SUBJECT: ENGINEERIN G MECHANICS
Transcript of SUBJECT: ENGINEERIN G MECHANICS
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SUBJECT:
ENGINEERIN
G
MECHANICS
FACULTY NAME:
P. RAJENDRA KUMAR,
Assistant Professor
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SYLLABUS
Unit - I
Forces
Unit - II
Friction
Unit - III
Beams & Trusses
Unit - IV
Center of Gravity
Unit - V
Moment of Inertia
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COURSE OBJECTIVE
Explain basic principles describing the equilibrium of system of forces under
static conditions
Discuss various types of friction, laws of friction and analyse body/bodies lying
on rough planes
Understand the assumptions in the analysis of trusses and list the types of trusses.
Distinguish between centroid, centre of mass and centre of gravity
Understand the concept of area moment of inertia and mass moment of inertia
about any axes.
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COURSE OUTCOMES Understand the concept of forces and apply the static equilibrium conditions,
Analyze co-planar and non-coplanar system of forces and apply theconcepts of mechanics to engineering applications.
Analyze the frictional forces to maintain the equilibrium of system.
Determine the axial forces in the members of determinate truss.
Identify the location of center of gravity and moment of inertia of a body byusing principle of moments.
Understand the engineering systems to prepare and demonstrate the modelswith the help of mechanics concept to solve the engineering problems.
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TEXT BOOKS R.K. Bansal, “A Textbook of Engineering Mechanics”, Laxmi
Publications, New Delhi.
R.K.Rajput, “Applied Mechanics”, Laxmi Publications, New Delhi.
Shames and Rao, “Engineering Mechanics”, Pearson Education India,
New Delhi.
R. C. Hibbler, Engineering Mechanics: Principles of Statics and
Dynamics, Pearson Press, 2006.
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STATICS
It deals with equilibrium of bodies under
action of forces (bodies may be either at
rest or move with a constant velocity).
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DYNAMICS
It deals with motion of bodies
(accelerated motion)
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BASIC CONCEPTS
Length (Space)
Time
Mass
Force
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NEWTON’S LAWS
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FORCE SYSTEM
When several forces of different
magnitude and direction act upon a rigid
body, then they are form a System of
Forces,
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Collinear Forces
Concurrent Force
SystemCoplanar Concurrent Force
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Coplanar Non Concurrent
Forces
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UNITS
Basic Units
Derived Units
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DERIVED UNITS
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COMPONENTS OF FORCE
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METHODS
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PARALLELOGRAM LAW
Statement:
It state that “If two forces acting simultaneously on a particle, be
represented in magnitude and direction by two adjacent sides of a
parallelogram then their resultant may be represented in magnitude and
direction by the diagonal of the parallelogram, which passes through their
point of intersection.”
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Let Two Forces P And Q Act At A Point ‘O’ As Shown In Fig .The Force P IsRepresented In Magnitude And Direction By Vector OA, Where As The Force QIs Represented In Magnitude And Direction By Vector OB, Angle Between TwoForce Is ‘α’. The Resultant Is Denoted By Vector OC in Fig. DropPerpendicular From C On OA.
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Conditions:
1. Resultant R is max when the two forces collinear and in the same direction.
i.e., a = 0° Rmax = P + Q
2. Resultant R is min when the two forces collinear but acting in opposite
direction.
i.e., a = 180° Rmin = P– Q
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CONDITIONS:
3. If a = 90°, i.e when the forces act at right angle, then
4. If the two forces are equal i.e., when P = Q
R = 2P.cos(θ/2)
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Two Forces Of 100 N And 150 N Are Acting Simultaneously At A Point. What IsThe Resultant Of These Two Forces, If The Angle Between Them Is 45° ?
Solution: Given F1 = 100N, F2= 150N and θ = 45°
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A 100N Force Which Makes An Angle Of 45º With The Horizontal X-axis Is
To Be Replaced By Two Forces, A Horizontal Force F And A Second Force
Of 75N Magnitude. Find F.
Sol: Here 100N force is resultant of 75N and F Newton forces, Draw a
Parallelogram with Q = 75N and P = F Newton
How to solve ?
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Resolution Of Forces
The process of splitting up the given force into a number of components,
without changing its effect on the body is called resolution of a force. A force is,
generally, resolved along two mutually perpendicular directions.
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It states, “The algebraic sum of the resolved parts of a no. of forces, in a
given direction, is equal to the resolved part of their resultant in the same
direction.”
Principle Of Resolution
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Note : In general, the forces are resolved in the vertical and horizontaldirections.
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The resultant force, of a given system of forces may be found out by
the method of resolution as discussed below:
Let the forces be P1, P2, P3, P4, and P5 acting at ‘o’. Let OX and OY be the two
perpendicular directions. Let the forces make angle α1, α2, α3, α4, and α5 with Ox
respectively. Let R be their resultant and inclined at angle θ with OX.
Resolved part of ‘R’ along OX = Sum of the resolved parts of P1, P2, P3, P4, P5
along OX.
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Note:
1. Some Time There Is Confusion For Finding The Angle Of Resultant (Q), The Value Of The Angle Q Will
Be Very Depending Upon The Value Of Σv And Σ h, For This See The Sign Chart Given Below, First For
Σ h And Second For Σ v.
A. When Σ v Is +Ive, The Resultant Makes An Angle Between 0º And 180º. But When Σ v Is –
Ive, TheResultant Makes An Angle Between 180° And 360°.
B. When Σ h Is +Ive, The Resultant Makes An Angle Between 0º And 90° And 270° To 360°.
But When Σ h Is -Ive, The Resultant Makes An Angle Between 90° And 270°.
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A Force Of 500N Is Acting At A Point Making An Angle Of 60° With The
Horizontal. Determine The Component Of This Force Along X And Y
Direction.
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The component of 500N force in the X and Y
direction is
ΣH = Horizontal Component = 500cos60°
ΣV = Vertical Component = 500sin60°
ΣH = 500cos60°, ΣV = 500sin60° .......ANS
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Sol: In both cases direction of resultant remain unchanged, so we used the
formula,
tanθ = Qsinα/(P + Qcos α)
Case-1: P = 2P, Q = P
tan θ = Psin α /(2P + Pcos α) ...(i)
Case-2: P = 4P, Q = P + 12
tan θ = (P + 12)sin α /(4P + (P + 12)cos α) ...(ii)
Two Forces Equal To 2P And P Act On a Particle. If the First
Force be Doubled and the Second Force Is Increased By 12KN,
The Direction Of Their Resultant Remain Unaltered. Find The
Value Of P.
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Equate both equations:
Psin α /(2P + Pcosα) = (P + 12)sin α /(4P + (P + 12)cos α)
4P2sinα + P2sinα cosα + 12Psinα cosα
= 2P2sinα + 24Psinα + P2sinα cosα + 12Psinα cosα
2P2sinα = 24Psinα
P = 12KN .......ANS
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Magnitude of the resultant force
Resolving forces horizontally,
ΣH = 25 – 20 = 5 kN
and now resolving the forces vertically
Σ V = (–50) + (–35) = – 85 kN
Magnitude of the resultant force
R = (Σ H)2 + (Σ V )2 = (5)2 + (–85)2 = 85.15 kN Ans.
A System of Forces are acting at the corners of a rectangular block as shown
in Fig. Determine the magnitude and direction of the resultant force.
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Direction of the resultant force
Let θ = Angle which the resultant force makes with the horizontal.
We know that
tanθ = ΣV/ ΣH = -85/5 = -17 or θ = 86.6°
Since ΣH is positive and ΣV is negative, therefore resultant lies between 270° and 360°.
Thus actual angle of the resultant force
= 360° – 86.6° = 273.4° Ans.
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Three Wires Exert The Tensions Indicated On The Ring In Fig . Assuming A Concurrent
System, Determine The Force In A Single Wire Will Replace Three Wires.
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Sol: First resolved all the forces in horizontal and vertical direction
ΣH = Sum of Horizontal Component
= P cos 0° + 2Pcos 75° + 5Pcos 150° + 4Pcos 225°
= –5.628P ...(i)
Four Forces Of Magnitude P, 2P, 5P And 4P Are Acting At A Point. Angles
Made By These Forces With X-axis Are 0°, 75°, 150° And 225° Respectively.
Find The Magnitude And Direction Of Resultant Force.
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ΣV = Sum of Vertical Component
= Psin 0° + 2Psin 75° + 5Psin 150° + 4Psin 225°
= 1.603P ...(ii)
R = ((–5.628P)2 + (1.603P)2)1/2
R = 5.85P .......ANS
θ = tan–1(RV/RH)
= tan–1(1.603P/–5.628P)
θ = –15.89° .......ANS
Angle made by resultant (5.85P),–15.890 and lies in forth coordinate.
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Sol: Resolve the forces horizontally and
vertically.
Consider force F1
Determine the magnitude and direction of resultant of the force
system acting at a point A of the bracket as shown in fig.
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F1x = 600 Cos 35° = 491N
F1y = 600 Sin 35° = 344 N
Consider Force F2
F2x = - 500 (4/5) = - 400 N
F2y = - 500 (3/5) = 300 N
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Consider Force F3
α = tan-1(0.2/0.4) = 26.6°
F3x = F3 sin α = 800 sin 26.6° = 358 N
F3y = F3 cosα = -800 cos 26.6° = -716 N
R = (Σ H)2 + (Σ V )2
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Magnitude of the resultant force
Resolving all the forces horizontally (i.e., along AB),
ΣH = 20 cos 0° + 30 cos 30° + 40 cos 60° + 50 cos 90° + 60 cos 120° N
= (20 × 1) + (30 × 0.866) + (40 × 0.5) + (50 × 0) + 60 (– 0.5) N
= 36.0 N ...(i)
The Forces 20 N, 30 N, 40 N, 50 N And 60 N Are Acting At One Of
The Angular Points Of A Regular Hexagon as shown in fig., Towards
The Other Five Angular Points, Taken In Order. Find The Magnitude
And Direction Of The Resultant Force.
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Resolving the all forces vertically (i.e., at right angles to AB),
ΣV = 20 sin 0° + 30 sin 30° + 40 sin 60° + 50 sin 90° + 60 sin 120° N
= (20 × 0) + (30 × 0.5) + (40 × 0.866) + (50 × 1) + (60 × 0.866) N
= 151.6 N ...(ii)
Magnitude of the resultant force,
R = (Σ H)2 + (ΣV )2 = (36.0)2 + (151.6)2 = 155.8 N Ans.
Direction of the resultant force
tan θ = ΣV/ ΣH = 151.6/36 = 4.21
or θ = 76.6° Ans.
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First resolved all the forces in horizontal and
vertical direction.
Clearly note that the angle measured by x-axis,
ΣH = 4000cos 45° + 3000cos 90°+1000cos 0°+5000cos 225°
= 292.8N ...(i)
ΣV = 4000sin 45° + 3000sin 90°+ 1000sin 0°+5000sin 225°
= 2292.8N ...(ii)
Determine the resultant ‘R’ of the four forces transmitted to the
gusset plate if θ = 45° as shown in fig.
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R2 = RH2 + RV2
R2 = (292.8)2 + (2292.8)2
R = 2311.5N .......ANS
tanθ = ΣV /ΣH
= 2292.8/292.8
θ = 82.72º .......ANS
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Resolving all the forces horizontally i.e. along East-West, line,
H = 20cos30°+ 25cos90°+ 30cos135° +35cos220°
= (20 × 0.886) + (25 × 0) + {–30(–0.707) + 35(–0.766) N
= –30.7 N ...(i)
The following forces act at a point:
(i) 20N inclined at 30° towards north of east
(ii) 25N towards north
(iii) 30N towards north west,
(iv) 35N inclined at 40° towards south of west.
find the magnitude and direction of the resultant force.
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And now resolving all the forces vertically i.e., along North-South line,
V = 20sin 30° + 25sin 90° + 30sin 135° + 35sin 220°
= (20 × 0.5) + (25 × 1.00) + (30 × 0.707) + 35 × (– 0.6428)
= 33.7 N ...(ii)
We know that the magnitude of the resultant force,
R = H2 + V2
On solving, R = 45.6 N .......ANS
Direction of the resultant force;
tanq = V /H
Since H is –ve and V is +ve, therefore q lies between 90° and 180°.
Actual q = 180° – 47° 42’
= 132.18º .......ANS
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Determine the resultant of four forces acting on a body shown in fig.
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ΣH = 1.094 KN
Σ V = -2.83 KN
R = 3.035 KN
θ = 68.86º
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It states, “If two forces acting simultaneously on a particle, be represented
in magnitude and direction by the two sides of a triangle, taken in order ;
their resultant may be represented in magnitude and direction by the third
side of the triangle, taken in opposite order.”
TRIANGLE LAW OF FORCES
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It is an extension of Triangle Law of Forces for more than two forces,
which states, “If a number of forces acting simultaneously on a
particle, be represented in magnitude and direction, by the sides of
a polygon taken in order ; then the resultant of all these forces may
be represented, in magnitude and direction, by the closing side of
the polygon, taken in opposite order.”
POLYGON LAW OF FORCES
P. RAJENDRA KUMAR 56
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GRAPHICAL METHOD
P. RAJENDRA KUMAR 57
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It states, “If three coplanar forces acting at a point be in
equilibrium, then each force is proportional to the sine of the
angle between the other two.” Mathematically,
LAMI’S THEOREM
P. RAJENDRA KUMAR 58
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Consider three coplanar forces P, Q, and R acting at a point O. Let
the opposite angles to three forces be α , β and γ as shown in Fig.
Now let us complete the parallelogram OACB with OA and OB as
adjacent sides as shown in the figure. We know that the resultant of
two forces P and Q will be given by the diagonal OC both in
magnitude and direction of the parallelogram OACB.
Since these forces are in equilibrium, therefore the resultant of the
forces P and Q must be in line with OD and equal to R, but in
opposite direction.
From the geometry of the figure, we find
P. RAJENDRA KUMAR 59
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P. RAJENDRA KUMAR 60
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Σ H =
An electric light fixture weighting 15 n hangs from a point c, by two strings ac and bc. the string ac is
inclined at 60° to the horizontal and bc at 45° to the horizontal as shown in fig.
P. RAJENDRA KUMAR 61
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P. RAJENDRA KUMAR 62
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A fine light string ABCDE whose extremity A is fixed, has weights W1 and W2 attached to it at B and
C. it passes round a small smooth peg at D carrying a weight of 40N at the free end E as shown in
fig. If in the position of equilibrium, BC is horizontal and AB and CD makes 150° and 120° with BC,
find (i) tension in the portion AB,BC and CD of the string and
(ii) magnitude of W1 and W2.
P. RAJENDRA KUMAR 63
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A light string ABCDE whose extremity A is fixed, has weights W1 and W2 attached to it at B and C. it passes
round a small smooth peg at D carrying a weight of 300 N at the free end E as shown in fig. If in the
equilibrium position, BC is horizontal and AB and CD make 150° AND 120° with BC, Find (I) Tensions in
the portion AB, BC and CD of the string and (ii) magnitudes of W1 and W2.
P. RAJENDRA KUMAR 64
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It is the turning effect produced by a force, on the body, on
which it acts. The moment of a force is equal to the product
of the force and the perpendicular distance of the point
about which the moment is required, and the line of action of
the force.
If M = Moment
F = Force acting on the body, and
L = Perpendicular distance between the point about which
the moment is required and the line of action of the force
Then M = F.L
MOMENT OF A FORCE
P. RAJENDRA KUMAR 65
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The point about which the moment is considered is
called Moment Center.
And the Perpendicular distance of the point from the
line of action of the force is called moment Arm.
P. RAJENDRA KUMAR 66
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Moment is of two types:
Clockwise Moment
Anticlockwise Moment
Clockwise Moment: It is the moment of a force,
whose effect is to turn or rotate the body, in the
clockwise direction. It takes +ive.
TYPES OF MOMENTS
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Anticlockwise Moment:
It is the moment of a force, whose effect is to turn or rotate the body, in the
anticlockwise direction. It take -ive.
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It states “If a number of coplanar forces are acting simultaneously on a
particle, the algebraic sum of the moments of all the forces about any
point is equal to the moment of their resultant force about the same
point.”
The practical application of varignon’s theorem is to find out the position
of the resultant from any point of the body.
VARIGNON’S THEOREM
P. RAJENDRA KUMAR 69
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The resultant of non-concurrent force system is that force, which will have thesame rotational and translation effect as the given system of forces, It may be aforce, a pure moment or a force and a moment.
R = {(ΣH)2+(Σ V)2}1/2
Tan θ = Σ V/ Σ H
Σ M = R × d
Where,
Σ H = Sum of all horizontal component
Σ V = Sum of all vertical component
Σ M = Sum of the moment of all forces
d = Distance between the resultant force and the point where moment of all forces are taken.
Resultant of non - coplanar concurrent force system?
P. RAJENDRA KUMAR 70
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Given : Force applied (P) = 15 N and
width of the door (l) = 0.8 m
Moment when the force acts
perpendicular to the door
We know that the moment of the force
about the hinge,
= P × l = 15 × 0.8 = 12.0 N-m Ans.
A force of 15 N is applied perpendicular to the edge of a door 0.8 m wide as shown in fig. (a).
Find the moment of the force about the hinge. if this force is applied at an angle of 60° to the
edge of the same door, as shown in fig. (b), find the moment of this force.
P. RAJENDRA KUMAR 71
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Moment when the force acts at an angle of 60° to the door
This part of the example may be solved either by finding out the perpendicular distance
between the hinge and the line of action of the force as shown in Fig. (a) or by finding out the
vertical component of the force as shown in Fig. (b).
P. RAJENDRA KUMAR 72
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From the geometry of Fig. (a), we find that the perpendicular distance between the line of
action of the force and hinge,
OC = OB sin 60° = 0.8 × 0.866 = 0.693 m
Moment = 15 × 0.693 = 10.4 N-m Ans.
In the second case, we know that the vertical component of the force
= 15 sin 60° = 15 × 0.866 = 13.0 N
Moment = 13 × 0.8 = 10.4 N-m Ans.
P. RAJENDRA KUMAR 73
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H = 79.29N
V = -110.7N
R = 128.17N
Θ = 51.78°
d =2.808m
Determine the resultant of four forces tangent to the circle of radius 3m shown in
fig. What will be its location with respect to the center of the circle?
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Resolving all the forces horizontally,
ΣH = 2P + 3P cos 120° + 4P cos 240°
= 2P + 3P (– 0.5) + 4P (– 0.5)
= – 1.5 P ...(i)
and now resolving all the forces vertically.
ΣV = 3P sin 60° – 4P sin 60°
= (3P × 0.866) – (4P × 0.866)
= – 0.866 P ...(ii)
Three forces of 2P, 3P and 4P act along the three sides of an equilateral
triangle of side 100 mm taken in order. find the magnitude and position of
the resultant force.
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We know that magnitude of the resultant force
R = (ΣH)2 + (ΣV )2 = (–1.5P)2 + (– 0.866 P)2 = 1.732 P Ans.
Position of the resultant force
Let x = Perpendicular distance between B and the line of action of the
resultant force.
Now taking moments of the resultant force about B and equating the
same,
1.732 P × x = 3P × 100 sin 60° = 3P × (100 × 0.866) = 259.8 P
∴
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Here tan θ1 = 3/4 θ1 = 36.86º
tan θ2 = 3/2 θ2 = 56.3º
First we find the moment of force F about points A,B,C and D
F = 4.5KN
(1) About point A:
MA = –F cos 36.86º X 3 – F sin 36.86º X 1
= –13.50 KN –m .......ANS
(2) About point B:
MB = F cos 36.86º X 3 + F sin 36.86º X 4
= 21.59KN–m .......ANS
In the fig. assuming clockwise moment as positive, compute
the moment of force F= 4.5 KN and of force P = 3.61 KN about
points A, B, C and D. each block is of 1m2.
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(3) About point C:
MC = F cos 36.86º X 0 – F sin 36.86º X 5
= 13.49 KN–m .......ANS
(4) About point D:
MD = F cos 36.86º X 3 – F sin 36.86º X 1
= 8.10KN–m .......ANS
Now we find the moment of force P about points A,B,C and D
P = 3.61KN
(1) About point A:
MA = –P cos56.3º X 3 + P sin 56.3º X 2
= 0.002KN–m .......ANS
(2) About point B:
MB = P cos 56.3º X 3 – P sin 56.3º X 3
= –7.007KN–m .......ANS
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(3) About point C:
MC = –P cos56.3º X 0 –P sin 56.3º X 4
= –12.0134KN–m .......ANS
(4) About point D:
MD = –P cos 56.3º X 3 –P sin 56.3º X 2
= –11.998 KN–m .......ANS
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Resolve all the forces in horizontal and vertical direction. From the condition of
equilibrium
Taking moment about point B, We get
T3 sin 30º X 4.5 –10000 = 0
T3 = 4444.44N .......ANS
A vertical pole is anchored in a cement foundation. Three wires are attached to the
pole as shown in fig. If the reaction at the point. A consist of an upward vertical of
5000 N and a moment of 10,000 N-m as shown, find the tension in wire.
P. RAJENDRA KUMAR 80
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H = 0
T3 sin 30º + T2 cos 45º – T1 sin 60º = 0
2222.22 + 0.707 T2 – 0.866 T1 = 0 ...(i)
V= 0
T3 cos 30º + 5000 – T2 sin 45º – T1 cos 60º = 0
8849 – 0.707T2 – 0.5T1 = 0 ...(ii)
From equation (i) and (ii)
T1 = 8104.84N and T2 = 6783.44N ......ANS
P. RAJENDRA KUMAR 81
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P. RAJENDRA KUMAR 82
A HORIZONTAL LINE PQRS IS 12 M LONG, WHERE PQ = QR = RS = 4M. FORCES OF 1000, 1500, 1000
AND 500 N ACT AT P, Q, R AND S RESPECTIVELY WITH DOWNWARD DIRECTION. THE LINES OF
ACTION OF THESE MAKE ANGLE OF 90º, 60º, 45º AND 30º RESPECTIVELY WITH PS. FIND THE
MAGNITUDE, DIRECTION AND POSITION OF THE RESULTANT FORCE.
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COUPLE
P. RAJENDRA KUMAR 83
If two equal and opposite parallel forces (i.e. equal and unlike) are acting on
a body, they don’t have any resultant force. That is no single force can
replace two equal and opposite forces, whose line of action are different.
Such a set of two equal and opposite forces, whose line of action are
different, form a couple.
Thus a couple is unable to produce any translatory motion (motion in a
straight line). But a couple produce rotation in the body on which it acts.
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The perpendicular distance (d) between the lines of action
of the two equal and opposite parallel forces, is known as
arm of couple.
Types of Couple
Clockwise Couple
Anticlockwise Couple
ARM OF COUPLE
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A couple whose tendency is to rotate the body on which it acts, in a
clockwise direction, is known as a clockwise couple. Such a couple is also
called positive couple.
A couple whose tendency is to rotate the body on which it acts, in a
anticlockwise direction, is known as a anticlockwise couple. Such a couple
is also called Negative couple.
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1. The algebraic sum of the forces, consisting the couple, is zero.
2. The algebraic sum of the moment of the forces, constituting the couple, about any point is the
same, and equal to the moment of the couple itself.
3. A couple cannot be balanced by a single force, but can be balanced only by a couple, but of
opposite sense.
4. Any number of coplanar couples can be reduced to a single couple, whose magnitude will be
equal to the algebraic sum of the moments of all the couples.
CHARACTERISTICS OF COUPLE
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Case I: Couple Moment produced by 40 forces = 12 Nm
Case II: Couple Moment produced by 30 N forces = 12 Nm
If only one hand is used?
Force required for case I is 80N
Force required for case II is 60N
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Let R be the resultant of the given system. And ΣH and ΣV be
the horizontal and vertical component of the resultant. And
resultant makes an angle of θ with the horizontal.
Resolving all the forces horizontally
ΣH = 150 – 150
ΣH = 0KN ...(i)
A Rectangle ABCD has sides AB = CD = 80 Mm And BC = DA =
60 mm. Forces of 150 N each act along AB And CD, and forces
of 100 N each act along BC and DA. Make calculations for the
resultant of the force system.
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Resolving all the forces vertically
Σ V = 100 – 100
Σ V = 0KN ...(ii)
Since Σ H and Σ V both are 0, then resultant of the system is also zero.
But in Non-concurrent forces system, the resultant of the system may be a force, a couple or a
force and a couple
i.e. in this case if couple is not zero then couple is the resultant of the force system.
For finding Couple, taking moment about any point say point ‘A’.
MA = –150 × 60 – 100 × 80, both are anticlockwise
Then, Resultant moment = couple = –17000N–mm .......ANS
P. RAJENDRA KUMAR 89
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RESOLVE A FORCE SYSTEM IN TO A SINGLE FORCE AND A
COUPLE SYSTEM
P. RAJENDRA KUMAR 90
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Hence the given force F acting at A has been
replaced by an equal and parallel force applied at
point B in the same direction together with a
couple of moment F × x.
Thus force acting at a point in a rigid body can be
replaced by an equal and parallel force at any
other point in the body, and a couple.
P. RAJENDRA KUMAR 91
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In designing the lifting hook, the forces acting on a horizontal
section through B may be determined by replacing F by a
equivalent force at B and a couple. If the couple is 3000 N-mm,
determine F.
P. RAJENDRA KUMAR 92
Force ‘F’ is replaced at point B, by a singleforce ‘F’ and a single couple of magnitude3000 N-mm.
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Now apply two equal and opposite force i.e. ‘F’ at point B.
as shown in Fig.
Now force ‘F’ which is act at point E and upward force
which is act at point B makes a couple of magnitude =
Force × distance
= F × 40
But 40F = 3000 i.e.
F = 75 N ........ANS
P. RAJENDRA KUMAR 93
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It states, “If a force acts at any point on a rigid
body, it may also be considered to act at any other
point on its line of action, provided this point is
rigidly connected with the body.”
PRINCIPLE OF TRANSMISSIBILITY OF FORCES
P. RAJENDRA KUMAR 94
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When two forces are in equilibrium (equal, opposite and collinear), their resultant is
zero and their combined action on a rigid body is equivalent to that of no force at
all., Thus
“The action of a given system of forces on a rigid body will in no way be changed
if we add to or subtract from them another system of forces in equilibrium.”, this is
called law of superposition.
LAW OF SUPERPOSITION
P. RAJENDRA KUMAR 95
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Consider two forces P and Q acting at A on a boat as shown in Fig. Let R be the resultant of these two
forces P and Q. According to Newton’s second law of motion, the boat will move in the direction of
resultant force R with acceleration proportional to R. The same motion can be obtained when P and Q
are applied simultaneously.
P. RAJENDRA KUMAR 96
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Consider a body acted upon by a number of coplanar non-concurrent forces. A little
consideration will show, that as a result of these forces, the body may have any one of
the following states:
1. The body may move in any one direction.
2. The body may rotate about itself without moving.
3. The body may move in any one direction and at the same time it may also rotate
about itself.
4. The body may be completely at rest.
CONDITIONS OF EQUILIBRIUM
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1. If the body moves in any direction, it means that there is a resultant force
acting on it. A little consideration will show, that if the body is to be at rest or in
equilibrium, the resultant force causing movement must be zero. Or in other
words, the horizontal component of all the forces (Σ H) and vertical component
of all the forces (ΣV) must be zero. Mathematically,
Σ H = 0 and Σ V = 0
2. If the body rotates about itself, without moving, it means that there is a single
resultant couple acting on it with no resultant force. A little consideration will
show, that if the body is to be at rest or in equilibrium, the moment of the couple
causing rotation must be zero. Or in other words, the resultant moment of all the
forces (Σ M) must be zero. Mathematically,
Σ M = 0
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3. If the body moves in any direction and at the same time it rotates about itself,
if means that there is a resultant force and also a resultant couple acting on it. A
little consideration will show, that if the body is to be at rest or in equilibrium, the
resultant force causing movements and the resultant moment of the couple
causing rotation must be zero. Or in other words, horizontal component of all the
forces (Σ H), vertical component of all the forces (Σ V) and resultant moment of
all the forces (Σ M) must be zero. Mathematically,
Σ H = 0 Σ V = 0 and Σ M = 0
4. If the body is completely at rest, it necessarily means that there is neither a
resultant force nor a couple acting on it. A little consideration will show, that in
this case the following conditions are already satisfied :
Σ H = 0 Σ V = 0 and Σ M = 0
P. RAJENDRA KUMAR 99
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Free body diagram is necessary to investigate the condition of equilibrium of
a body or system. While drawing the free body diagram all the supports of the
body are removed and replaced with the reaction forces acting on it.
FREE BODY DIAGRAM
P. RAJENDRA KUMAR 100
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1. Draw the object under consideration; it does not have to be artistic. At first, you may want
to draw a circle around the object of interest to be sure you focus on labeling the forces
acting on the object. If you are treating the object as a particle (no size or shape and no
rotation), represent the object as a point. We often place this point at the origin of an xy-
coordinate system.
2. Include all forces that act on the object, representing these forces as vectors. Consider the
types of forces described in Common Forces—normal force, friction, tension, and spring
force—as well as weight and applied force. Do not include the net force on the object. With
the exception of gravity, all of the forces we have discussed require direct contact with the
object. However, forces that the object exerts on its environment must not be included. We
never include both forces of an action-reaction pair.
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3. Convert the free-body diagram into a more detailed diagram showing the x- and y-
components of a given force (this is often helpful when solving a problem using Newton’s first
or second law). In this case, place a squiggly line through the original vector to show that it is
no longer in play—it has been replaced by its x- and y-components.
4. If there are two or more objects, or bodies, in the problem, draw a separate free-body
diagram for each object.
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Given : Weight of cylinder = 100 N
Let RA = Reaction at A, and
RB = Reaction at B.
A smooth circular cylinder of radius 1.5 meter is lying in a triangular
groove, one side of which makes 15° angle and the other 40° angle with
the horizontal. Find the reactions at the surfaces of contact, if there is no
friction and the cylinder weights 100 N.
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Applying Lami’s equation, at O,
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First of all, consider the equilibrium of the cylinder P. It is in
equilibrium under the action of the following three forces
which must pass through A i.e., the centre of the cylinder P
as shown in Fig. a
Two Cylinders P And Q rest in a Channel as shown in Fig. The cylinder P
has diameter of 100 mm and weighs 200 N, whereas the cylinder Q has
diameter of 180 mm and weighs 500 N. If the bottom width of the box is
180 mm, with one side vertical and the other inclined at 60°, determine
the pressures at all the four points of contact.
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From the geometry of the figure, we find that
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The system of forces at A is shown in Fig. (b).
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Now consider the equilibrium of the cylinder Q. It is in equilibrium
under the action of the following four forces, which must pass
through the centre of the cylinder as shown in Fig. (a).
The weight of the cylinder Q is acting downwards and the reaction
R4 is acting upwards. Moreover, their lines of action also coincide
with each other.
Net downward force = (R4 – 500) N
The system of forces is shown in Fig. (b).
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Two smooth pipes, each having a Mass of 300 Kg and 0.35m diameter, are supported
by the forked tines of the tractor in Fig. a . Draw the Free-body Diagrams for each pipe
and find the reactions of point of contact.
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The Lever ABC is pin supported At A And Connected To A Short Link
BD As Shown In Fig. a. If The Weight Of The Members is Negligible,
Determine The Force Of The Pin On The Lever at A .
P. RAJENDRA KUMAR 120