Chinnaraju, Associate Professor, Division of Structural Engineering, Anna University, Chennai - 600 025.
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Elastic : If a material returns to its
original size and shape on removal ofload causing deformation, it is said to beelastic .
Elastic limit, is the limit up to which thematerial is perfectly elastic.Elastic stress is the maximum stress orforce per unit area within a solid materialthat can arise before the onset ofpermanent deformation.
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• When stresses up to the elastic limitare removed, the material resumes its
original size and shape.
• Stresses beyond the elastic limit causea material to yield or flow. For suchmaterials the elastic limit marks the end
of elastic behaviour and the beginningof plastic behaviour.
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The strength of any material relies on thefollowing three terms:
Strength ,Stiffness and Stability .Strength means load carrying capacity, or
it is the ability to withstand an appliedstress without failure. The applied stressmay be tensile, compressive, or shear.Stiffness means resistance to
deformation or elongation, andStability means ability to maintain its initial
configuration.Dr.K.Chinnaraju, Associate Professor, Division of Structural Engineering, Anna University, Chennai - 600 025.
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Stiffness (k)
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Stress is a measure of the internalreaction between elementary particles of
a material in resisting separation,compaction, or sliding that tend to beinduced by external forces.
Mathematically, it is expressed as theratio of the load applied to the crosssectional area.
Unit: Usually N/m 2 (Pa), N/mm 2, MN/m 2,GN/m
• Note: 1 N/mm2
= 1 MN/m2
= 1 MPaDr.K.Chinnaraju, Associate Professor, Division of Structural Engineering, Anna University, Chennai - 600 025.
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Strain is defined as the amount ofdeformation an object experiences
compared to its original size and shape.• i.e., strain is the relative change in shapeor size of an object due to externally
applied force.• Mathematically, it is expressed as the
ratio of change in dimension to originaldimension
• i.e strain = ∆/L
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Hooke’s Law: It states that providing thelimit of proportionality of a material is notexceeded, the stress is directly proportionalto the strain produced.• i.e., with in the elastic limit, the stress is
directly proportional to the strain• If a graph of stress and strain is plotted as
load is gradually applied, the first portionof the graph will be a straight line.
Dr.K.Chinnaraju, Associate Professor, Division of Structural Engineering, Anna University, Chennai - 600 025.
f
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• Modulus of Elasticity (E) • It is defined as the stress intensity required
by the body to produce unit strain.• It is a measure of the stiffness of a
material.Direct stress ( ζ )
E = ------------------Direct strain ( ε)
Units : N/m 2 (Pa), or N/mm 2, or MN/m 2, orGN/m 2 etc.,
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Direct or Normal stress
When a force is transmitted through abody, the body tends to change itsshape or deform. The body is said to
be strained.
• Direct Stress = Applied Force (F)
Cross Sectional Area (A)
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Direct Stress Cont...
• Direct stress may be tensile, t orcompressive, c and result from forces
acting perpendicular to the plane of thecross-section
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Tension
Compression
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Direct or Normal Strain
• When loads are applied to a body, somedeformation will occur resulting to achange in dimension.
• Consider a bar, subjected to axial tensileloading force, F. If the bar extension is ∆ and its original length (before loading) is L,then tensile strain is:
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Direct or Normal Strain Cont ….
• Direct Strain ( ) = Change in LengthOriginal Length
i.e. = ∆/L Dr.K.Chinnaraju, Associate Professor, Division of Structural Engineering, Anna University, Chennai - 600 025.
∆
FF
L
Di t N l St i C td
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Direct or Normal Strain Contd.
• As strain is a ratio of lengths, it isdimensionless.• Similarly, for compression by amount,∆ :
Compressive strain = - ∆ /L• Note: Strain is positive for an increasein dimension and negative for a
reduction in dimension.
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Shear Stress and Shear Strain
• Shear stresses are produced byequal and opposite parallel forcesnot in line.
• The forces tend to make one partof the material slide over the otherpart.
• Shear stress is tangential to thearea over which it acts.
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Shear Stress and Shear Strain Contd .
Dr.K.Chinnaraju, Associate Professor, Division of Structural Engineering, Anna University, Chennai - 600 025.
P Q
S R
F
D D’
A B
C C’
L
x
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Shear Stress and Shear Strain Contd .
Dr.K.Chinnaraju, Associate Professor, Division of Structural Engineering, Anna University, Chennai - 600 025.
Shear strain is the distortion producedby shear stress on an element or
rectangular block as above. The shearstrain, (gamma) is given as:
= x/L= tan
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Shear Stress and Shear Strain Contd
• For small angle ,
• Shear strain then becomes the change inthe right angle.
• It is dimensionless and is measured inradians.
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Complementary Shear Stress
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a
1
1
2 2
P Q
S R
Consider a small element, PQRS ofthe material in the last diagram. Letthe shear stress created on faces PQand RS be 1
b
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Complimentary Shear Stress Contd.
• The element is therefore subjected toa couple and for equilibrium, abalancing couple must be broughtinto action.
• This will only arise from the shearstress on faces QR and PS.
• Let the shear stresses on these facesbe
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2
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Complimentary Shear Stress Contd.• Let t be the thickness of the material at
right angles to the paper and lengths ofsides of element be a and b as shown.
• For equilibrium, clockwise couple =anticlockwise couple
• i.e. Force on PQ (or RS) x a = Force on
QR (or PS) x b•
Dr.K.Chinnaraju, Associate Professor, Division of Structural Engineering, Anna University, Chennai - 600 025.
1 2
1 2
x b t x a x a t x b
i e. .
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• Thus: Whenever a shear stressoccurs on a plane within a material, itis automatically accompanied by anequal shear stress on theperpendicular plane.The direction of the complementaryshear stress is such that their couple
opposes that of the couple due to theoriginal shear stresses.
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Deformation of Simple BarsWe know, modulus of elasticity,
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Dr.K.Chinnaraju, Associate Professor, Division of Structural Engineering, Anna University, Chennai - 600 025.
Ex 1: A lampweighing W = 50Nhangs fromthe ceiling by a steelwire of diameterD = 2.5mm Determine theelongation Δ of thewire due to thelamp s weight.
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Deformation of a solidtruncated conical Bar
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Φ x
Deformation of the element
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Deformation of the element,
Where
where,
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T l d f i f h b
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Total deformation of the bar,
=
=
=
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0
l
= l
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= -
= -
=
=
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0
l
f f f
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Deformation of uniformly taperingrectangular bar
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Total deformation of the bar,
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L
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Elongation of a bar due to itsself weight
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Deformation of the element,
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Total deformation,
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where w = total weight ofthe bar
=
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Deformation of a Stepped Bar
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40 kN 50 kN
Deformation of a Stepped Bar Ex 2: A steel bar ABCD is shown infig. Determine the total change inlength of the bar. Take E = 200 Gpa.
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Free body diagram
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= 0.0333 - 0.18 + 0.05= -0.0967 mm (- sign indicates the
deformation in contraction)Dr.K.Chinnaraju, Associate Professor, Division of Structural Engineering, Anna University, Chennai - 600 025.
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Composite barDefinition : A bar made up of two or
more different materials and fastenedtogether to prevent uneven strainingand act as a single bar subjected toaxial loading or temperature change.
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by equilibrium condition
P = P S + P C
= f S A
S + f
C A
C ------ > (1)
by compatibility condition
Δs = Δc
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solving ( 1 ) & (2 ), we get f s and f c
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Ex 3: A steel rod of diameter 25 mm is placedinside a copper tube of internaldiameter 30 mm and external diameter40 mm, the ends being firmly fastened
together. Determine the stressesinduced in the steel rod and coppertube when the composite bar is
subjected to a compressive load of 500kN. Take E s = 2 x 10 5 N/mm 2 andE c = 1.1 x 10 5 N/mm 2
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Solution
Area of steel rod A S
Area of copper tube A c =(π /4) × (40 2-30 2)
By equilibrium equation, P=
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By compatibility condition
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By compatibility condition,
Solving (1) and (2) , we get
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Ex 4:
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Ex 4: A steel rod of diameter 30 mm and
length 500 mm is placed inside aaluminium tube of internal diameter35 mm and external diameter 45 mm
which is 1 mm longer than the steelrod. A load of 300 kN is placed on theassembly through the rigid collar.
Find the stress induced in steel rodand aluminium tubeTake E s = 200 GPa and E a = 80 GPa
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Solution
Initial load carried by aluminium tubealone corresponding to acompression of 1 mm
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Load for composite action,
= 300000-100330= 199670 N
By equilibrium condition ofcomposite action,
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Solving (1) and (2), we get
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Ex 5Two vertical rods one of steel and the
other of copper are rigidly fastened at theirupper end at a horizontal distance of 200 mmas shown in fig. the lower end supported arigid horizontal bar, which carries a load of 10kN. Both the rods are 2.5 m long and havecross sectional area of 12.5mm 2. Whereshould a load of 10 kN be placed on the bar,so that it remains horizontal after loading.
Also find the stresses in each rod. Take E s=200 Gpa and E c=110Gpa. Neglect bending ofcross bar.Dr.K.Chinnaraju, Associate Professor, Division of Structural Engineering, Anna University, Chennai - 600 025.
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by compatibility,
by equilibrium condition,
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Solving (1) & (2), we get
Position of load
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Thermal stresses
Whenever there is some increase ordecrease in the temperature of a body,it causes the body to expand or
contract.If the body is allowed to expand orcontract freely, with the rise or fall oftemperature, no stresses are inducedin the body.
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Thermal stresses ….
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If the deformation of the body isprevented, some stresses are induced inthe body. Such stresses are calledthermal stresses or temperature stresses.Change in length of a bar due tochange in temperature, ∆ = lαt Where ,l = length of the member
α = co efficient of thermalexpansion of the materialt = change in temperature
Note: strain = α tDr.K.Chinnaraju, Associate Professor, Division of Structural Engineering, Anna University, Chennai - 600 025.
Thermal stresses
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Note„f is compressive in nature due to
increase in temperature and tensile innature due to decrease in temperature
We know, for an axially loaded bar ,
Thermal stresses
,
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E 6
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Ex:6 A steel rod of length 3m,
diameter 20mm is subjected to anincrease in temperature of 100 °C.Find (i) the free expansion of the rodand stress induced in the rod whenthe expansion is fully prevented.(ii) the stress in the rod when theextension permitted is 1mm . Take α=12 ×10 -6/°c and E S= 200 Gpa.
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SolutionFree expansion of steel rod = lαt
Stress induced when the expansion isfully prevented ,f = Eαt
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If the extension permitted λ = 1mm
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If the extension permitted,λ = 1mm
extension prevented = (lαt- λ) = 3.6-1= 2.6mm
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Ex:7 A tapered bar as shown in Fig. below issubjected to a increase in temperature of90 ˚C. Find maximum and minimum stressinduced in material when expansion istotally prevented.
Take α = 12 × 10 -6 / ˚C, E = 2 × 10 5 N/mm 2.
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d1 = 100mm d 2 = 150mml = 400 mm
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Soln:Free expansion, Δ = l αT
If the expansion of the bar is totallyprevented, then this is equivalent to thesame bar is subjected to a compressiveforce (P)
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P P
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Soln:
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Thermal stress on composite
bar
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Ex:8 A composite bar is made with
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Ex:8 A composite bar is made witha copper flat of size 50 ×30mm and
steel flat of 50 ×40mm of length500mm each placed one over theother. Find the stress induced in the
material, when the composite bar issubjected to an increase intemperature of 100 °C. Take
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For composite action;There is a push in copper and pull in steel.
For equilibrium, push in copper ( ) = pull in steel ( )
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Actual expansion of copper (extension)
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Actual expansion of copper (extension)= (free expansion of copper –
contraction due to composite action)
Actual expansion of steel= (free expansion of steel) +
(expansion due to composite action)
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F i i
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For composite action,
…………….(2) Sub (1) in (2)
f s=32.78 N/mm2
(T)f c=43.60 N/mm 2 (C)
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Ex:9 A rigid horizontal bar of negligiblemass is connected to two rods asshown in Fig. If the system is initiallystress-free. Calculate the temperature
change that will cause a tensile stressof 90 MPa in the brass rod. Assumethat both rods are subjected to the
change in temperature.
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Solution
Let , Pbr be the force in brass rodand Pco be the force in brass roddue to the change in temperature.
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(Stress induced in the copper rod)
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We know,
Where δbr and δco are the amountof deformations prevented in thebrass and copper rod respectivelyDr.K.Chinnaraju, Associate Professor, Division of Structural Engineering, Anna University, Chennai - 600 025.
δ δ
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Let δT(br) and δT(co) are the amount offree deformations induced due tochange in temperature in the brassand copper rod respectively.
Net deformation of brass rod= δbr - δT(br) and
net deformation of copper rod
= δT(co) - δco
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(drop in temperature) Dr.K.Chinnaraju, Associate Professor, Division of Structural Engineering, Anna University, Chennai - 600 025.
Shrinking on stressesh d f h l
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The inner diameter of the steeltyre is slightly greater than the
outer diameter of the woodenwheel.The steel tyre is heated andslipped on to the wooden wheeland cooled to fit.Strain in the steel tyre= (π D - π d)/ π d = (D - d)/d
Stress in the steel tyre= E (D - d)/d
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ELASTIC CONSTANTS
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Poisson's ratio (µ ), is the ratio, whena sample object is stretched, of thecontraction or transverse strain
(perpendicular to the applied load), tothe extension or axial strain (in thedirection of the applied load).
i.e., it is the ratio of lateral strain tolongitudinal strain.
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When a material is compressed in
one direction, it usually tends to expandin the other two directionsperpendicular to the direction of
compression. This phenomenon iscalled the Poisson effect .
Poisson's ratio µ( nu ) is a measureof the Poisson effect.
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Most materials have Poisson's ratio
values ranging between 0.0 and 0.5. A perfectly incompressible materialdeformed elastically at small strains
would have a Poisson's ratio ofexactly 0.5.Rubber has a Poisson ratio of nearly
0.5.
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• Most steels and rigid polymers when
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used within their design limits (before
yield) exhibit values of about 0.3,increasing to 0.5 for post-yielddeformation (which occurs largely at
constant volume.)• Cork's Poisson ratio is close to 0:
showing very little lateral expansionwhen compressed
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Poisson s ratio,
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,
µ =
Volumetric strain of a rectangular bodysubjected to an axial force
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Initial volume,
Final length,
Final breadth,
Final thickness,
Final volume, _
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Change in volume,
Neglecting the product of two or
more small quantitiesV _
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Volumetric strain,
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(or)
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(or)
Differentiating, we get
ie.,
Volumetric strain = Sum of linear strainsDr.K.Chinnaraju, Associate Professor, Division of Structural Engineering, Anna University, Chennai - 600 025.
N
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Note:
1) For a solid cylindrical bar ofdiameter „d and length „l
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Note:
2) For a sphere of diameter ‘D’
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Volumetric strain of a rectangular body
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Volumetric strain of a rectangular bodysubjected to three mutuallyperpendicular forces
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The resultant strain in x direction,
Similarly
and
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Volumetric strain,
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Ex:10 A solid metallic bar of size 200mm× 100mm × 70mm is subjected to forces
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× 100mm × 70mm is subjected to forcesin three mutually perpendicular directionsas shown in Fig. Find the change involume of the bar. Take E=200GPa andPoisson s ratio, µ=0.25. Also find thechange that should be made inthe 900kNload, in order that there should be nochange in volume of the bar.
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Dr.K.Chinnaraju, Associate Professor, Division of Structural Engineering, Anna University, Chennai - 600 025.
P y = 900 kN
900 kN
P x = 600 kN600 kN
P z = 800 kN
800 kN200 mm
70 mm
100mm
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Soln:
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change in volume,
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For,
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Bulk modulus
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Bulk modulus
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When a body is subjected to threemutually perpendicular stresses ofequal intensity, the ratio of direct
stress to the correspondingvolumetric strain is called Bulkmodulus (K)
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Bulk modulus
The ratio of the stress on the body tothe body's fractional decrease involume is the bulk modulus. i.e., it is defined as the direct stressrequired to produce unit volumetricstrain in the body.
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Relation between Bulk Modulus
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and Modulus of Elasticity
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V l t i t i
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Volumetric strain,
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Shear modulus
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Shear modulus
• Shear Modulus or Modulus of Rigidityis the coefficient of elasticity for ashearing or torsion force.
• The ratio of the tangential force perunit area to the angular deformationin radians is the shear modulus.
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• The shear modulus is the elastic
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modulus we use for the deformation
which takes place when a force isapplied parallel to one face of theobject while the opposite face is held
fixed by another equal force.
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• When an object like a block of heightd i A i
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L and cross section A experiences a
force F parallel to one face, thesheared face will move a distance Δx.The shear stress is defined as the
magnitude of the force per unit cross-sectional area of the face beingsheared (F/A). The shear strain is
defined as Δx/L.
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The shear modulus N is defined as
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Shear modulus,
the ratio of the shearing stress to the
shearing strain.
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Relation between Shear Modulusand Modulus of Elasticity
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C
and Modulus of Elasticity
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Shearing strain
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Strain in the diagonal AC
Linear strain in the diagonal AC
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qB
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q
q
q
q
A
B C
D
q
q
A
B
D
fq
q
f cos 45 ( a√2 * 1) – q (a * 1) = 0f = q
a
aq
q
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Considering an element in the diagonal,
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Strain in the diagonal AC,
)
From (1) & (2)
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Relation between E,K and N
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We know that,
From (2),
From (1),
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( ),
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Ex 11: A bar (square) of size 10mm × 10mmb d l ll f k h
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is subjected to an axial pull of 25kN. The
measured extension over a gauge lengthof 200mm is 0.25mm. Final dimension ofthe bar is 9.997 × 9.997 mm. Find thePoisson s ratio µ and the three elasticmodulii.
Soln: L = 200mm
ΔL = 0.25mm
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Soln:
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P = 25 kN
Δ = 0.25 mm
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Strain energyWhenever a body is strained some
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Whenever a body is strained, someamount of energy is absorbed in thebody. The energy that is absorbed inthe body due to straining effect isknown as strain energy.
(or)The potential energy stored in a bodyby virtue of an elastic deformation,equal to the work that must be doneto produce this deformation .
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Work and EnergyF Consider a solid object
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F
F
dr
F
dx
Consider a solid object
acted upon by force, F, at apoint, O, as shown in thefigure.
The work done = F dr
x z
y
For the general case:W = F x d x i.e., only the force inthe direction of thedeformation does work.
Amount of Work done
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Constant Force: If the Force isconstant, the work is simply theproduct of the force and thedisplacement, W = F X
Force
FDisplacemen tx
Amount of Work done
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Linear Force: If the force is proportionalto the displacement, the work is
F
Displacementx
oo x F W
2
1
Fo
x o
Strain Energy
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Dr.K.Chinnaraju, Associate Professor, Division of Structural Engineering, Anna University, Chennai - 600 025.
F
x
Consider a simple spring system,subjected to a Force such that F isproportional to displacement x;
F=kx.Strain energy = kx 2
Strain Energy
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oo x F W 2
1
This energy (work) is stored in thespring and is released when the forceis returned to zero
Strain Energy Density1
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y
xa
a
a
y
xa
Fx
d
d x
F W 2
1
32
2
1
2
1aeaeaU
x x x x
Where U is called the StrainEnergy , and u is the StrainEnergy Density.
x x x x eaae
V
U u
2
1/
2
1 33
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Strain energy density
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density
density Dr.K.Chinnaraju, Associate Professor, Division of Structural Engineering, Anna University, Chennai - 600 025.
• Resilience is the property of a material toabsorb energy when it is deformed
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elastically and then, upon unloading tohave this energy recovered.
• The total strain energy stored in the bodyis generally known as resilience.
• The maximum energy which can be storedin a body up-to elastic limit is called proof
resilience
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• Modulus of resilience is the energy
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that can be absorbed per unit volumewithout creating a permanentdistortion. It can be calculated byintegrating the stress-strain curvefrom zero to the elastic limit anddividing by the original volume of thespecimen
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Ex:12. A cube of mild steel issubjected to a uniform uniaxial
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jstress as shown;Determine the strain energy densityin the cube when:
x
(a) the stress is300 MPa; (b) thestrain in the x-
direction is 0.004(a)
y
x
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(a) For a linear elastic material
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0.0100.0080.0060.0040.0020.0000
100
200
300
400
500
CONTINUED
S t r e s s
( M P a )
Strain
u=1/2(300)(0.0015) N.mm/mm 3
=0.225 N.mm/mm 3
(b) Consider elastic- plastic
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Dr.K.Chinnaraju, Associate Professor, Division of Structural Engineering, Anna University, Chennai - 600 025.
0.0100.0080.0060.0040.0020.0000
100
200
300
400
500
CONTINUED
S t r e s s
( M P a )
Strain
u=1/2(350)(0.0018)
+350(0.0022)
=1.085 N.mm/mm 3
Strain Energy for axially loaded bar
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AE
L F F U
AE
FL
A
F
22
1
;;
2
axial
F= Axial Force A = Cross-Sectional Area
Perpendicular to “F” E = Modulus of elasticity,L = Original Length of Bar,
F
A
L
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UNIT – 2
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BEAMS – LOADS AND STRESSES
Beam - Definition A structural member which is long whencompared with its lateral dimensions,subjected to transverse forces soapplied as to induce bending of themember in an axial plane, is called abeam.
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In most cases, the loads areperpendicular to the axis of the beam.
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perpendicular to the axis of the beam.
Such a transverse loading causes onlybending and shear in the beam.
When the loads are not at a right angleto the beam, they also produce axialforces in the beam.
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Types of loads(a) Concentrated loads
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(b) Distributed loads(c) couples
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• Based on the degree of statical indeterminacybeams are classified as
(i) statically determinate beams
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(i) statically determinate beams
Ex: simply supported beams with or with ouroverhangs andcantilever beams
(ii) statically indeterminate beamsEx: Continuous beams,
Propped cantilever andFixed beams
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(i) statically determinate beams
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• (ii) Statically Indeterminate Beams
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SHEAR FORCE AND BENDING MOMENT
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• When a beam is loaded by forces orcouples, stresses and strains are createdthroughout the interior of the beam.
• To determine these stresses and strains, theinternal forces and internal couples that acton the cross sections of the beam must befound.
• To find the internal quantities, consider asimply supported beam as in Figure below
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• Cut the beam at a cross-section C located at adistance x from end A and consider the freebody of left or right part
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body of left or right part.
• The free body is held in equilibrium by theforces and by the stresses that act over thecut cross section.
• The resultant of the stresses must be such asto maintain the equilibrium of the free body.
• The resultant of the stresses acting on the
cross section can be reduced to a shear forceV and a bending moment M.
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Concept
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• Concept
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• The stress resultants in statically determinatebeams can be calculated from equations of
ilib i
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equilibriumDefinitions:• Shear Force: is the algebraic sum of the
vertical forces acting to the left or right of the
cut section
• Bending Moment: is the algebraic sum of
the moment of the forces to the left or to theright of the section taken about the section
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• Sign conventionThe shear V and the bending moment M at a
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given point of a beam are said to be positivewhen the internal forces and couples actingon each portion of the beam are directed asshown in Fig. a .
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• These conventions can be more easilyremembered if we note that
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• 1. The shear at any given point of a beam is positive when the external forces (loadsand reactions) acting on the beam tend toshear off the beam at that point as indicated
in Fig.b .• 2. The bending moment at any given point
of a beam is positive when the externalforces acting on the beam tend to bend thebeam at that point as indicated in Fig. c.
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• Ex: 13• Draw the shear
d b di g t
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and bending-moment
diagrams for a simplysupported beam ABof span Lsubjected
to a singleconcentrated load Pat it midpoint C
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Beam
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SFD
BMD
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• Ex: 14• Draw the shear and bending-moment diagrams
for the simply supported beam shown in Fig
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for the simply supported beam shown in Fig.
5.13 and determine the maximum value of thebending moment.
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Beam
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SFD
BMD
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• Ex.15
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Beam
SFD
BMDDr.K.Chinnaraju, Associate Professor, Division of Structural Engineering, Anna University, Chennai - 600 025.
• RELATIONS AMONG LOAD, SHEAR,AND BENDING MOMENT
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Dr K Chinnaraju Associate Professor Division of Structural Engineering Anna University Chennai - 600 025
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Ex.16 Draw the SFD and BMD for thesimply Supported beam subjected to a
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simply Supported beam subjected to a
triangular loading as shown below.
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A B
V A VB
X B
Step 1 Determination of support reactionsTo find V apply moment equilibrium condition
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To find V B, apply moment equilibrium condition
at A, i.e., ∑ M A = 0
To find V A
, ∑ V = 0
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A B
V A
XX
Step 2 Shear force diagram
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General equation for shear force at a sectionX, at a distance x from A,
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Step 3 Bending Moment Diagram
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M A = 0
MB = 0
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SFD
BMD
For M x to be max ,
Determination of Maximum bending moment
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Since is not admissible,
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Therefore,
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Step 1: Determination of support reactions
To find V B apply moment equilibrium condition
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B, pp y q
at A, i.e., ∑ M A = 0
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Step 2 Shear force diagram (SFD)
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Step 3 Bending Moment Diagram (BMD)
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Ex : 18 Draw the SFD and BMD for theSupported beam shown below
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Soln:Step 1: Determination of support reactionsTo find the reaction at B, apply moment
equilibrium condition at A, ∑ M A = 0i.e., 10- V B x5=0VB = 10/5 = 2 kN , and V A = 10/5 = 2 kN
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Step 2 Shear force diagram (SFD)(F A)L = 0, (F A)R = -2 kN
F = 2 kN
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FC = -2 kN
(F B)L = -W, (F B)R = 0Step 3 Bending Moment Diagram (BMD)
M A = 0(MC)L = -2 × 2 = -4 kNm
(MC)R = 2 × 3 = 6 kNmMB = 0
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SFD
BMD
Ex:19 Draw the SFD and BMD for the Supportedbeam shown below
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Soln:Step 1: support reactions
V A = 8/4 = 2 kN
VB = 8/4 = 2 kN
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Step 2 Shear force diagram (SFD)(F A)L = 0, (F A)R = 2 kN
(F ) = 2 kN (F ) = 0
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(F B)L = 2 kN , (F B)R = 0Step 3 Bending Moment Diagram (BMD)
(M A)L = 0
(M A)R = -8 kNmMB = 0
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Ex:20. Draw the SFD and BMD for theSupported beam shown below subjected to a
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trapezoidal loading.
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Soln:Step 1: Determination of support reactions
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p ppTo find V B, apply ∑M A = 0
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y = 3 +2x
Step 2 Shear force diagram (SFD)
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Position of Zero Shear
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( - ve value is not admissible)Therefore, x = 1.6225m
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Step 3 Bending Moment Diagram (BMD)
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For M x to be maximum,
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Soln:
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Step 1: Determination of support reactions
To find V B, apply ∑M A = 0
-18 + 34 – VB ×8 = 0
VB = 2 kN
VA = - 2 kN
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• Step 2 Shear force diagram (SFD)
(FA)L = 0, (FA)R = -2 kN
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FC = 0
FD = 0
(FB)L = -2 kN , (FB)R = 0
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Step3: Bending Moment Diagram (BMD)
M A = 0
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(MC)L = -2 × 2 = - 4 kNm(MC)R = - 2 × 2 – 18 = - 22 kNm
(MD)L = - 2 × 6 – 18 = - 30 kNm
(MD)R = 2 × 2 = 4 kNm (or)
= - 30 + 34 = 4 kNm
MB = 0
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EX:22 Draw the shear force and bendingmoment diagram for a cantilever subjectedto a point load at the free end.
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Solution:Step 1: Support Reactions:
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Step 1: Support Reactions:VA = W ; M A = WlStep 2: Shear force diagram (SFD)
(F A)L = 0, (F A)R = W(F B)L = -W, (F B)R = 0
Step 3: Bending Moment Diagram (BMD)(M A)L = 0, (M A)R = -Wl , M B = 0
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SFD
BMD
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Ex:23.Draw the shear force and bendingmoment diagram for a cantilever subjected
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to a u.d.l over the entire span
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Solution:
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Step 1: Support Reactions:
Step 2: Shear force diagram (SFD)(F A)L = 0, (F A)R = wlFB = 0
Step 3: Bending Moment Diagram (BMD)(M A)L = 0, (M A)R = - , M B = 0
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SFD
BMD
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Ex:24. Draw the shear force and bendingmoment diagram for a cantilever shownbelow
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Soln:Step 1: Support Reactions
V A = 4 ×5 + 10 = 30 kN
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V A
Step 2: Shear force diagram (SFD)
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(FA)L = 0, (FA)R = 30 kNFC =30-4X5=10 kN
(FD)L = 10kN, (F D)R = 10-10=0FB =0
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Step 3: Bending Moment Diagram (BMD)
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(M A)R = - 114 kNm
(M A)L = 0
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SFD
BMD
POINT OF CONTRAFLEXUREFrom B.M diagram it is concluded that thepoint of contra flexure occurs in the portion
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p pDC, at a distance x from D.
• From similar triangle principle
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Therefore, x= 0.6 m
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Step 1 Determination of support reactions
To find V B , ∑ M A = 0
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3 × 8 × 8/2 – VB × 8 + 6 × 10 = 0
VB = 19.5 kN
To find V A , ∑ V = 0
V A - 3 × 8 + V B – 6 = 0
V A = 10.5 kN
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Step 3 Bending Moment DiagramM A = 0,MB = -6 × 2 = -12 kNm
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and M C = 0Maximum BMOccurs in the span AB at the point of zero
shearThe shear force is zero at 10.5/3 = 3.5m from A
Mmax
= 10.5 × 3.5 – 3 × 3.5 2 / 2 = 18.375 kNm
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Beam
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SFD
BMD
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Step 1 Determination of support reactions
To find V C , ∑ MB = 0
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(- 2 × 2 × 1) +( 4 × 6 × 3) – (VC × 6) = 0
VC = 11.33 kN
To find V B , ∑ V = 0
(-2 × 2 )+ V B - (4 × 6 )+ V C = 0
VB = 16.67 kN
Dr.K.Chinnaraju, Associate Professor, Division of Structural Engineering, Anna University, Chennai - 600 025.
Step 2 shear force diagram
(F A) = 0 kN
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(F B)L = - 2 × 2 = - 4 kN
(F B)R = - 4 + 16.67 = 12.67 kN
(F C)L = -11.33 kN
(FC
)R
= 0 kN
Dr.K.Chinnaraju, Associate Professor, Division of Structural Engineering, Anna University, Chennai - 600 025.
Step 3 Bending Moment Diagram
M A = 0
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MB = - 2 x 2 x 1 = - 4 kNm
MC = - 2 × 2 × 7 + 16.67 × 6 - 4 × 6 × 3
= 0
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Maxmium Bending MomentPosition of zero shear( max BM ):X = 11.33/4 = 2.8325 m
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Bending moment at a section x from C is givenby M x = 11.33(x) – 2(x)2
Therefore M max = 11.33(2.8325) – 2(2.8325)2
= 16.05 kNmPoint of contra flexure
11.33(x) – 2(x)2 = 0, gives x = 0 , 5.665m
Dr.K.Chinnaraju, Associate Professor, Division of Structural Engineering, Anna University, Chennai - 600 025.
Ex.27 Analyse the beam shown in fig anddraw the SFD and BMD. Mark all salientvalues and also draw the axial force
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diagram.
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H A = 12 cos (30) = 10.39 kNStep 1 Determination of support reactions
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To find V B , apply
(6 × 2) + (2 × 4 × 6) + (6 × 9) – (VB
× 8) = 0
VB = 14.25 kN
V A = (6+8+6) – 14.25
= 5.75 kN
Dr.K.Chinnaraju, Associate Professor, Division of Structural Engineering, Anna University, Chennai - 600 025.
∑M A = 0
Step 2 shear force diagram
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Step 3 Bending Moment Diagram
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Point of Contra flexureLet the point of contra flexure (P) be at
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a distance x from B in the portion DB.We know the BM at any section X in
DB at a distance x from B,
Dr.K.Chinnaraju, Associate Professor, Division of Structural Engineering, Anna University, Chennai - 600 025.
At P, BM = 0
X = 0.806 m , 7.44 m (which is not admissible)
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Axial Force Diagram
Portion AC is subjected to an axialtensile force of 10.39 kN
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Dr.K.Chinnaraju, Associate Professor, Division of Structural Engineering, Anna University, Chennai - 600 025.
Ex:28. A beam of length l metre carries a udlof w kN/m over the entire length and rests
i h b h id
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on two supports with both sidesoverhanging equally. At what fraction ofthe length must the supports be placed so
that the maximum BM produced in thebeam is least possible? Draw the SFD andBMD for the beam.
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Soln:Let the supports be placed at distance
x from each edge of the beam.
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For maximum BM to be least possible,magnitude of max –ve BM must be equalto magnitude of max +ve BM.
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Maximum +ve BM will occur at the centre
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Therefore,
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Negative value will not be admissible
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BENDING STRESSES IN BEAMS
• The bending moment at a section tends tob d d fl t th b d th i t l
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bend or deflect the beam and the internalstresses resist its bending.
• The process of bending stops, when every
cross section sets up full resistance to thebending moment.• The resistance offered by the internal
stresses, to the bending, is called bending
stress, and the relevant theory is called thetheory of simple bending.
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Assumptions in Simple BendingTheory1. The material of the beam is perfectly
h (i f th ki d
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homogeneous (i.e., of the same kindthroughout) and isotropic (i.e., of equalelastic properties in all directions).2. The beam material is stressedwithin its elastic limit and thus, obeysHooke's law.3. The transverse sections, which wereplane before bending, remain planeafter bending also.
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Assumptions in Simple Bending Theory
4. The beam is made up of number oflayers placed one over the other, and
h l f th b i f t d
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each layer of the beam is free to expandor contract, independently, of the layerabove or below it.5. The value of modulus of elasticity is thesame both in tension and compression.6. The beam is in equilibrium i.e., there isno resultant pull or push in the beamsection.7. The beam is initially straight
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Theory of Simple BendingConsider an initially straight beam,under pure bending.
The beam may be assumed to bed f i fi it b f
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The beam may be assumed to becomposed of an infinite number oflongitudinal fibers. Due to the bending, fibres in the lower
part of the beam extend and those inthe upper parts are shortened.Somewhere in-between, there would bea layer or fibre that has undergone no
extension or change in length.This layer is called neutral layer.
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Theory of Simple Bending
• Consider a small length of a simply supportedb bj d b di
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beam subjected to a bending moment asShown in Fig. (a).
• Now consider two sections AB and CD, whichare normal to the axis of the beam RS.
• Due to action of the bending moment, thebeam as a whole will bend as shown in Fig.(b).
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Theory of Simple Bending
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y
Fig.5.3
f bt
f bc
C
T
• As a result of this moment, let this small lengthof beam bend into an arc of a circle with ‘O’ ascentre as shown in Fig.
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δa
f
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Moment of resistance we know, that on one side of theneutral axis there are compressivestresses and on the other there are
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stresses and on the other there aretensile stresses.These stresses form a couple, whosemoment must be equal to the externalmoment (M).The moment of this couple, whichresists the external bending moment, isknown as moment of resistance.
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C
T
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• In the case of a beam, subjected totransverse loading, the bending stress at apoint is directly proportional to its distancefrom the neutral axis
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from the neutral axis.• It is thus obvious that a larger area near the
neutral axis of a beam is uneconomical. This
idea is put into practice, by providing beamsof section, where the flanges alonewithstand almost all the bending stress.
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Ex. 29. For a given stress, compare the momentsof resistance of a beam of a square section,when placed (a) with its two sides horizontal and
(b) with its diagonal horizontal as shown in Fig
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(b) with its diagonal horizontal as shown in Fig.
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Dr.K.Chinnaraju, Associate Professor, Division of Structural Engineering, Anna University, Chennai - 600 025.
Ex:30. A rectangular beam is to be cut from acircular log of wood of diameter D. Find the ratioof dimensions for the strongest section in
bending.
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bending.
Dr.K.Chinnaraju, Associate Professor, Division of Structural Engineering, Anna University, Chennai - 600 025.
Fig.5.8
Section modulus of the rectangular section,=
2
6=
× 2 − 2
6=
2 −
6
for Z to be maximum, = 0
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for Z to be maximum, 2 − 3 2
6= 0 2 − 3 2 = 0
=3
= 0.577
2 = 2 −2
3
=2
= 0.8165DDr.K.Chinnaraju, Associate Professor, Division of Structural Engineering, Anna University, Chennai - 600 025.
Ex:31.Three beams have the same length, thesame allowable stress and the same bendingmoment. The cross-section of the beams are a
square, a rectangle with depth twice the width
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square, a rectangle with depth twice the widthand a circle as shown in Fig. Find the ratios ofweights of the circular and the rectangular
beams with respect to the square beam.
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Dr.K.Chinnaraju, Associate Professor, Division of Structural Engineering, Anna University, Chennai - 600 025.
Ex:32. Two beams are simply supported over thesame span and have the same flexural strength.Compare the weights of these two beams, if one
of them is solid and the other is hollow circular
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with internal diameter half of the externaldiameter.
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Dr.K.Chinnaraju, Associate Professor, Division of Structural Engineering, Anna University, Chennai - 600 025.
Ex:33. A rectangular beam 320 mm deep issimply supported over a span of 5 m. Whatuniformly distributed load the beam may carry, if
the bending stress is not to exceed 100 MPa.
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gTake I = 250 X 10 6 mm 4.
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Soln.Section modulus, Z = I/y = 250 X 10 6 / 160
= 1562500 mm 3.Moment of resistance, M = f max x Z
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, max
=100 x 1562500= 156.25 x 10 6 mm 4.
We know that maximum bending moment,M = wl 2 /8
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Ex:34. A beam section is of T-shape,formed by 2 planks of 120 mm and 20
mm. The beam is simply supportedover a span of 3m and subjected to a
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mm. The beam is simply supportedover a span of 3m and subjected to au,d,l of 0.4kN/m. Draw the bending
stress distribution diagram across thesection at centre.
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Soln: M = 0.45 kNm
= 0.45 x 10 6 Nmm
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The neutral axis is at a depth of 95 mm from bottom.Dr.K.Chinnaraju, Associate Professor, Division of Structural Engineering, Anna University, Chennai - 600 025.
=
We know ,
Where ,
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N A
SHEAR STRESS DISTRIBUTIONShearing stresses at a section in a loaded
beam:
Consider a small portion ABDC of length dxf b l d d i h if l di ib d l d
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of a beam loaded with uniformly distributed loadas shown in Fig.
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when a beam is loaded with a uniformlydistributed load, the shear force and bendingmoment vary at every point along the length ofthe beam.
Let, M = Bending moment at AB,
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, g ,M + dM = Bending moment at CD,F = Shear force at AB,
F + dF = Shear force at CD, and/ = second moment of area of the
section about its neutral axis.
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Now consider an elementary strip at adistance y from the neutral axis.
Let f = Intensity of bending stress across AB at
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Let, f = Intensity of bending stress across AB atdistance y from the neutral axis
f + df = Intensity of bending stress across CD
and
da = Cross-sectional area of the strip.
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We know
Therefore intensity of bending stress on theleft side of the strip
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left side of the strip,
Similarly, intensity of bending stress on theright side of the strip,
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We know that the force acting on the stripacross AB
= Stress × Area = f × da =
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Similarly, force acting on the strip across CD= (f + df) × da
... Net unbalanced force on the strip
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The total unbalanced force (F) at anylayer at a distance y 0 from the neutral axiscan be found out by integrating the aboveequation between y 0 to y 1.
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i.e., F
Where, ay = first moment of area of thesection above the layer taken about theneutral axis.
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We know that the intensity of the shearstress,
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( where b is the width of layer)
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Distribution of Shearing stress over aRectangular Section
Consider a beam of rectangular section ABCD of width „b and depth „d as shown
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„ p „in Fig.
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We know that the shear stress on a layerJK of beam, at a distance y from the neutralaxis,
where F = Shear force at the section,
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a y = first moment of the shaded areaabout NA
I = second moment of area of thewhole section about its neutral axis,
andb = Width of the section .
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We know that area of the shaded portion AJKD,
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Substituting the above values ,
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From the above equation, that shearstress increase as y decreases.
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At a point, where y = d/2, shear stress= 0
We also see that the variation of shearstress with respect to y is a parabola.
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At neutral axis i.e., at y = 0, the value ofshear stress is maximum.
Thus substituting y = 0 and I = b d 3 / 12 in the
above equation ,
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where,
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The shear stress distribution diagram isshown in Fig.
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Distribution of Shearing stress over aTriangular Section
Consider a beam of triangular cross section ABCof base „b and height „h as shown in Fig .
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b x
N A
2h/3
We know that the shear stress on alayer JK at a distance y from the neutralaxis,
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Where, F = Shear force at the section,
a y = first moment of the shaded areaabout the neutral axis and
I = second Moment of area of the
triangular section about its neutralaxis.
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We know that width of the strip JK,
. A f th h d d ti AJK
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. . Area of the shaded portion AJK,
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Centroid of the shaded area from the neutral axis,
Substituting the values of b x, a and y
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Now for maximum intensity,differentiating the shear stress andequating to zero, we get
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Now substituting the value of x in theequation of shear stress,
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The shear stress distribution diagram isshown in Fig.
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N A
2h/ 3
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We know that the shear stress on a layer JKat a distance y from the neutral axis,
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Where, F = Shear force at the section,a y = Moment of the shaded area about
the neutral axis,r = Radius of the circular section,I = second moment of area of the
circular section about the neutral axis,b = Width of the strip JK .
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We know that in a circular section,width of the strip JK ,
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and area of the strip,
. .. Moment of this area about the neutral axis
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Now moment of the whole shaded areaabout the neutral axis may be found out byintegrating above equation between thelimits y and r, i.e.,
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We know that width of the strip JK,
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Differentiating both sides of the above equation,
2b· db = 4 (- 2y) dy = - 8y· dy
y·dy = -1/4.b.db
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Substituting the value of „ydy ,
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We know that when y = y, width b = b and when y
= r, width b = 0. Therefore, the limits of integration
may be changed as “b to zero” in the above
equation.
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0
b
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Now substituting this value of ay in theoriginal formula for the shear stress, i.e.,
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Thus we again see that shear stressincreases as y decreases.
At a point, where y = r, shear stress= 0 andthe shear stress is maximum where y is
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zero( at neutral axis).
We also see that the variation of shearstress is a parabolic curve.
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To find the value of maximum shear stresssubstitute y=0 and in the above equation,we get,
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The shear stress distribution diagram isshown in Fig.
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Ex:35. A wooden beam 100 mm wide x 250mm deep and 3 m long is simplysupported at its ends. It carries a u.d.l of40 kN/m over the entire length. Determine
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the maximum shear stress and sketch thevariation of shear stress along the depth ofthe beam.
Sol: uniformly distributed load (w) = 40 kN/m
= 40 N/mm.
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We know that maximum shear force,
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and area of beam section, A = b· d = 100 x 250 = 25 000 mm 2
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... Average shear stress across the section
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and maximum shear stress,
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The diagram showing the variation ofshear along the depth of the beam isshown in Fig.
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mm
mm
MPa
Ex: 36. An I-section as shown in Fig is subjectedto a shearing force of 200 kN. Sketch theshear stress distribution across the section.
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We know that the second moment of
area of the I-section about it horizontal
centroidal axis ( x-x),
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We also know that shear stress at the
upper edge of the upper flange is zero.Dr.K.Chinnaraju, Associate Professor, Division of Structural Engineering, Anna University, Chennai - 600 025.
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The shear stress distribution diagramacross the section is shown in Fig.
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N A
Ex.37. A T-shaped cross-section of a beamshown in Fig. is subjected to a vertical shearforce of 100 kN. Calculate the shear stress atimportant points and draw shear stress
distribution diagram Moment
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Dimensions are in mmY
N A
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N A
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Y
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Shear stress distributions over some common sections
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Shear stress distributions over some common sections
UNIT 3 TORSIONSHAFTWhen you ride a bicycle, you transfer powerfrom your leg to the pedals, and through shaftand chain to the rear wheel
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and chain to the rear wheel.In a car, power is transferred from the engineto the wheel, requiring many shafts that formthe drive train.
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Shaft…
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(a) (b)
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Shaft…
“ any structural member that transmitstorque from one plane to another iscalled a shaft” A b i id t b i t i h it
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A member is said to be in torsion when itis subjected to twisting moment about itsaxis.
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TorqueTwisting moments or torques are forces actingthrough distance so as to promote rotation.
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TorsionTorsion is the twisting of a straight bar when
it is loaded by twisting moments or torques that
tend to produce rotation about the longitudinal axisof the bar.
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For instance, when we turn a screw driver to
produce torsion, our hand applies torque ‘T’
to the handle and twists the shank of the
screw driver.
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• Torsion
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Torsion
In engineering problems many members aresubjected to torsion.
Shafts transmitting power from engine to therear axle of automobile, from a motor tomachine tool and from a turbine to electric
h l f b
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motors are the common examples of membersin torsion.
A common method of transmitting power is bymeans of torque in a rotating shaft.
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Turbine exerts torque T on the shaft.
Shaft transmits the torque to the generato r.
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Generator creates an equal andopposite torque T.
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Bars subjected to Torsion
Let us now consider a straight barsupported at one end and acted upon by
two pairs of equal and opposite
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two pairs of equal and oppositeforces as shown in Fig..
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Bars subjected to Torsion
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Definition of TorsionWhen a pair of forces of equal magnitudebut opposite directions acting on body, ittends to twist the body. It is known astwisting Moment or torsional moment or
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simply as torque.
In the case of a circular shaft if the force isapplied tangentially and in the plane oftransverse cross section, the torque may
be calculated by multiplying the force withthe radius of the shaft.Dr.K.Chinnaraju, Associate Professor, Division of Structural Engineering, Anna University, Chennai - 600 025.
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SIMPLE TORSION THEORY
When a uniform circular shaft is subjected to
a torque, it can be shown that every section
of the shaft is subjected to a state of pure
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shear The moment of resistance
developed by the shear stresses being
everywhere equal to the magnitude, and
opposite in sense, to the applied torque .
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Shear System Set Up on an Element in theSurface of a Shaft Subjected to Torsion
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For the purposes of deriving a simple theory todescribe the behaviour of shafts subjected totorque it is necessary to make the followingbasic assumptions: Assumptions Made in Theory of Torsion1 The material of the shaft is homogeneous
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1. The material of the shaft is homogeneous,perfectly elastic and obeys Hooke’s law.
2. Twist is uniform along the length of theshaft
3. The shear stress induced does not exceed
the limit of proportionality.4. Strain and deformations are small.
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Assumptions Made in Theory of Torsion
5. The sections which were plane and circular
before twisting remain plane and circularafter twisting . (This is certainly not the casewith the torsion of non circular sections )
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with the torsion of non-circular sections.)
6. Cross-sections rotate as it rigid, i.e. everydiameter rotates through the same angle. i.e.,Radial lines remain radial even after applyingtorsional moment.
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• Practical tests carried out on circularshafts have shown that the theorydeveloped below on the basis of these
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passumptions shows excellent correlationwith experimental results.
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• Derivation of Torsional Equations• Consider a shaft of length L, radius R fixed at
one end and subjected to a torque T at the
other end as shown in Fig.
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Induced shear
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Strength of a solid shaft• consider the torsional resistance developed by
an elemental area ‘da ' at a distance ‘r’ from
centre (Ref. Fig.).
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(a) (b)
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Unit for Power
• If T is taken in N-m, then unit of power is in N-m/sec i.e. Watt.
• Since Watt is a small quantity in practice, it isexpressed in kilo watts (kW).
• Old practice was to express power in Horse
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Power unit. It may be noted that
• One Horse Power(HP) = 0.746kW= 746 Watts= 746 N m/sec.
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Ex. 43 Compare the weight of a solid shaftwith that of a hollow one having same lengthto transmit a given power at a given speed, ifthe material used for the shafts is the same.Take the inside diameter of the hollow shaftas 0.6 times the outer diameter.
• solnLet d be the diameter of solid shaft
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d 1 the outer diameter of hollow shaft... Inner diameter of hollow shaft = 0.6 d 1 Let P =Power to be transmittedN = r.p.m.
and T = the corresponding torque.
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• Ex. 44. Prove that a hollow shaft is strongerand stiffer than the solid shaft of the samematerial, length and weight.
• Solution• Let d be the diameter of solid shaft• d1 be the outer diameter of hollow shaft and
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d 1 be the outer diameter of hollow shaft and
d 2 inner diameter of hollow shaft.• The two shafts have equal weight and
length and are of same material.
• Hence, equating the weight of solid shaft tothat of hollow shaft, we get,
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• Ex: 45. A solid shaft transmits 350 kW at120 rpm. If the shear stress is not toexceed 70N/mm 2 , what should be the
diamete r of the shaft? If this shaft is to bereplaced by a hollow one whose internaldiameter = 0.6 times outer diameter,determine the size and the percentage
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determine the size and the percentagesaving in weight, the maximum shearingstress being the same.
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Ex. 46. What percentage of strength of a solidcircular steel shaft 100 mm diameter is lost byboring 50 mm axial hole in it? Compare the
strength and weight ratio of the two cases.• Solut ionDiameter of solid shaft
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d= 100mmDiameter of hollow shaft:outer, d 1 = 100mm
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Ex:47. A solid shaft of mild steel 200mm indiameter is to be replaced by hollow shaft ofalloy steel for which the allowable shear
stress is 22percent greater. If the power tobe transmitted is to be increased by 20percent and the speed of rotation increased
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by 6 percent. Determine the maximuminternal diameter of the hollow shaft. Theexternal diameter of the hollow shaft is to be200mm.
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solution
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COMPOUND SHAFTS
Compound shafts are shafts made up of a number of
small shafts of different cross-sections or of different
materials connected to form a composite shaft to
transmit or resist the torque applied
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transmit or resist the torque applied.
Types
Shafts in series
Shafts in parallelDr.K.Chinnaraju, Associate Professor, Division of Structural Engineering, Anna University, Chennai - 600 025.
Shafts in series:
In order to form a composite shaft sometimes
number of small shafts of different cross-sectionsor of different materials shafts are connected in
series.
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To analyze these shafts, first torque resisted by
each portion is found and then individual effects
are clubbed.
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Shafts in series:
At fixed end torque of required magnitude
develops to keep the shaft in equilibrium.
The torques developed at the ends of any
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portion are equal and opposite.
The angle of twist is the sum of the angleof twist of the shafts connected in series.
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Shafts in Parallel:The shafts are said to be in parallel when
the driving torque is applied at the junction of the
shafts and the resisting torque is at the other
ends of the shafts .
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Here, the angle of twist is same for each shaft,but the applied torque is shared between the two
shafts.
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•Ex :48.
A solid stepped shaft, ABC , is fixedat A, and is subjected to torques T B = 880N·m and T C = 275 N·m as shown in Fig..Segment AB has a length of 1.5 m anddiameter 50 mm. Segment BC has alength 1.0 m and diameter 30 mm. Thematerial is steel with a shear modulus of G
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= 77 GPa. Determine (a) the maximumshear stress in AB , (b) the maximum shearstress in BC , and (c) the total angle of twist
of shaft ABC , θ AC . Dr.K.Chinnaraju, Associate Professor, Division of Structural Engineering, Anna University, Chennai - 600 025.
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• Fig. (a) A stepped-shaft subjected to torques T Band T C . (b) FBD of entire system.
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Ex:49. A stepped shaft is subjected to torque asshown in Fig. Determine the angle of twist atthe free end. Take G = 80 kN/mm 2 . Also find themaximum shear stress in any Step.
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Fig. (b) shows the free body diagram of theportions of shaft
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Fig
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• Ex:50. A brass tube of external diameter 80mm and internal diameter 50 mm is closelyfitted to a steel rod of 50 mm diameter toform a composite shaft. If a torque of 10kNm is to be resisted by this shaft, find themaximum stresses developed in eachmaterial and the angle of twist in 2 m length.
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Take G b = 40 x 10 3 N/mm 2
Gs = 80x 10 3N/mm 2
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----- (2)
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• Ex:51. A bar of length 1000 mm and diameter 60mm is centrally bored for 400 mm, the borediameter being 30 mm as shown in Fig. (a). If thetwo ends are fixed and is subjected to a torque of
2 kNm as shown in figure, find the maximumstresses developed in the two portions.
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Fig 7.6(b)
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Fig 7.7
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Fig 7.8
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Fig 7.9
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SpringsDefinition:
A spring may be defined as an elasticmember whose primary function is todeflect or distort under the action ofapplied load; it recovers its original shapewhen the load is released.
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orSprings are energy absorbing units whosefunction is to store energy and to restore itslowly or rapidly depending on theparticular application.Dr.K.Chinnaraju, Associate Professor, Division of Structural Engineering, Anna University, Chennai - 600 025.
Springs … Springs are used in railway carriages,motor cars, scooters, motorcycles,rickshaws, governors etc. According to their uses, the springsperform the following functions:(i) b b h k i l di
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(i) To absorb shock or impact loading asin carriage springs.(ii) To store energy as in clock springs .
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Springs … (iii) To apply forces to and to controlmotions as in brakes and clutches.(iv) To measure forces as in springbalances.(v) To change the variationsh i i f b i fl ibl
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characteristic of a member as in flexiblemounting of motors.
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Types of SpringsHelical spring: They are madeof wire coiled into a helicalform, the load being appliedalong the axis of the helix.
In these type of springsthe major stress is torsionalh d i i
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shear stress due to twisting.Types: (a) Close-coiled, and
(b) Open-coiled Dr.K.Chinnaraju, Associate Professor, Division of Structural Engineering, Anna University, Chennai - 600 025.
(ii) Spiral springs: Theyare made of flat strip ofmetal wound in the formof spiral and loaded intorsion.In this the majorstresses are tensile and
i d t Fig 7 11
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compressive due tobending.
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Fig 7.11
(iii) Leaf springs:
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These type of springs are used inthe automobile suspension system
Leaf springs … They are composed of flat bars of varyinglengths clamped together so as to obtaingreater efficiency .Leaf springs may be full elliptic, semi ellipticor cantilever types,
In these type of springs the major stresses
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In these type of springs the major stresseswhich come into picture are tensile &compressive.
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Close-coiled helical spring with 'Axial load'
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when the spring isbeing subjected to anaxial load to the wire ofthe spring gets betwisted like a shaft.
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• Assumptions:(1) The Bending & shear effects may be
neglected(2) For the purpose of derivation of formula, the
helix angle is considered to be so small that itmay be neglected.
Any one coil of a such a spring will be assumedto lie in a plane which is nearly perpendicular tothe axis of the spring This requires that
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the axis of the spring. This requires thatadjoining coils be close together. With thislimitation, a section taken perpendicular to theaxis the spring rod becomes nearly vertical.
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• Hence to maintain equilibrium of asegment of the spring, only a shearingforce V = W and Torque T = WR arerequired at any cross section.
• In the analysis of springs it is customary toassume that the shearing stresses causedb th di t h f i if l
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by the direct shear force is uniformlydistributed and is negligible
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D = mean coil diameter
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D = mean coil diameterd = diameter of spring wire
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Ex:56 A close-coiled helical spring is to have
a stiffness of 900 N/m in compression, with amaximum load of 45N and a maximumshearing stress of 120 N/mm 2 . The solid
length of the spring (i.e., coils touching) is 45mm. Find:(i) The wire diameter,
(ii) The mean coil radius and
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(ii) The mean coil radius, and(iii) The number of coils.Take modulus of rigidity of material of the
spring= 0·4 x 1 0 5 N/mm 2 .
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Ex:57. For a close-coiled helical springsubjected to an axial load of 300 N having 12coils of wire diameter of 16 mm, and madewith coil diameter of 250 mm, find:
(i) Axial deflection;(ii) Strain energy stored;(iii) Maximum torsional shear stress in the
wire;( ) h hl
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wire;(iv) Maximum shear stress using Wahl'scorrection factor.Take: G = 80 GN/m 2
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• Close – coiled helical spring subjectedto axial torque T or axial couple.
When a twisting couple is applied to the spring
parallel to the axis of the spring wire it producesa bending effect on it.
Depending upon the direction of application ofthe twisting couple or turning moment the springcoils will close or open out
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g p g p gcoils will close or open out.
In both cases the radius of coils changes andbending stresses will be induced.
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• Ex:58. A closely coiled helical spring madeof wire 5 mm in diameter and having aninside diameter of 40 mm joins two shafts.The effective number of coils between theshafts is 15 and 735 Watt is transmittedthrough the spring at 1000 r.p.m. Calculatethe relative axial twist in degrees between
the ends of spring and also the intensity ofb di t i th t i l E 200
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p g ybending stress in the material. E = 200GN/m 2 .
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Ex:59. A close-coiled helical spring made of roundsteel wire 6 mm diameter having 10 completeturns is subjected to an axial couple M. The meancoil radius is 42mm. If the maximum bendingstress in spring wire is not to exceed 240 MN/m 2 ,determine:(i) The magnitude of axial couple M;
(ii) The angle through which one end of spring is
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turned relative to the other end.Take: E steel = 200 GN/m 2
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Solution. Diameter of steel wire,d = 6 mmNumber of complete turns, n = 10
Mean coil radius, R = 42 mmMaximum bending stress, ζb = 240 N/mm 2
E steel = 200 GN/m 2
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UNIT – 4
DEFLECTION OF BEAMS AND COLUMNTHEORIES
DEFLECTION OF BEAMSThe deformation of a beam is usually expressedin terms of its deflection from its originalunloaded position.
The deflection is measured from the originalneutral surface of the beam to the neutral
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neutral surface of the beam to the neutralsurface of the deformed beam.The configuration assumed by the deformedneutral surface is known as the elastic curve ofthe beam.
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Elastic curve
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Accurate values for these beam deflectionsare sought in many practical cases:
In buildings, floor beams cannot deflectexcessively to avoid the undesirablepsychological effect of flexible floors to theoccupants and to minimize or preventdistress in brittle-finish materials;
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Methods of Determining Beam Deflections
Double integration method
Macaulay s method Area –moment method (Mohr s Theorem) Conjugate beam method
Strain energy methodMethod of s per position
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Method of super position
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• The first integration y' yields the slope ofthe elastic curve and the second integrationy gives the deflection of the beam at anydistance x.
• The resulting solution must contain twoconstants of integration since EI y" = M isof second order.
• These two constants must be evaluatedfrom known conditions concerning the
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from known conditions concerning theslope deflection at certain points of the
beamDr.K.Chinnaraju, Associate Professor, Division of Structural Engineering, Anna University, Chennai - 600 025.
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2. For slope and deflection:
(i) if you measure x from left end, then clockwiseslope is positive and downward deflection ispositive(ii) if you measure x from right end, then anti-clockwise slope is positive and downward deflectionis positive
+ x
+ Y
+ x
+ Y
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+ Y
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+ Y
DOUBLE INTEGRATION METHOD
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AW
B
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AB
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Ex:63
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Ex:64 A Cantilever is subjected to u.d.l overthe entire length. Derive equations for slopeand deflection and find the slope anddeflection at free end.
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Ex :66. Cantilever with u.d.l over a length from
the free end.
(1)
(2)
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(3)
Ex:67. A Cantilever is subjected to triangularload as shown in Fig. Derive equations forslope and deflection and find the slope anddeflection at the free end.
AB
x
w
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Ex:69. A simply supported beam of length L
carries a concentrated load W at mid span.Derive equations for slope and deflection anddetermine the slope at the supports and
maximum deflection in the beam.
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Ex.70: Derive equations for slope and deflection
and determine the maximum deflection in asimply supported beam of length L carrying auniformly distributed load of intensity w applied
over its entire length.w
A B
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MACAULAY S METHOD
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• Macaulay s Method:Using the double integration method to findexpressions for the deflection of loaded
beams, it is normally necessary to have aseparate expression for the BendingMoment for each portion of the beambetween adjacent concentrated loads orreactions.Each portion will produce its own equation
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Each portion will produce its own equationwith its own constants of integration.
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• Macaulay s Method: It will be appreciated that in all but thesimplest cases the work involved will belaborious, the separate equations being linkedtogether by equating slopes and deflectionsgiven by the expressions on either side ofeach "junction point”.
However a method devised by Macaulay
enables one continuous expression forbending moment to be obtained and providedthat certain rules are followed that the
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that certain rules are followed that theconstants of integration will be the same for allsections of the beam.
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• Ex 71: A simply supported beam of length L
carries a load W at a distance ‘a’ from one end( a > b). Find the slope at the supports, slopeand deflection under the load. Also find the
position and magnitude of the maximumdeflection.
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Fig. 8.14
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Ex:72 Find the deflection at C in the beam
loaded as shown in Fig. (a)Take EI=10,000 kNm 2
4m 2m
30 kN
0.5 m
4m 2m
30 kN
A BC
A BC15 kNm
(a)
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V A VB(b)
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10 kN 12 kN
2m 3m 1m
6m
A BC D
Fig. 8.18
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10 kN 12 kN
2m 3m 1m
A B
x
x
x
C D
x-2V A=8.67 kN VB=13.33 kN
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Slope x Value EquationTable 8.1
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Deflection x Value Equation
Table 8.2
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Fig. 8.20
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10 kN/m
A B
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A BC D1 m 2 m3 m
Fig. 8.22
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Fig. 8.25
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A
A
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20 kN 10 kN30 kN/m
1 m 1 m 1 m 1 m
A B C DE
Fig. 8.26
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20 kN 10 kN
30 kN/m
30 kN/m
A B C D E
Fig. 8.27
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Maxx=0
Max
Max
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Hence the elastic curve (deflected
shape) is as shown in Fig.
10 kN30 kN/m
1 m 1 m 1 m 1 m
A B C D E
20 kN
101 1153.54mm 15.833mm
Fig. 8.21
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152.22mm
101.11mm
Fig. 8.28
MOMENT AREA METHOD(MOHR’S THEOREMS)
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The moment-area method, developed byMohr, is a powerful tool for finding thedeflections of members primarily subjected
to bending.
This method is used generally to obtain
displacement and rotation at a point on abeam.
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MOHR S
THEOREM BMD
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Consider a length of beam AB in itsundeformed and deformed state, as shownin Fig 9.1
P 1Q 1 is a very short length of the beam,measured as „ds along the curve and „dx along the x -axis.
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„d θ is the angle subtended at the centre ofthe arc „ds . M is the average bending moment over
the portion „dx between P and Q.The distance dΔ is the vertical interceptmade by the two tangents drawn through
P 1 and Q 1 on the vertical line passingthrough B.
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Mohr’s Theorem I:
The change in slope between the tangentsdrawn to the elastic curve at any two pointsis equal to the product of 1/EI multiplied by
the area of the moment diagram betweenthose two points.(OR)
The change in slope over any length of amember subjected to bending is equal to thearea of the curvature diagram over that
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Mohr s Theorem II:The deviation of any point B relative to thetangent drawn to the elastic curve at any otherpoint A, in a direction perpendicular to theoriginal position of the beam, is equal to theproduct of 1/EI multiplied by the moment of anarea about B of that part of the momentdiagram between points A and B.(OR)For an originally straight beam, subject tobending moment, the vertical intercept betweenthe tangent to the curve of one terminal and thetangent to the curve of another terminal is thefirst moment of the curvature diagram about the
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first moment of the curvature diagram about the
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SIGN CONVENTION
For bending moment:sagging bending moment is positive
For slope:
when tangents are drawn at two pointsof the elastic curve and the angle measuredfrom the tangent at left hand point to thetangent at the right hand point, if anti-clockwise, the angle is +ve and the totalarea of bending moment diagram betweentwo points will be +ve and vice versa
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two points will be +ve and vice versa
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SIGN CONVENTIONFor deviation:
The intercept by the two tangents,drawn at two points on the deflection curve,on the vertical taken at a point, if below thedeflection curve will be taken as +ve and thetotal moment of area of bending moment
diagram between the two points about thevertical will be +ve and vice versa
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A B A B
BBA A
Sign convention for slope and deviation
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Expressions for Area and horizontaldistance of C.G of some commonfamiliar BM diagrams
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A BC
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A B
B’
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Ex: 79. A simply supported beam of span 6m of
uniform section is subjected to two points of10kN each at its two-third span points asshown in Fig. Determine slope at A,B,C, D & Eand deflection at C &D.
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Ex: 80. A simply supported beam hasflexural rigidity of 2EI for the left half spanand EI for the right half span as shown inFig. Determine the slope at A,B and C anddeflection at C if the beam is subjected to a
concentrated load of W at its mid span.
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Ex.81 The middle half of the beam shown in
Fig. has a moment of inertia 1.5 times that ofthe rest of the beam. Find the mid spandeflection.
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B
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Ex:83. A cantilever subjected to apoint load W applied at a distance“a” from the fixed end. Find theslope and deflection at the freeend.
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Ex: 84. A cantilever subjected to a U.D.L overthe entire length. Find the slope and deflectionat the free end.
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Ex:86. A cantilever of span „l has flexuralrigidity of 2EI for a half span from fixed endand EI for the remaining half span as shown inFig. Determine the slope and deflection at Band C.
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A B
Fig.9.26
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Fig.9.28
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BMD
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h f f l h
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THEORY OF COLUMNS
We come across various instances ofmembers subjected to compressiveloads.These members are given different
names depending upon the particularsituation in which they are placed.
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Post is a general term applied to acompression member.Columns, pillars and stanchions arevertical members used in building frames.Strut is a compression member in a truss
(Tie is a tension member in a truss)Other examples: piston rods,connecting rods, side links inforging machines etc.,
Boom is the principal compressionmember in a crane.
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A structural member whose lateral
dimensions are small as compared to itslength and subjected to compressiveforce is known as a strut.
A strut may be horizontal, inclined orvertical. But a vertical strut, used inbuildings or frames is called column.
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CLASSIFICATION OF COLUMNS1. Short column:Short column fails by crushing (compressiveyielding) of the material.
2. Long column:Long column fails by buckling or bending.( geometric or configuration failure)
3. Intermediate column :Intermediate column fails by combinedbuckling and crushing. (failure due to both
material crushing and geometrical instability)
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material crushing and geometrical instability)Dr.K.Chinnaraju, Associate Professor, Division of Structural Engineering, Anna University, Chennai - 600 025.
• When a slendermember is subjected toan axial compressiveload, it may fail by a
condition calledbuckl ing .• Buckling is a geometric
instability in which thelateral displacement ofthe axial member cansuddenly become very
large ( Figure 10 1 )Dr K Chinnaraju Associate Professor Division of Structural Engineering Anna University Chennai 600 025
BUCKLING
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large ( Figure 10.1 ).Dr.K.Chinnaraju, Associate Professor, Division of Structural Engineering, Anna University, Chennai - 600 025.
• Buckling:
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Examples of structural members and
systems that are subjected to loads that maycause buckling are:
1. Building columns that transfer loads to theground;2. Truss members in compression;
3. Machine elements4. Submarine hulls subjected to waterpressure
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STATES OF EQUILIBRIUM( concept of elastic stability)From mechanics it is known that a
body may be in three types ofequilibriumi.e., Stable equilibrium
Neutral equilibriumUnstable equilibrium
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Mechanism of buckling• Let us consider Figures 10.4 , 10.5 , and
10. 6 and study them very carefully• In Figure 10.4 some axial load P is applied
to the column,• The column is then given a small
deflection by applying the small lateralforce F
• If the load P is sufficiently small, when theforce F is removed, the column will goback to its original straight condition
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Mechanism of Buckling• The column will go back to its original
straight condition just as the ball returns tothe bottom of the curved container.
• In Fig.10.4 of the ball and the curvedcontainer, gravity tends to restore the ballto its original position, while for the columnthe elasticity of the column itself acts as
restoring force• This action constitutes stable equilibrium
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j , , g g, y,
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j , , g g, y,
h f f l hFig. 10.5
( Neutral equlibrium)
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Dr.K.Chinnaraju, Associate Professor, Division of Structural Engineering, Anna University, Chennai - 600 025.Fig. 10.5
Mechanism of Buckling• In figure 10.5 of the ball and the flat
surface, the amount of deflection willdepend on the magnitude of the lateralforce F.
• Hence, the column can be in equilibrium inan infinite number of slightly bent positions.
• The action constitutes neutral or precarious
equilibrium
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Dr.K.Chinnaraju, Associate Professor, Division of Structural Engineering, Anna University, Chennai - 600 025.Fig. 10.6
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g. .
Mechanism of buckling• Depending on the magnitude of P, the
column either will remain in the bentposition or will completely collapse andfracture, just as the ball will roll off thecurved surface as in Figure 10.6.
• This type of behavior indicates that for axialloads greater than straight position of a
column is one of unstable equilibrium inthat a small disturbance will tend to growinto an excessive deformation.
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Buckling
Definition“ Buckling can be defined as the suddenlarge deformation of structure due to a slightincrease in an existing load under which thestructure had exhibited little, if any,deformation before the load was increased ”
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(stable)
(unstable)
(neutral)
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In this figure 10.7, the two solutions areidentified as branching paths A and B.
Path A (the trivial solution) is shown as thefundamental path.
Path B on the other than is shown as thepost-buckling path.
The point C where the fundamental path
meets the post-buckling path is shown as abifurcation point (a point where the fundamentalpath bifurcate (splits) into two or more paths).
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EULER S COLUMN THEORY Euler derived an equation, for the
buckling load of long column based onbending stress (neglecting the effect of directstress).
This may be justified with the statement,that the direct stress induced in a long columnis negligible as compared to the bending
stress.Therefore this cannot be used in shortcolumn.
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Assumptions in the Euler's Column Theory
1. Initially the column is perfectly straight andthe load applied is truly axial.2. The cross section of the column is uniformthroughout its length.3. The column material is perfectly elastic,homogeneous and isotropic and thus obeysHooke's law.4. The length of column is very large ascompared to its cross-sectional dimensions.
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5. The shortening of column, due to directcompression (being very small) is neglected.6. The failure of column occurs due tobuckling alone
7. The self weight of the column is neglected8. The ends of the column are frictionless9. The direct stress is very small comparedwith the bending stress corresponding to thebuckling conditions.
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Sign Conventions
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Fig. 10.7
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1. A moment, which tends to bend the column
with convexity towards its initial central lineas shown in Fig. 10.7(a) is taken aspositive.
2. A moment, which tends to bend the columnwith its concavity towards its initial centralline as shown in Fig. 10.7 (b) is taken as
negative.
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Types of columns
Based on the end conditions we havefour important types of columns1. Both end pinned
2. Both ends fixed3. One end fixed and the other end
pinned4. One end fixed and the other end free
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1. COLUMNS WITH BOTH ENDS HINGED
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Consider a column ABof length l hinged atboth of its ends A and B
and carrying a criticalload P . As a result ofloading, let the column
deflect into a curvedform AX 1B as shown inFig. 10.8.
PFig. 10.8 (a)
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Fundamental Mode(First harmonic)
Second harmonic(mid point bracing)
Third harmonic(Third point bracing)
P 1 P 2 P 3
Fig. 10.9
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P
Fig. 10.10
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3. COLUMNS WITH ONE END FIXED ANDTHE OTHER HINGED
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H
Fig. 10.11
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Moment at X,due tothe critical load P,
Fig. 10.12
δ
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Table 10.1. Effective Length for columns withcommon end conditions.
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S.No EndConditions
CripplingLoad(P)
1. Both endshinged
2. One end fixedand other free
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S.No End Conditions CripplingLoad(P)
3. Both ends fixed
4. One end fixed
and the otherhinged
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• Physically, the effective length is thedistance between points on the buckledcolumn where the moment goes to zero,i.e., where the column is effectively pinned.Considering the deflected shape , themoment is zero where the curvature is zero(from beam theory).
• Zero curvature corresponds to an inflectionpoint in the deflected shape (where thecurvature changes sign).
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Critical Column Stress
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Critical Column Stress
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2 Ar I
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Critical Column Stress
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Limitations for the use of Euler s formula
1. It is applicable to an ideal strut only and inpractice, there is always crookedness inthe column and the load applied may notbe exactly co-axial.
2. It takes no account of direct stress. Itmeans that it may give a buckling load forstruts, far in excess of load which they canbe withstand under direct compression.
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Y=34mm
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S.No Material
1 Mild steel 320
2 Cast iron 550
3 Wrought iron 250
4 timber 40
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Solution:
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If the effective length of the stanchion is 8.5m, calculate the safe maximum load, the
working stress being interpolated from thefollowing table
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20 40 60 80 100 120 140
123.9 120.3 113.0 100.7 84.0 67.1 53.1
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Fig
23 mm 23 mm
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UNIT – V
STRESSES IN TWO DIMENSIONSTHIN SHELLS
• In engineering field, we daily come across vessels of
cylindrical and spherical shapes containing fluids such
as pipes, tanks, boilers, compressed air receivers etc.
• Generally, the walls of such vessels are very thin as
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• In general, if the thickness of the wall of a shell is
less than 1/l0th to 1/15th (approximately 7%) of its
diameter, it is known as a thin shell.
• These vessels, when empty, are subjected toatmospheric pressure internally as well as
externally. In such a case, the resultant pressure on
the walls of the shell is zero.
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• whenever a cylindrical shell is subjected to an
internal pressure, its walls are subjected to tensilestresses.
• It will be interesting to know that if these stresses
exceed the permissible limit, the cylinder is likely
to fail in anyone of the following two ways as
shown in Fig. 11.1 (a) and (b).
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Fig.11.1
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Stresses in a Thin Cylindrical Shell
The walls of the cylindrical shell will besubjected to the following two types of tensile
stresses:1. Circumferential stress and
2. Longitudinal stress.
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In case of thin shells, the stresses are
assumed to be uniformly distributed across
the wall thickness.
However, in case of thick shells, the
stresses are no longer uniformly distributed
across the thickness and the problem
becomes complex.
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Circumferential Stress
• Consider a thin cylindrical shell subjected toan internal pressure as shown in Fig.11.2(b)
• We know that as a result of the internalpressure, the cylinder has a tendency to
split up into two troughs Fig.11.2(a)
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Fig.11.2. Failure of thin cylinder
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Fig.11.3
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Fig.11.4. Circumferential stress(a)
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Fig.11.4. Circumferential stress
(b) (c)
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Longitudinal (or Axial) stress
• Consider the same cylindrical shell,subjected to the same internal pressure as
shown in Fig.11.5
• We know that as a result of the internal
pressure, the cylinder also has a tendency
to split into two pieces as shown in the
figure.11.5(a)
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Fig.11.5. Longitudinal stress
(a)
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(b)
(c)
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Therefore the longitudinal stress is given by:
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Ex:97. A stream boiler of 800 mm diameter is made
up of 10 mm thick plates. If the boiler is subjected to
an internal pressure of 2 MPa, find the circumferential
and longitudinal stresses induced in the boiler plates.
Solution:
Given: Diameter of boiler (d) = 800 mm;
Thickness of plates (t) = 10 mm and
Internal pressure (p) = 2 MPa = 2 N/mm 2
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Ex:98 A cylindrical shell of 1 5 m diameter is made up
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Ex:98. A cylindrical shell of 1.5 m diameter is made up
of 16 mm thick plates. Find the circumferential and
longitudinal stress in the plates, if the boiler is subjectedto an internal pressure of 2.5 MPa. Take efficiency of the
joints as 80%.
Solution: Given,
Diameter of shell (d) = 1.5 m = 1500 mm;
Thickness of plates (t) = 16mm;Internal pressure (P) = 2.5 MPa
Efficiency ( )= 80% = 0.8
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E 100 A li d i l h ll f 500 di t
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Ex:100. A cylindrical shell of 500 mm diameter
is required to withstand an internal pressure of
4 MPa. Find the minimum thickness of the
shell, if maximum tensile strength in the plate
material is 300 MPa and efficiency of the joints
is 70%. Take factor of safety as 5.
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Fig.11.6.
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Solution:
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Ex:103. A cylindrical boiler is subjected to an
internal pressure, p. If the boiler has a meandiameter, d and a wall thickness, t, deriveexpressions for the hoop and longitudinalstresses in its wall. If Poisson s ratio for thematerial is 0.30, find the ratio of the hoopstrain to the longitudinal strain and compareit with the ratio of stresses.
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WIRE BOUND THIN CYLINDRICAL SHELLS
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WIRE-BOUND THIN CYLINDRICAL SHELLS
• Sometimes, we have to strengthen a cylindricalshell against bursting in longitudinal section (i.e.,
due to hoop or circumferential stress).
• This is done by winding a wire under tension,
closely round the shell as shown in Fig. 11.7.
• Its effect will be to put the cylinder wall under
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The tension in wires gives rise to externalpressure on the cylinder and hence introducescompressive hoop stress in the cylinder.
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Fig. 11.7 .
• When internal pressure is applied, hoop
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W e te a p essu e s app ed, ooptension is introduced.
• Hence, net hoop stress is algebraic sum ofthe above two types of stresses, which isobviously less than hoop tension that would
have developed if there is no wire winding. • This technique of strengthening cylinders is
usually adopted for materials which are not
very strong in tension (like cast iron) and insuch cases steel wires are used.
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Fig. 11.9 .
wo wo
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Fig. 11.10 .
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Ex:105. A cylinder made of bronze 180 mmt id di t d 15 thi k i
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outside diameter and 15 mm thick isstrengthened by a single layer of steel wire2·25 mm diameter wound over it under aconstant stress of 75 MN/m 2 . The cylinder issubjected to an internal pressure of 27 MN/m 2 with rise in temperature of the cylinder by120 °c. Assuming the cylinder to be a thin shellwith closed ends.
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Fig. 11.11Dr.K.Chinnaraju, Associate Professor, Division of Structural Engineering, Anna University, Chennai - 600 025.
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THIN SPHERICAL SHELLS• C id hi h i l h ll bj d
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• Consider a thin spherical shell subjected to
an internal pressure as shown in Fig. 11.12•
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Fig. 11.12
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Fig. 11.13
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Fig. 11.14
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CYLINDRICAL SHELL WITH HEMISPHERICALENDS
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ENDSFig. 11.15 shows a thin cylindrical shell with sphericalends.Let d = internal diameter of the cylindert1 = wall thickness of cylindrical portiont2 = wall thickness of hemispherical portion
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Fig. 11.15
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Fig. 11.16
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Fig. 11.17
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Ex:108. The dimensions of an oil storage tankwith hemispherical ends are shown in the Fig.
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The tank is filled with oil and the volume of oilincreases by 0.1% for each degree rise intemperature of 1 0C. If the coefficient of linearexpansion of the tank material is 12 x 10 -6 per0C, how much oil will be lost if thetemperature rises by 10 0C
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BIAXIAL STATE OF STRESSSo far we have considered stresses arising in
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So far we have considered stresses arising in
bars subjected to axial loading, beamssubjected to bending and shafts subjected totorsion, as well as several cases involving thinwalled pressure vessels .It is to be noted that we have considered amember, for example, to be subjected to onlyone loading at a time, such as bending.
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Biaxial state of stress … But frequently members are simultaneously
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But frequently members are simultaneously
subjected to several of the previouslymentioned loading, and it is required todetermine the state of stress under theseconditions.
The wall of a thin walled cylinder is in abiaxial state of stress (hoop stress incircumferential direction and longitudinalstress in length direction)
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The wall of a thin walled sphere is in abiaxial state of stress (hoop stress in two
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biaxial state of stress (hoop stress in two
orthogonal directions)
An element in a web of beam has normalstress and shear stress due to bending orloading.
A bar subjected to axial load and twisting,
the material has normal stress due to axialload and shear stress due to torsion.
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TRANSFORMATION OF PLANE STRESSES
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• Though the state of stress at a point in astressed body remains the same, the normaland shear stress components vary as the
orientation of plane through that pointchanges.• Under complex loading, a structural member
may experience larger stresses on inclinedplanes than on the cross section.
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Transformation of plane stresses ….• The knowledge of maximum normal and
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gshear stresses and their plane's orientationassumes significance from failure point ofview.
• The material will fail (or crack) along the
plane on which the normal stress ismaximum.• Hence, it is important to know how to
transform the stress components from oneset of coordinate axes to another set of co-ordinates axes.
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Fig.12.1Dr.K.Chinnaraju, Associate Professor, Division of Structural Engineering, Anna University, Chennai - 600 025.
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Dr.K.Chinnaraju, Associate Professor, Division of Structural Engineering, Anna University, Chennai - 600 025.Fig.12.1
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Sign convention
Orientation of the plane:
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Orientation of the plane:
Anticlockwise direction is positive if measured fromvertical plane
Normal stresses : Tensile positive
Shear stresses :Shear stress on vertical plane which tends to rotatethe element in anticlockwise direction is positive.
i.e., sign convention as shown in Fig.12.1 is positive
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60 N/mm 2
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60 N/mm 2
80 N/mm 2
R
S
30 ̊
60 ̊80 N/mm 2
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• Principal Stresses and principalplanes
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• From transformation equations, it is clearthat the normal and shear stresses varycontinuously with the orientation of planesthrough the point.
• Among those varying stresses, finding themaximum and minimum values and thecorresponding planes are important fromthe design considerations.
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12.4
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12.6
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f x f x
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Ex:110. At a point in the web of a girder the bending
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stress is 60 N/mm 2 tensile and the shearing stress at
the same point is 30 N/mm 2 . Determine
a) Principal stresses and principal planesb) Maximum shear stress and its orientations
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60 N/mm 260 N/mm 2
30 N/mm 2
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60 N/mm
30 N/mm 2
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Ex:111. At a point in a strained material the
resultant intensity of stress across a plane is
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113.14 N/mm 2 tensile inclined at 45 ̊to its normal
as shown in Fig. 12.9. The normal component of
intensity across the plane at right angles is 30N/mm 2 compressive. Find the position of principal
planes and stresses across them. Find also the
value of maximum shear at that point.
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30 N/mm 2
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45 ̊
113.14 N/mm 2
30 N/mm 2Fig.12.9Dr.K.Chinnaraju, Associate Professor, Division of Structural Engineering, Anna University, Chennai - 600 025.
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Fig.12.10Dr.K.Chinnaraju, Associate Professor, Division of Structural Engineering, Anna University, Chennai - 600 025.
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Dr.K.Chinnaraju, Associate Professor, Division of Structural Engineering, Anna University, Chennai - 600 025.
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Fig.12.11Dr.K.Chinnaraju, Associate Professor, Division of Structural Engineering, Anna University, Chennai - 600 025.
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Dr.K.Chinnaraju, Associate Professor, Division of Structural Engineering, Anna University, Chennai - 600 025.
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Maximum shear plane
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Fig.12.12
C
P (f n,q)
O
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CONSTRUCTION OF MOHR’S CIRCLE Sign conventionNormal stress:
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Tensile positiveShear stress:Shear stresses on two opposite and parallel
planes which tend to rotate the element inanticlockwise direction is positive.Orientation of planes:
Anticlockwise with respect to the reference plane(corresponding to the state of stress on thevertical plane)
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Construction of Mohr s circle…
Step 1: Select suitable (same) scale for normal
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stresses (X- axis) and shear stresses(Y- axis)
Step 2: Mark the points A and B on the graphcorresponding to the state of stress on the vertical
plane (A) and horizontal plane (B) by consideringappropriate sign convention.
Step 3: Join A and B (which is the diameter ofMohr s circle) by a straight line, which cuts thenormal stress axis (X axis) at C, which is the centreof circle.
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Construction of Mohr s circle… Step 4: With C as centre and AB as diameter draw acircle, which is the required circle representing the
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state of stress on the element.Note:
The circle cuts the normal stress axis at two points.
The coordinates of these points are the principalstresses ( maximum coordinate value is the majorprincipal stress and minimum coordinate value is theminor principal stress) and the line connecting these
points with centre of circle is the correspondingrepresentation of principal planes.
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Ex:112 An element in a strained body is asshown in Fig. 12.13(i) Find the major and minor principal stresses
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and its corresponding principal planes.(ii) Find the maximum shear stress and its
corresponding planes.
(iii) Also find the normal and tangential stresseson an inclined plane at 60 ̊ to the verticalplane.
Solve by analytical method, and compare withgraphical method.
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Fig.12.13
A
B
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Graphical method
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Fig.12.14
CO
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Ex:113 Find the strain energy stored in asimply supported beam subjected to a pointload at centre. Take EI = constant
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throughout
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Fig.12.15
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Ex:114 Find the strain energy stored in asimply supported beam subjected to a pointload at centre as shown in Fig.12.16
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Fig.12.16
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Ex:115. Find the strain energy stored ina simply supported beam as shown in
Fi 12 17 T k EI
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Fig.12.17. Take EI = constantthroughout
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w
A B
Fig.12.17
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xFig.12.18
• Ex:117. Find the strain energy stored dueto bending in a cantilever subjected to au.d.l as shown in Fig.12.19 Take EI =
t t th h t