STRENGTH OF MATERIALS [For Engineering Degree^ Diploma and A. M. I, E, Students]
By S.
RAMAMRUTHAM B.E.,
PrincipaJ,
Modern
{CMh M.l.C.B. New Delhi
Colleise of Engineering,
Auihor of Design of Reinforced Concrete Structures, Design of Steel Structuies, Theory of Structures, Applied Mechanics etc.
DHANPAT 1682, N.\I
RAI
& SONS
SARAK, DELHMiC«006
(H.O.
JULLI^OR)
Design Of Rei^niced Concrete StructnKs
Design of Steel Stmctures
Theory of Straetares Prestressed Concrete
Applied Mechanics Hydraulics. Fluid Mechanics and Fluid Machines Steel Tables
First Edition: 1962
Reprint: 1970
CONTENTS Chapter 1.
Pages
*
‘
Simple Stresses and Strains
Introduction— Definitions, stress, strain, tensile and compresstresses— Sheat stress— Plastic limit— Hooke’s law — sive poisson’s ratio— Modulus of Elasticity -Modulus of Rigidity, Bulk Modulus— Bars of varying section '—Extension of a tapering rod— Composite section -modular ratio- Bar of uniform strength- Equivalent area of composite sections— Temiterature stresses— Hoop stress— Stresses on oblique sections— State of simple shear - Relation between the Elastic constants— Volumetric Strain— Rectangular blodt subject to normal stresses— Diagonal tensile and diagonal compressive stresses— Solved problems 1 to 71 —Problems for exercise. 1
2.
Strain
- 100
Energy— Impact Leading
Strain Energy —Elastic, plastic and rigid members— Stresses due to different types of axial loading —Gradually applied loads— Suddenly applied loadj— Impact loads— Solved problems 72 to 84— Problems for exercise. 101—118 3-
Centre of Gravity and
Moment of Inertia
of Gravity— Definition— Lamina — Moment of an area— Centroid of a uniform lamina— Centroids of laminae of various shapes— Triangle, circle, semicircle, trapezium — Built-in sections— Analytical and graphical methods— Moment of Inertia of a lamina— Definition —Parallel axes theorem— Perpendicular axes theorem— Moment of Inertia of laminae of different shapes - Rectang ilar, ciicular, triangular and composite sections— Solved problems 85 to 104— Problems for Centre
continuous beams -Conception of Shear Force and Beading Moment— Sign conventions—shear force and Bending Moment diagrams for cantilevers, beams supported at ends. Beams with overhangs— Point of contrafiexure -Member subjected to couples— Members subjected to Oblique loading— Miscellaneous types of members and corresponding S.F.
and B.M. diagrams-;-Iqter-reIation between S F. and B. m! diagrams— To obtain the B.M. diagrams from S.F. diagram- Solved problems 105 to 130 -Problems for exercise.
158-227 5. Stresses in
Beaau
Definition— Pure or 8im{de bending— Theory of simple bending— Netural layer— Neutral axis— Beading Stress distribution-moment of resistance— Assomp^os in the theory of
—
(i7)
Chapter
Pages
simple binding— Practical application of bending equation modulus— Section moduli for different shapesSectioi) Rectangular, triangular, circular, I-section, T-section— Normal force on a partial area of a beam section — Moment of resistance of a partial area of a section -Fliiched beams— Equivalent section— Beams of uniform strength— Shear stress distribution on a beam section— Shear stress distribution on circular, triangular, I and T sections— Shear rectangular, stresses in bolts connecting components in laminated beams. Proportion of B VI and S F. resisted by flange and web of an [ section— Shear centre— Solved problems I3l to 199—
bmm
Problems 6.
228—337
for exercise.
Direct and Bending Stresses Stress
distribution of the section
rectangular column.
The middle
of an eccentrically loaded rule— Core or kernel of
third
—
a section -Circular section—Hollow section Structural section— Walls and pillars— Solved Problems 200 to 223 — 338—370 Problems for exercise. 7.
Masonary Dams Forces acting on a dam— Stress distribution on the base of a dam. Stability of a dam— Minimum bottom width of a dam 371—388 section. Solved Problems 224 to 228,
8.
Deflection of
beams
Member
10.
9.
bending into a circular are— slope, deflection and ladius of curvature — Derivation of formulae for slope and deflection— Cantilever— Propped cantilevers- Beams— Macaulay's Method — Beams subjected to couples— Moment area method -Mohr’s theorems— Relations between maximum bending stress and maximum deflection — Beams of varying section -Strain energy stored due to bending— Law of reciprocal deflections - Bette’s law— The first theorem of Castigliano— Impact loading on beams— Laminated SpringsConjugate beam method— Solved problems 229 to 312 Pro?-, 389—52'’ blcms for exercise.
Fixed and Continoons Beams Fixed beam -Relation between the free B.M. diagram and the fixed B.M, diagram-slope and deflection— Effect of sinking of supports— Fixed beam subjected to couple— Degree of fixing— Advantages and disadvantages of fixing beams— Continuous beam— Clapyron’s thcorm of three moments 528—581 Solved problems 313 to 324— Problems for exercise. Toraioii of Shafts
Pure Torsion— Theory of Pure Torsion —Torsional mement of resistance. Assumptions in the theory of pure Torsion— Polar modulus— H.P. transmitted by a shaft— Torsional Rigidity— Stepped shafts— Composite shafts — Keys— Couplings — Shear and Torsional resiltenoe— Shafts of non^drcular section— Close
coiled helical springs— Torsion of a tapering rod. Problems 325 to 361 —Problems for exercise. 11. Priacipal stresses
Solved
’582-632
and strains
Normal stresses— Tangential or shear streses— Principal
stresses
—Principal planes— Graphical and analytical methods— Ellipse of stress— Determination of principal stresses and strains— Obliquity— Mohr’s circle of stress— Combined bending and Torsion— Strain energy in terms of principal stresses— Equivalent bending moment and equivalent torque— Principal strains— Criterion for failure — Ellipse of strain— Solved prob633—682 lems 362 to 388. Problems for exercise. 12.
Thin Cylinders and Spheres
Thin cylinders— circumferential ond longitudinal Stresses— Riveted cylinderical boilers— Wire bound pipes. Thm spherical shells— Biaxial stresses in doubly curved walls of pressure vessels— Stresses in a conical tank. Solved probkms 342 to 683—705 349. Problems for exercise. 13.
Hiick cylinders and Spheres
Thick cylinders— Derivation of formulae— Lamme’s equations
—Hoop
413— Problems 14.
radial pressure distribution— compound spherical Shells - Solved problems 350 to 706—726 for exercise.
stresses
—Thick
cylinders
and
Colnmns and Struts
—
Introduction Axially loaded compression members— Crushing load— Buckling or critical load or crippling load— Euler’s theory of long columns— Different end conditions— Effective length of colums— Assumptions made in Euler’s theory— Limitations of Euler's formula— Empirical formulae— Rankine’s formula Straight line formula —Johnson's parabolic formula— Formula given by the I S. code— Column •abjected to eccentric loading— Euler's method— Rankinc’s method— Prof Perry’s formula— Columns with initial curvature —Laterally loaded struts— Solved problems 413 to 429. Problems for exercise. 727— 768
—
15.
Rhetcd
Jtrfats
Tjrpes of joints— Lap and butt joints— Failure of a riveted joint— Tearing strength, shearing strength, bearing strengthEfSciency of a joint— Riveted joints in structural steel work— Chain riveting and diamond riveting— Eccentric Riveted conn^ions— Resistance of a rivet against translation and rotation. Solved problems 430 to 442. Problems for -
exercise. 16.
769 —798
Wdded Couaectioiis The welding process— Advantages of welded connection — Disadvantages of welded connection —Types of weld— Minimum sizes of weld— Effective length- Minimum length— Fillet
weld applied tp the edge of a plate— Angle between fusion faces - Throat thickness -Intermittent
-
fillet
welds— Lap
joints
welds in slots or holes— End returns— Bending about fillet -Permissible stresses in single welds— Combined a 17. in welds— Eccentric welded connections. Solved stresses 799— 830 problems 443 to 462 Fillet
Analysis of Framed Stroctures Perfect frame -Deficient frame— Redundant frame— Reactions supports— Analysis of a truss -Method of joints -Method
at
of section— Graphical method. Solved problems 463 to 489.
831-914 18.
Simple Mechanical Properties of Metals Yield or flow of material— Tensile stress— Stress— Strain diagrams for Mild Steel Specimen— Limit of proportionality— Ultimate stress— Working stress— Factor of safety— Measurement of ductility -Unwin’s Method based on reduction of sectional area— Hardness— Scratch test— Indentation test— testing— Fatigue of metalsBrinnel’s method— Impact Endurance limit. Solved problems 449 to 491. 915—922
19.
Elements of reinforced Conaete General principles of design— Assumptions— Singly reinforced beams-Nctural axis-Lever arm— Moment of resistance— or critical sections— Unbalanced Balanced or economic sections— Under-reinforced and over-reinforced sections—
Doubly reinforced beams— Shear in beams- Shear stressesDiagonal tensile and diagond compressive stresses in concrete-Stirrups-Diagonal reinforcement— Bond stresses— End ancliora.e -Standard hook— Reinforcement— T and L beams- Axially Loaded Columns- Combined bending and direct stresses. Solved problems 492 to 520, Problems for
923— 998
exercises.
Appendix Index
Useful tables.
999-1035 1036—1038
1 Stresses and Strains §1.
btrodactioB
we come across may be
Materials which plastic
and
materials.
rigid
An
elastic
claailQed into elastic,
matoial
undeigoes a deformation when subjected to an external load^ such deformation disappears on the removal oftheloi$ng. plastic material undergoes a continuous deformation Ai^ng the ^riod of loading and the deformation is permanent and materitd does not regain its original dimensions on the removd' df the lAaffiag rigid material does not undergo any deformation when subjected
A
^
A
to
an external loading. In practice no material
We attribute these
is
absolutely elastic nor plastic nor rigid.
when the deformations me within certain Generally we handle a member in its elastic range. Structural limits. members are all generally designed so as to remain in the riastic properties
condition unde r the action of the working loads. §2.
Resistance to Deformation
A material when subjected to an external load system goes a deformation. Against this deformation the ateri al will offer a resistance which tends to prevent the defonnatitin. This material as long as the ntember is resistance is offered by the forced to remmn in the deformed condition.^ This resistance is offered by the material by virtue of its srrengrA. In the elastic stage, the resistance offered by the material is proportional to the deformation brought about on the materia] by the external tna/Ung The material will have the ability to offer the necessary resistance when the deformation is within a certain limit. loaded member remains in equilibrium when the resistance offered by the member against the ddbrmation and the applied load are in equifibriom. When the member is incapable of offering the necessary leristance against the external forces, the deformation wOl continue leading to the failure of the member.
m
A
§3.
Stiem
The is called
the food.
force of resistance offered by a body against the stress. The external force acting on the body
the
The load
is
in tte material of the
b^.
Tj^s of stresses. area
eppUed on the body white the Fig.
1
(a)
shows a rod of uniform tiie aids A and B.
A and subjected to axial leads F «t
is
stress is
naiw
» .
SntSNOTB OF MAtWIAlS 2
,-^„ .i«.io.yyi»niialtottc
longitaillMl
nit »f
”*'*^theiiieii>bwtalakentooiMSiit(>tl«ol)iirBC«iia by the sertioa XX. whicli it is dMded of the part C. consider the equilibrium Let us
See Fig
1
P®"
(W-
is
subjected to the
mlo
.
_ _
, , F externally
in equilibrium, the part
kli thifoS
J
C oflm a r«i8-
^t
In other words, we may against a possible „ offering the resistance stress. against the deformation is the R resistance This
SnolraUhe^Son
XX is
This part
B
Mie
say,
XX.
R
Son XJf. equal
ai>ove, *hc rwislto^ Obviously for the case mentioned offered by the section to the load. If the resistance
Mdo^ite
defonnatioD be assumed to be uniform across the^ scctioii> in^sity of the resistance per unit area of the section is called At ist&uity of stress or unit stress. In common usage the word sftoss is used to mean the intensity of stress.
iMiml tli9 difc
Intensity of stress
=p=-jR
A
P
=-
.•
A
Let doe to the application of the load the length of the dtange from / to /+/.
The
memha
ratio of the change in length to the original called strain.
is
•
a f
. 8train=e=-j-
member
length of the
=
3
SDfPU STRESSES AND STRAINS
of stresses. material is capable of offering the following ftrpes section of a offered by resistance the When (0 Tensile stress. the section is said to offw length, in increase an against is member a by the a tensile stress. For example, the stress offered intensity of the tensile The stress. tensile is a Fig. 1 in rod of the stress is given by
A
s^on XX
R The corresponding
_ ..
^
P
strain is called .
a
tensile st^in.
Increase in length
Tensile strains
If the bar >45 of Fig. 1 (ii) Compressive stress. to pushing axial loads as shown in Fig. 2, a resistance against a decrease in length. any section such as
be subjec^ set up by
is
XX
Fr..2
This resistance is called a compressive resistance. of the compressive resistance or stress is given by
The
intensity
Let due to the external loading the len^h of the member decrease by dl. The ratio of the decrease in length to the original length is called a compressive strain.
Compressive strain
Decrease in length Original length
SfRENGTH OP MATSRIALS
4
shows a rectangular block of height (no Shear stress. Fig. 3 unity. width and L / and length
Fig. 3
Let the bottom face of the block be fixed to a surface EF. Let a force P be applied tangentially along the top face of the Such a force acting tangentially along a surface is called a block.
hear
force.
For the equilibrium of the block, the surface EF will offer a tangential reaction P equal and opposite to the applied tangential force P. Let the block lx taken to consist of two parts G and Consider the equilibrium to which it is divided by a section XX. of the part G.
H
See Fig. right, the part
ttot
4.
In order the part a resistance
H will offer
G may
not
R along
the section
move from
left
XX
to
such
R=P.
ic)
(a) Fig. 4
Similarly, considering the equilibrium of the part H, that the part G will offer a resistance along the section that R^P.
R
The
resistance
R along
the section
XX is
we
find
XX such
called
a shear
rests-
tmee.
XX
Fig. 5 shows a failure at the section caused by the tangential loads acting on the top and bottom faces of the block. This type of ftflure is called a shear failure. In a shear failure, the two parts into which the block is separated, slide over each other. Hence if udi a shear failure should not occur, the section must be able to offer tangential resistances along the section opposing the force qt file t<^ face and the force P at the bottom face. For the
XX
P
equifi.
SIMPLH STRtSSHS
AND >rRAlNS
uz>
5
id
(b>
Hig. 5
brium of tbe system the shear resistance
R shtndd be equal
to the
tangential load P,
R^P. The
intensity of the shear resistance along
the section :
XX
is
called the shear stress.
Sheai stress - ^ ~
R A
Shear resistance Shear area
R _ P
Lx
l
"~L x
1
Shear deformation. Fig. 6 (a) shows a rectangular block subjected to shear forces on its top and bottom faces.
P
Fig. 6
When the block does not fail in shear, a shear deformation occurs as shown in Fig. 6 (6). If the bottom face of the block bo fixed, it can be realized that the block has deformed to the position A^BiCD. Or we can say, that the face ABCD has been distorted to the position A\B\CD through the angle BCBv=^^. Let us now imagine that the block consists of a number of horizontal layers. These horizontal layers have undergone horizontal displacements by dilferenl amounts with respect to the bottom face. can assume that the horizontal displacement of any horizontal layer is proportional to its distance from the lower face of the block.
We
be dh
Let the horizontal displacement of the upper face of the blodc Let the height of the block be /.
STRENGTH OF HATBRiAtS considered any other horizontal layer
shear strain. We could have which is at a distance x from the lower face. say the layer the layer XX. dx be the horizontal displacement of
XX
Let
dx Then shear Since ^
is
strain
very small,
^=tan^= j- = shear
Hence, the angular deformation the shear strain. §4.
^
in radian
strain.
measure represents
Elastic limit
A material is said to be elastic when it undergoes a deformation on the application of a loading such that the deformation disappears on the removal of the loading. When a member is subjected to an
When the its section svill olfer a resistance or stress. removed, obviously the stress will vanish and the deformaBut this is true when the deformation caused tion will also vanish. by the loading is within a certain limit. For every maieriaJ the property of assuming or regaining its previous shape and size is exhibited on the removal of the loading, when the intensity of stress If the loading is so is within a certain limit called the elastic limit. large that the intensity of stress exceeds the elastic limit, the member If after exceeding the loses to some extent its pioperty of elasticity. elastic limit the loading is removed, the member will not regain its original shape and a residual strain or permanent set remains. axial
loading,
loading
is
Hooke's law. It is observed that when a material is loaded such that the intensity of stress is within a certain limit, the ratio of the intensity of stress to the corresponding strain is a constant which is characteristic of that material. Intensi ty of stress
^constant.
strain
In the case of axial loading, the ratio of the intensity of tensile or cotnpressive stress to the corresponding strain is constant This ratio
is
called
denoted by
E
Young’s Modulus or Modulus of Elasticity* and
is
e In the case of shear loading also, the ratio of the shear stress to the corresponding shear strain is found to be a constant when the shear deformation is within a certain limit. This ratio is called Shear Modulus or Modulus of Rigidity and is denoted by C, or G.
N
fS.
Units
In this book SI andMKS units are adopted to express quantities of various magoitudes. The following nomenclature is
SiSdT
tlllPLK STRESSES
AND STRAMS
KILO
7
MILUIQT^
I0«
MEGA GIGA
MICRO 10-« NANA 10-*
10«
10»
TERRA
PICA
1012
I0-»*
In the SI units force is generally expressed in newtats. newton ikN) means 1000 newtons. In the
MKS units force is expressed in kg
was to express force
in
Stress intensity
is
kg
The
kilo-
(the earlier practice
wt).
expressed in various forms
newtonlmn^, newtonim*, kglcm\ kglnfi 1
J\r/meife2= 10-« iV/mm*
1
Njmm^ =10® N/metr^-
Problem
A rod of
!.
l
mega Newtonlmei^^
25 mm in ^tnketer and 200 cm an axial pull of 450(1 kg. Find {i) the
steel is
The rod is subjected to long. intensity of stress, (it) the strain,
and (Ui) ehngation. TUdce E—Tl X lOA
kglcm*. SoIutiOD.
Diameter of
Length of rod
PoU
rod=d=25 mm=2‘5 cm —1—200 cm =P=4500 kg
.
(i) Intensity
of stress
—
kx2’5*
=A— ntP
Area of the section
=/
P
^
'
.
«=4 909 cnr
4500
,
7 kglotfi
Strain
916'7 f “ .£’“21x10®“^
(Hi) Elongation
=d/=StramXorigina! length
(ii)
» 00004365 X 200 cm ‘0-0873 cm.
mm
in diameter tmd 2 metre long Problem 2. (SI) A steel rod 25 subjected to an axial pull of 45 kN. Find (/) the intensity of stress, (ii) the strain, tmd (Hi) elongation. Take E—2(X) GNfmetr^. is
Solution. Diameter of rod =25
Length of rod Puii
Area of rod
mm
**2 metn
P=45
=-J
jt)^=45000
N
(25)*-490-9 mnfl
=490-9 X10“« metr^ (i) Intensity
of jtresr=/—
P
STRENGTH
8
45000
MATERIALS
..
.
“490'9X 10r« ‘=9167 X /O® Nlmetr^~=9r67 Njmm^
MN/metr^
m>9J'67 (h) Strain
—d/^Strain X original length =0’0004583 x 2 metre
(h7) Elongation
=^0 0009166 metre •sO'9166 Probicin
metre long. the the
member tie
A wooden
3.
It is
is
tie is 7'
mm.
wide, 15 cm deep and I'SO of 4500 kg. The stretch of Find the Young's Modulus for
5 cm
subjected to an axial pull
found
to
be 0 0638 cm.
material.
Area of tie=j4*=7‘5x 15=112’5 cm^
SoIntioB.
=/>-4500 kg
Pull .'.
hg/cm~
Stress
Change Strain
in length
Original length
Young's Modulus
_ 0 0638 =00004253 ISO
= E— f e
40
“cF0W4253 ProUem
A
load of 400
kg/cm-.
kg has
to he raised at the end of a must not exceed 800 kgjcm^ what is the minimum diameter required ? If^ai will be the extension of 3' 50 metre length of wire ? Take E—2x /(/> kgfem^. steel wire.
4.
If the unit stress in the wire
SoIntioB.
Load on the wire= 1F=400 kg
=A=*y
Area required
Let the diameter of the wire be
ueP •••
^=
d cm
0-5
^
d-yj ^^0-7979 cm 7'979
mm
£xt0irjiMi=«d7’=Strainx original length
cm^
MMPU STRESSES AMO STRAINS
9
800
X3S0 an 2X10* =m0’l4 cm =ar4
mm
ProUen 5. (SI) A wooden tie is 60 mm wide, 120 mm deep and 1‘50 metres long. It is stdtjected to an axial pull of 30 kN. The stretch of the member is found to be 0‘625 mm. Find the Young's Modulus for the tie material. SoiathM.
Area ofthetie=X==60x 120= 7200 mm®=-7200xl0’* metr^
Puli=P=30
ifciV=30,000 JV
Stre88-/=
^=
_ Mrain-c=
72^^-6 =
Change
.
^
0‘625
in length
Qjiginal
10* Nlmetre^
len^ “ rsx 1000
= 4 167X 10-« Young's Modulus—
E=— e
4167X10*
-
,
,
W=«-
=10^ Nfmetr^ =10xl(F N/metre^
=10 GNJmetr^. ProUem 6 tensile
divisions in the O' 00 1
(SI).
load of 40 kN.
200
mm, find the
A 20 mm diameter
brass rod was subjected to a The extension of the rod was found to be 254
mm
extensometre.
If each division
is
modulus of brass.
electric
Stdathm. 7C
Area of the rod=y4=-^ (20)*
mm*
=3 14’ 16 mm* =314*16 xl0-« metre*
PuIl=P=40 r
Stress- /=•-
^ ^
itiV= 40,000
_
N
40,000 3j4*i6’x i0-«
^
= l•2732Xl08^/mefre* Lmgth of specimen=/=200 mm «d7= 254 XO’OOl =0*254 mm
Extension
Strain=e=
=0*00127
,
etpial
to
STKENGTIi OF tIAlEUAXS
10
r2732x
t
Modulus=E=
Young's
‘e
“
108
Njmetr^
0 00127
=^1002-5xmNlmetr^ =‘l00-25xl(fl Nlmetr^
= 100-25
GNImetre^.
Problem 7. A hollow steel column has to carry an axial load of 200,000 kg- If the external diameter of the column is 25 cm, nd the Take the ultimate stress for the steel column to be internal diameter. 4800 kglcm^ and allow a load factor of 4. Soiotion.
=D =25 cm
External diameter
-d
Internal diameter
Load on
the column
=
200,000 kg
Ultimate stress
=4800 kgjcm^
Factor of safety
=4
Safe stress =/=
Ultimate stress Factor of safety
4800
4
= 1200 kgjcrn^
Sectional area required
W
200,000
“l200~ ( 252
= V6-61
(7w2
-2)= 166-67
625-d*^212'21
d2=41279 d°‘20'30 cm.
Problem 8. (SI) meted on a mild steel
The following data
refer to
(0 Diameter of the Gauge length
steel
(vi)
V
a load of 100 ktl is
elastic limit
Maximum
(v)
ivii)
Extension at
Load at
(»v)
tensile
test
coif
-30 mm
bar
(a) (itf)
a
bar.
load
Total extension
—200 mm =0139 mm =230 kN =360 kN
=56 mm
Diameter of the rod at failure
=22' 25
mm
J^'^*^^ote ia) The Young's modsdus (b) The stress at elastic
Fig. 7 shows a bar which consists of three lengths /i, h and h with sectional areas Ai, Az and Aa and subjected to an axial load P.
Even though the intensities
of stress
For
instiUDce,
will
total force on each section is the same, the be different for the three sections.
Intensity of stress for the portion
p
lAB—fi= -j-
STRENGTH OF MATERIALS
12
and. Intensity of stress for the portion
Let
E be the Young’s
and
p ^ ^3
Modulus.
—
Strain of the part
and
CD^fs^
Strain
of the
part
BC
Strain
of the
part
CD=
Change
in length
of the part AB--=dli=eiIi
Change Change
in length
of the part
in length
of the part
BC—dh=cxh CD=dh=exh
Total change in length of the bar=rf/=/i-f tf/g+J/g.
Problem
9.
shows a bar consisting of three lengths. Find and the total extension of the bar for an Take E= 2xl(f> kgfcm\
Fig. h
the stres-ics in the three parts
axial pull of 4 tonnes. Solution. Intensity
Load P-4 tonnes =4000 Ag. of stress on the part A B
~565'8 kg/cm^.
SIMPLE STRESSES
AND
S111AINS
Intensity of stress
13
on the
part
BC-fz== 1274
Intensity of stress
on the
part
kg.fcnfi.
CD-fz>
=480
kg.lem*.
-
( 3 25)2
Total extension
dl‘=dh+dh-\-dlz
= 4'^i+=|-/2+^.fa ( fth +A&+/3iyi
2 x lO®
[565-8x18+1274x26
+480x16]
cm.
=0‘0255 cm. 10. A bras.i bar having a cross-sectimud area of 10 sq. subjected to axial forces shown in fig. 9. Find the total change in length of the bar. Take E> ’^^ J OSx Kfi kg.Icnfi.
ProUem
cm.
is
B 5,000kg.
\
C
8,oo
\*-60cm -»|*
2,0(mkg.
I
\toookg.
—mcwFig. 9.
Part AB. The section of the bar in this part jected to a tension of 5000 kg. SolirtioB.
.'.
Extension of
is
sub-
AB= ^rh AH 5000 x 60
idx 105x10®
=
cm. (Extension)
Part BC. The se^on of the bar cominession of 8000—5000^3000 kg. Contraction of
BC=~^^BC-
in this part is subjected to
a
STRENOIB OF MAIimiALS
14
3000X100
loxrosxio*
= CD.
Part
The
(extraction)
section of the bar in this part is subjected to
a
compression of 1000 kg. .'.
Contraction of
CD '
.4E 1000 xJ20
“ 10x105 xl0« = -— cm. =0’01 14 j .'.
Change
in length of the
“Js —CtOlM
cm. (contraction)
member
cm. (Decrease in length).
ABCD
nnbiem 11 (SI). A member is subjected to poin loads P\, P%, Pi, awif P4 as shown in Fig. 10. Calculate the force Pz necessary for equilibrium if Pi =‘120 kN, Pa=220 and P\^I60 kN.
kN
Determine
also
the net
chmge
h
length
of
the
member.
Take
£<=200 GN/m‘.
z IB* ,
Sototion.
Resolving the for^s
on the rod nlong
its &xiS;i
120+P8-2M+160
Pz=2^ kN Part
AB
Force on the cross-section-Pi=i 20
Extewdon
kN- 120,000 N (tensile)
ofAB=-+r -JjO.OOO X075 [1600 X I0~^[200 X 10®J .
“ +0 00028 metre— +0*28 mm
wc
+
8IMPLB snssnss Part
1
AND STRAINS
15
BC
= 120— 220 =» — 100 kN ==—100,000 N (compressive)
Force on the cross-section =Fi—P2
Contracuon of
100000 X
BC^-
Fo^l
=— O’OOOS metre*" —O'SO mm CD
Part •
»)rce
on the cross-section=P4 « 160^kN
= 160000 N Extension—
Net change
in length
(fensUe)
16OO0axl.2 X lO^'^’^^x 900 [
lO*]'”^*'^^
=-i-0’00107 metre»+l‘07 of the member
mm
=+02i-0‘i0+r&l ^+0‘55 mm
(exteniion).
P
A member ABCD
PraUeB
2, is subjected to point loads, Pi, 12. Pa and P4 as shown in figure 11. Calculate the force 2 necessary for equilibrium, if Pi— 4500 kg., Pz— 45000 kg.. Pi— 13000 kg. Determine the total elongation of the member, assuming the modulus of elasticity to be 2' lx IC^ kg.jcnr^.
P
M /!—4:
US
I
L
ftocm
±J
—
—mm. Fig. 11
Sohition.
Resolving the forces on the rod along
its axis,
have,
Pi+Ps-Pa+Ps Bat Pi=4500 .-. 4500
+
.'.
kg.,
Ps=45000
kg.
and
P4= 13000 kg.
45000=Pa+ 13000 Pj =36500 kg.
Part AB Force on the cros8>8ection=Pi
=4500 Extension of
AB=
kg. (tensile)
Pih
AiE 4500 XlM
'
6-25> 86400
E
(extatsion)
we
—
STRENGTH OP MATERIALS
16 Part
BC
Force on the cross-section =Pi—i*8
«450C- 36500
— Contraction of
BC=
—32000
32000 x 60
25 76800
Part
kg.
kg. (.compressive)
E
cm.
cm. (contraction)
CD
Force on the cross-section=P4 =73000 kg. (tensile) Extension of
CD= _
Pih
„ '44E AiE
13000 x 90
£
12-5
93600 —— ^
cm.
cm. ,(extension), .
Total change in length of the 'member
_
86400 ,76800 ,93600 103200
.
103200
21 X
10«
=0'049143 cm. (extension) subjected to a tensile
load
SotatloR.
Area required for the middle portion
Rg.
12.
^
SntPU
STRESSES
AND
STRAINS
17
Let the diameter of the middle portion be
nJ* ~4
y6
“
7
cms
d’=‘3'7I8
.
Let the length of the middle portion be Stress in the
d rms.
x
cms.
end portions 5200 ttx5“
^' _
1
4
-774
kg-lcm^ ,
kg/cmK
1
Total extension of the rod--0‘016 cm.
Extension of the
end portions-f Extension
ol
ti'.c
portion
n
•
middle
-0016 cm
V
(.70-.v)4Kt
-0016
r
(3(1
nv»|6x£ 056x2xlO«
.v;4
•
0
r
•
774 1(^0
14(Xiv^ 32000
8"77
Vy'i.x
i
.T-"
FfoWfm
a
tr, :
t
In
A
14.
rojh's
(t;)
thi
rca rj
Mock
pidh y from wluck
J C*K
t.
ff ^ is suyponded load H'and (A). In hath la.so. rU rapes have ki^ enfl. rnr and the value of E h
L'i)
b
imtimtons
iB ami
In it) 14'
'
•
Pt
tided
and
W
CB are
m
such a
nded from a
is
topes pined Wtvr tear both ropes
imioiifit
bind, for t th
*
downward morettu m application of the
'
ABC
ror\:
striuh by ibe same
•’*
'
cjadva'lv
I v
soio!' frir loon'vs
to a
-3:('00
14(KH-
*
23223- ^74
M
32000
had
*
and A the
^he stre.^srs In i
idbyand
the rope<
the block dm:
[
and find the the gradual
{London University)
Strength of materials 18 In
(a)
Solution,
this
T-]
tension in since the the rope is uniform Let the smooth. is pulley P kg tension in the rope be ol Hence for the equilibrium
arrangetnent the
h52m
T
the s>stcm,
2P-H^
W
/
4
2
-250 /.
4-56m.
45601
I
kg.
Intensity of stress
on
the rope section ’-P
nr
P A
-
250 -kgicmr-
=3
1
‘25
M'-i
TONNt'
r UNfie
(»•
kg lent*.
Fig. 13.
56M'52« 10'64 m.
Length of the ropc==4 56 4 4
The
increase in length of the rope
31-25
Let the
3 394
<10-64x100 cm.
cm
downward movemeni of 2S- 3 394 cm
the pulley be
cm.
«-77><>r,v2.
second arrange lunt the h>aJsshai 'i1 by the two should bc\nC\ th it thc\ estend by the same Let the stress ifiionsiry on the sections of the lopes 4B and
ih) In
ropes
AB
ftmount.
CB be pi
the
and
ard Pi
respccci\cl>\
Biquatmg the extensions of the two
m P‘i
h'0^_
J3
U
^
4‘5n ^
'
4
.
in
BqI tennon
^
r >pe
- jpi
in i4B4-tcnsion in
kg
CB
-*
W
i
wc
]ia\e.
^X SIMPLE STRESSES
AND
=
19
STRAINS
500
/»i+P2=—j,
4
500
3P8+;»2=— 7 3
^~
500 8
p2’^26 8 kgicnfl. Pi =
and
35‘7 kglcm^.
26 8
Downward movement of the
pulley
^Extension of the rope
AB or CB
^V662 cm. Problem 15. A steel subjected to a pull of St,
tie
rod 4 cm.
in diameter
add 2
long is
To what
length the bar should be bored centrally so that the total extension will increase by 20% under the same pull, the bore being 2 cm. diameter.
Take E^2000
tjern^.
et
at Fig. 14.
ilutioo.
*
4
«
— (4)2«47c
cm^.
«
4n
/ 'E
‘
're
X 2000
x200=
Extension after the bore
is
l_
5«
made=r2x
J'5J5
6 Lei the bar be bored to a length cl reduced section A' "=4ji
—" 4
I
metres.
Area at the
(2)®
4nr-ic=>3n
enfi.
Extension of the rod
imttrn
I
pi. i<
STRi
20
- 1) (2 lOn 2 -/
^
25n
_i_ 25si
15Jt
^
2/
,
^
3nx2U00
'“itx2d00^^
NCIH OP MATERIALS
15 “25 To 30-15/+20/-'36 "^
5/- 6
/=»r2 m.
Problem 16 A rectanr gular base plate is fixed at each of its four corners by a 20
mm.
and
nut
diameter bolt as shown in
Fig. 16.
The
I
ig.
16
between nut and plate are of 22
mm.
plate
rests
on
washers of 22 mm. inter-nal diameter and SO mm. external diameter. Upper washers which are placed internal diameter and 44 mm.
external diameter.
which the
/
If the base plate carries a load of 12 t {including self weight is equally distributed at the four corners) calculate the stress on er washers before the nuts are tightened-
What would be the stress in the upper and lower washers when the nuts are tightened so as to produce a tension of 0’5t on each bolt ?
(AMIE May SoIntioD.
Area of the lower washer
Load
(5®— 22*) cm.®
4 =
15-83 cm.®
transmitted fo one lower washer =
4 Stress intensity in the lower
1971)
washer*
3/
= 3000 kg.
kg.jcm.*
= 189'4 kg.lcm.^ When
the nuts are tightened the compressive irasner •tension the bolt =0-5/ =500 kg.
m
Area of the upper washer
Stress intensity in the lower
load in the upper
""X ^4‘^*“2'2*) cm®. = 1140 cm*. washer* 1 1
40
kg.fcrrfi.
.43’8S kg.lcm
*
—
SIMPLE STRESSES
AND STRMNS
Now the compressive
21
load on the lower washer
-^000+500- ^500 washer
Stress intensity in the lower
3500 15‘83
= 22 /
kg.Jcnfi.
Fig. 17 shows a rigid bar ABC hinged at A and ProbleoDi 17. suspended at two points B and C by two bars BD and CE made of aluminium and steel respectively^ The bar carries a load of 2000 kg. midway between B and C. The cross-sectional area of the aluminium bar BD is 3 sq. mm. and that of the steel bar CE is 2 sq. mm. Deter^ mine the load taken by the two bars BD and CE. {A.M.LE. Nov., 1965) Modulus of Elasticity for aluminium Eai^7000 kg Modulus of Elasticity for steel Ef^^ 20^000 kglmm.^
Solution.
STEEL
A
rod
rigid
will
not bend. It will remain straight. But the aluminium and steel rods will extend due to their elasticity.
HOD
Fig. 17 shows the position of the rigid bar after the aluminium and steel rods have undergone their extensions. Fig, 17.
Let the tensions in the aluminium and\steel rods be
S
kg. respectively. Since the rigid bar remains straight, the extensions are proportional to their distances from A.
BD
Let the extension of Extension of
3D
be
33% = 8
C£ = CCi =
— xS=25 2
—
But extension of £Z?== 8 = 7 A ah a
and extension of
.
/
R of
kg.
and
CE and
STRENGTH OF MATERIALS
22
Now
consider the equilibrium of the rigid bar.
on the
laking moments of the forces A, we have,
rigid bar,
about the end
/?x1+5x2 =2000x1-5 J?+25 =3000 But
...if)
U 5+25=3000 ‘^„'
s - 3,(100
^^
3000
x80.
^ j^ 26 kg.
(tensile)
181
80 §7.
X 1326=348 kg.
(tensile)
Extension of a tapering rod
l ilt, i:/
Fig. 19
shows a bar uniformly tapering from a diameter di
one end to a diameter d?
at the
at
other end.
Let the member be subjected to an axial tensile load P.
dx of the bar at a distance x
Let *
•
) d'^di—kx. Cross-sectional area at distance
^
5=s >1'
—
--^Wt-Arx)®
4 Intensity of stress
x from the
^
on the section ‘P
=P
.
AP x(di-A:x)®
larger
end
SIMPLE STRESSES
AND
23
STRAINS
P
Strain
'
E
AP
=
ntHdi — kxi~
Extension of the elemental length
d'c
^edx 4P ~~KE(di-kx,^
dx
Total extension of the bar /
=8.
_4P
f
dx
^E
1
{
0 /
4P
J
k=-
But
fcjf I rfi— d\
4P nEk I di-kl di - d2
r/if
r
8-.
-
’
\
r:E{di--d‘i)\di~ d^-hdz
(1 ~
=_
nFXdx—dzyx. dz
jvf’frfi
—
U
dif
‘
'l
di)
2)
K£rf,t/3
For the particular case when the dx
and for
r«>d is
of unifonn diameter,
=d2 ~d
this case
s
4P/
^~\EtP tapers xmiformly rom 30 mrn. to ] 5 mm. If tin odhe subjected to
ProMem
18.
A rod of 30
centimeter'^.
£
kg-Ictrfi.
Solution.
The
extension of the rod S=.
•nEdxdi
is
given by,
w
STRENGTH OP MATERIALS
24 /’=--600 kg.
fn our case,
/^-30 an. {li --
r/2
mm. -3 cm,
30
— 15 mm
^1*5 cm.
E^ixnf kg.lcm^.
and
4x600x30
.
75x2x108x3x1*5 :=.0'()02547
Problem
from error inwheil
Modulus
tension
19.
If a
cm.
diam
I*!
ushv*
’tcr
the
to
cm
test bar is found to taper uniformly {D{-a) cm. diameter prove that the
mean diameter
to
the
Young's
{A.M.LE. May, 1965}
percent.
is
calculate
j
tad^di^iDA- a) ^di — (D—a)
Diameter at the larger
Solution.
Diameicr
ai the smaller
end
Let the length of the bar be
/
Let the Young’s Modulus be Let the extension of the
E
member be
S
JFl /:
API
-
^d\d%^
But
di - D~\~a and
d%—D-’a
API If the
mean
Youngs Modulus.
dian
Dbvi.msly
be adopted let E' be the computed E is erroneous.
4/V Ttn^r
4Pl tzD'H vji
J
error in
the
Modulus, when the mean diameter
coraputatioD is
E-E' (^ £
of the
Youngs
adopted
}
JPL
API
nZ)‘iS
API
X 1 00 percen
SIMPLE STRESSES
25
AND STRAINS
°
^
xlOO
percent
— ^X 100 percent 2
10 a v-
(
percent.
D
)
Problem 20. A bar of steel /v of lenf'th I and is of uniform The width of the bar laries uniformly from u at one end thickness Find the extenshm of the rod when it carries an to b at the other end. axial pull
jP.
.Solution.
Fig. 20
shows the tapering rod.
Consider any section
X— X distant
Width of the
= a—
section
a*
from the bigger end.
b
-
y-^A*
where
Thickness at the
section ^
k
t
Area of the section = f (a ~ Ax) o
Stress
/.
^
on the
•
F
~
Extension of an elcmenlaJ length dx
t
(a
-kx)
E
^
^
—
STRENGTH OF MATERIAU
26
dx tE
a—kx
J 0,
(a-kx) ]
_a
P
a-Kl
iLk
a-b
A-
But
1
I
PI
R ®
a
,
b'
£/ (a-fc)
Probiem 21. A siraif^iii bar of itecl rectangular in section is SOO cms. long and is of uiiijonn thickness I 5 cm. The width of the rod varies uniformly from cms. at one end to 4 cms. at the other. If the rod is subjecleJ to an axial tensile load of 3000 kg.,JinJthe extension of the rod Take Ta --2x I O’’ kg-jcm'^. Solation.
pi Extension of the rod
,
^ ^
Lt \a—o)
In our case
log,
0
kg. /
= 5(H)
1-15 a
~
I
ms.
cms.
10 cms.
6=4 cms and
£=
i0« Aif./cm*
2
X
3000X100 X rs (10-4)
!!)«
,
10
4
^^H)x300x0'9163 2 x io*irr‘5x6
—0‘045815 cm.
AND STRAINS
tSIMPLB STRESSES §8.
27
Bars of Composite Sections
Suppose the cross-section of a member consists of different
memW will be shared by
the various
on
load applied
the
materials,
components
P
the the
of section. For instance suppose a column consists of an outer tube of area Ai and Young’s Modulus El and an inner tube of area A2
and Young’s Modulus
£2
Let
.
the length of the column be /. Suppose a load P be applied on the column. Let the unit stresses on the outer and inner tube sections be />] and p 2 .
Load on outer tube-f-Ioad on the inner tube
~ Total
load on the column
P\<\+P%42—P
...(i)
Fig.
Let dl be the decrease
in length
2l
of the column.
Strain of each tube
But
From computed.
equations
(i)
From Eqn.
£i__
Pz
E\
Ez
and
(it)
pi=
{ii\
...(«)
the stresses pi
Et p^*.
-
•£2
Problem 22. A internal diameter and
i
compound tube conusn of a steel tube IS cms. cm. thickness and an outer brass tube 17 cm.
and / cm. thickness. The two tubes are of the The compound tube carries an axial load of WO tonnes. .stre.sses and the load carried by each tube and the amount it Length of each tube is 15 cms. Take E$=2xl(P ks tern * ^‘
internal diameter
same
length.
Find the shortens.
and E.== lx
m
SoIntioB
kg/cm^.
Area of steel tubc=/l.= -—(17*— 15*) cm.*
= 50-27 ^
The ratio
^
is callc
outer and inner tubes.
i
cm
*
the modular rauo between the materials of thj
STRENGTH OF MATERIALS
28
Area of brass tubc™>4i»— ~(I9‘^— 17^) cm,^
= :6 55c/w2 Let the stresses in steel and brass be p»
and ph kg.jcm.^ respec-
lively.
Strain in brass
Strain in steel
Eb
Es
Pb
ps-~^2pi>
jL.h
Load on stecl+Ioad on copper = Total load p,A,+pt>Ab—P
i-e.,
2pi-x50 27+p(,x56-55= l00,00() kg. 1
57 09 p(,= 100,000
_ 100 000*^'^^'”“
„
,
,
,
157 09
pi,
=636' 5 kg-lcm.^ 2
.
.
X 636
5 = 1273
kg /cm.^
Load on the brass tube=Pi,=pi,4i,=636 5x56-55
=35990 Load on
kg.
the steel tube
127.,
= 64010 Decrease in length of the
x 50 27
kg.
compound tube
=Decrease
in length
-Decrease
in length
of either of the tubes of brass tube
I
E.
-
«36 5
bt section.
=^0-009548 cm.
xT6«
1
7^
cm.XJO cm.
The cohmn carries a load of 18 tonnes and the steel bars Take E ~>i t tm ?^ ^
stresses in concrete f^S-Irm.^ and Ec^014xl(fi
kg./cm.*
SohtioB.
Area of i4.
steel
bars
= 8x3 l42=25 siy 25 14
136
c/w.2
cm2
Actual area of concrete
"'^‘="3‘’*-25 14=874-86 cm* and steel be p. and p,
, i-ct the stresses in concrete
respectively.
SIMn£ STRBSSES AND STKAINS Strain in concrete— Strain in steel
PL. "E.
E,
P.-E,- P»
21 pt~\Spt Load on
steel
s=Tot8l load i.e., I
.„(/)
+ load on concrete on the column.
F4R,
ptAt-^ptAc—P Spc X 25- 14+p. X 874-86 =P== 18000
22
kg.
1251-96^,-18000 ^' =
18000
,
,
,
l25r96*^/^-
— 14' 37 kg.tcm.^ p$ — l5x 14' 37 kg.fcmJ^
/.
=215 55 kg Icm^ ProUein 24. A load of 30 kg. is applied on a short concrete column 25 cm. 25 cm. The column is reinforced by steel bars of total area 56 cm.^ If the modulus of elasticity for steel is 15 times that of concrete find the stresses in concrete
and steel.
If the stress in concrete should not exceed 40 kg.fcm.^^ find the area of steel required so that the column may support a load of
60ft00 kg.
When
SolotioD.
the column carries
a load of 30M0 kg.
=*^#=56 cm.* 25*— 56= 569 cm.* Area of concrete Let the stresses in steel and concrete be p» and pe Area of steel
respectively.
= Strain in concrete
Strain in steel JL-
P-L
En. E
ps^e/p^ pt=l5pt load on steel+load on concrete
=Load on piAi‘\~pcA.=P 15 p»
X 56-\-p* X 569
column.
...(0
STRENGTH OF MATERIALS
30 ^-TO.OOO kg.
30,000 30,000
1409
pc=2r29 p,= When
the
\5
,
,
,
kg-lcm.^
^21 29= 3I9’35 kg-lcm.^
column carries a load of 60,000 kg.
Let the area of steel bars be An cm.^
Area of concretc=^r=(625-^.) cm.^ Strain in concrete
Strain in steel
f’-P''E. Ec
•
Pf=p-pc p.-^-l5pr.
But
Pf
.
^ 40
kg. Jem ®
P..--I5X
Load on
steel 4- load
40-600
kg.lcm.^
on concrete
=Load on column peAc
~P
600 /l,+40 (625-.4.S)
= 60,000 560 /!.- 35000
35000
.
2
Problem 25. A compound tube is made by shrinking a thin steel tube on a thin brass tube. A$ and Ab are the sectional areas of the steel and brass tubes, and £% and Eh are the corresponding values of Young^s Modulus. Show that for any tensile load the extension of the compound is equal to that of a single tube of the same length and total cross^
tube
sectional area^ but having a Youfigs
Modulus of As'^-Ab
Solution.
Area of
Let the load on the compound tube be
steel
P
tube
Aica of brass tube Let the stresses in
^Ab
steel
JP*
Es
and brass be
=r.
^Eb
ErP'>
and pb respectively,
AND STR MNS
SIMPLE STRESSES
Load on
steel
31
+ load on brass = Total load on the compound
tube
psAs-{-pbAit=P
i.e.,
E»
pbA»+pbAi>’=‘F
Eb
]=/> rEiiA$'\~Ei^Eo
,
"]
'•'‘[fiAfBx)’ Extension of the
compound tube =df ==ExteRSion of steel or brass tuoc tb
dh
P-
4\E,A,+EbAb
\i }
E be
Young’s Modulus of a tube of area the same load and undergoing the same extension. Let
" *-( {Aa+At,)E jP/
carrying
)
PI
(E^Ab^ Eo Ah)
(Aa-\-Ab)E
F<^A.^EuAh
Problem 26. A tube of aluminium 4 cm, external diameter and 2 cm, internal diameter is snugly JiUtd on to a solid steel rad of 1 cm, diameter. The composite bar is loaded in compression by an axial load P. find the stress in aluminium when the load is such that the stress in steel is 700 kg.lcm.'^ What is the xalue ofP ? £*> «»2 x /O® kg.fcm\
(AMLE. May
Ea^7xl(fi kg./cm.^
42^22
“
SolutioB.
( i4s~“(2)‘^=^7c cni.^
4 j 1 Modular
ratio
=i?i
£• = -zr= 20
3jc
cm
2
1969)
SIRENGTH OF MATERIALS
-
fa
X 700
P
Total load
lA
245 kg.jcm,^
kg
i
-245 x3Ji-f700X7t« 1435 n -4/OeS
kg.
Air.
Vrohhm 27/ A rompouiui bar consists of a central steel strip placed between two strips of brass 25 cm wide and 0 64 cm. each 2 5 cm wide and 1 cm thick. The strips are firmly fixed together 2’ 5 cm. wide and to form a compound bar td rectangular section {2t+0 64) cm thick. Determine <) the thickness of the brass strips which will mUke the apparent meduhis of elasticity of compound bar ] 570 tonnes I ctn^ and (h) the ^'laKimnm axial pull the bar can then in either the brass carry if (he stress is not to exet d 1*^7 tonnejem Take the valuer •*/ E for steel and brass as 2070 tonnes! or (he steel ^m.^ and t4(f tonnes fem^ ( London Uni vers ity) '
on the com-
Let the load
Solution.
pound bar he P
•
tonnes.
Let the stresses in bra^s and
pb and pt tonnesjan
^
sem
BRA^S
be
steel
?
respectively.
Strain in steel
2
o^cm
L
strain in biass
iim
SttAtfS
x_
p» .
Eb
Id
Hut load on
steel
"DTO
P’
Eb'
114)
P'
1-816
load on brass = Total load
]
Pf^An+pbAh1*816 p//(2*5x *64)
Fig. 23
E.
p' \r
P x2rx2’5
P-
-
P
tonnes.
pdim+5t)
tonnes.
Area of the composite section
-
.4
2*5x0*64 f
2*5
x2r cm.^
r60 r5/) cm.^ Apparent Young’s Modulus i
E" Strain
1
570 tonnesjem!^
^
AE />d2*9054-5/)
(L6U+5t)1570 This must be equal to the strain of brass or
steel
-
SiliPLE STRESSES
AND
/>fc^2'90S4~S
•
••
33
STRAINS
0
ll-60+5<)l 570
pi
“1140
2*905+51 1*60+51
1570 1140
1*377
2*905+ 5/-2*203+6*»8M 1*8851=0*702
=
1
0 702
cm
0*j72
1*885
Since ps= 1*816 pb and since tbe stress in eitbcr biMS or steel should not exceed 1*570 tomelcml^
pt—VSlQ tomefcm.^
Let
/>6=-|rg^j “0*865 laww/cm.* .*.
Load on
the
bar=P=^.^.+p6^>
= 1 *57 X 2 5 X 0 64+0*865 x 2*5 x 2 X0*372 umne$
=2*512+ 1*608 ='^*/2
tmmes.
PfoUen 28. Two vertical wires are suspended at a ^stance of 50 an. apart as shown in Fig. 24. Their upper ends are firmly secured and their lower ends support a rigid horizontal bar which carries a load fV. The left hand wire has a diametir of l'6 mm. and is made of copper and the right hand wire has a diameter of 0 9 mm. and is made of steel. Both wires initially are 4 5 m. long (a)
Wf both
Determine the position of the wires extend by the
line
of action of
W
if due
to
same amount
(h/) Determine the slope of the rigid bar if a load of 20 kg. is hung at the centre of the bar. Neglect the weight of the bar.
Take £i=*2*l XIO* kg./cm.^ and £«= Sidntioa.
x
1*3
|0* kg.jem.* {A.M.I.E. Nov., 1968)
^•=0*00636 cm.^
^*=0*02010
c/n*.
=1*615
fi^mft
^
f '*
i4«+fnil«
mW
.
Ar^mA, I-6I5X('*0063« 0*0201
+
1
*615
*||
X00063
J
1
STRENGTH OF MATERIALS 34
W
r*=^0-338
Taking moments about copper
WxSO^lVx
0-331
^>0
x—16'900 cm.
Oae(b) When 20 Load
i
is al
kg. load
COPPFR U6nim
mid spin
0!A.
each wire=10 kg.
I
10x450 *‘“00201 xr^ix
10*
10X450 00636x2x10*
'0
ca
>0"1722 cm.
0‘3b3^ cm.
J
Let * be the inclination of the rigid
^
,
OtA
W
30
Fig. 24
=0 003632
® JO*®
e=(r
n\ Two
Problem 29.
rods one of steel and the other of and are 50 cm apart. .md length of each rod are ^ cm and 4 metres respectively. Diameter A cross fixed to the rods at the lower ends carries a load of 500 kg such tlMt the cross bar remains horizontal even after loading. ^ Find the stress in each rod and the position the copper are
e^h
vertical
rigidly fixed at the top
of
Take
E,=2xi0«
kg.jcm.^
and E,
load on the bar. x /OO ^^,^2
-
(A.M.I.E. Winter 1978) Solution.
Area of steel rod t'
-d*-^-(2)*=7t
Modular
=
jc
cm"^
OtA
\copm te
400
cm
ratio
Et
2 cm
Ksrm
Area of copper rod =* /4 1
2 cm OtA
c/m2
1
X 10*
^
is the cross bar
remainVhoSntal ?h!
^onsofthe
steel
tods are equal
Sinr^Tk
hnvethe same
orSS
strami of these rods*are
1500 kg ks ^ the
e^Sd
— a:—} Fiib.
*
25
— soms SrRflSBS AND sntAINS
35
Strain in steel^Strain in copper
et—e»
f±^A Em
Ee
f,==mfe,hM
Let
7*«
/•= 2 /. and Te be the tensions *
in the steel
Ti^fgAt^TlftAi^Tfe T»=^fcA»=ft
m^2 and copper rods.
ft
ie
T*=‘2T*
r.+r4-50OA* 2r.+r,-5oo kg.
But
r.=
500
, _ j kg. and
Let the SOO kg load be at a distance
^ r.=
1000
x from
Considering the equilibrium of the mcnnents about the right end,
Ay-
the copper rod.
cross bar,
and taking
500*=r.x50 500 X.
1000 " 3
X50
x=33'33 an. 30. Two vertical rods are each the upper end at a distance of
Problem fastened at
63 arts, apart. Each rod is 300 cms. long and 12 nun. in diameter. A horizontal rigid cross bar cormects the lower ends of the rods and on it is placed a load of 450 kg. so that the cross bar renuuns horizonttd. Find the position of the load on the cross bar and die stresses in each rod. One rod is of steel for which snei E=r96 X 104 kg.jcm.* and the other of bronze ejuf for which E-^0‘63x 104 kg.fcm.* SehrtiM.
BRO/Of
Area of eadi bar
=1131 cm.* Let the stresses in sted and bronze be pt aadpv kg-fan.* respecdvdy.
1
Since the rigid bar remains horizontal, the catensions of tiw steel and bronze bars are equal.
Ps 450i^
FIs.
26
SnCBNGTH
OTMAmii^
36 Strain in steel
» Strain in brass.
p± Et
Et Et Ih
Ei
1% 0 63 ph.
Load on
f load on br«izc-fot|ll load
steel
i4.=.4»=l'311
But 3'111
/>» X
1*311 +ifex
cm*
1*311—450
4*650p»=450
=9^-80 kg./trrt*. jp,=3*lll x96*8— 30/*l kf./on.* Cdnader the equilibrium of the rimd rodt see Fig. 26. load be api^ed at x ems. from the steel bar. Taking moments about the .*.
left
Let
tiie
aid we have
Ax60*=450xjc 96*8 X 1*131 x60=450:s 96*»x 1*131X60 ctns.
X’‘t4'6
.*•
cm.
Hence the load must be If 14' 6 cats, from the steel bar.
on the
a
diatahee
bar 50 cm. long and 7 cm. Omiaer 7 5 cms. inside diameter and The ahminium cylinder is (7015 cm. axial load of 60,000 kg. is mpHedt^e cover plates as shotm in Fig. 27.
Load OB steel+Ioad on alumimam =totaI load on the poflopoate ptAf\-p»A.^P (>-0015) 44000 x 38*4H-14000»X 3^36=6000011: i
SIMNCTH OP IMIBUAU 16938+48I 04*=60+25-4 2174048-85-4
/.
85-4
«
*- 21^045=0 03928 an. /».=(S-0015) 44000 kg.Icm.*
-(0 03928-0 015) 44000 kg./an.*
~ 1068-32 kg.lem.^ 14000 5
and
= 14000 X 0 03928 kgjcn^. =549 92 kg.fcnt,^ §9.
EquWaleot Area of a Compomid Sectioa
compound Suppose a column consists of a concrete oolumn reinforced with steel
•
•
bars.
Let the gross area of the
oolumn be
^
>4.
Let the area of
steel
^ ^ ^O^RALL / AR£Ag^A
ai ARfACf
be
Si sna^A^
A$.
Actual area of con-
mte-^AcMA—As).
^
^ '
Let the stresses in conCrete and steel be pc and p,
~ '
p.
it^)ectively.
Strain in
Concrete— Strain
^
in Steel
P*^mpc
...(#)
where
E, ‘s
called the
modular ratio between
OQilcrete.
Load on
steel -{-load
on concrete =load on column
P*At-\-pcAt^P
pd.A»~i~mAt)
=P
P.^
iL-_
steel
and
SIMPLE STRESSES
AND
STRAINS
A,"‘(A—A$)
But
_
P A — At-f-mAt
P ^‘’°A+{m-l)A. Suppose in place of the composite section, a plain concrete column of area A-\-{m— l)A, had been provided, the stress in concrete
P A-\-(m—ljAt
Hence for determining the stress in concrete, we may consider that the given reinforced concrete column is equivalent to a plain concrete column whose sectional area
=At^A-{-(m — This area >(<=/4-H(m—l)
is
lyA*
called
the equivalent concrete
area.
Stress in
concrete= „ Equivalent concrete area
Stress in steel
The above
.
,
= modular ratio x stress in concrete
principle, for instance,
can be applied to problem
23, page 28.
column=30
In the problem, Size of the
Modular .•.
ratio
=m=
p-
=15
XSc
Equivalent concrete area
=i4»=i4+(m — 1) At
=30*+(15-l)x25T4
cm.®
=1251-96 cm.® Stress in concrete
_ ~P‘'^
_
Load on the column Equivalent concrete area
1800CL
"l25r96
Stress in
kg.lcm.^
—14‘37 kg.fcm.* steel=p»=mp« — 15 x 14*37 kg.jcm.^ =s215'55 kg.jcm.^
Problem 32. A steel strip of cross-section 40.'' mm. X 10 mm. is two copper strips one on either side, each of cross-sectUm 40 mm. X 7 5 mm. to transfer the load. There are two bolts on the line of the pull. Show that neglecting frictim and the deformation of the bolted to
STKBNGTH OF MATERIAU
bolts
of 3
the ratio a pull applied to the pint will be shared by the bolts in
Assume
to 4.
E for steel is twice
of copper.
that
Solntioa.
members
Figure 30 shows the details of connection of the in the problem.
mentioned
P
kg., i.e., the load Let the load applied on the connection be the load transLet plate. the steel of end of P kg. is applied at the the load ferred to the bolt AbtPi kg. Hence between the two bolts to transferred will be load This kg. will be (P-Pi) plate in the steel
the bolt B.
The load Pi transferred to the bolt A two copper plates between the two bolts. between the (wo bolts. Load on the
plates
^Pi
^
in copper.
/
1
(1
^
Vi yim
ySTE(i
•
A
\
i
>J
\
jJ
.
L
J
—
IOtbw ,
IJ
the plates
/Ctms
n
mmm ^
tratisferred to the
kg.
* Strain
Strain in steel
n
be
Now consider
— (P— Pi) kg.
steel plate
Load on the copper
will
Fig. 30
P-Pi_ A$E» ArEr
Pi
.
Pi AkEc At
Ec
“ A, 2x40x75
P-Pi’‘A.E. Pi
P-Pi“ 40X10 -h.
P-Pi“ But load on the andJhe load on
bolt
E, \_ •
2
24
A =Pi P«*P— Pi
the bolt
Ratio of the loads shared by the bolts
A and B=3 -.4. Two copper rods and a steel rod, together support a rigid uniform beam weighing P kg as shown in Fig. SL The stKsm ProUem
respectively.
supported.
33.
Find the magnitude of the load Young s Modulus for steel is twice
P
that
Area of copper component
-/4.=2f4x 41 -32 cm*.
that
can be safelv ^ ^
of cooner.
ample SntBSSES A^D STRAINS
41
Area of steel component
=/!»= 5 X S'* 25 cm*. Length of copper component=f«= 15 an. Length of steel component =1*== 25 an. Decrease in length of coppcr=Decreaae in lengdi
of
steel
=8
6=gc/«=e»/» •
^5
“25 =
If.
Ce
Stress Stress in
in
0-6
steel
copper=p«=ec£ii
£l.==IL po
€e
=0-6x2=r2 Et
p$’^Vlpe :. when p, reaches 600 kg.jcm^. p, wiU reach r2X600720 kg /an*, whidi is less than its permissible value. P^peAfi-ptAt =(600 X 32)+(720 x 25) ’-‘37200 kg.
kg.
SnUBNGTH or materials:
42
FroUen 34. support a load the rods.
Two copper rods and one
of 25000 kg. as shown
rod together Find the stresses Us
steel
in Fig. 32.
Take Et^2xl(fi kg./cm.^ and Ec=1^10^ kg.fcm.* Sdotim. Each rod will be compressed by the same amount. Let the decrease in length of each rod be * cm. Let the strain in copper and
.
steel
be
and
respectively.
le
.
7~
€$
»
e.Let the stresses in
Y
€e
.
e.
and copper be p, and pc respectively. pt=e,Ec ind p,—eeEc steel
^‘==— Pc
-
•
Ec
Cc
P»
p,-j p» Load on steel+Load on copper=Total load applied i.e.,
p»/4«'4"Pe^«=7*
*'**-^^
4
y p«X 16+p< X(2x 10)— 2SOOO kg. 64
-yPc+20 p«-2SpOO kg.
SOiPU STKBSSES AND STRAINS 124
-3- /».==25000 kg.
25000 x3"
kg.lcm.*
”124 *
/.
pt=‘604’84kglcm.* p.
= j X 604 M=S06 45 kg.lcm.*
PraUm 35. Two
and one steel rod together losses ^^PPff • f and 1200 kg-lcm-
copper rods
su^rt a
load as shown in steel are not to exceed 600
Fig. 33. kg.lcnt.*
If the
P Kg
ROD’-s.
smi fiO0]
COPPER ROD
<«c»x4
5C1flX3C1ll
I
3CIIIX3CW 12
cm I
kW/gr
/////777?y a’cR
%}////m//77P Fig. 33.
load that cat be supported.
Young's Modulus for steel
is
twice that
of capper.
be compressed to the. same extent. Let the decrease in length of eiach rod be * cm. e# respectivdy. Let the strain in steel and copper be e» and 3— Cl. beetle
Each rod
will
•
L
et
12
= 0-6
20 e» in steel and copper be p» and p# pB^enE* and pt^eeEo /»
Let the stresses
•
pt
et
respectively.
^-=0*6x2=r2 £•
p,^\1p,. Suppose
steel is
permitted to reach
kg.lcm.* the oonrespoiKhng stress in
its
safe stress
of 120^
cof^ wiBhr^^ 'WO®
STRBNOIH OP MjllBtlALS
44
kg.lcm.^ which exceeds, the safe stress of 600 kg-lan.* for copper. Therefore let copper be allowed to reach its safe stress of 600 kg/cm.*
Corresponding Total
T2— 720 kg.fcnt^^
wdl be 600 x
stress in steel
load—'P==load on
steel
t-load
on copper
~p$At-i-peAc
,
=720 X 16 + 600 x 2 x 9 ^22320 kg.
kg.
Three vertical rods equal in length and each 12 and together diameter are equispaced in a vertical support a load of 1000 kg. the rods being so adjusted as to share the load equally. If now an additional load of 1000 kg. be added determine the stress in each rod- The middle rod is of copper and the 2 X 10^ kg.jcm.* Take outer rods are of steel. Et= 1 X 10^
Problem 36.
mm.
pl^
in
a^
kg-lcm
*
SolntioB.
(/)
Stresses due to the initial load
Area of each bar the load
Initially
4
of 1,000 kg.
cm.^ = T 13 cm.*
xV2^
on each bar 1000,
The
each bar
initial stress in
1000
po— 294 '9 (a)
kg./cm.*
Stresses due to additional load stresses in
...
,
copper and
of 1000 kg.
steel
additional load of 1000 kg.
= Strain in
Strain in copper
Et
steel
steel.
Eg
E*
Load on
^
Ee
^
Pc—2pc
+ load on copper = Total load.
P$ /4»+pe Ac'=P
2;p.(2xi-I3)+p.xil3
+ 000 %. 5-65 p.
=
1000 kg.
p. = ^kg.lcm.* ft
and
be pe and
—
m
kg./cm.*
p.-2x 177= 354
/>»
due to the
SmPIB STEBS8ES AMD Fiaal
45
STRAINS
stms
294*9+ 177— 47/ P kgjcnfl.
in copper
=sp<»+ps=:294'9+354=^^5'P kgjcnfi*
Final stress in steel
A steel rod 18 mm.
in diameter passes centrally through a steel tu^ 25 mm. in internal diameter and 30 mm. in’ extenusd diameter. The tube is 75 cm. long and is closed by rigid wadiers of negligible thickness which are fastened by nuts threaded on the rod. The nuts are tightened until the compressive load on the tube is 2 tonnes. Calculate the stresses in the tube and the rod.
Pioble^ 37.
find the increase
in these str^s$es
me quarter of a turn relative to cm. Take
when one nut
the other.
is
tightened
by
There are 4 threads per
E^2000 tonnesjcm^. When the nuts
arc tightened the tube will be compressed and the rod will be elongated. Since HP external forces have been applied, the compressive load on the tnbe must be equal to the tensile load on the rod. SointipB.
f—
U
0 m
scM
^
r™ Fig. 34
(32-2-5*)-
Area of the tube
4
=Ar=~
Area of the rod
81
x(l-8)*--,«\ K
crn^.
Let the stresses in the rod and tube be p. and pt tonnesicm.*' reflectively.
Tensile load
on the rod— compressive load on the tube prAt ^pi-A *
At
UK
100
275
^“'324^ (0 Vnten
the eompressive load an the tdbe is
2
tonnes.
2
.'..Stfess.m flie
tobe—p*^ ^l^romes/em*.
—
toimeslcn/^
—lt926 totmeslen^ {eomprasMlTtey
STRBNGTH 275 Stress in the
rod=/?r^
^0'7S6 (ii)
When one nut
is
XO 926
W MATIUAU
twinesjcm^
tonneslcm^, (tensile)
tightened by one quarter of a turn.
Lct/t and/r be the stresses due ty tightening of the nut quarter of a turn.
Obviously ft
is
a compressive stress and ft
is tensile,
by one
and
324^' Reduction
in the length oi the
.
E
tube
/
_/,x75 2000
cm.
Extension of the rod
-•I' .Ax 75
^
cm.
275
/fX75
‘324
2000
68-66/.
cm.
2000
But contraction of tAc tube'\-extension of the rod’^axial advanca fif the nut.
75/
,
63-66/
“* ,
2ot)0
2000
(
~ ) = 0 0625 cm.
75/+63-66/,=.125 138-66/ = 125
fi==0'90 tlcm^, (compressive)
275 f'‘°
^
324
0 9 = 0-754 tjem^. {temiU) *
•netal
bar of diameter
D and
and E the Yomg s Modulus of the materud efthebm. (A.M.I.E. May, 1975)
SBIPLB CniESSeS
rod
AND STKAINS
47
Consider any sectton SohitiOB. distant x from the lower end.
XX
Weight of the rod below the sectioa
of the
XX
where 41— sectional area of the rod. Stress at the section
XX^f^
«»YJf
Consider an elenMntal loigth dx of the rod from XX.
Extennon of the elemental length of rod ’=‘~dx
FIS.3S
STRENGTH OF UATEUAIA
48
Suppose the area of the upper and lower ends be Ai aad Aa respectivdy.
end. end.
Let the area of the section be /I at a distance x from the lower Let the area be 4 at a distance x+dx from die lower
Let the weight per unit volume of the
Ginsider the equilibrium of the strip
upwards— Total
Total force acting
Let
member be w
EFGH force
acting
downwards
p be the uniform stress intensity.
p{A-\-dA)—pA+wA dx p dA~wA dx j —dA = w dx A p Integrating, we get .
.
—
log.
where
Cl ^constant of integration
At
jr=0, log*
• •
Aa~ Cl
—-x+iog. A%
log.
log.
'
Ai
w X p wx
wx A=Aaf p
...(/>
w/
^1=^2/
Obviously
Eq-
(i)
may
2'3k^o
..Hi)
also be written as
At
p
X
Vthe w tfthe bw IM ^n£ii
the tie is to
€*liRtltwe^8tms.leHL^
...mo metres hng.
uJdof ^
^
material
aMPLE
STRESSES
AND STRAINS Area of the
Solatioa.
Intensity
of
49 at the bottom
tie
=/»=
stress
Wt. per unit volume =M’ = Tfce area at
=A2—5 cnfi.
— =14000 —^000 10
,
lUUJ
kg.jcrr^.
kg-lcm^.
any distance x from the bottom end
2'31ogio
is
given by
^
j Ai
p
Let the area at the upper end be A\
23Iogr„-^ =
J/ 8 X 180 0
^
1000x14000 9 8'/50
logic
-4^ =rooi A2
Ai^V00lx5^5W5 cm\ shows a Problem 40. Fig, rigid square platform of negligible
P
weight and of side I supported by four identical elastic pillars each of height h If a load P be applied at
a point
distant a and h from the adjacent sides and find the pressure on each pillar and the depression of the centre of the plat-
AB
AD
form, Soiotion.
Let the pressures
on the legs AA\^ BBi, CCi, DDi be Pa, Pb, P and Pd respectively. For the equilibrium of the platform.
Pa+PK+P.+Pd
=P
Taking moments about AB, we have, Pel-^-Pal^^^Pa
P.+P4 =
Pa I
m
STRENGTH OF MATERIALS
50
Taking moments about AD, we have i>»/+/»c/*=Ph ...(/«)
Let
Sa>
adO
CCi and DDi.' These pressures
on the
be the depressions of the pillars AAj, BBi, depressions are proportional to the respective
pillars.
Where AT is constant
8a— AlPa.
SaoiF,
h=KPi, dc=--KPe
h=KPi — Average of depressions of A O
Depression of
and
C
—Average of depressions of B and
D
KiPa+Po) "
__8.+8.
-
2
2
“
“
2
K(P^+P4 2
P.+Pt^Po+Pi Rewriting the above equations.
P.+P.+/>.+Pi-P
...(0
Pc+Pd=^
...(iV)
Pi+Pc=~
...(f/f)
P«+Po=P»4-P
From
equations
(/)
and
Pa'f'Po
Subtracting eq.
(if)
(jv),
we
get
— Pt-f-Pd — -^
from
>1 «
eq.
(ff/),
1
we
get
..(v)
SaiFU SntESSES and strains
SI
Substituting the value of Pd in equation (v/)
<»-«)}
P-=
1-2 (b-a)[
Substituting the value of Pa in equation
P‘=
(//)
-4y|l-2
P«=-j^|2 (a+b)— Substituting the value of P» in equation (>y)
J*.-P.+Pd-P.= -|—
2(a+b)~/|
/-2(a+b)| Thus the pressures on the
pillars are.
P.= -J|3f-2
(u+b)|
P*= £-{/+2 (*-<»)}
P.=-^|2 (o+*)-/)|
Let the Young's modnius of the material of pillan be Depression of the centre O of the platform
=8=J
where
A
is
pillar.
P«+P«=“-^
ProHea 41. in
(Depression of the pillar AAi^ depression of the pillar CCi)
the sectional area of each
But
shown
E
Fig. 39.
BD
CD
and support a tkaiPas AD, If the three ropes are of the same sectioned ana.
Three ropes
STRENGTH
52 (Ike
middk rope be
and the other ropes beat
vertical
JM the load carried by each
(Of
UATERIAIS
6 with the vertical^
rope.
Fig.J9
Let the length of /) be /i rope be ^ Let the tension in the middle and Let the tension in each of the ropes have, we vertically at Resoh-ing the forces Sotatioa.
CD
k. be
n y
D
/t+2ec6s6-i*
y=l(PInraease in length of
AD
Increase in length of
BD
R) sec 8
..(0
But
we
Differentiating,
get,
2/i/i-2/. dt dll
h
~dl
-cos
h AE _=cos8 R AE‘ I
cos* 6
-j^cos 0
Q^R cos* But
e
- J?)
Rcos*
2R
6=
P-R 2
.(fl)
sece
sec®
cos* 0=(j»-/()
J? (1+2 cos*
6)-?
1+2 cos*
I
..(i)
SIMFU SIKBSSES AND STKAOV
53
^„_Pcos*0 r+2cos*'8 Problem 42*. A rigid horizontal beam of kngth 21 is earied by three wires each of length I hut of sectional areas Ait A%, As as shown be placed at a distance ,Klfrom the Uft endt in Fig. 41. If a load find the tensions in the three wires neglecting the weight of the beam.
W
Solotioa. in the wire
Let the tension
lit
AA' he P,
and tension
r*
wire
in
the
in
the wire
1
^:/j/////////////M////////////,//,C
CCheQ and tension SB' he R.
<+«
I
@
5^
0
R
P
For the equilibrium, we
^
g
have
/>4-e+«=»' left
-(o
—
Taking moments about the end of the beam, we have
’I"*
n
RI+Q2I^Wia
R+2Q^WK
Fig 41.
P^JV-Q-R ==lV-i(fVK—R)~R
^W-lfVK~ V (2-a:)-
...m Since the
beam
Extension of
will
always remain straight
BB'
=mean
Let the extensions of AA’,
Viiii/or siiideuls
may
of the extensions of A A' and CCf.
CC and BB' be Sx, Sg and 9^
leave this numerical.
STKEMOTH
54 C»
«8=
Since
AzE “
—
“f" Sj
-
we have
lAiE
2
MATOtlAtS
CH>
^
Q-
l ‘
AiE
--^1 At Substituting for
P and R
4
A3
_
.
AAi
1
4Ag
a. '
2Ai
Ai
y<2
2-£ -LI -_E| 4
Aa _
I
R A2
Ai
[
2-K Ax
_
R being known the tensions equations (ii) and (//7).
] )
^
W
Aa
rC.-U. ^ ^ 4^2
4,4i
1 J
._WK~R
K>izA
f
WK-R
+
2>Ji
Aa
[_L ^ -J_
1
Q, we have, W(2 K)-R f
F and Q can
4
K Aa
be determined from
Problem 43. A uniform rope of length I units hangs verticallyFind the extension of the first a units of length of the rope from the top due to the weight of the rope itself Find also the total extension of the rope. Solalion. Consider an elemental length dx of the rope at a distance x from the botto n of tne rope.
Let the weight per unit volume of the rope be
p.
Let the cross- secti,)jal area of the rope be A*• Force on tae cross-section of the elemental
— P Ax .
.
Stress
on the section of the elemental part
Extension of the elemental part
/ •*.
Total extension
~S —
£
1^“*^
0
part
— SMPLB
SrRGSSBS
AXD STRAINS
55
PP 2E Exteosiou of the top a units of length
“Total extension— extension of the bottona (/— fl) units of length.
=
pp
p (/-fl)*
2E
2E
2El
P-il-df
P
§ 11.
2 /a— o*
" 2E
^
II
aUll
] ^
—d)
Temperature Stresses
When the temperature of a material changes there will be corresponding change in the dimension. When a member is free ta expand or contract due to rise or fall of temperature, no stresses will be induced in the member. But, if the natural change in length due to rise or fall of temperature be prevented, stresses will be offered.
AB
Suppose a rod of length / be fixed at the rads A and £. Let the temperature rise by T. If the member was free to expand, the free expansion of the member would be
^ 1
BB'=»Tl where a is the coefficient of linear expansion. If the member is allowed to freely expand no stresses will be induced. But if the member is prevented from expanding, compressive stresses will be induced.
(h>
f — s.
(t)
N,
=5 =:) B
a'
IZ±f 1
This can be realized as follows. Let the rod B be of length t Let its ends A and B be fixed. Suppose there is a rise of temperature. The rod tends to expand
+
by
B
B is
B'
—
IJ,
(W)
Fig.
44
«77.
Suppose the fixture at the end removed so that the rod freely expands by aJI so that BB'^^a-Tl. Let now an external load be applied at B so that the rod is decreased in its length from (/-|-«77) to /.
Let a be the sectional area of the rod.
Compressive 8tress=p^
P a
SIRENGTH OF MATERIALS
56
Strain
z+ar/ Stress ,
/
’E (Young’s modulus)
Strain
Hence when the rod
is
prevented from
expanding temperature
^olTE.
stress
The
thrust
on the rod section
~P~pa ~~(xT£a In generah the temperature strain
_
Expansio n or contracti on prevented original length
Suppose a rod of length L when subjected ro a rise of temperature is permitted to expand only by 5, the temperature strain
^^JExpansion preverUed Original length
1
Temperature
stress
^F^Ee E(oTl-l) /
Problem 44. A rod is 2 metres long at pansion of the rod when the temperature is raised
Find the exto
pansion is prevented, find the stress in the material. Take kg./cm.^ and « = 0-0000/2 per °C (AM/E, Solution.
Rise in temperature^ T= 80— 10
Free expansion
=a
If this ex-
80*C.
E=-IxJO^
May
1974)
= 70°C.
T/
.=0-000012 x 70 X 2x100 cm. —O' 168 cm. Temperature stress
=a r£ =0 000012 X 70 X 1 X 10« =840
ture
of
ture me
is IS
2^^ rtdsed to raised
is
6rc.
kg./cm.^
kg. I cm. ^
Fmd the
20 metres long at a tempera^hen the tempera-
temperature stress produced (/)
when
E5
SIMPLE STRESSES
AND STRAINS
57
the expansion of the rod is prevented (ii) when the rod is permitted expand by 5'S mm. Take ol^12x 10~^ per *C and £= 200 GNjm.^
to
Solttilon.
Free expansioo of the rod~a77
-12X10 --^-JO'8
When
1
(65-- 20)20
0108 metre
=^-0
(')
«
mm.
the expansion is fully prevented
emperature
stress
—ar£
- 12 X 10-^’ X (65- 20) X 200 X 10»
Njmi
~ 1 08 X ] 0*' Njmetre^ ^108 MNImetre^ When
(a)
the
rod
is
permitted to expand by
In this case, expansion prevented /.
5' 8
mm.
= 10’8 — 5*8 — 5 mm.
^Expansion prevented
Strain
Original length 5
1
20xldb0“~4000 Temperature stress ^^Strmnx 1
4000
X 200 X 10»
'-=^50X10^ N/mctre-
—50
MN metre^ !
Problem 46. (S.I.). A 15 mm. diameter steel rod passes centrally Through a copper tube 50 mm. external diameter and 40 mm. internal diameter. The tube is closed at each end by rigid plates of negligible thickness. The nuts are tightened lightly home on the projecting parts of the rod. If the temperature of the assembly is raised by 6(fC. Calculate the stresses developed in copper
Take
and
steel.
Eb^ 210 GNImetre^ £c-^I05 ONImetre^ a, = 72 X 70-6 per 'C a, - 1 7' X 70~^ per ;
;
;
‘C.
Solution.
Area of the
steel
rod
=
/4.s
—
(1 5)^
mm.^
—56*25 n mm.^ Area of the copper tubc«v4c— ~*(502— 40^) mm.^
—225 w mml^ Free expansioo of steel jFree
—v-bTI
expansion of copper— «cT/
STRENGTH OP MATERIALS
58
Let the actual expausion of each component be 8
aLcTl>S>asTI steel is in tension
and copper
is
in compression.
and copper.
Let /• and fc be the stresses in steel
For the equilibrium of the system Tension in stccl= Compression in Copper. f,A,-=fcA<
/-4/. Actual expansions of steel
Actual expansion of copper
-
«.r+A =a.r- jEr £,s
But/«-4/r and substituting for 12
X 10“® XbO+r—
ats,
= i7s X
720 X 103
we
Es and Ec,
get
y fio
^ ,
ac,
j^,3_
/•
3/ 105
=330 X 103 jLy /
— U 'S^x
rneirc^
Njmetre^ 55 MNjmetr^
Z=4/.==4 X ends
pa^^t^ueh
exter^TdiLetTr^
Fit
rt TJ
1
\
i(fi
SS=46 2 MNImetr^.
A
screwed at the
SO mm.
internal
and
of the whole assembly is raised 126°C and the iuitt nn screwed lightly home on the «»* of the tube Fnd common temperamre Iw falleFtol6^''a^ to
Coefficient Coefficient
of expansion for
steel = 1 2x KT* per'C of expansion for gun metal ’=20 x 10~* per *C
SlfMPLB STAfiSSBS
AND
59
SIRAINS =2'1
Modulus of Elasticity for steel Modtdus of Elasticity for gun metal Solatioii.
Area of
steel
x 70* kg-lcm^.
=0'94 X Kfi kg.Icnfi. IE., May 1966} (A
M
tube
32-2-5® Jem®.
Area of the gun metal
rod=^i/=—
= 1*21
x2*2® cm^.
n cm^.
Let the length of the rod and tube between the nuts be
/
cms.
two members had been free to contract, 77 of the gun metal rod— =«• Tl contraction of the steel tube
If the
free contraction free
Since a,/ is greater than ol* the free contration of the gun metal rod is greater than the free contraction of the ^teel tube. But, since 1-
^ZZZZZZZZZZZZZZZZZZl
6UN metal 90D
Fig.
45
the ends of the rod have been provided with nuts the two members are not free to contract fully, each of the members will contract by Let S cm, be the final contraction of each rod. the same amount. The free contraction of the gun metal rod is greater than 5, while the Hence the steel tute free contraction of the steel tube is less than S. will be subjected to compressive stress while the gun metal rod will and pt, be the stresses in steel be subjected to tensile stress. Let and gun metal.
For the equilibrium of the whole system. Total compressive force in steel
—Total tension .*•
in
gun metal.
psAn'=p(iAn
r21n P"
'16 />««=1*76 pg
STRENGTH OF kUTHMAU
60 Final contraction of steel
= Final
contraction of
gun metal
J,TI+
a,T+
P.t
Ei
T^m - 16 =V/ 0’C 'Jv
12 X U?
2’i
:
1
X lie
Pa 0-94 Xl0«
20x I0-«XI10
lUM-
X i0« X
I-
10-
i
’r+ok)
'•(
2
Pf^46?'7 kg.icfn^ {tensile) i 76 A 462*7 kgjcnfips
**.
‘-8I4‘J kg.lcm-. (compressive)
Problem 48 A steel bar placed between two copper bars each having the same area and length as the steel bar at A5®C. At this stage they are rigidly connected together at both the ends. When the temperature iv raised to 315' C, the length of the bars increases by 0*15 cm. Determine the original length and the final stresses in the bars.
Take
£1
-**
2* I
---0
x
/O® kg. /cm?
000012 per
Er-=^ I
:
a.--
;
X
I(fi
kgfemi^
;
0 0000175 per
{AM IE, Summer
COPPER COPPCA.
h
mi
t
•0‘1S
cm Fig.
46
Solatioii.
Let the sectional area of the
steel
Sectional area of the copper
component be A cm.®
component=2y4 cm.*
Free expansion of steel component =a< 77 Free expansion of copper component=«cr/ Let 8 be the
at^l
expansion «.ri
each bar.
<8
1978)
SIMPLE SrRBSSES Steel
AND STRAINS is
6t
and copper
in tension
Let /« and fc be the stresses in
is
in
compression.
and copper
steel
respectively.
For the equilibrium of the system Tension in
compression
steel
in copper.
fA^f(2A) Actual expansion of
steel
— Actual
a,r/+-^ /-a.2Y-4
expansion of copper.
/
^
a,7’+-4-=- a'7’-
£
r-ais-is-soo'c 0 000012 x 300
12x300+^1 1-9524
---
f X
10 ®
1650 tS'^5* 1 1
f—2 X 845
kgjcm.^ (compressive) ] 1
= 1690 22
kg.jcm,'^ (tensile)'
consider say the steel bar.
Actual expansion of the
steel
=
bar
15
^+2-f x*^j 06 1
/•
x 300-
17-5x300-/,
/ft
Now
-0-0000175
2n"xio«
690*22
12X300
150000
3600 H- 804*87 /- 150000 4404*87 /- 150000
1—24 05
/.
cm.
Problem 49. A 12 mm- diameter steel rod passes centrally through a copper tube 48 mm. external and 36 mm. internal diameter and 2 50 metres long. The tube is closed at each end by 24 mm. thick The nuts are tightened until steel plates which are secured by nuts. The whole ossemthe copper tube is reduced in length by O' 508 mm. bly is then raised in temperature by 60*C. Calculate the stress in after the rise of temperature^ assuming copper and steel before diat the thickness of the plates remains unchanged.
md
Take
kg.jcmf,
u.^I2y.lO-^rC
and
Ec^E05x l(fi kg-jcmK n.^I7
5xl0^rc
STRENGTH OF MATERIALS
62 Solution.
Area of the
steel
rod=.4.“ ^r2)*cw2.==0-36«cm2.
Area of the copper tube -3’62)
Caseii). Stresses the tightening When the nuts nuts. are tightened the steel rod will be subjected
Me
cm.*=2’52n
arfi.
*
to
K
Fig. 47 the and me tensile stress ana to tcnsiic pper tube will be subjected to compressive stress.
the stresses in copper and
Let pe and p$ be
steel.
Total compression in coppcr=Total tension in steel.
pC^O^^psAs
2 52n 0 36k
Ar ps-
Ai
Pi^lpe c* Strain
„
copper = er
in
change
=
.
f-
in -length -
original length
OOSOg e«==
250 Stress in
copper=pc=ec Ec 0*0508 "
Xl05xl0«*g./rm.2
250
=213' 4 kgjcm,^ (compressive) Stress in steel
=pc=7/;a = 7x213*4
- 1493 Case
(a).
If the
S kg.lcm:^
Stresses due to rise
two members had been
Free expansion of steel
==
of temperature.
free to
expand.
uTL
Free expansion of copper^ x/r/n Since ac is greater than the free expansion of copper is grratcr than the frw expansion of steel. But since the ends of the rod are provided with washers and nuts the members are not free to expand fully Final expansion of each of the members
will be the Let this final expansion be 5. The free expansion of copper IS greater than 8 while the free expansion of steel is less thanl. Hencethestee rod will be subjected to a tensile stress while the cop^r tube will be subjected to a compressive stress. Let f, and f. be the stresses in steel and copper. For the equilibrium of Ac whole "uuw system,
same.
SIMPLE STRESSES
AND
STRAINS
63
Total tension in steel=Total compression in copper
ftAt—feAe r
f
•
17-^'
Final expansion of steel
=Final expansion of copper a,Tl.+
^.
U^olcTL- §-/. iLc
£0$
T=(ffC,
But
/.=250+4-8 = 254-8 cnw. /«— 250 cms.
and
12xl0-«X60 x 254-8+^-^.J‘^^^Jg*
=
17
5>cl0-«x60 x 250-
/cx250 105x~10«
= 72‘64 kg.lcm? (compressive) f, = 7 xn-64 kg./cm.^ fc.
Final stresses
perature
f,=S08’4S kg Im.^ (tensile) due to tightening the nuts and
rise
of tem-
:
Stress in copper
•^pc+fc=2l3'4+72'64=286'04 kg./cm,*
Stress in steel
=p.+/s = 1493’8+508'41 ’=2002' 28
(compressive)
kg.jcm.' (tensile)
Problem. 50. A steel rod 20 mm. diameter and 6 metre long is connected to two grips one at each end at a temperature of 120‘C. Find the pull exerted when the temperature falls to 40*C (/) if the ends x l(fi kg.lcm.^ do not yield (it) if the ends yield by 0 I J cm. Take
E=2
md«.^l2>tlO-^
Case
Length of the rod=/=600 cms
temperaturc=7’= 120— 40=«80°C
(/)
When
the ends do
mt yield.
Temperature stress=*7!E -
Pull in the rod
l2xl0-«x80x2xl0«A:g./cm.2
= 1920 kg.lcm.^ = Stress x area
(tensile)
= 1920x~x2*fcg ^6033
kg.
STRENGTH OF MATERIALS
64
When
Case (ay
the ends yield
by O il cm.
Contraction prevented
Temperature
=
strain
Origin^TkiigVh aTt — ^
80x600— OTl
12X10
600
0'^ 600 Temperature stress =Strain x Young’s Modulus
^ 0'466 60^
_ / n 0* kg.lcm.^ X 2 X 1,nA,
-1553 kx-lcm.^ Pull in the rod
—Sttess •'area
= 1553 X Problem
A
X 2®
kg.
= 4878
kg.
cm. external diameter and 3
mm.
thick encloses centrally a solid copper bar of 3 cm, diameter. bar and the tube are rigidly connei (ed together at the ends at a
The
51.
steel tube
temmetal when heated ta
Find the stress in each perature of 30"C. Also find the increase in length if the original length of the I80*C, assembly is 30 cm Coefficients of expansion for steel and copper and 1 7xp)'^ rc\pectively per degree centigrade^ are J OSxIO
E^2' I XlO^ kg^janr for
sit'd
and
I' 1
x iO^ kg.jcm'^ for copper.
Solution.
Area of
steel
tube
Area of copper bar -Jr-
(4
^
^
52— 3 ’9^)-= 3*959
cm-.
Since the coefficient of expansion for copper is greater than that of steeL the free expansion of the copper bar is greater than the free expansion of the steel tube. Since the two components are rigidly
connected together at the ends,
actual expansion of steel --^-actual expansion of copper. 8 Let be the actual expansion of each component.
Obviously, 8 is greater than the free expansion of the steel tube than the free expansion of copper. Hence steel is in tension and the copper bar ms in compression. For the equiBbrium of the ^ system.
Total tension in steel— Total compression in copper Let the stresses in steel and copper be/# and
ft respectively*
miKB SnUBSn AND SIXAINS
C5
f*A*
7069 ^ 3-959
A,-'"
1-785/;
Actual expansion of steels Actual expansion of copper
a,Tl+
^/=«.
».T+
n—^l Jbc
JDt
/.
.acT-^
In
jt,(t
r=180-30=150"C /.
rOixiO-6xl50+2Tj47ol“l'^’‘*<^**» 1620+
1-785/.
21
-=2550-
^
-2550-0-9091 1-7591 /.=930
1620+0-85
/.
/« ““
—flMOf
/,
=^52S’8 kg.lcm.* p930 75^
iam^resatfe}
f'‘‘l7i5xS2gr»-~943-9kg.lem» component
(UHsOey
Increase in length of either
=«.
( =[
n+ ^
/
“•^+6-)' 1-08x10-6x150+
30
c»r.
*0'062 cm.
A weight of 20 tomes is supported by three short 52. each -5 cm.^ in section. The central is of steel and the The pillars are so adjusted that at a temouter ones are of copper. perature of J5°C each carries equal load. The temperature is then raised to 115'C. Estimate the stress in each piUar at JTC and IIS^C. Take El ’=‘2 y 10^ kg Icm.^ ; Et=^0'8xl0^ kgJem.*;tu>^l2xfO-AfC and »e=18 5 x W'^jC. {.A.M.LE. May, 1965) Solution. Area of each pillar— .4— 5 cm.* ProUem
pt^
pillars,
Initial stresses
At 15®C each
pillar
carries-^ tonnes.
Stress in each pillar—
toimeslem*.
-I333’33kg.lcm.*
I
STRENGTH OF MATERIALS
66
of temperature alone. Let the stresses due of temperature aloue be pc kg Icm.^ (compressive) in copper
Stresses due to rise
to rise
and
steel. p* kg-tern.^ (tensile) in
Lit the change in length of each
member be
I^oicTl—^-
«.r/+-§'
,,T+^^c,cT-Pf PL Ec P*
•
•
.
.£i«r(«.-«.)=(ll5-15)(18-5-12)10-« Er
P'
I
looxesxio'^
‘lx 10*"*'0'8xl0« I’Ll jPl ==650 8 2
^0
2/>.+5/>.=2600 pc At
Also
...(i)
= pc At
p.X5 -prXlO p.=2p. Substituting in Eqn<' (0,
2
...(«)
we
get,
X 2pc-l-5pc =2600 P(-==--^-=288’89
and
^rg./cm.*
(compressive)
Pc=2x288-89 = 577-78 kg.lcm.^
(tensOe)
Final stress in copper
= 1333 33+288 89= /622-2.? kg.Jcm.* Final stress in steel=l333
33- 57778 = 755-55 %/cm.*
ProMem 53. A flat bar of aluminium alloy 24 mm, wide and 6 mm. thick is placed between two steel bars each 24 mm, wide and 9 mm. thick to form a composite bar 24 mm. x 24 mm. as shown in The three bars are fastened together at their ends when the temperature is 1(PC. Find the stress in each of the materials when the temperature of the whole assembly is raised to SOTC.
Fig. 48.
If at the new temperature a tensiie load of 2000 kg. is applied to the composite bar what are the final stresses in steel and allov ? Take **
m,-m 24 xl(r*perC.
X IC^ per “C and
sun PLB STRESSES
Solution*
AND STRAINS
67
Area of aluminium
^a=2-4 X 0-6 - 1-44 cm.2 Area of steel in«=2 X 2*4 X 0*9=4*32
cnfi
Stresses due to rise of ternIf the two members had perature. been free to expand, (i)
free expansion of steel ^dsTl free expansion of aluminium --OiaTl
But since the members arc fasFig. 48 tened to each other at the ends final expansion of each member would be the same. Let this expansion be The free expansion of aluminium is greater than 8 while the free expansion of steel is less than Hence steel is subjected to tensile stress while aluminium is subjected to compressive stress. Let ps and Pa be the stresses in steel and aluminium. For the equilibrium of the whole system Total tension in steel=Tota] compression in aluminium /?»
Final increase
PiA$"^paAa X4*32=«/?aX 1*44
in
length of steel=Final increase in length of
aluminium.
But
7'-=50-I0=40’C
12X10-«X40+ ,-fi73-24xl0-*x40-
,
^
— X10«
480+^=.960—|-p. ^+’Y/>«='480 1920
^+3ip.-19» Pk’^S76 kg./cm,* (jeompressive)
x
SIMMOTH
to enternal load
Let the stresses due nod alumiaium.
of 2000 kg.
to the external loading
be
and
/ in sleel
alaminittm. Strain in 8teel=8traio in
^L
.
£•
fi
E.
.
But load on steel+Load on aluininiom>»' Total load
V44fa+Anf,^7m r-M/.+4 32x3/.-2000 14'4(>/.-2000 f
.8
2000.
/•“144 **•/<»»•
..
’^69'44 kg.fcm.* (compressive)
/.*3x 69-44 Final stresses due to Stress in
JIrg./an*
^208.32 hg.fcm.^ (compressive) rise of temperature and loading
Two steel rods one of 8 cm. diameter and the other end by means of a turn budUe. The other end of each rod is rigidly fixed and there is inltialty a small tension in the rods. If the effective length of each rod is 4 Problea. S4.
^6 cm. diameter are joined end to
metres, find the increase in this tension when the turn buckle is turned by one-quarter of a turn. On the rod of bigger diameter there are I’S meads per centimetre while there are 2 threads per centimetre on the other rod. Neglect the extension of the turn buckle, also what rise in temperature
Selatien.
would nullify the increase in tension. Take E=2 J0» kg./cm.* and e.^J2'X.l(r^fC.
Cross-sectional area of the stnalif- r
4
“M-2S
X 6® cm.*
cwi.*
bar
mVLB STRBSns AND STRAINS
69
Fl|.
49.
Cross-sectional area of the bigger bar
X8* cm.*
4
-50-27 cm.*
When
the turn buckle
is
Extension of the smaller
turned by one quarter of a tsrn»
bar=-^
Extension of the bigger bar
^ cm.
•
—
cm.
Total extension of the two
rods»
o
O
cm.
7 -24 Let the tension in each bar be
T kg.
Total extension in the two bars
400P f
‘2xl0«V
“
+ ,
\ 1 50-27 I
400 7iS5P 2x10®'' 28-28 x 50-27
P-26380 In order this tension must be total
1
28-28
kg. nullified
by
expansion of the two rods mustbeequal to
Let the
.-.
rise
of temperature be TX!
-®xrx 800 -;5
I 2 xl 0
7_ 24
-
24X12X800 -J0-58*C.
rise
7
of tempomture
— STRENGTH OP MATERIALS
ProUem 55. A
steel
rod 32
mm.
in diarneter is fixed co^entria^
^ ^
outside ai^ inpde diameters of 48 nm. in a brass tube which has tube are 40 cms. long 34 mm. respectively. Both the rod and the wAicA is held between two stops rod compound The level. their ends are raised then is bar the temperature of the are exactly 40 cms. apart and by 60rC. distance between the stresses in the rod and tube if the (o)
the stops
Find (0 remains constant
(il) is
0 025 cm.
increased by
stops if the Find the increase in the distance between the 8000 kg. force exerted between them is Ei.’=0'9 x 10* kg.fcm.* kg.jcm.^ rake E>=2x ib)
m
«,= 12 X 70 Solution,
(a) (i)
*
and
per°C
the distance between
When
the stops remains
constant.
m^ctsTEa
Stress in steel
Stress in brass
= 12 X 10"® X 60 X 2 X 10® kg.fcm.* = 1440 kg./cm.* (compressive) — a»r£» =21 X
10"*
X 60 X 0*9 X 10® kg.jcm.^
= 1134 kg./cm.* (compressive) (a)
When
the distance between the stops is increased
by 0’025 cm.
—
expansion prevented
,
Strain in steel
-r ,, original length
“
a.r/-8
~
/
12X10-^x60 x 40-' 0 025 40
=0-000095 Stress in steel
=£«e»=2 x
10®
x 0-000095 kg jcm.*
= 190 kg. Icm.*
(compressive)
prevented
Strain in brass
onginal length
" “
•bTl^ /
21xlO-®x60x4n-0-02S 40
=0000635 Stress in brass
=£^6 =0-9 X 10* xO-000635 kg.lcm.* —571’5 kg.lcm.* (compressive)
— SIMPU
SIHeSSBS
(b)
When
AND
8
71'
SPRAINS
the force exerted between the stops is
8000 kg.
Let the expansion of the composite member be 8 cm. c* •• Strain
m steel *
1
—
— j
“
12xl(Hx 60 x 40-8 40
=.(720xl0-«— ’“pt=Etei
Stress in steel
=2x 10* ^720X10^--;^^ kg.lcm.^ )440_^*j kg.lcm.* Similarly strain in brass
=e»—
— ——
«* Tl
j
21
”
Xl0~«x 60 X 40-8 40
=.(l260xl0-«--^) •^pt^Eb
Stress in brass
e»
=0'9 X I0«( 1260 X
kg-tcm.*
)
=( 1 134-^ X 10« 8 ) kg.lcm* Area of Steel
=^.„ix3'2* cm * 4
«=8'04I cw*.
Area of brass
=^46= ^^4'8*— 3‘4*
Load on
on brass
steel +load
cm.® =9*016 cm*. j
Total load between the stops
ptAt+pi,Ab—P (
1440- -2^-)8 04H1
1
(
1
134-— x 10« 8^ 9 016 =8000 kg.
580+10220-605000 »
8 -8000
13800 605000'
i(jr
02281 an.
SIMNOTH OP MATBUAU
72 HtacfSiMPi.
112.
SO diows a thin steel tyje of ioternal diameter d. Such a tfn can be dirank on to a wheel of slightly bigger diameter D. The la this stage the glial -tyie is heated so that its diameter exceeds D. now the tyre be cooled it it gtee» tyre Is slaved on to the whed. pnventoi fh>m assuming its original diameter d. Hence it will grip ‘
Fig.
U
the wheel. tyre.
Hence a pensile stress u induced circumferentially along the Sodi a sireas it called a hoop stress. Temperatttre strain ^
amtraction prevented ^
original length
icD—vd
~
ltd
D-d
~
d
Hoop stress due
to fall of temperature
It is Prahlem 56. rigid wheel is 3 metres in diameter. derired to shrink on to the wheel a thin steei tyre. Find the internal diameter of the tyre if qfier fitting the hoop stress in the tyre is 900 kg.lem.*. find also the least temperature to which the tyre must be luated dbofe diat of the wheel.
rigid wheel 1'25 metre in Udometer is to be If the stress in the steel tyre is not to excifid 140 MNImetr^,find the minimum diameter of the tyre. Find also the minimum temperature to which the tyre is to be raised so that it can befitted over the wheel.
The moment of resistance of a singly reinforced beam of breadth b cm. and effective
rectangular reinforced concrete
)
STRENGTH OF MATERIAL
944
d cm. 6 bd^ kj^. cm. If the stresses in the extreme fibre of conCrete and in steel do not exceed 50 kg Icnu^ and 1400 kg.jcm.^ respectively and the modular ratio equals 18, determine the ratio of the depth of neutral axis from the outside compression fibres to the effective depth of the beam and the ratio of the area of the tensile steel depth
beam.
to the effective area of the
For a balanced section, with
Solution
kgfem.^ and
18,
kg.lcm.^, 1400 resistance of the balanced section
moment of
the
- 8'5
bd^
But the M.R. of the given beam
only 6 bd^.
is
M
M.R
R. of the of the given beam is Jess than the balanced section, the beam section should be under-reinforced. Hence Since the
steel attains the
maximum
Hence
stress earlier to concrete.
= 400 kg jcm.^ maximum stress in concrete t
Corresponding
1
““
c
^
/!
given by,
d n n
1400 18
Let
is
n
18c 1400“
d-n
'
= Hid 1400
nid
18
d—nid
*
1400 c=18
MR. b nid
i4m ( 2 X f8 V
[
f>«2 (
'
l-ni)
>-3
)(.-
I-«l;I\
Y )-6 3
bd^
/
6x2x18 1400
f
-=( •- ^ ^=0154
l—m
Solving the above equation by
trial
and
error,
we
/ii=0-34
«=0-34d
c-
<400 Ij,
=40
0-34 -
|_o-34
kg. Icm.
.
.
2
get
^
plements or reinforced concrete
945
=Total tension
Total compression
40
fcx0'34dx^ =/<(Xl400 At
0^34x20
bd
1400"
=0 00486
Pioblem 502. A reinforced concrete slab has an overall depth of the centre of the reinforcement being 2 cm. 10 cm., the effective cover to steel are not to exceed 50 kg jcm} and and concrete in stresses If the the safe uniformly distributed load which can be J 400 kg Icm.^, find The slab is supported on beams spaced at 3 metres placed on the slab. Find also the spacing of 10 mm. diameter bars to resist the centres. maximum bending moment. The maximum bending moment for a one wl^
metre wide strip of the slab be taken as -jj load on the slab in kg. per metre^ metres.
and
I is
kg.
m. where
the spacing of the
w
is
beams
the in
m= 18.
Take
Corresponding to
Solution.
c=50
kg. Icm.
t= 1400 kg /cm.^ /n=18
and For the balanced
section,
M.R.=S and the
Hence
5 bd^
arm a=0’87 d. moment of resistance
lever
the
offered by the balanced section
per metre width
=8'5xl00x(I0—2)2
kg. cm.
=54,400 kg. cm. Let the safe distributed load on the slab be w kgjmetre^. Maximum bending moment for a 1 metre wide strip
Equating the resistance,
we
wP
wxS ^
“IT*
12
•
X
100 kg. cm.
maximum bending moment
to the
moment of
get,
X 100 = 54400
H-x 12
54400 X 1 2
9X100
.
imelre^
725’3 kg.lmetre*.
The above load of the slab also,
is
the total load on th^ slab including the weight
946
STREKOTH OFUATERiai
Dead load of thfc
slab per square metre
— X
X 2400=240 kg.jmetr^
1
Net external load which the
slab can support
•=12S-i-2AQ=485'3 kg.lmetre^
M
Af= .
Area of steel
ta
54400 -.ro 1400 x 0*87 x8
cm*
=5*58 cm? Spacing of 10 mm. diameter bars area of
1
bar
X 100
Total area of steel per metre width
0-79x100 cm.
5-58
Hence,
let
us
^14-2 cm. provide 10 mm. diameter
bars at 14 cm. centres.
Effect of varying the steel ratio on the depth of neutral axis and moment of resistance
1180.
the
For
M
this discussion let us consider
1
50 grade of concrete.
Permissible compressive stress in concrete
= 50 kg.jcm.^ Permissible tensile stress in steel
•=1400 kg./cm.^
Modular
=18
ratio
For a balanced section depth of the neutral
me
,
axis
n
d—n
/
18X50
n
1400
ji=0-39 d ,
Lever arm
.
—a=d~
0-39
d
^ ^ d—
”
,
=a—
=0-87 d
Moment of resistance =M.R.>=6
n
=6x0*39dx-^— x0-87r/ =8'5 bd?
is
given by
elements op reinforced concrete
947
i
=Qb(P where ^=8 50 “Total compression
Total tension
AtXt=bn-~ 2 Ai'x 1400-
’bx0 i9dx
=p.
Steel ratic
At
0 39 X 25
hd =0-00696
1400
Percentage of stecl=100 /?=«0’696%
Now
for all values of n less than 0*39 d the corresponding values of the lever arm a, 100 p and the M.R. arc tabulated in the following table (page 948). For this range in the value of n the section will be an under-reinforced section. The moment of resistance should therefore be estimated corresponding to the maximum tensile stress in steel.
Now
let us considei a further range of values of n from 0’39 d These sections arc over-reinforced sections and hence for these section the moment of resistance should be computed corresponding to the condition of maximum stress in concrete. The values of a, 100 p and the moment of resistance for various values of n are
to 0 1 d.
tabulated. It is
(i)
axis
worthy to note
As
:
the percentage of steel increases the depth of neutral
n also increases.
U4RtA7m Of MOMENT Of RfStSTAMCE WCTH
7 0
fOfO!
02
(hS
04 OS Og 07 OS 09 fO
H
renciNTAce or smi •toop i’MOOlsfaifAASO m*tS Fig. 828
f$
h4
H H
f> »4
948
STRENGTH OF MATERIALS Properties of Uoder-reiiiforced Sections
m—18
Stress in Steels 1400 Percentage
I^verarm a
Safe
kgjcm,^ Moment
of steel
of Resistance
100 p
M^pbdta j
0-967
d
0 03
0*933
d
0 14
0*35
d
0-883
d
6-43 bd^
0-39
d
0*870
d
8*50
Properties of Over-reinforced Sections
m= 18.
Stress in Concrete =» 50 kg.lcm.^
4 »
elements of REINPOkCED concrete
As
(a)
949
the percentage of steel increases the lever
arm de
creases. (in)
The safe moment of resistance increases rapidly and somewhat uniformly as 100 p (percentage of steel) varies from 0 to 0 69. For further increase in 100 p the safe moment of resistance The critical point at which increases at an apprecicAly slower rate. the change in rate of increase of moment of resistance occurs repreHence it is important to sents the condition for a balanced section. note that by providing more steel than the requirement of the balanced section though it is possible to increase the moment of resistance,
it
increase of the
is
uneconomical due to appreciably slower rate of
moment of resistance.
(See Fig. 828).
Doubly Reinforced Beams
§181.
Beams reinforced with steel in compression and tension rones \wll be are called doubly reinforced beams. This type of beam ronsideraappearance room, head to due when necessary found its limited tions the size of a beam is limited. The beam with enough have not side, may tension the on reinforced if dimensions, moment of resistance to resist the bending moment. By increasing cannm the steel only on the tension zone the moment of resistance be can resistance of moment the Usually indefinitely be increased. ol moment balanced the over than more 25% not by increased teMion the on over-reinforced section resistance, by making the resistance Hence in order to further increase the moment of side reinforced doubly a dimensions, of a section of limited tne Besides this a doubly reinforced beam is also used provided.
b«m
m
following circumstances
:
external live loads cither face of the member. (i)
The
Ex
:
A
pile
which
is
and compression zones may («)
load
The loading
may
lifted in
alternate,
may
i.e.,
occur on
such a manner that the tension
alternate.
^^city
of the eccentric and the «de. another to axis the one side of impact or may be subjected to a shock or
may be
may change from (///) The member
accidental lateral thrust. Analysis of a doubly reinforced section
Fig 829 shows a b cm wide beam reinforced doubly and d cm deep to the centre of tensile reinforcement.
h
JT
I
Neutral axis.
** I ^
L
.'
Let A. and At be the areas of reinforcenaent in the compression and tension zones.
Let n be the depth of neutral
cither
I
^
<
t
^
Wg. 829 Equating moments of areas on axu, wa haire. ade of the neutral axis, about the neutral
•-
1
brfi
j- xmAc(n— de)—Ae(n—de)—mAt(d—n)
brfl
Y
(m—l)A.{n-~dc)=mAi{d~n)
...U)
If the stresses c and t, i.e., the stresses in concrete and tension reinforcement are known, we have
me It
...n'
d—n
t
very important to note in the cr^e of a singly reinforced dimensions, in order that the actual neutral axis ma\ with the critical neutral axis, there is a certain definite
is
beam of chosen coincide
amount of steel
required.
But, in a doubly reinforced beam of chosen dimensions, the reinforcements At and A may he adjusted in an infinite number of ways so I
that the actual neutral axis
and the
critical neutral axis
may
coincide.
Since total compression ^Total tension, we hare,
C^T bn
+(ffi -i)Atc'-~4t
.( 3
t
Stress in compression stalIf t' is the level of the compression steel the stress I(ut
Stress
Moment
-
t
incompresnon
-
sf?;;!
slrci^ in io
ii ocretc
compression sfeeJ-
at
//;i
r
—
-
,•«.
of resistance
This is computed by taking moments of the compressive forces about the centre of gravity of the tension reinforcement.
M.R.^hn §182.
2 (
J-
i-(m-l)
.T c’ (d
-A)
...(4i
j
Types of Problems
The following are the types of problems analysis of
Type! Data
Overo-l section,
;
c an'
Required
:
.1
wc come
across in
ami the working
the
stresses
’
Mousent of
resistance.
The position of the actual neutral axis first deterFq. I). The position of the critical neutral axis is found
Solution.
mined (.vfc from £q (2j with the given values of the
wrir king stresses c and t. If the depth of actual neutral axis is greater than the depth of ciritica! Hence neutral axis, concrete will attain its maximum stress earlier.
the
M.R.
stress, c
is
worked out from Eq.
(4) taking c at
the given
working
should be taken as
If the
depth of neutral axis
than the depth of
is less
critical
axis, the steel in the tension zone reaches its maximum stress earlier. The stress in concrete corresponding to the working stress of t in
the tension reinforcement is found from Eq. R. is found from Eq. (4). c the
The following example
illustrates the
With
(2).
M
this value
of
above type.
Problem 503. A beam of reinforced concrete is 25 cm wide and 48 cm deep to the centre of tensile steel It is reinforced with four compressive steel at an effective cover of 5 bars of 20 mm diameter cm. and with four bars of 26 mm, diameter as tensile steel. If the stresses in concrete and steel are not to exceed 50 kgdem.*^ and 1400 kgfem.'^ respectively^ determine the
The modular ratio—
moment of resistance of the
section.
18,
Ac^\ 2*57 cm,^
Solution
Depth of actual
^
neutral axis
Taking moments about the neutral
axis,
we have, 25
'i-
4
(1
-18x2r24 Solving,
«
8-1)12-57 («-5)
we
(48-/I)
= 2217
«
get
The depth of
critical
cm.
neutral
axis
^
is
given by 1_8>^5()_ 1400"
ru
~48-m
Fig. 830 Pig.
18'78 cm.
n<
Since the depth of actual neutral axis of critical neutral axis, concrete attains the
is
greater than the depth stress earlier to
maximum
steel. .
.
Stress in concrete will be allowed to reach 50 kg./cm.* c
= 5n
fcg./cwi.*
-d'
•
X 50«38-73
fcg./cm.®
M /?.=25x22-17x-y[ 48-^]+(18-l)12-57x 38-73 [48-51 kg. cm.
= 562,600+355,800=918.400 Type 2
Data
:
kg. cm.
Overall section, At
and At, Max. B.M,
952
SnENGTH OF MATERIALS Required
:
Stresses c and t in concrete and tensile in compression steel.
steel
and also
The
position of the actual neutral axis is first deterExpress the moment of resistance in terms of the stress c in concrete and equate to the given bending moment. From this eqation the stress c in concrete is determined. Solution.
mined from Eq.
(1).
compression steel=wc' =
The
stress in
The
stress in tension steel is given
me ^
—-“V.
by the relation
n
t
illustrates the above type* Problem 504. A doubly reinforced concrete beam is 25 cm. wide and 50 cm. deep to the centre of tension reinforcement. The areas of The centre of the compression and tension steel are 12 9 cm.^ each. compression steel is 5 cm. from the compression edge. If m — 18 and
The following example
the bending moment at the section stresses in concrete and steel.
is
700,000 kg.
rOicm.
Taking moments about the ^neutral
we
the
See Fig. 831
Solution.
axis,
cm., calculate
I
have,
?|^-V(18-l)12-9(n-5)
= 18 X 12*9(50- n) Solving,
we
get
ii= 16*40 cm.
Let the maximum be c kg./cm.^
stress in concrete
Stress in concrete
.*.
of the compression
_ —c
,
at
the level
steel
n^dr
^ 16*40-5
~
16*4
‘^*
=0*6952 c M.R.^mbn
=25Kl6*4|-[
d
—
+
I)/4cc'
50-^]
(4
— d^
H-(18-l)12 0x0-6952c
(50- 5)=700,003 9128 c+6860 c=700,000 kg. cm. 15988 c=700,000 kg. cm.
c=43*77
kg. cm.*
kg. cm.
EUMEMtS OP
KElNPOftCED CONCRETE
Stress in compression steel
Stress in tension
953
= 18x30‘‘13 = 5»7‘74
_(0-16-4) ^1614 kg Type
3,
Data
safe stresses c
Required
X
:
IS X
43 77
/c'w.*-
lcm,^
maximum bending moment,
Overall section^ the
:
kg.lcm.'^
sleel=^~-^mc
and
r
in
concrete and steel
Ac and At.
Solution. With the working- stresses* c ana t aetermine the depth Find the R. in terms of the stress in neutral axis This equation concrete and equate to the given bending moment. will involve only Ac as the unknown which can be determined.
of
M
critical
By equating total compression to total tension, find At. The following example illustrates this type. Problem 505. A rectangular beam reinforced on both sidc.s is BO cm wide and 75 cm. deep. The centres of steel are 5 cm. from If the limiting stresses in conc rete and steel arc
the respective edges.
50 kg.lcm.^ and 1400 kgjcm.^
respecti-
determine the steel area for a bending moment of 1^400,000 kgl cm. vely ^
|*
—
-»|
Take SolntioD.
The
section
will
be
designed as a balanced section.
The depth of axis
critical
neutral
given by,
is 1
8x5 0
wc
1400 ne
^27 39
cm.
50 kg. I cm-.
Stress in concrete
Stress in concrete at the level
comnression
=c =
=
of
steel
''X50kg.lcmj‘ 27 39 Fig.
kg.lcmP’
M./?.-30x2/39x
832
— 50
[ +(18-1)
4.
>
x40 87(70-5)=1,400,000
1,250,000+45160 •
1,400,000
At=3’32 cm?
kg. cm.
= Total
Total compression
30 X 27 39 X
2^4-(18-
-
I
)
tension
x 3 32 X40 g7
x
1
;00
20540+ 2307-= 1400 A 2
76 32
The
§18}.
beam theory
steel
This is a method cf de? theory assumes the following (/) (i7)
(m) (/v)
compression tens59n
The
:
by comprcssi^
resisted cf.!v
resisted only bs tension
is
stress in
is
Ooubly remforee J beams.
ignini.!
compression
ste«
-tress
-
'
-si;el
steel
ii
(ensii'n steel
ifj
;
;
;
concrete serves only as a v b of an I beam whose hanges are represented b\ the ccn.orossion and lo'^ion reinforcement. .
In this i.e.y
.
method areas of compi
and tension
-i^ion
steel are equal,
Ac = At
The M.R. of
i—d
stress
of
)
is.
or
ther
i
re,
•
t{d
j
given by*
)
M
A.^A
A
beam
die
Ar V
...(4;
r;j~d.
UOO
/
n.
A:r
be assumed
>'
ictermining the
in
reinforcement.
A rcctunvular Problem 506 Td' 30 cm. wide and 7: cm. de< ^ respective
find the
edges,
theoryy for a bendin Solution.
:
re inf
'
'
mome*v of
Distance between
'
c
both slds is cm. fro n the
reinforced oo 'el ar~ ores of oent r .uirca ^00 k;c
ilie
sttcl
team
cm.
»pressiori
and leuston
reinforce-
ment -75 — : ~65 i400 Avf. vm.-
Allowing,
c/'*
1.4(0+ c*m.2
ir
1 .^
4
'
tv/
1400 §184.
Shear stresses
in
honiogeneouN sections
Fig. 833 shovss a simpfv suppv
trated load IV at the centre
Fig.
iod
beam
subjecicJ
to
concen-
.
We
find that the sheaf force at the section
Hence, the cross*scction site resistance.
If really
form, the shear
.4
BCD
-
has to offer an ecju.il and oppoof the shear resistance ii uni-
the intensity
stresses at the section
“
would have been
area AliCJ) But, actually, the intensity of shear resistance
Now system.
beam shown
consider the
Consider two sections
SQEflBSSBEB
> HW
1-1
and
nor uniform.
is
in Fig.
'i
tt subjeeieJ to
2-2. i/v apart.
Let the
a load rieiid-
r
0 )C Fig. 8.S1
M
and \f -\-J\t respect iveK. and 2-2 be ing moments Now consider an elemental part of the beam, of widi!’ b anil linekness dy and length dx, situated at a heiglo ..f v from the ne.urul This part is separately shown in ig layer at sections 1-!
i
'
'
i
Let / be the
about the neutral
Bending the elemental Section (1-1)
Bending rhe
elemental
moment of inertia
of the
cr.
s-.sectioii
of the iteam
axis.
stress
on
part
at
stresses
part
on at
section (2-2)
M+dM
T
-/+r//=-~rNet
,
.V
force at the
elemental part =r(/’Xarea of crcs.sof the elemental
i
scction
8J5
pStJT
=tf/.
Total
area as
force
shown shaded
bdy
— d.U /
>. b(Jy
on the part of the beam of length (Fig. 835)
end of
STRENGTH OP MATERIALS
956
=
b.
ydy == -j -
I
X moment of shaded
where
/i
bdy. j
area about the
neutral axis
-area shaded
y =distance of C.G. of shaded area from
N
the
A.
Cut this net force should be balanced by horizontal shear. Let q be the inlersity of hcrizontal shear stress. Horizontal shear resistance = force on the part of the beam of length dx and of area shown shaded
b dx
Ay
.
_ dM dx dhd
r?
=S.F.
Ay_ ‘
Ih
at the section
C
direction
the intensity of shear stress in a horizontal stress in a vertical But, this also represents the intensity of shear shear). direction (by the principle of complementary section Shear distribution in a beam of rectangular
This
is
§185‘
Consider a beam b cm, by d
cm.
\
Let the shear force at the sec-
be 5. The shear stress ^ at a point y cm, above the neutral ax»s is given by
moment above the point the N.A.
law.
of
area
considered about
*
\
>>
y
lion
y
\
/A
|
/
I
i
»
*
-
^
l
^
Fig. 836
Hence, the distribution of shear intensity follows a parabolic This is shown in Fig. 836.
elements of reinforced concrete
We
957
find that the shear stress
=0 and the shear
stress is
at
>.= |-
maximum
at
y^O qmttx
= —•
^ 4
Sd"^
8/
Since
_ Sd -
12
3
l'
But
J —average shear bd (Jinax
Shear stresses
§186.
in
=
5 bd stress.
3
an R.C. beam
In the case of reinforced concrete beam in which it is assumed that tensile stresses are not lesistcd by concrete, the distribution of shear stresses will not exactly follow the law of equations (/) and (//). However, for the compression zone of the follows the shear distribution section, the law of equations (/) and (n). The shear stress in concrete in the tension zone is constant, as shown in Fig 837.
The shear strsss in concrete in the tension zone therefore is the maximum shear stress. This can be determined as follows
Fig. 837
:
Consider the concrete beam subjected to a bending. Consider two sections 1-1 and 2-2 dx apart. Let the cross-section of the beam be b cm, and d cm, effective depth. Let the bending moments at sections Let the lever arm respectively.
1-1
{M+d\f)
Tension in the reinforcement at section 1-1
Tension in the reinforcement at section 2-2
=T+dT
M+dM Q
and 2-2 be
M and
958
STRENGTH OF MATERIALS
Fig.
838
Net force on the reinforcements tending them to move
If the reinforcement be firmly bonded with concete so that the reinforcement will not slip out of concrete, then the net force in the reinforcement will induce shear stress equal to
dr Horizontal shear area of
dT ^
bdx
beam between
section 1-1
_ dM _J ” bdx a
1_.
ab
and 2-2
^ dx
This is the horizontal shear stresses in concrete which be equal to vertical shear stress intensity.
will also
Effect of shear stresses
§187.
ABCD acted upon by shear The effect of the shear stresses is to shape shown in Fig. 839 (c). We find that
Consider a rectangular block stresses
q as shown
in Fig. 839.
deform the block to the
AC
are developed on the diagonal plane are developed on the diagonal plane BD. It can be easily shown that the intensity of diagonal compression or diagonal tension is also equal to the shear stress q applied on the
compressive
stresses
and
stresses
tensile
ELEMENTS OF RFINFORCED CONCRETE block.
If the riiatcrial of the block
959 is
weak
in
tension,
the failure
occur along the diagonal B]) and the block will be split up into two along this plane. If the material is weak in compression, then failure can occur by crushing along the plane AC. will
is a material weak in tension, and strong in compresat least ten times as strong compression as in tension.
Concrete sion.
It is
Hence
m
a concrete block result by diagonal tension. if
The
I.S
is
subjected to shear stress failure
may
has specified
specification
that the safe diagonal jem!^ for 150 grade concrete. Hence if the shear stress which is also equal to the diagonal tensile stress is less than 5 k^Jcm.^y the concrete block is safe. If the shear stress exceeds 5 kf'.lcm.'^ then the block requires to be strengthened by diagonal or vertical reinforcement. See Figs. 840 (a) and (fc).
tensile stress for concrete
is
M
5
Further the design will not be considered safe even with such reinforcements if the shear stress exceeds four times the allowable shear stress, re., if the shear stress exceeds 4x5“20 k^.lcm.^, the size of the block should be suitably increased so that the shear stress does not exceed 20 kg,jcm^.
(b>
ia) Fig.
840
Hence summarising the above# we have, when q<5 kf'.fkm.^ no shear reinforcement :
and
q> 5
Ag
q<20
kg./cm.^J
q> 20
kg.lcm,^^
shear
reinforcement
is
required. is
. *
resist
‘
size
provided
to
the diagonal tension.
of the block
is
to be changed so
vw
STRENUIH UF MATBRIAIS that the shear stress will not exceed 20 kg.fcm^. Figs. 841 (a) and (6) show how such diago-
nal tensile stresses are
developed
, !
I
!
I
a beam. by
in
Suppose a
failure
diagonal tension occurs so that the part ABCD is
split
parts
up
ABC
into
the
and DCB.
In order to safeguard the structure against such failure by diagonal tension, reinforcement connecting the two parts and required. are These reinforcements are Fig. 841 called shear reinforcements. As already suggested, [in Fig. 842 (a) and (h)] the reinforcement may be provided vertically or diagonally.
ACB
DCB
When
the shear reinforcements arc provided vertically they arc These consist of bars of 6 mm. to 10 mm. diameter bent round the tensile steel, as shown in Fig. 842 (o).
called stirrups.
Fig. 842
to provide small diameter bars of 10 mm. to 12 mm. in the compression zone of the beam properly anchor in oraer to It
IS
also necessary
the stirrups.
each stirrup legs as section.
In Fig. 842 (a) consists of two in the cross-
shown
In such a case we 4 say the stirrups are two-legged, some cases in order to
b
Lmeo srnmps
6 ligged lb)
Fig. 849
^
elements of reinforced concrete greater shear stresses it becomes necessary to preside legged stirn ,>s (four legged, six- legged. efc.}. These
resist
Figs.
843
several
shown
are
and
(a)
in
(d).
^7
n
^NDS OF RESIST NtCiAUVE BENOs.^C fN S/
Two-Legged
F'U.
Design of vertical that
t
ri:e
concrete has faiico by ^diagonal tension arc all j^a— to a -r -:hear force
ch
stirrups
ic
It, ' crack load equ,^! to nasimum S, which the as ihceu leaction. Nee Fig. K F" also re same that L/*! the '^rackt'!’’ p!'(nc is Miciinei at 45'" to the centre hoc of che bfani i)‘)d -'hat it extends a '»r'ri7wpjal d: stance equal to the lever arm tt\e beam.
1—
/
1
»
1
c.
-
Number /.
/
i; Fig.
843
stirrup
one stirrup
rvr=-Mdh*A.iOle srre-^ in tension in
p
a
i
.
^ar:^ of one
Let
L Beam.
sfirniprs
iv as^iujTK' ihat
NO
Stirrur'*^ in
MOMFNl An
pitch of .stirrups iff
a
stirrups in the horizontal distance
Av
Total load on the stirrups =
t
tvs -=-
P
S
4 vitwQi
s
...fir)
A. should be determined faking into
account the number of
legs provided in each stirrup
Since the shear force decreases from the ends towards the enhese stirrups will be close at the ends and can be increased towards the centre. As per our code of practice, the spacing of these stirrups shall not exceed the lever arm distance of
centre, the spacing
the
beam Strictly at sections
the
allowable
limit
where the shear
of
5
kg-lcm.*,
stress
shear
q—
g
^
is less
reinforcement
is
than not
962
STRENGTH OF MATERIALS But
theoretically required.
even
if
it is
the induced shear stress
a practice to always provide stirrups than 5 kg.jcrrfi.
is less
Q^/m^ire
Fig. 846
supported
L7
(ol t^L
t
shows a simply
beam
carrying a distributed load of w kg.jmetre. Let the span of the beam be / metres.
We
have wl
This occurs at the end. J
where
section
the
.ct
hear stress is 5 kg.jcm!^ be at a distance of x metres the
Fig.
r
fromjlthe centre.
846
.
.y
//2
From
_
5 fji/rtia;
x can be determined. of x on each side of the middle
the above relation,
point, Hence for a distance shear reinforcement is not theoretically required, but practically provided to a nominal extent at a spacing not exceeding the lever arm distance of the beam.
from each end stirrups are pro) The disvided in accordance with the requirement of Eq. (iV), For the distance of
tance
^
—
I
(
y
from each end may be divided into a number of
Jc
]
sections and the shear forces at these sections can be determined. The pitch of stirrups corresoonding to these sections can now be This will assist in deciding about changing the pitch at calculated. suitable sections.
Problem 507. A' beam 25 cm. wide, 50 cm. effective depth and 6 metres span supports a total load of 19050 kg. including its weight. Find the maximum shear stress and determine the spacing of 10 mm. stirrups.
SoIntioB.
Assume C“=50 kg.lcm.^ and /=1400 kg.lcm.“ a=0-87 d
^ This
is
^
S 9525 oh “fO-S7x 50x25)
greater than 5 kg.lcm>^
»i== 18
=8‘75 kg.lem.^
blements of keinforceo concrete .
be*dia^^^^
not
h icm
.
963
Further the shear stress is Hence, the dimensions of the beam need
Suppose two-legged 10 mm. bars are suggested for stimips *«rups, wiU be AvIwO
their spacing
P—2 xQ 79x I400x 0 87 x 50 '
9525
Let us. therefore, suggest 10 at 10 cm. centres. Let the point where the shear stress equals the allowable safe shear stress of 5 kg. fern " be X metres from the centre. * 5 • 3"
• •
“
I
diameter two-legged sdrnim “*
8 75
i-f5
— r71 say
mm.
metres
*‘‘E-
Hence shear reinforcement is needed from the support.
for
3-r7l=»129
metres
‘30 metres
For the middle 3 4 metres nominal
may be
stirrups at
25 cm. centres
When
inclined rein-
provided.
§188.
Inclined or diagonal reinforcement.
forcements are provided, they consist of main tensiem reioforoemeat bent up at a certain angle as shown in !-ig. Bars are usually bent at 45* with the 848 horizontal Bars can be bent up only if the remaining bars are sufficient to resist the prevailing bending moments.
Suppose Av
the area of reinforeement bars the vertical component of the tension in these sin 45°=0'707 Avtv. bars -
bent up.
Fig. 848
Usually tv
is
is
If tv is the stress in these
taken at 1400 kg.jcm^.
quantity exceeds the maximum shear force S, then the shear is safely resisted by the bent up bars. Oficn with the bars which can be spared to be bent up the shear value of 0 707 Avtm may be less than the maximum shear force. In such cases for the baJance shear force of (S— 0 707 /firt*) vertical stirrups should be provided. However, vertical stirrups are always provided with a spadng not exceeding the lever arm distance of the beam. If this
§189. Lattice girder effect, (a) Single syatcai. It
is
not oraagh
if
bars are bent up just near the ends to resist the shear. In order that the beam is safe against shear failure, shear reinforcement is jxrovided throughout the length whether with diagonal sted or with veftkal steel.
m
STRENGTH OF MATtKIALS
964
When a number of bars arc available tw be beni. up to re shear, it is usual to assume that the beam is equivalent to a consisting of concrete compression members and steel tension mer bers as shown in Fig. 849.
SO U—
/
4 '4
a
-
—
-
a —
-
'tf4a
H
^
The usual arrangement h to assume the firu imaginary The ificlined pression member AB at 67^* with the horizontal. tension members are at 45* with the hori'onta! With such =Atrtv3 sin 45'’--
a system, 0*707 Autu^
the
shear resistance
any
at
sect, mi
The tendon members of this imaginary truss are prov'ded y Beading up bars are possible onlv vvhen a up bars number of bars are present at the bottom and a number iT them art' The arrangemv no longer required to resist the bending moment shown in Fig 850 is called a single system of bent up hdw The heh;hl of the imaginary truss is equal to the lever arm disiance a t
the bent
From
the geometry of the triangle
AC CB -av Le
the bars bent up at from the support.
>
of 1*414 tal,
Care
ABC of the
-2-
we
h ivc
1414 a
bent from a point at a distance
If the inclination of the bars be at any angle 0 the arrangement would be as shown in Fig 850.
_
B
truss,
witi:
the horizon-
^
f
Ft-. 850
worth noting that if the bent up bar say CB is at 0 with should be bisecting the the horizontal, the compression member CD It
is
-90-2.
angle jBCjEso that
ment
is
not done,
i
e
»
if
the compression
If this arrage
members are not taken
at
tLEMENfi OF REiNFORCtD
966
with the horizontal, wcfind the design
90
shear reiaforccnieat
becomes uneconomical. Sometimes the imaginary compression members at
45°
shown
are also taken with the horiiLontal while the bars are also bent up at 45* as
in Fig. 851.
rig. 85^
In suoh cases section by the expre s.jch xV a value of the horizontal part
li* "
•:
A
’culating
*^hilc
n 0
7
cat
txet^
’hr
o
tensile stress IS
oar.'i.
owakc
--
i
at any t.^ken to assunrie arc not developed in
resistance
s?icar
be
:
c r^ isile
k
r 707 value of !u used while calcalatir the
taken at 0*707
the
140o 4 ie./rw ^ he value of 1400 -990 ki
steel .should be Suppose the allowable in this case should be stress in
rcsisiancc.
k
Double system. If in addition to the bars bent up as shown 849. additiona’ bars are also bent up as shown in Fig. 852, the arrangement is called a double system arrangement in hig.
Fij.
852
In this case the shear resistance at any section==-2x*70?
AuU.
was stated in an earlier It LiniUiiig the shear stress be allowed to ekcced four not should stress paragraph that the shear Hence tf the safe shear stress tunes the safe shear stress of concrete §190.
of concrete to exceed 4
is
5 kg. It -m
“
the ihcar stress in
no case
shall
be allowed
there should be that after all, if shear an upper limit to the the shear stress has e^.eeded ihc safe stress of 5 kg./c'n‘, shear reinforcement of proper amount may be provided. But it should not be
x ‘5=20
may be felt as to why Miess. It may also appear
k,; !cnP.
It
forgotten that there suould not also be any failure by diagonal
com-
stR&Hjrti OP materials
966
imtssoii. Suppose the shear stress is so large that the diagonal compression stress can just reach its working stress. Corresponding to this, the diagonal tension would require such large amount of steel that
concreting will become difficult which will result in air pockets. The concrete in such a case would consist of a number of disjointed concrete pieces separated by steel bars:
Bond
§191.
One of the main assumptions forced concrete
is
in developing the theory
that the reinforcements
do not
slip
of
rein-
from the concrete
When concrete sets and thus hardens, it will firmly it. round the reinforcejments. It is because of this grip between concrete and steel, the two materials share the applied loads. Once this grip is absent the reinforcement provided would serve no
surrounding grip
purpose.
Supjwsc the reinforcement of the beam shown
in Fig.
853 has
lost the grip with concrete.
(a)
it; it is just as good as loosely providing a reinforcement present earlier When the beam is loaded the steel rods slip nd the beam fails since the reinforcement has not really shared the oading. Hence this grip between the concrete and steel i.s very iDportant and the gripping stress, bereaftti called the bond stress, should therefore be within a limit.
Then
>les
It
concrete
may be
realised 4bat the function of this bond in reinforced is exactly the same as the function of rivets in
members
^uih up plate girders which consist of web plates and flange angles nd cover plates. If for instance the flange angles arc not properly weted to the web plate the flange angles will not function. If ne number of rivets connecting the flange angles and the web is asufficient, these rivets will fail and immediately the flange becomes separated from the web: In almost the same manner when the induced bond stresses are very large the bars get separated from the ooncrete or let os say the bond between the concrete and the steel is
fct£WENt$ 6F
concrete
961
broken and this will result in the load of the beam to be resisted only by the concrete. The beam will thus fail by tension even though sufhcieat amount of steel from bending moment considerations has been provided. Bond stresses often are not receiving that much good attention which they deserve. While designing particu.arly. beams subjected to heavy loads and footings, bond stresses shall always be determined and shall be compared with the allowable bond stress.
Direct bond
§l92.
In big. 854 (o) is shown a bar short length ; while in Fig. 854 {b)
Fig
embedded inconcerete only shown a bar embedded
is
for a for a
854
obvious that assuming the bars not to fail, it !t is greater length. requires a greater load to pull out the bar in the arrangement of the arrangcbig. 854 ^iS'iUnn what is required to pull out the bar nicf t c-f Fig ^54
m
TIk' m^crojty ef
bond
stress
Load
in the
bars
Contact area of the bar with concrete I
el
tor Icngih oT crr*bcdmcnt
i
BoHii
w hei
“ jr n al d- diameter of bar
r;i|!t d liie average bond luaxiinum 'dress t.
,s
to its
e
st.’"es'‘
i .
stress.
Let the bar be subjected
96S
STRENOTB op llATEltULS Length of embedment*-/^ tjt4o»
M
The
’I.S.
allows a value of Sb =6 kg.Jcm.^
specification
for
ISO grade concrete.
/— 1400
If
fcg./cm.®
Sb =6 kg.fcm.^
and .
dXtAOO
, /=
we have
I-SSd The The following
practice Is thus
...(I)
to provide a
hood length of 58 diameters.
are the factors that give the property of a good
oond between concrete and reinforcement. (a) Sufficient cover for reinforcement. (h) (e)
Richness of concrete. Using twisted bars, welding the stirrup
main bars. id) Roughness of §193.
bars with the
steel.
Local bond
Consider an R.C.
0
beam
®
subjected to a certain loading. Consider two sections l-I and 2-2 distant dx See Fig. 855 Let the bendapart. ing moments at sections 1- 1 and 2-2 .
dIUtinnnnnf l ihhnnnnr
aDmamcm
p
j
be
M
{M+dM)
and
Let the lever
arm
Tension
mentt
at section 1-1 steel
Net force
m
reinforcei
steel
M
and Tension = ^ and >
reinforcement
at
section
Af-f-dM
Fig. 835
.’.
respectively,
distance be a.
in the tension reinforcement in a length
dx -
~ a
length of reinforcement, the bond force between the steel For, and the concrete=(S0) dx Sb where (20 ) is the total perimeter of reinforcement. Equating the force of bond to the net force on the this
tensile reinforcement,
we have, (SO)
dx. Sb=‘
S.F.=S. ...( 2 )
ELEllEHTS OF RBINFORCEO CONCRETE
9^9
This bond stress ioduc.'d due to the rate of change of bending
moment
is
called the heal bond stress.
specification has recommended a safe iOcal 150 mix concrete. 10 kg.lcm.^ for I.S.
M
In designs the Eq.(2)
is
bond
stress
form
in the
of
...(3) aSti
From stress to 10
the
this,
perimeter of bars required to limit the bond
kg.lcmr can be computed.
Hence reinforcement required from bond considerations must be provided though from bending moment considerations no reinforcement may be required Eq. (3) shows that the required perimeter of reinforcement proportional to the shear force. For a simply supported beam, for instance, the bending moment at the support is zero and the shear is
force
maximum. Hence some bars
is
are to be maintained in the bottom such that
the perimeter of bars provided
may be
curta led at such
at least
is
—
The remaining bars
where they are no longer required also be bent up at suitable
piaccs
for bending moment. These bars may places to serse as shear reinforcement.
Eod anchorage eraibedocd embedded
§194.
Bars
cri c
in
arc sometimes
crcte
hooked so as
to have pr? pler anehorage with conciete If bars are the h provided ».r bond ;:np necessary A redu ed. length can hook shalL'.U'ays .onfirm to the specr catior^ -^hown .
in Fig. 856.
The anchorage
.
value of the li ook alone is considered ir*. ]^d yKcve J
In following
A
standard hook.
of the bar.
‘pecificalion
V
has
stated
the
;
Aachci
ot H,
assumed u.* of the bar each 45’ tn.
•nCUru
•'
(a) ir of the roun.
cur\C'
nr
‘
^
ar
'1
-
a -'ad?!''
.
l*c
at
A\fhatever
’
a reinforcing bar may be that of the length quivakni iOameier of the round bar for .
Ti>
.it,
0j
.'fthe
jf the
(h> Ti
of fhe
856.
jiiietcr
r<’'r'ncctJon
tlf
.
!<^;jst
not less than twice the diameter
^-traigbr
four
the angle
assumed anchorage value
he,
timess the diameter of the round
;
which the bar is bent, the not be taken as more than equi-
.itough
sfaouid
bar
970
5rRENGTfe[
valent to a length of bar equal to sixteen
round
MAfER.'Xt^
times the diameters of the
bar.
Bars in tension. In the tensile reinforcement the length measured from any section to the end of the bar plus the equivalent anchorage value of hook shall be such that the average bon^1 stress induced to develop the actual stress at the section shall not exceed the permissible average bond stress. In the case of the tensile reinforcement of circular section, the length measured from such section up to the beginning of the hook shall at least be equal to n times the diameters of the bar minus the anchorage value to the hook,
where In
Actual tensile stress
n
no case
in
the bar
Four times the permissible average bond
shall such value of
stress
n be less than 12.
Bars in compression In this case, the length measured from any section to the end of the bar shall be such that the average bond induced to develop the actual stress at the section shall not exceed 1 ‘25 times the permissible average bond stress. In the case of bars of circular section the length measured from such section shall be at least equal to n times the diameter of the bur where
stress
_ ~
In
Actual compressive stress
in
the bar
Five times the permissible average bond stress
no case the value of n
But when a hook anchorage purposes.
sary,
is
!>e less
provided
than 12. Hooks are unnecesshall not be accounted for
it.
§195. Riiinforccmcnt
Reinforcement used shall coiiiortn to the requirements of 432 specificaiion f(»r MiU stu I owl high ti nslle steel bars aod hard drawn steel wire ff>r concrete, teinfor cement (Revised). The reinforcement shall be free from loose mill scale, loose rust, oil and grease or any such harmful niarter, immediately before placing the The reinforcement sh d! he placed and positioned strictly concrete. following the requirements 196. Bending Bars
shown
in the structural
drawings.
Bending
bars shall be dvnie with great caution. Often this j(^b does no' receive that much attention which it deserves. Bending bars are expected to fulfil certain definite functions and hence bars must be bent so liiat there is good advantage of the worked out design. There are instances of failures of structures for want of correct bending, even tliougbi the designs worked out are
not faulty. §197. The necessity of bending r inforcetnent. Bars are bent under different circumstances, dfiey nuy be bent to form hooks so as as Sometimes bars have to be tent to develop proper anchorage. to form loops as in the case of stirrups as shear reinforcement. Bar^ may also be bent to resist diagonal tension They m3y also be bent up to form necessary ricnforcement for hogging bending moments. The following are the types of bend we normally come across :
h
elements op reinforced concrete (a)
i)71
Hooks
at the end of bars in beams. (b) Bars bent up at ends and hooked in
beams (c)
for resisting
diagonal tension. Bars which serve for positive bending
moment which bent up negative
to
are
(c)
resist
bending
moment. (d)
yr
.
Bars bent to form loops to serve as shear reinforcement.
These
shown
are
c
in
Fig. 857.
The
857
Fifi
code has further recommended the following Splices ID tensile reinforcemeot. Splices at point of niaximurn tensile stress shall be avoided wherever possible splices where used shall be welded, lapped or otherwise fully developed. In any case I.S.^
:
;
the splice shall transfer the entire computed
Lapped
splices in tension shall not
than 36
mm,
diameter, such splices
For contact
stress
from bar to
be used for bars of si/cs shall preferably be welded.
spaced laterally closer than 12- bar than 15 cm or 6 bar diameter^ from edge, the lap shall be increase:! by 20 percent or ch^sely spaced spirals shall enclose tlR* phee for its full
meter or located
Where
bar.
largoi
splices,
dn
close]
.
one half of tlvC bars are spliced witlnn a Icncfli of 40-baJ diameters or where solves ao- made ai p.nnts of tak- n Mich a. auac.ojug ‘r.axMnum stre^. special precaution shah the length of the lap, and'or using spire'v or cio ely spaM ii arour.d. and f
rc than
Splices in compression rtinforcemeat used, the lap lengths shall
conform
Wh.: r<'
Ltpp.
'
i'l;
p-
n.eut»
mste.; of jan;vl Welded splices may be ii'C df diamcR .'•eldWhe'“e bar size exceeds ^6 ably be used. In bars required for e'.rn}'ri:>SM.5. onK ii.e von^nre^stve .stress may he transmitted by bearing 4'^q^.,:rc c.u Kr-if .u concrete contae: by a suitably welded aesc or mechanic il u ?"Mce
eailicr
1
mm
^
^
In column^ where longitudinal bars arc otr^r it a sphee, the slope of the inclined portion of the bar with the axis oMhc c(du/na shall not exceed 1 in 6 and the portions of the bar above and below the offset shall be parallel to the axis of the column. Adequate hori-
zontal support at the offset bends shall be treated as a matter of design, ancl shall be provided by metal ties, spirals or part.s of the Metal ties or spirals so designed shall be placed floor construction
near (not more than eight' bar diameters from) the point of bend.
1
ST«EN<3T«r<5F^AftrtiAts PeriilIgsiMe Stresses im
Steel Reioforcement Permissil^Ie stresses in
kgjcm
•
Type of stress in the steel
ii*= I
s^
8^ •
5g*:
§|5S (/)
Tension
Other than
:
{b)
in
shear retn-
Upto and including 40
mm
i4oo; )
r
Over 40 mm.
130oJ1
Half the gua-
Tension
ment
1900
lOOo
1300
1600
reinforce-
1400
1400
1400
column bars
1300
1300
13C0
in helical reinforce-
in a
1900
raoteed yield stress subject to a maxi-
mum of («)
is*-.
io
(a) helical reinforcement
a column and foi cement.
c,
compression
mem-
ber.
(/«)
Tension in ment.
««iicar
Compression (v)
in
bars in a beam the compressive resistance of the conereie is taken into account
Compression or slab
in
The
calculated compressive
when
stress
w’.
the modular ratio.
Compression in bars in a beam or slab where the compressive resistance of the concrete not taken into account,
Uplo and
including 40
Over 40 mm.
is
mm.
Half the guaranteed yield stress subject to
a
mum Note
/.
Note
2.
When
maxiof 1900
432- (960 is mlid steel c informing to grade II of I.S, used, the perniissible stress shall be reduced by 10 per cent, or tf the design details have already been worked out on the basis of mild steel conforming to Grade 1 LS. : 432-1960, the area of reinforcement shall be increased by 10 per cent of that required of Grade 1 steel. Yield stress of steels for which there is no clearly defined yield point should be taken to be 0*2 per cent of proof stress :
eliments of reinforced concrete
973
The
horizontal thrust to be resisted shall be assumed as li times the horizontal component of the nominal stress in the inclined portion of the bar. Offset bars shall be bent before they are placed in foims.
Joining or Lapping.
not be
than
less
(a)
For bars
in tension
tame cr
ar
h)
in
reinforcement shall
:
times the permissible average
or 30-bar diameters whichever (
lap
actual tensile stress
..
,
The length of
:
For bars
in
compression
stress
is greater,
:
a^al ar
bond
coinpressivc stress
the permissible average bond stress
or 24-bar diameter whichever
is
greater
Minimom spacing of reinforewnent The tnirsimuni horizontal distance between parallel reinforocments shall n<."t be les' than the following :
n>a(i) Diameter of bir when bars arc of the same diameter. meter of the thickest bar when bars of more than one size are used. //i” // {(() Maximum size of coarse aggregate plus 6 mm. 2‘^ mm. A aggregate size be taken as 19 wm., this spacing equals greflttT distunce should be’ providi’d wlwti lomenunt. shall riie vertical distance between two horizontal main bars mm. But this does not apply at a splice or lap be not less than and when such lemforcements are transverse to each other.
All reinforcements shall have a cover of concrete and Coser. the thickness ot such a cover exclusive r>f plaster or other decorative finish, as per IS. code shall be as follows ; At each end of a reinforcing bar not less than 25 mm. bar. such of diameter the twice nor les.s than a column— not less than (b) For longitudinal reinforcement in 40 mm. nor less than the diameter of bar. In the case of columns bars do not of minimum dimensions of 20 cm. or less, whose
(a)
mm.
exceed
mm.
-25 mm. cover may be
used.
beams -not
less
than 25
compressive shear or other reinforcement in a than 13 mm, nor dia. of reinforcement. nor less than 13 mm. (e) For any other reinforcement— not reinforcement. than the diameter of (d)
slab- not less
dia
(c) For longitudinal reinforcement in nor less than diameter of such bar.
§198.
For
tensile,
less
T-beams
Strictly rectangular beams are uncommon in reinforced concrate since the beam carries in almost all cases a slab with which it Hence the structure becomes a slab which is stifTen-d
is
monolithic.
974
STRENGTH OF MATERIALS
by concrete ribs. The slab and the rib due to their monolithic nature form a T-beam. The flange of the T-beam provides the necessary resistance to compression while the vertical rib provides the depth and hence the necessary lever arm. The width of rib must be such as to accommodate the tensde reinforcement.
Fig.
§199.
Width of
flange of
858
a T-beam
A certain portion of the slab on either side of the beam can be considered as forming the compression flange. The width B {see Fig. 858) of the flange which can be considered as acting effectiof the T-beam, the vely with the rib depends upon the span breadth of the rib, the overall thickness of the rib and the spacing of T-beams. If the spporting beam happens to be an end beam, the flange of the beam is present only on one side of the beam and the beam in such a case is called on L-beam. The width of flange of T and L beams may be determined from the following requirements recommended by I.S. 4S6 specification. () For T beams, () For L beams,
~ -{-br+ZiU
B= j
where
/
hr
= effective
span
.
= width of the rib.
It is important to note that the part of the slab considered as the flange of the T-beam can function with the beam only when the flange has adequate reinforcement transverse to the beam and it shall be built integrally with the beam or effectively bonded together with the beam.
In this connection the I.S. code has stated the following
The
flanges'
of the T-beam or L-beam
:
may be
part of a slab or in the same
which is spanning either transverse to the beam direction as the beam. In any case the flange shall have adequate reinforcement transverse to the beam and it shall be built inte^Ily with the beam. However, where the main reinforcement of a slab, which is considered as the flange of the T-beam or L-beam is pai^lel to the beam, transverse reinforcement extending to the length indi-
elements of reinforced concrete
Fig.
caied in Fig.
975
859
859 shall be provided near the top surface of the
slab.
quantity of such reinforcement is not specifically determined by calculation, it shall be not less than 60 percent of the main reinforcement'in the centre of the span of the slab constituting the flange. If the
Depth of Rib. This is deteruiined by the effective depth of the beam. The effective depth ol a 1 or L beam is the distance between the top compression edge and fhe centre of the tensile reinforcement. In preliminary computations the depth can be taken as yj of the span for medium and to span for heavy loads, xj tf’
A
for light loads.
Some
designers follow the
A
following specifications,
viz.
The ratio of efft -live sran to overall depth cf a not exceed the following Simply supported beams 20
beam
shall
:
25
Continuous beams Cantilever
§200
Width of
beams
:
10
rib
This shall be such as to accommodate the necessary tensile reinforcement. The width shall also be such as to prevent lateral instability. This width is generally b^ween J and f of the depth of
STRENGTH OF MATERIALS
976
More often architectural requirements fix the width which be the same as the width of the supporting column.
the rib. shall
Neutral axis of a T-beam
§201
The depth of the moments of areas on
neutral axis can be determined either side of the neutral axis.
by equating Three cases
arise, viz. (i)
(fO (Hi)
The The The
Case
neutral axis
neutral axis neutral axis
may be situired within the flange. may be just at the bottom edge of the slab. may be below the slab.
Neutral axis within the iiange (Fig. 860).
(i).
Such a beam
will be-
rectangular a beam of width B.
have
as
moments
Taking about the N.A.
Case
(ff). In thickness
this
of
case the
slab.
Hence Eq. Case case.
(1)
still hold.-*
Neutral
(Hi).
'sxis
good. below the slab (Fi
This is the usual In this case, taking
861).
-
1
moments about N.A.
We have. Bd,
\
f
.
(."-TT
=mAtid—n)
Wn—
1
ji
Ti
T-
1
'
«)*
2
d
...(2)
In these computa-
# • •
tions it is usual to ignore force in I the compressive of the beam. etherib '
Hence,
it is
usual to discard the term
Fits.
br
861
in
Eq.
(2)
and
hence practically, we have
Bd.[n~
-<3»
on i^uation (2) u to be noted that the above amendment area of the compression The calculations. the made only to simplify Bdt as taken been thus has r-beam It is
elbmbkts of reinforced concrete §202.
977
Lever arm of the T-beam This
is
the
distance
between the line of action of the resultant compression to the line of action of the
j
resultant tension.
Let the maximum compressive stress in concrete be c kg^lcm.^ Let the compres-
bottom edge of
The
the flange be c kg,lcm
-
sive stress in concrete
centre of gravity of the resultant compression
is
at the
situated
depth from the compression edge j) is the ; actual depth of centroid of the pressure trapezium corresponding to the flange ^ at a
(rig. oo2).
c
+2c*
a\
c+c
(4)
3
a^d-y
Lever arm
Substituting in Eq,
(4),
we
have,
n
d»
n—'dB
3
c4-
3n-2ds
^
2n—d»
...(5)
3
Eq. (5) may be found to be more convenient than Eq Moment of Resistance of the beam M.R.^Total compression or total tension x lever arm
id-y) Substituting for
(4).
...( 6 )
c'
c+
n-d$ id-J)
X c Bd,(d-y)
M.R.
M R.
is
also equal to At
.
t(d—})
.(7)
(8)
—
STRENGTH OF MATERIALS
978
Problem 508. An R.C. T-beam with a flange width of 102 cm. has a tension steel of area 22 8 cm*. Taking the modular ratio as 18 and the permissible stresses in concrete and steel as 50 kg. /cm." and 1440 kg /cm.^ determine the moment of resistance of the beam. The thickness of the flange is 13 cm. and the effective depth of the beam is 51 cm. Solution.
At^22'B cm.^ Taking moments about the neutral
axis
and assuming it to be situated below the slab.
We Fig. 963
have,
102xl3(n-6-5) -18x22 8(^!-n) n — 17 cm.
Since this value of « is greater than the thickness of tlie slab our assumption that the neutral axis is below the slab is correct.
Depth of
by
critical neutral axis is given
18X50 _ 51
-n.
n.=19‘9 cm. Since
«<«<
steel attains the
maximum
stress earlier.
Distance of C.G. of the total compression from the top edge -
3/1
2d»
~ d$
2n-^
'
3x17-2x13 2x17-13
J3
5‘
1
3
6 cm.
or alternatively.
But
c+2c'
d.
^
c+c
3
c
n—di n
17-13
_£
17
17
-0-235C
C+2X0-235C
y
C+0-235C
^
1-47
1235 =5’ 16 cm.
13
3‘ cm.
c
J
S
kllments or reinforced concrete
979
arm—
Lever
— 51 — 5*16
cm.
-45*84 cm. t(d-y)
= 22 8 X 1400 X 45*84 k^. ^ L463,000 kg. Problem 509.
4
cm.
cm.
T~hcam ha^ a flange width of 120 cm
,
the
The reinforcement cami^^U f ^ if :/ li an cf\^ctlvc depth of 40 em sirt mo: iiko'oci-'T if iKi '0 fe itn,! s\(i shaVi not exceed 50 kg.cm^ and I 4 A-q U'm.'^ .»? coth respi C’i^ e!" find the oioment of reds tance of the beam satooi. Modufarjec tliii'knc\:,
i
lar raU-^>
J5r.
Solution \
Assuming p'.enis iibout
is
ih
the N
]2n
I
SuKc
/r
22*62
IS
i{//
f/
22 62 cm.^
i
the neutral axis have, -t ,
is
tf
below
nuv
of neutral
axis
(50— /i)
li!5’S7 cm. oar J^^ampl!on about the
»
taking
the sluK
p«>sition
coriect
Depth
r*rrr’t»‘:al
neutral axis
is
given by
I
4»»
t-iOO
n
Since n
--
Hr
I5'6^ cm.
steel will attain
the
2n-~2d^ 2n - d
,
^
..
^ 3
maximum
stress earlier
d 3
13 87-2x10 2x 13 87-10
v'
cm.
«=4 06 cm.
d—
Lever arm .*.
40 —4*06 --35*94 cm.
Ait(d-y)
M.R. -
22 62X1 400 X 35*94 kg, cm. / 139000 kg. cm.
Prohiem 510. The breadth and thickness of the Jlange of a T-bcam are I hQ cm. and 15 cm respectively* Steel reinf orcement of area 4 5 24 cm d pro'.ideJ at an effective depth of 70 cm. If the modular ratio equal find the stresses in concrete and steel if the moment of resistance of the beam section is 32fl00 kgm. *
y
980
STRENGTH OF MATERIALS Solution.
moments about
Assuming the N.A. we have,
to be below the flange,
takin?
the N.A.
170 X 15
(n-r5)=18x45'24 (70-n) n=22'€3cm. 3 >t~ 2«
m
dt •
T
_ 2 x 22-63 -2X15 2 x 22-63-15
15 '
3
=6-26 cm. Lever arm
=W-^)=70- 6-26 =63
M.R.
=/l« r(rf-^)=32000xl00
=45-24xtx63 =32000X100 32000X100 x‘ 6374
"’45'24
74 cm.
74
kg.lcm.^
^1,110 kg.jcm^. Stress in concrete
given by
is
I8xc_ illb
22 63
70-22
63
C’^29'45 kg. /cm
®
Axially Loaded ColumiH
:^203.
A column forms a very important component of a structure Columns support beams which in tu'-n support walls and slabs. It should not be forgotten that the failure of a column results in the The design of a column should therefore collapse of the structure. receive importance
4xially loaded colanns. An axially loaded column s line of thrust of the load supported by the column coincides with the longitudinal axis of the column. §204.
one in which the
Plain concrete columos. Columns whose unsupported do not exceed four times the least lateral dimension may be made of plain concrete Further the load should be axialh applied. Columns of greater lengths should be adequately rein-
§205
lengths
forced. §206. R.C. colnmns. Columns may be cast to any of the cic following shapes— square, circular, hexagonal, octagonal, Longitudinal reinforcement (or main steel) is provided to resist comAs per I. S. 456— a reinpressive loads along with with concrete. forced concrete column shall have longitudinal steel reinforcement and the cross-sectional area of such reinforcement shall be not less
elements of reinforced concrete
981
than 0'8% nor more than 6% of the cross-sectional area of the column required to transmit all the loading. The object of stipulating a minimum percentage of steel is to make provision to prevent buckling of the column due to an accidental eccentriciiy of The object of stipulating a maximum percentage of the load on it. sled is to provide reinforcement within such a limit to avoid reinforcements congestion of ulr'ch would make it very difficult to place the concrete and This may be consolidate it. best jeali/cd from the following Consider two tv\o examples. columns 45 cm. X45 cm.
A'Miu-
10-32/Mm
A-O
Reinforcement required at 0*8% of gross
x 45-
-16*2 This may be provided by four bars of 24 mi area of 18' 10 cm.^ [Fig. 864 fn)).
Reinforcement required
at
6%
.,
an.‘-
diameter with an
x 45-
of the gross
-12 15
ctrfi.
the bigger diameter bars be selected, say 32 mm. dianu ler bats, we will require 16 har.s of 32 mm, diameter providing a total area of 8‘04x 16-* 128 64 cm,^ |Fig. 864 (/;)]. The difficulty of placing concrete between the 16 bars of 32 mm, diameter with the Practically overall size of 45 cm x 45 cm. may be quite apparent. the maximum percentage of steel may be limited to 4 per cent of the gross area so as to ensure a good and sound concrete.
Hven
1
2,
if
ll the ratio of the length to least radius of gyration is less than the requirement regaiding minimum amount of steel will not
ajiply.
The longitqdmal reinforement should
be
laterally
tied
by
transver e links to provide a restraint against outward buckling of each of the longittidinal bars. I S. 456 code stipulates that the dictiiieier of longitudinal bars shall not be less than 12 mm. and that the diameter of the transverse reinforcement shall be not less than one fourth of the diameter of the main rods and in no case less than 5 mm. in diameter.
In the case of pedestals and columns in which the longitudinal reinforcement is ignored for purposes of calculating the permissible loid on the column the longitudinal reinforcement shall not be less tluui 0*15% of the gross area of the column section. least
§207. Spacing of transverse of the following
links.
This shall not exceed the
:
(a)
The
least lateral
dimension of the columns.
STRI
982
NOTH OF MA«RIals
Sixteen times the diameter of the smallest longitudinal rod in the column.
(/>)
re inforcing
Forty-eight times the diameter of the transverse reinforce-
(c)
ment. Cover. The minimum cover to a column reinforcement or diameter of bar whichever is greater.
^208.
equals 40
mm.
Effective length of
§209.
not necessarily
its
a colnmn.
The
actual length.
column is of fixity of the ends of the columns.
It
clTective length
of a
depends on the degree
The following (able (page 983) to the actual length i (corresponding gives the which refers to the length of the column from floor to floor or between properly restrained supports). This table is in accordance with I.S. 456 code. effective lengths
Safe loads on R.C. columns.
§210.
A
column will be considered as a short column eftl M«""« least lateral dimension does ratio of effective length to its 12*. not exceed Short
when the §211.
Permissible load on a column
Reinforced concrete columns
methods
method based on
(i)
1-S.
(ii)
(i)
may be
designed by the following
•
code method.
Method based on the Let
A be
the elastic theory.
elastic theory
the overall area of the
column
section.
be Ac and Let the area of compressive reinforcement m. be ratio modular be Let the compressive stress in concrete
let
the
c.
the reinforcement and the Since there is no slipping between Hence to satisfy steel are equal. concrete, strains in conciete and this
condition Stress in steel
= modular ratio x stress in /•=
concrete
me
Let IF be the load on the column. Load on concrete -I- load on steel = W.
c{A
— Ac)=‘Ac mc=IV
regarded •For mote exact computations a column can be least radius of gyration doe column when^the ratio of the effective length to its oot exceed 50,
t
LfcMENTvS
OF RErNFORCED COKCRETfi
983
Degree of end restraint of compression member
Theoretical value of
Recommended value of
effective
effective
length
length
EfTectively >^e)d in position a<^d
rotation at both
(/ e.
restrained
against
both ends are fixed)
ElTectively held position at both ends, restrained agriinst rotation at one end (i.e. fixed at one end and hinged at the other end)
EiT.’ctively held in position at
restra
ned against rotation
both (i e.,
0*5 /
0’65
0*7 /
0*80/
100/
100
I
1
end#, but not both ends are
/
hinged.
ElTectively held in position and restrained against rotation at one end, and at the other partially restrained against rotation but not held In position
1*50
EtTectively held in posit on at one end but not rcS' trained against rotation, and at the other end restrained against rotation but not held in position
and restrained against rotation at one end but not held in position nor lestra ned against rotation at the other end, i.e., fixed jt one end and free at the other end
2001
Tool
2*00
2'00
F^^’cctively held in position
ColamM
Safe Compressive Stress ia Concre te in SJ.
Grade of concrete
M.K,S,
UNITS
Grade of Concrete
Safe stress in
Compression
NImm*,
M M
10
2*5
15
4*0
M 20 M 25 M 30
5-0
M
/
/
/
(IS 456)
UNITS Safe stress in
Compression kg.Jcm}
M 100 M 150
40
M200
50
M250
60
25
1
60
!
8*0
3'"
90
M 40
10 0
'
M300
80
M350
90
M4r^
100
STRENGTH OF MATERIALS
984
On this theory taking c at 40 kg.lcm.^ (or the stipulated stress) the safe load on the column section can be determined. Until recently columns were designed on the elastic theory. (ii) I.S.
code method
The
safe load
on a short column
area of
^
"1
Lconcrete J
y
[safe stress
“I
is ,
j
given by,
f area
safe stres
of"! [
L
J
I
Safe compressive stress in concrete shall be taken as follows
Safe compressive stress in mild (1300 kg./cm^).
steel
bars
is
1 J
:
equal to 130 'H/mm-
Problem 511- An R.C. column 30 cm. ><30 cm. in section Is reinforced with H bars.of 20 mm. diameter. Jf the permissible stress in concrete is 40 kg.lcm.* find the safe compressive load by simple elastic
theory.
Take
18.
Solution.
Area of column=i4=30x30'=900 cm.*
Area of steel
=/4(=8 x
^ (2)*=25i2 cm.*
Equivalent concrete area=y4« = /l-l-(m— 1) Ai
=900-|-(18-l) 25 12-=1327 04 cm
*
Equivalent 1 Safeload-r^^^"®^''®®1xr Un concrete J L concrete areaj
=40x1327 04 =53082
kg.
kg.
Problem 512. (S.I.) A short column 30 cm.xJO cm. in section reinforced with 8 bars of 22 cm. diameter. Find the safe load on = 18 Safe -stress in the column by simple elastic theory. Take concrete is 4Njmm^. is
m
Solution.
Area of the column
=A=30x30=900cm.2 Area of
steel
=.4(=8x-^
(2'2)*=30 4
cm
Equivalent concrete area
=At=A-\-(.m — l)i4(
= 900-f(18-l)30-4cm.* -1416-8 cm.^ Safe stress in concrete
—4 7V/mm.*=400 N!cm *
*
elements of reinforced concrete
985
1
Equivalent Safe load=r^“‘'" Lm CimcreieJ Leo:. Crete areaj = 400 X 1416*8 New'ton.s - - S66 7 Jo A V u /ons 72 Kih>riewtoiiS. to
"|
Problem 513. A short cohnin of Minute seaii^n is to he do^ii^ncd carry an axial load of l,02JOO ky. Design tin column by LS. code
method. Solution.
assume
ct us
1
Hence and
Cl
A/ Is
liuit
=-4t)
c
= 1300
/.
Area of
/.
Area
2®;.
-
o( concrete-'^
used.
he A
t/n
*-
as steel reinforcement,
~
— (^02.4
>4
cm
*"
concrete ai\ a x safe si^'ss in concrete ^^eel area xsafe stress in steel
Saf J load
/.
0‘02 i cn,
0*98.4
'
»iii
colunm
of area
steel
is
kg./i
Let the sectional aiea of the colu Let us assume
gratle concrete
)
-
ko.lcm
'
40-P^ ‘'2v4x 1300
0’98.4
<='
dfd.OOO h e 13*2.300
1
6^
2.4 .f
Hence pre
~ V''
cohirr-n
Size
nie
Area of the 40(1600
m
>10
cmJ
-
r>
3'i
(rnr
coiufn!» section-
.4
62 cm,
<4ii co)
t
)
-I3)2,3{'0
I26(M.-3830{» ir--3(r4
Provide 8 bars of 2
2
mm
d:ainetcr (30’41 cmc^).
Lateral less
ties.
Diameter to be not
than (/) \il)
5 inn I
One-fourth
main IjcX us,
diameter
steel
of diameter of x 22 = 5*5 mm.
therefore, provide
6
tics.
Fig. 865
This shall not exceed the following =-40 cm. (0 Least lateral dimension of main bar--* 12x22 — 26 4 cm. («) 12 tiroes the diameter of transverse steel iiii) 48 times the diameter ss48x6 288 m/M.— 28 8 c/m. Spacing.
:
mm.
:
STRENGTH OP MATERIALS
986
mm.
Let US, therefore, provide 6 [See Fig. 865].
diameter
26 cm. centres
lies at
Long columns. When the ratio of effective length of a §212. to its least lateral dimension exceeds 12 the column will be regarded as a long column. Such columns are liable to be buckled column
and to include this factor in the design the working stresses in concrete and steel are taken at a lower valu^*, by giultiplying the usual working stresses by a co*efficient Cr called a reduction co-efficient. Hence for a long column Safe stress in concrete— Cr corresponding safe stress tor short column and safe stress in steel— Cr corresponding safe stress for short column The co-eflBcient Cr is to be determined from the following relation
Cr-i 25-
Ut
486
For more exact computations Cr —
[
where Cf=*reduction co
f25—
lef
160 A'm
]
efficient
/«/=effective length of the
column
6 —least lateral dimension iTm—least radius of gyration.
Values of Cr for various values of
are given in the following
b
table /
let
lef
Cr
b
b
-
/«/
Cr
T
Cr
0-250
;
12
rooo
24
0 750
36
0*500
48
13
0979
25
0 729
37
0479
49
0*229 1
14
0 958
26
0*708
38
0-458
15
0 937
27
0 688
39
(
50
0
2('8
I
0188
51
*438
1
16
0-917
17
0895
1
28
0*667
40
0417
29
0'646
41
0*396
0lb7
52
0-146
53 j
;
0875
18
30
0-625
42
0 375
!
0-854
19
31
0 604
0*354
43 j
20
:
0833
32
I
54
0-125 1
0-104
55 1
1
0083
44
0 333
56
45
0313
57
0*063
i
1
46
0*292
58
0-042
0*271
59
0-583
'
j
0
21
22 i
8! 3
33
0-563
0*792
34
0-542
I
i
!
0 771
23
35
0-521
;
47
:
0021
:
;
1 !
1
elements of reinforced concrete
987
Problem 514- A column 38 cm. x 38 cm. X 8 metrc.='38 cm. Solution /«/=length of column lef
b
=btX) cm.
800 -2105. 38
This is greater than Reduction co-cfl5cient
12.
Therefore, the column
0 = 1‘25-
is
a long column.
If 48f>
800
= 1-25 48X38
0-811
x Safe load on the long column -Reduction co-ellickiit safe load on short column.
•
Let the area of reinforcement be .'.
:.
4-
cm.-
(1444— /!,) cm.Area of concrete=38x38 — Safeload=0-811 [40(1444-.40-! 1300x,4,] -80.000 kg. /lc=--33‘2
This
is
between 0
8%
cm-
and
6’,-;
of
area
tlic
»>r
the
column
section.
8 bars of 24
mm. diameter
will
provide
3',
19 cm.-
provide. 1 as in the previous cxai iple. Lateral ties shall also be structures, a Continuous columns. Ofic i in inultistoried *213 a lloor uom o te storey to another. Iti through up continues column inu>t be first continued up the mmn bars of the column of the floor been, ,einf™ce,nen„ the outsid. bars continue up frames into this column. When the width it is necessary that the beam, the of reinScement tfil^he the width ol the than more 8 cm least at be the Column should may be smaller above SoiLtimes the column si/e iti pltin u beam. column ® In such cases the main bars of the HpIow it floor.lcvcl, or alternatively these the at inwards Will Imve to be bent ami separate lap „*,.0Ded iust below the iloor level connecting the part of the column above for 'provided^ b!fi? may Es and below the floor. show two alternative arrangements. Figs. 866 (fl) and (6) These are circular columns, Spirally reinforced column S2I4 uniformly spaced spiral and closely with are reinforced Columns of circular longitudinal steel. to addition in reSfSrccment separate loops Sometimes reinforced. spirally are usuallv The continuous spiral in place of the spiral.
mam
mS
alw be provWed
988 is
STRENGTH OF MATERIALS
adopted in preference to separate loops. A column with helical shall have aticast six bars as longitudinal re-
reinforcen cm inforcement.
()
C'olumn reinforcement taken within the main bars of the beam.
(h)
Fig. 866
Column reinforcement taken outside the mam bars of the beam.
The safe load on a spirally reinforced column is given by the following expression
P — (’/lk + Cly4( + 2^^.49 P Safe load on the column
where
J;
-
The
cross-sectional area of concrete
column core excluding the area of longitudinal reinforcement (For core diameter sec Fig. 867). in the
/f
~ The equivalent (vclumc of helical
re-
inforcement area of helical reinforcement per unit length of the column).
A —The
cross-sectional area of longitudinal steel in compression.
/.
= The
permissible stress in helical
re-
inforcement and Ci^ the permissible compresThe sum of the terms cAk and ItoAh sive stress for column bars. shall not exceed 0*5 FcA where Fc is the ultimate cube strength of d from the work tests. The permissible tensile the concrete reqj stress in the helical reinfoicement may be taken at 1000 kg-jem^. .
Problem 515. A column of circular section is 326 mm in diameter rein forced with 6 bars of 22 mm. diameter as longitudinal steel and helicallv reinforced with 6 mm. diameter bars at a pitch of 6 cm. Find the safe load on the column. Adopt c=40 kg.jcm.^^ ci^lSOO
and
is
kg./cm^ and
U^IOOO
kg./cm.^
Solution. Diameter of colomn—326 mm. = 32*6 cm Allowing 40 mm. cover to longitudinal steel, the diameter of the corc^
32*6-2 X 4=24*6 cm.
elements of reinforced concrete
989
Safe load on the column
P=cAk-\-ciAi'+2tbAi>
Ab — Volume of the spiral per cm run of the column length of the spiral per c/w. run of the column x area t'flielical reinforcement.
"
Length of the
spiral
per pl:ch lencth '
Pitch"
,
,
,
xare.i of hciic.jl
reinforcement
Length of the
=
spiral per pitch length
diameter of centre line of
iielical
reinforcement
=icX(24’6+0'6)— 79'i8 cm.
Ab= Adopting
c~40
79- 18
X0
28
— 3 '70
cm."
6 ri -I30()
kg.lcm.^,
kg.jcm."
mA
22-81 j4-
l.-^ou
1000
kg.lcm’K
Safe load
X 22-81
-I
lOOOX
V7(!
A.;
=55780 kg =55*78 •.
tonnes.
Combined Bending and Direct
218.
Stresses
Often we come across members .subjc.^ted to direct stresses accompanied by bending stresses. A very cu.mmon example is that of a column subjected to an eccentric load or a column of a storeyed Other instances arc in arehes, tank walls, chimneys, building. In some cases the direct stress may be predomisilos, bins, etc. nant and the bending stresses may be small. While in some cases the beading stresses may be predominant as compared woh the direct stresses. There will also be instances in which both types of Let us discuss the case that we stresses may be predominant. usually
come
across.
the section is subjected to an axial load and a moment, of moment to the load is called the eccentricity and such a section can be analysed as though the load has been applied it the above eccentricity.
When
the
ratio
Case fending.
1.
Rectangular section subjected to compression and
Eccentricity
is
less
than
.
See Fig. 868.
990
STRENGTH OF MATERIALS
y
In this case the resultant stresses in concrete will remain compressive and the resultant stresses are given by
\
‘
•
•
1
“"r*
where
;
p,
L
X--
_ P
_
Z
Ioad=P.e.
»
-X
M
Eccentric load due to eccentric
i
1
,
1
Z=Section
i
modulus
about
J
axis with ccccptric.
the
•
•
is
repect to which
*
the load
Equivalent concrete
j »
for the section shown
V
in
symmetrical reinforcement
Fig. 868
the equivalent area of section 4
are.t
the iigure
we
ha’ c
hD^-(m-\)At
.
U d area of reinforcement. At the axis Equivalent moment of inertia about ' r- ^ ^
w'i,ere
XX
hD^
.
i? "
})
"2
The
resultant stresses arc J‘
-
P.e /
D
\
\ 2 ) The following examples illustrate the above case. Problem 516. A rectangular reinforced concrete section 70 cm, deep and 45 cm. wide is rcinfonrd with? bars of 28 mm. diameter ffom the top edge and seven simiplace I at an effective coxcr of ^ 4.
le
Determine lar bars at the same vjjn the eeAt r from the bottom edge. applied at a ai.^ which he can aeiuen^ the the maximum thrust on tanceof JO cm from Hu antii line if thejcompressive stress in concrete is not to exceed 5(f Solution.
6
kg
Take m-^18.
,‘cm
e=10 cm. ==^--11*67 rm 6
D 6 Total area of steel provided — 2 X 43* 1 *= 86*2 cm,^ Equivalent area of concrete for the given section .4 — bD^rim —])A< =-45x701(181*
= 4615*4 m2 mrurent Equivalent I
Inertia axis
about
the
eontio?
of '
d
XX Fig.
869
elements of reinforced CONCRErt
991
+(m— 1) A '
13
'
^
45 \ 703
17 XS( (35— 5)^2^ + 17x86-2
t7M.«
- 2 605,110 c/itj ,
Maximum
compressive
stress in concrete
P
_
Af
,
A,
P.KlO 2605110 2
4615'-4
P-^I4.\m
kg.
Problem 517. The horizontal thrust for a two- hinged arch is kg. The crown section of the arch is a square of found to he II 30 cm. side. It is reinforced with h‘03 r/?*.**^ of steel above the centrathe axis. The centres idal axis and equal amount of steel below 5 cm. from the upper and lower edges of respectively are steel of the crown section. The section i.s also .subjected to a bending moment in tenof lOOflOO kg. cm. Assuming that the concrete does not fail compressive stresses in con.sion, calculate the maximum tvn.dle and section. Find also the tensile and compressive crete at the crown stresses in steel.
Solotion.
r .
T5i:m I
Take
m = 18.
Equivalent concri*te area of the arch section
^ ^
—
r
^
1
'^0x30-1 (18- 1)X2X6*03 cm.‘^ 1105 Equivalent moment of Inertia A*
*1
ij
^
30x303
,
I
j
(18- 1)2x603
- 88000 cm.* Extreme stresses in concrete IIOOO 1105
Fig. 870
=9-95+17 05
Maximum
strc.s.v
-
=27
xl5 kg./cm\
in concrete
05 kg.lcm.^
kg.jcm.^
tensile stress in concrete = 17 05 9 95 -
Compressive
88000
kg.lcm.-
compressive
= 9 95 + 17 Maximum
100,000
^
-
-
= 7-70 kg.fcm.^
stress in steel
=-18[
=
9.95+
\l
383-76 kg. lent >
xWOsJax/
r STRENGTH OP MATERIALS
992 Tensile stress in steel -18
1
[
!^-
x 17‘05 -9'95
j
15
kg.lcmr
~-25'6 kgJcm.^
Problem. 518. An R.C. column 30 cm x 30 cm. is reinforced four bars of 26 mm. diameter placed at an effective cover of 5 cm. Find how far from the centres the line of thrun may pass along V'ith
the
YY axis without causing mm.
diameter
h-
=2124 cm Let the
maximum
I"
eccentricity be e cm.
/
--
^O.crr.
n
.
e
focm
Equivalent concrete
cm
—cm •3
»
1
(See Fig. 871)
area
Take m—I8.
V
Area of 4
Sointion.
bars of 26
tension in concrete.
•
-
10
-
i---
=30x30+118-1)
1
tocm
!
21-24 cm.2
1
ti
=1261 cm.®
sent
moment
Equivalent
I
of
Inertia
“
Y
30X30®
Fig. 871
12
+(18-1)
21-24
X
10* cm.-*
= 103600 cm.* If tension in concrete should be avoided the direct should be equal for the section.
and bending
stresses
Let
P
be the applied load
P
P.e
30
1261~ 103f>06’^ 2 e—5'4S cm. Problem 519. A two-hinged arched rib has a section 30 cm. with wide and 90 cm. deep, at the crown. The section is reinforced reinforcement six bars of 22 mm. diameter at the top and an equal The reinforcements are placed at an effective cover at the bottom. thrust on the of 5 cm from the respective edges. If the resultant section line
is
100,000 kg. inclined at 3‘ with the tangent to the arch centre the vertical axis and 10 cm. from the centre line of
and acting on
the top the section, determine the stresses in concrete and steel at bottom of the section ; modular ratio may be taken as 15. Sointion.
See Fig. 872.
and
eLBMENTS OF RBINFORCBD CONCRETE
V
993
Since c=10 cms- which is less than the stresses will remain compressive. Thrust norma! to the cro$s*section 100,000 cos 3*
^65Q'55 kg.jcm.^ compressive in steel top and 238*9'^ ky. ^emr compressive steel at
at in
bottom.
When tbe eccentricity is so large that excesivc tensile stress^ arc developed, hi this case the ctiTicrete on the tension zone is axis found from ficst Ignored and tthe position of the neutral principles.
Fig.
873
mBNQTH W MATBMAiS
994
Fig. 873 shows the section of an R.C. membor sotyected to an eccentric load. The stress at a point is proportional to its dittanoe from the neutral axis. Let the stress at any point be given by c’^ry where ^=distance of the point from the neutral axis r=>a co-efficient of proportionality and
Total compression— Total tension'— Thrust on the section
] b dy ry-|-(m— 1) Atr(n—d0)—mAt rid—n)'‘“P
P=r [yV(«-l) Adii-dc)-m
At(d-n)
Moment of resistance— bending moment
Similarly,
Total moment of the induced compressive and tensile stresses about the neutral axis
or
bn
]
.
—
y
1)
1
V— bending moment,
J
Aerin—dey^-^mAtr(.d—-n)^=^Pe^
+(m—
»)*
J
htfi
Pe **
y+(»w— !)./<»(«—
P~~hn^
y But
'
-l-(m— i)Ae(n—d0)—mAt(d—ni)
e»=e-f«—
D 2
~ +(m—l)Ae(n—dti)*+mAt(d—a)^
^ +(m—
l)Ae(n—dc)
—mAt(d—n)
Hence, for a given pmition of the eccentric load the depth [of neutral axis can be determined from the above relation. 52fl. The haunch section of a bowstring girder bridge a bending moment of l,93i,500 kg. cm. and a norma! The section is 40 cm. wide and 80 cm. deepthrust of H 1,260 kg. Bght ims of 18 mm. dia. are provided at the top and an equal reinfbrcement at the bottom. The reinforcements are placed dt at ^ective cover of 6 cm. from the respeoive edges. Determine tin mnxbnum stress in concrete and steel. The modular ratio may be
Problem
it subjected to
gBmas
15.
=
BLEMBNTS op RBINF(MICED CX>NCRETB Solntkm.
995
Ao^At=m20'36 cm.‘
•
b- 40
cm
•
See Fig.874. Eccentricity from the centre of the section
M ~ 1,93,15.000 cm. P
81260
=23*77 cm
The eccentricity is considerably large to produce tensile stresses. is
given by Fig.
un btfi
D
2
.
~T
80
23
^
+(w
40/1^ .
874
g
.
~3'^^'"~^U^n-dt)^+mAt(d-n)^ l)Ae{n—de)--‘mAi(d—n)
+l4x20*36(»-6)a+15 x 20*36(74-»)*
=4o„T 2
Simplifying,
we
+14x20*36(w-6)-15x20*36(74-n)
get
ii*-48*69«®+2209 05»- 193212*471 or
48 •69n+2209
Solving by
and
trial
error,
0:>]
-0 19321 2' 471
we have
When n=63 «-62 b-627
LWS- 195966*54
11-62*6
1^5-192796*73
»=62*66
L/fS- 193269
b-62652
2ri7S= 193206 24
188 124*74
193593*77
b=62*653 Taking moments about the
«.i( 74-A]
13
L/fS- 193213*71 tensile steel.
+(15-l)x20*i6'”-~)cx68 1
-81260 X (34+23*77) .*.
20 X 62*653
||
-81260 x
57*77
66557*5c+17526*5c=46,94,390 2
e=S5'83 kg.lcm.*
;
STRENGTH OP MATERIALS
Conesponding
stress in tensile steel is given
15x55-83 t
by
62653 “74-62-653 .
— —
P
15x55 83x11-347
,
,
9
-a-653
r=/J/.7 kg.lcm*
Enn^es 00
C!bapter 19
The cros«s-«ection of a singly reinforced concrete beam is 1. 30 cms. wide and 50 cm deep to the centre of the tension reinforcement wblcS consists of four bars of 1 6 mm diameter. If the stresses in coircrete and steel are not to exceed 50 kg I cm.* and 14('0 kg Icm.^ respectively, determine the moment of resistance of the beam. Take (497,-00 kg. cm.)
in- 18.
A reinforced concrete beam 30 cm. wide by 60 cm. total 2. depth has a span of 8 metre.
in addition to its
own
Concrete cover below the
weight.
steel centre
= 4 cm.
Weight of the beam
*2400 kg./metre*
Permissible stress in concrete
=50 kg.jcm.*
Permissible stress in steel
“1400 kg.fcm.*
Modular
=18 (12-94
ratio
cm.'’^)
3. A singly reinforced beam is 20 cm. wide and 40 cm. deep to the centre of tension reinforcement which consists of four bars of 16 mm. diameter. If the stresses in concrete and steel are not to exceed 50 kg Icm.* and 1400 kg.jcrr^i find the moment of resistance (325.600 kg. cm.) of the beam. Take m=18.
The moment of resistance of a rectangular concrete beam 4. of breadth b cm. and effective depth d cm. is 9T5 bd*. If the stresses and steel shall not exceed 50 kg /cm ^ and the modular ratio equals 18 find the ratio of the depth of neutral axis from the outside compression fibres to the effective depth of a beam and the ratio of the area of The heam is the tensile steel to the effective area of the beam (0 427 O OOoA’-O reinforced for tension only in the outside fibre of concrete
and 1400 kg Jem.*
5.
respectively
Find the percentage of tension reinforcement necessary
for |
u
singly reinforced balai ced rectangular section if the permissible stresses in concrete and steel are c and t kg.jcm.* respectively and tbe
modular
ratio is
m
ELfiMBNTS OF REINFORCED CONCRETE
997
6. The section of a singly reinforced concrete beam is subjected a sagging bending moment of 20,000 kg m. If the stresses in concrete and steel are not to exceed 50 kg.jcm.^ and 1400 kg.lcm,^ The width of the respectively, find the dimensions of the beam. Take m = 18. beam may be made | the effective depth.
to
(51 cm.
x68 cm.
effective)
A
simply supported slab is subjected to a bending moment 7. of 850 kg. m. per metre width. If the stresses in concrete and steel are not to exceed 50 kgjcrn.^ and 1400 kg Icm.^, find the effective, Take, m « 18. depth required and the area of steel
cm
(10
.
;
6 98 cm.^ per metre width)
A
simply supported rectangular concrete beam is reinforced 8. tension only. The beam is subjected to a beading moment of If the beam is 30 cm. wide and the stresses in con918,000 kg. cm. ^ rescrete and steel are not to exceed 5 kg.jcm.^ and 1400 kg. lent of steel. pectively, find the effective depth and the area for
)
(60 cm.
;
12‘5S cm.^)
9. A doubly reinforced rectangular concrete beam is 30 cm. wide and 50 cm. deep to the centre of tension steel. It is reinforced with four bars of 20 mm. diameter as comoressive steel at an effective cover of 4 cm and with four bars of 24 mm diameter as tensile steel.
If the stresses in concrete and steel shall not exceeed 50 kg lcm.^ and 1400 kg.jcm.^ respectively, fina the moment of resistance of the
section.
Take
m=
1
(lj)53,200 kg. cm,)
8
A
doubly reinforced concrete beam is 24 cm. wide and 55 10. cm. deep to the centre of tensile reinforcement. The areas of comThe centre of the compression and tension steel are 15 rm.* each. 12. from the compression edge. If = 18 and pression steel is 5 cm the section is subjected to a maximum bending moment of 750,000 kg. cm., find the stress in concrete and steel {c^34 kg.lcm.- t^l020 kg.jcm.- ; u==^463'5 kg./cm,^)
m
;
reinforced on both sides is 30 cm. wide steel are 4 cm. from the respective edges. !f the limiting stresses in concrete and steel arc 50 kg./ern.'^ and 1400 kg.: cm - respectively, find the steel areas for a bending 11.
A
rectangular
and 70 cm. deep.
moment of
beam
The centres of
1,300,000 kg. cm.
18. Take (Ac^4'22 cm.^
;
At^l5‘99 cm.^)
An R.C. beam 30 cm. x30 cm. in section is reinforced with four bars of 24 mm. diameter as compression steel and an equal amount as tension steel, the effective cover to the rcinforocraent being 5 cm. The section is subjected to a bending moment of 3500 kg. m. If the modular ratio is IS, find the stresses induced in concrete and 748' 2 kg.lcm.^ ; tc^396'2 kg.jcm^^ steel (c^37 89 kg.lcm.^ ;
SntBKGTH OP MATEXIAU
998 13. is
A doably reinforced beam 30 cm.
reinforced with four bars of 24
and an equal amount as
wide and 64 cm. deep m. diameter as comi^sion steel
tensile steel.
The
are provided at an effective cover of 4 cm.
respective reinforcements
If the stresses in concrete
and steel shall not exceed SO kg.fcm.* and 1400 kg.lem.* respectively and the modular ratio is 18, find the moment of resistance of t^ section.
What would be
14.
the
moment of resistance based on steel beam (1,373,400 kg. cm.
theory?
A pile 30 cm. X 30 cm. in
;
1,419,040 kg. cm.)
section is reinforced with four
mm. diameter, the effective cover to the centre of reinforc^ ment Mng 5 cm The pile section is subjected to a bending moment
bars of 24
of 1600 stresses
If the
ikg. m. while hoisting it. induced in concrete and
(c“47*Jd
ikg./cm*.
modular
ratio is 18, find the
steel. ;
t—1126 kg.jcm .^
:
u=>439ycg.lcm.'^
APPENDIX I TABLE 1 Mttnent
CoefllcieiitB for ContiBnoiis
{Eqnl Span)
Bcmbs
(Dead Loads)
.Af^— Coefficient X total load on span x span
Uniformjy distributed toads O
X-
1ZS
^
0^96 0
X”
0
0
sr
0
ft?
^
Wf
^
0 096
^
0 0 75
0
^
on
^
too
^
tOI
(hlt$
0 0 79
*
0 081
0 107
01J6
JT 0
O
0107
ffS
^ 0099
m
^
0 099 OtfS
€hl07
0 086
^
0 079
^
0 too
"Tk
Point toad at centre points 0 16S
sr
0 203
^
0 203
0175
0’175
ST'
JT JT-
*
0213
Point
om
^
0 174
Oist
^
*
0 210
0-211
*
0 183
0 213
* 0.174
0
* 183
0174
0-160
0 160
*
*
*
hod
q
181
0
191
0 210
"Ik 0 174
0 J8t
^
0
2ft
ot one third points
om *
0139
^
0
139 0.166
0 156
0
tfi
0 f43
O
ttf
Ct42
Of55
^
^
om
^
^
0 /43
0 142 0 114
^
O-tSS
0 fOB
0f43
"Tk
1
lOQO
STEENGTH OF MATHUyO^
TABLE
2
Moment CoefBckots for Contimons Beams (Equal S^pana)
(Lire Loads)
M — Coefficient X total load on span x span
STRENGTH OF
il002
TABLE
MA1BRUU
3 (Contd.)
Fixed end momeRts Mab and Mba and end slope angles 6ab and 6ba KtUKtntraM