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INTRODUCTION
Having studied in the earlier chapters two different approaches, we shall in
this chapter learn the third approach to the solution of kinetics of particles.
This approach requires the use of Impulse Momentum Equation involving the
parameters like force, mass, velocity and time. Using this equation eliminates
the determination of acceleration giving direct results in most of the cases.
In the second part of this chapter we shall deduce the Conservation of
Momentum Equation from the basic Impulse Momentum Equation and use it
to solve problems involving a system of particles subject to internal action
and reaction forces and not involving any external forces on the system (i.e.
such a system where momentum is conserved).
Study of collision of particles forms the third part of this chapter. Here we
shall learn the interesting phenomenon which takes place during a collision.
The study reveals that there exists a certain relation between the velocities of
the colliding particles before they collide to the velocities they acquire after
impact.
IMPULSE
Consider a particle acted upon by a force F as shown in Fig. (a), for a duration
of t sec.
This force is said to impart an impulse on the particle and the magnitude of
this impulse is the product of the force and the duration for which it acts.
If the force F is constant (Fig. (b)), during the time it acts, then
Impulse = F t …………[1(a)]
If the force F is variable (Fig. (c)), the impulse between the time interval t1 and
t2 is
2
1
t
t
Impulse = Fdt …………[1(b)]
Impulse is a vector quantity and its unit is N.s
Kinetics of Particles Impulse Momentum Method
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IMPULSIVE FORCE
A large force when acts far a very small time and which causes a considerable
change in a particle's momentum is called an impulsive force. For example,
when a moving particle collides with another particle, the collision duration is
very small, but the particles after collision have different magnitudes of
velocities and in some cases even different directions of velocities, thereby
indicating a considerable change in the momentum.
Other examples of impulsive forces are, when a bat hits a ball, the action and
reaction forces at the contact point are impulsive forces which impart a new
momentum to the ball. Also when a spring loaded toy gun releases the bullet,
the spring force is an impulsive force in this case.
Impulsive forces are different from usual forces for the reason that the
impulse generated by the impulsive forces is mainly due to the large force
value, which acts for small time, whereas usual forces also generate impulse,
where the duration (time) an equally important parameter, is large and
equally contributes to the impulse generated.
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IMPULSE MOMENTUM EQUATION
From Newton‟s Second Law Equation we have,
F = ma
or
dv
F = m
dt
 ……….since a = dv / dt
or
d(mv)
F =
dt
 ………. makes no change since m is constant.
Here the product mv is referred to as the linear momentum of the particle and
may be defined as the amount of motion possessed by a moving body. It is a
vector quantity and its SI units are kg.m/s or N.s
Now F dt = d (mv)
Integrating between the time interval t1 to t2 during which the velocity of the
particle changes from v1 to v2.
2 2
1 1
t v
2 1
t v
Fdt = d(mv) = mv - mv 

2
1
t
1 2
t
mv Fdt = mv 
2
1
t
t
Fdt is the impulse on the particle, we therefore have
1 1-2 2mv + Impulse = mv ………. [2]
Equation 12.2 is known as Impulse Momentum Equation. This equation gives
rise to Principle of Impulse Momentum which may be stated as “for a particle
or a system of particles acted, upon by forces during a time interval, the total
impulse acting on the system is equal to the difference between the final
momentum and initial momentum during that period”.
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APPLICATION OF IMPULSE MOMENTUM EQUATION
Impulse Momentum liquation is a third equation other than the Newton‟s
Second Law Equation and Work Energy Principle Equation, using which we
can analyse the kinetics of particles.
Impulse Momentum Equation involves parameters viz. force. mass, velocity
and time. Thus the velocity of the particle at the new position may be worked
out knowing the forces acting on the particle and the duration for which they
act.
A1so, if the initial and final velocities of the particle are known, the duration
for which the particle is in motion can be found out.
This method therefore eliminates the calculation of acceleration and many
times use of the kinematics relations, to give direct results. We will further
deduce the Conservation of Momentum Equation from the Impulse
Momentum Equation and apply it to a system of particles where the
momentum is conserved.
To use the method of Impulse and Momentum, we need to draw. Three
figures. The L.H.S. figure would show the initial momentum vector of the
particle. The central figure shows the F.B.D. of the particle. The R.H.S. figure
shows the final momentum vector of the particle. Drawing of these figures
helps in writing the Impulse Momentum Equation. Since all terms in this
equation are vector quantities, a proper sign convention for the direction need
to be chosen before plugging in the values.
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Conservation of Momentum Equation
Figure shows a man (B) standing at the end of a boat (A). The system of man
and boat is initially at rest i.e. vA = 0 and vB = 0
If the man jumps off horizontally in the water with a velocity vB‟, he induces a
backward motion to the boat, which now starts moving with a velocity vA‟.
If the water resistance is neglected the question is, how is the motion of the
boat induced?
To jump off from the boat, the man exerts an impulsive force through his feet
on the surface of the boat. This induces a reaction impulsive force to the man,
which throws him in the water. Also since the water resistance is small, it
may be neglected. Thus the impulsive force exerted by the man is the cause of
the backward motion of boat.
The interesting part here is that the impulsive force exerted by the man on the
boat or the reaction impulsive force of the boat on the man are nothing but
action and reaction forces acting for the same time interval. Due to this the
net impulse in the direction of motion is zero. The Impulse Momentum
Equation thereby reduces to Conservation of Momentum Equation. Applying
this concept to the above example, we have
mv1 + lmpulse1-2 = mv2
i.e. (mAvA + mBvB) + Impulse1-2 u = (mAv‟A + mBv‟B)
0 = mAvA ‟ + mBvB‟ or –mAvB ‟ = mBvB ‟
since mAvA = mBvB = 0 and Impulse,_, = 0,
This relation indicates that knowing the masses of A and B and velocity of
man (vB') as he jumps, we can find the velocity of boat (vA'). The negative sign
attached to the magnitude of the velocity tells us that the boat moves in the
opposite direction to that of man.
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The conservation of momentum phenomenon takes place in other similar
situations such as when a bullet is fired from the gun and thereby the gun
recoils backwards, or during the collision of two particles, the particles move
with different velocities after the collision. In general we may say “for dynamic
situations involving a system of particles, if the net impulse is zero, the
momentum of the system is conserved”. The equation of Conservation of
Momentum is therefore expressed as.
Initial Momentum = Final Momentum …… [3]
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EXERCISE 1
1. A 1200 kg automobile is traveling at 90 kmph when brakes are fully
applied, causing all four wheels to skid. If μk is 0.1, find the time required
for the automobile to come to halt.
2. A dish slides 1200 mm on a level table before coming to rest. If μk = 0.18
between the dish and table, what was the time of travel.
3. A car at 72 kmph applies brakes and comes to rest in 8 sec. Find the
minimum coefficient of friction between wheel and road.
4. A bullet of mass 1 gram has a velocity of 1000 m/s as it enters a feed block
of wood. It comes to rest in 2 milliseconds after entering the block.
Determine the average force that acted on the bullet and the distance
penetrated by it.
5. A particle of mass 5 kg is acted upon by a force defined by a relation F = 60
t + 40 N. Find its velocity after 5 sec if it starts from rest and moves in a
straight path.
6. A 380 gm football is kicked by a player so that it leaves the ground at an
angle of 40° with the horizontal and lands on the ground 35 m away.
Determine the impulse given to the ball. Also find the impulsive force if the
contact was for 0.3 sec.
7. A 1500 kg car moving with a velocity of 10 kmph hits a compound wall and
is brought to rest in 400 milliseconds. What is the average impulsive force
exerted by the wall on the car bumper?
8. A ball of mass 100 g is moving towards a bat with a velocity of 25 m/s as
shown in figure. When hit by a bat, the ball attains a velocity of 40 m/s. If
the bat and ball are in contact for a period of 0.015 s. Determine the
average impulse force exerted by the bat on the ball during the impact.
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9. A 2 kg mass rests on a smooth horizontal plane. It is struck with a 9N blow
that lasts 0.02 second. Three seconds after the start of the first blow a
second blow of 9N is delivered. This lasts for 0.01 second. What is the
speed of the body after 4 seconds? Refer figure.
10.A 30 kg boy stands stationary on a 50 kg boat. If the boy jumps off the
boat horizontally with a velocity of 3 m/s, determine the velocity of the
boat just after the jump.
a) A 30 kg boy is stationary on a 50 kg boat which is initially at rest. If the
boy jumps off the boat horizontally with a velocity of 3 m/s relative to
the boat, determine the velocity of the boat just after the jump and also
the true velocity with which the boy jumps. Neglect water resistance.
11. Two men A (500 N) and B (700 N) lined up at one end of the boat (3000 N)
and dived horizontally off the boat in succession with a velocity of 4 m/s
relative to the boat. Find the velocity of the boat after the second man B
had dived. Neglect water resistance.
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12. A 30 kg boy is standing on a 50 kg boat A which is initially at rest. If the
boy jumps off horizontally with a speed of 2 m/s relative to the boat A on
another identical stationary boat B, determine the speed of both the boats
A and B. Neglect water resistance.
IMPACT
A collision of two bodies which takes place during a very small time interval
and during which the colliding bodies exert relatively larger forces on each
other is known as Impact.
Line of Impact
When two bodies collide, the line joining the common normals of the colliding
bodies is known as Line of Impact. Refer figure.
Types of Impact
Impacts are basically divided into two categories viz. a Central Impact and an
Eccentric Impact. When the mass centres of the colliding bodies lie on the
Line of Impact, the Impact is said to be a Central Impact. When the mass
centres of the colliding bodies are not located on the Line of Impact, we call
such Impact to be an Eccentric Impact.
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Central Impact is further classified into Direct Impact and Oblique impact.
In case of Direct Central Impact, the bodies travel along the Line of Impact i.e.
their velocities are directed along the Line of Impact. On the other hand in
case of Oblique Central Impact, the velocities of one or both the bodies are not
directed along the Line of Impact.
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DIRECT CENTRAL IMPACT
Let us now study the phenomenon of a Direct Central Impact. What really
happens during an impact is quite interesting. Let us understand stage by
stage as to what happens during a direct central impact.
1) Fig. (a) shows two particles A and B with velocities vA and vB. If vA is grater
than vB, the impact will soon take place.
2) The period of impact is made of period of deformation and period of
restitution.
3) During the period of deformation Fig (b), the two particles exert large
impulsive force on each other. The
deformation of both the particles continue
till maximum deformation. At this stage
both the particles are said to have
momentarily united and move with
common velocity v. Fig (c).
4) Now the period of restitution begins Fig (c). The two particles restore their
shape during this period. Sometimes permanent deformations are also set
in the particles. During this period the impulsive force exerted by the two
particles is lesser than during the period of deformation. At the end of the
period of restitution the two particles separate from each other. Fig. (d).
5) The two particles A and B now have new velocities vA‟ and vB‟ respectively.
Fig. (e).
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Coefficient of Restitution
Let us apply Impulse Momentum Equation in the x direction to the particle A
during the period of deformation. Let P be the impulsive force exerted by
particle B on A. At the start of period of deformation the velocity of particle A
is vA and at the end of period of deformation its velocity changes to v, being
the common velocity of A and B.
1 1-2 2mv +Impulse = mv
A A Am v - Pdt = m v ………. (1)
Here Pdt is the impulse due to the impulsive force P acting during the period
of deformation. Now let us apply Impulse Momentum Equation to the particle
A during the period of restitution. During this period a smaller impulsive force
say R be exerted by particle B on A. At the start of period of restitution the
velocity of A is v and changes to vA' at the end of the period of restitution.
1 1-2 2mv + Impulse = mv
A A Am v - R dt = m v ' ………. (2)
Here R dt is the impulse due to the impulsive force R acting during the
period of restitution
From equations (1) and (2) we have
A
A
R dt v - v '
=
v - vPdt


If
R dt
e =
Pdt


then A
A
v - v '
e =
v - v
………. (3)
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e is referred to as the Coefficient of Restitution and is defined as the ratio of
the impulse exerted between the colliding particles during the period of
restitution to the impulse exerted during the period of deformation.
Similarly if the Impulse Momentum Equation is applied to the particle B, we
get
B
B
v ' - v
e =
v - v
……… (4)
From basic algebra if
B D B + D
A = = , then A =
C E C + E
From equations (4) and (5) we therefore have,
A B B A
A B A B
v - v ' + v '-v v ' - v '
e = e =
v - v + v - v v - v

or  B A A Bv ' v ' e v v   ………. (5)
we will refer equation 5 as Coefficient of Restitution Equation.
The value of coefficient of restitution „e‟ lies between 0 and 1. It mainly
depends on the nature of the bodies of collision. For example, the rebound
velocity of a rubber ball which falls freely from a certain height on to the
ground is different from that of a tennis ball which falls freely from the same
height.
A special case arises if e = 0 or if e = 1
If e = 0, the impact is referred to as a perfectly plastic impact. In such impact
the two bodies move with same velocity after impact. The momentum is
conserved but loss of energy takes place.
If e = 1, the impact is referred to as a perfectly elastic impact. In such impact
momentum is conserved‟ and there is also no loss of energy i.e. energy is also
conserved.
For all other impacts e lies between 0 and 1. In such impacts the momentum
is conserved, but there is loss of energy during impact, as heat and sound is
generated.
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Procedure to solve Direct Central Impact Problems
Given velocities before impact i.e VA, VB and coefficient of restitution e and to
find velocities after impact.
1. Step (1) During impact since there are no external forces acting on the
colliding bodies, the momentum of the system is conserved, i.e.
conservation of momentum is applicable, which is
Initial Momentum = Final Momentum
' '
A A B B A A B Bm v m v m v m v  
2. Step (2) Use Coefficient of Restitution Equation i.e.
 ' '
B A A Bv v e v v  
3. Step (3) solve the two equations to find the velocities vA' and vB' after
impact.
Note: Take proper sign conventions for the direction of velocities while using
the Conservation of Momentum and Coefficient of Restitution Equations.
Special Case of Direct Central Impact
A special case happens when a ball has a direct central impact with a rigid
body of infinite mass. For example, a ball hitting a wall or striking the ground.
Consider Line of one such case of ball having a impact direct central impact
with ground.
Applying Coefficient of Restitution Equation, we get,
 B A A B
A A B B
A A
v ' v ' e v v
0 - v ' = e (v - 0) v = v ' 0
v ' = - e v
  
 

The - ve sign indicates that the motion of ball after impact is in the opposite
direction
 The magnitude of the velocity of a ball after a direct central impact with
ground or wall is given by
A Av ' = e v ……… equation for special case of direct impact.
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Relation between ‘e’ and Height of Bounce ‘h'’
Let a ball be dropped from a height „h‟ on the ground. Let h' be the height of
rebound after „n‟ bounces. If „e‟ is the coefficient of restitution between the ball
and the ground, then e is related to h' as
1
2nh'
e =
h
 
 
 
OBLIQUE CENTRAL IMPACT
 When the velocities of either one or both colliding particles is not directed
along the line of impact, the impact is said to be Oblique Central Impact. In
such an impact not only the magnitudes of velocities after impact are
unknown, but the new direction of travel is also unknown and needs to be
worked out.
 In an Oblique Central Impact the impulsive force acts along the line of
impact. Thus velocity changes occur only along the line of impact and no
change in velocity takes place in a direction perpendicular to the line of
impact.
Procedure to Solve Oblique Central Impact Problems
Given: Initial velocities of particles A and B to be VA at an angle α and VB at
an angle β , coefficient of restitution e.
To find: Velocities vA' and vB' and new angles α ' and β ' after impact.
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Step 1) Let the line of impact be now called as n direction of impact. Let t be
the direction perpendicular to the n direction.
Step 2) Resolve the initial velocities vA and VB along the n and t direction so as
to get their components vAn, vAt and vBn, vBt.
Step 3) Work as a direct impact problem in the n direction, taking vAn and vBn
as initial velocities. Using Conservation of Momentum and Coefficient
of Restitution Equations, find velocity components vA'n and vB‟n after
impact.
Step 4) Work in the t direction. Since velocities don‟t change in the t direction,
we have vA‟t = vAt and vB‟t = vBt
Step 5) The magnitudes of velocities after impact are therefore given as
 
2
A A nv ' = v ' and    
2 2
B B n B tv ' = v ' v '
The new direction of velocity is given as
-1 A t
A n
v '
α' = tan
v '
and -1 B t
B n
v '
β' = tan
v '
Special Case of Oblique Central Impact
A special case happens when a ball has oblique central impact with a rigid
infinite mass such as a rigid wall or ground. Consider one such case of a ball
having an oblique impact with the ground.
Applying Coefficient of Restitution Equation in the n direction of impact, we
get
 B n A n An Bnv ' -v ' = e v - v
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 A n An Bn B0 - v ' = e v - 0 v v 'n = 0
 A n Anv ' = e v
since velocities don‟t change in the t direction, we get
A t A tv ' = v
 The magnitude of the velocity components of a ball after oblique impact
with ground or rigid wall is given by and
A n An
A t A t
v ' = e v
v ' = v



…… equations for
special case of oblique impact.
EXERCISE 2
1. Three identical cars A, B and C are ready for dispatch from a factory. At the
instant the cars have their brakes released. An accidental forward push to
car A causes it to move with a velocity of 2 m/s and hit car B.
(a)Determine the speed of cars A and B just after the impact.
(b)If a series of collision takes place between the three cars, determine the
velocities of the three cars after all collisions are over.
Take e = 0.7 between the bumpers.
2. Ball A of mass 0.6 kg moving to the right with a velocity of 4 m/s has a
direct central impact with ball B of mass 0.3 kg moving to left with a
velocity of 1 m/s. If after impact the velocity of ball B is observed to be 5
m/s to the right, determine the coefficient of restitution between the two
balls.
3. A railway wagon weighing 400 kN and moving to the right with a velocity of
2 m/s, collides with another wagon weighing 200 kN and moving with a
velocity of 5 m/s in the opposite direction. If the two wagons move together
after impact, find the magnitude and direction of their common velocity.
Also find the percentage loss of kinetic energy of the system.
4. A ball of mass 2kg impinges on a ball of mass 4 kg which is moving in the
same direction as the first. The coefficient of restitution is % and the first
ball is reduced to rest after the impact. Find the ratio between velocities of
balls before the impact.
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5. A ball is dropped on to a smooth horizontal floor from a height of 4 m. On
the second bounce it attains a height of 2.25 m. What is the coefficient of
restitution between the ball and the floor?
6. A ball is thrown vertically downwards with a velocity v0 from a height of 1.2
m so that it hits the ground and just touches the ceiling after impact. If the
ceiling is 4 m high from the ground find v0. Take e = 0.75.
7. A body A of mass 2 kg is projected upwards from the surface of the ground
at t = 0 elocity 20 m/s. At the same time another body B of mass 2 kg is
dropped along the same line from a height of 25 m. If they collide
elastically, find the velocities of body A and B just after collision.
8. A smooth spherical ball A of mass 5 kg is moving in a horizontal plane from
left to right with a velocity of 10 m/s. Another ball B of mass 6 kg traveling
in a perpendicular direction with a velocity of 20 m/s collides with A in
such a way that the line of impact is in the direction of motion of ball B.
9. Assuming e = 0.7, determine the velocities of balls A and B after impact.
10. The 9 kg ball moving down at 3m/sec strikes the 5.5kg ball moving at 2.5
m/sec as shown. The coefficient of restitution e = 0.8. Find the speeds vi
and V2 after the impact
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11. Two identical spheres A and B approach each other with the velocities as
shown. Determine the magnitude and direction of the velocity of each
sphere after impact.
Take e = 0.7
12. Two smooth spheres A and B having a mass of 2 kg and 4 kg respectively
collide with initial velocities as shown in figure. If the coefficient of
restitution for the spheres is e = 0.8, determine the velocities of each sphere
after collision.
13. A bowler bowls a ball which strikes the ground at an
angle of 60° with a speed of 20 m/s as shown. Find the
velocity of the ball just after it strikes the ground.
Assume smooth surfaces and e = 0.7
14. A ball is thrown against a frictionless wall. Its velocity
before striking the wall is shown. If e =0.8, find the
velocity after impact.
15. Two identical billiard balls collide with velocities as shown. Find the
velocities of the balls after impact. Also find the percentage loss of kinetic
energy. Take e = 0.9.
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16. Two smooth balls A (3 kg) and B (2 kg) strike with given velocities as shown.
If e = 0.7 find the velocities of the balls after impact.
17. Two smooth balls A (3 kg) and B (4 kg) are moving with velocities as shown
before they collide. After collision ball A rebounds in a direction at 40°
counterclockwise with the horizontal axis. Determine the coefficient of
restitution between the balls.
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COMBINATION PROBLEMS
We have completed our study of the three different methods of solving kinetics
of particles viz., Newton‟s Second Law, Work Energy Method and Impulse
Momentum Method. We have also worked with the Conservation of Energy
Principle and Conservation of Momentum Principle which were the offshoots
of Work Energy Method and Impulse Momentum respectively. Problems on
impact involving use of two equations viz, the Conservation of Momentum and
Coefficient of Restitution Equations have been dealt with.
So far we have used these methods in isolation, since the problem
requirement was being satisfied with one method only. However certain
problems may need application of more than one method to solve them. Such
problems are referred to as Combination Problems.
Combination Problems need to be first broken into parts, each part requiring
the use of one of the methods at a time. While working with a particular part,
the same procedure and equations are to be adopted as has been explained
before. The value obtained from solving one part of the problem is used as a
data for the next part and thus the entire Combination Problem is dealt with.
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EXERCISE 3
1. A shell of weight 200 N is fired from a gun with a velocity of 350 m/s. The
gun and its carriage have a total weight of 12 kN. Find the stiffness of the
spring which is required to bring the gun to a halt within 300 mm of the
spring compression.
2. A sphere tied to a string of length L is released from rest from the horizontal
position at A. The sphere swings as a pendulum and strikes a vertical wall
at B. If e = 0.7, find the angle θ defining its total rebound.
3. A ball of 200 gm mass is propelled from A by a spring mechanism. The ball
falls on a smooth floor and after rebounding at B falls in the cup at C.
Determine the location x of the cup. The spring is initially compressed 100
mm. Take k = 3000 N/m and e = 0.75
4. Block A of mass 1.125 kg is released from
rest in the position shown and slides
without friction until it strikes the ball B of
mass 1.8 kg of a simple pendulum.
Knowing that coefficient of restitution
between A and B is 0.9, determine
a) the velocity of B immediately after impact
b) the maximum angular displacement of the pendulum.
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5. A 3 kg sphere is released from rest and strikes a
5 kg block kept on a horizontal floor. If e = 0.7
between the block and sphere and μk = 0.3
between the block and ground, determine
(a)the distance traveled by the block before it
comes to rest.
(b)the tension in the cable just after impact.
6. A 2 kg sphere A is released from rest when Aθ
= 50° and strikes a 4 kg sphere B which is at
rest. If e = 0.8 between the two spheres,
determine the values of Aθ and Bθ
corresponding to the highest position to which
the spheres will rise after impact. Take length of both the pendulums to be
1 m.
7. A small steel ball is to be projected
horizontally such that it bounces twice on
the surface and lands into a cup placed at
a distance of 8m as shown. If the
coefficient of restitution for each impact is 0.8, determine the velocity of
projection „u‟ of the ball.
8. A pile of 400 kg mass is being driven into ground with the
help of a hammer of mass 1000 kg. Hammer falls through a
constant height of 2.5 m. Assuming plastic impact between
hammer and pile, find the number of blows required to
drive the pile by 1 m when the resistance offered by the
ground to penetration is 300 kN.
9. A pile hammer, weighing 15 kN drops from height of 600 mm on a pile of
7.5 kN. How deep does a single blow of hammer drive the pile if the
resistance of the ground to pile is 140 kN? (Assume plastic impact and the
ground resistance is constant)
a) How many blows are required to drive the pile 1 m in the ground.
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24
10. A 3 kg mass falls on a 2 kg platform mounted
on two springs. If k = 300 N/m of each spring,
determine the maximum distance the platform
moves down from its present static position
after impact. Assume perfectly plastic impact.
11. A bullet of mass 30 gm moving horizontally with 400 m/s strikes a 2 kg
wooden block suspended by a string 2.5 m long. To what maximum angle
with vertical will the block and embedded bullet swing.
12. A particle of mass „m‟ starts from rest at A
and slides down a smooth track ABCD held
in a vertical plane. What should be the
minimum height h so that the particle
completes its journey on the track ABCD
without falling off the track at C.
13. A ball slides down on a smooth
inclined surface and strikes the ground
at B. Determine the magnitude of
velocity and direction of the ball after
impact. Take e = 0.6
14. Two particles A (3 kg) and B (2 kg) are
initially at rest 10 m apart on a 25° inclined plane. Particle B being ahead
of A. If μk between A and incline is 0.15 and between B and incline is 0.25,
determine the time taken and distance traveled by the two particles before
they collide.
If e = 0.75 find their velocities after collision.
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25
EXERCISE 4
Theory Questions
Q.1. What is impulse and momentum? Explain its principle?
Q.2. State and derive the Impulse Momentum Equation.
Q.3. State the Law of Conservation of Momentum Principle.
Q.4. What do you mean by impact, impulse and coefficient of restitution?
Q.5. Write a short note on: Different types of impact and their characteristics.
OR List the types of collisions.
Q.6. Write a short note on Coefficient of Restitution.
UNIVERSITY QUESTIONS
1. Two smooth balls collides as shown in figure. If mA = 1 kg, mB = 2 kg and e
= 0-75. Find the velocities after impact. (10 Marks)
2. A ball of mass m kg hits an inclined smooth surface with a velocity
AV =3m/s Find our velocity of rebound. (6 Marks)
3. If a ball is throw vertically down with a velocity of 10 m/s from a height of
3m. Find the maximum height it can reach after hitting the floor, if the
coefficient of restitution is 0.7. (6 Marks)
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26
4. A collar of mass 1 kg is attached to a spring
and slides without friction along a circular rod
which lies in a horizontal plane. The spring is
undeformed when the collar is at B. knowing
that the collar is passing through the point D
with a speed of 1.8 m/s, determine the speed of
the collar when it passes through point C and
B. Take stiffness of the spring, K = 250 N/m, Radius of the circular path =
300 mm and distance
OA = 125 mm. (6 Marks)
5. A ball of mass „m‟ hits directly to a similar ball of mass „m‟ which is at rest.
The velocity of first ball after impact is zero. Half of the initial kinetic
energy is lost in impact. Find coefficient of restitution. (6 Marks)

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Kinetics of particles impulse momentum method

  • 1. www.ekeeda.com Contact : 9029006464 Email : care@ekeeda.com 1 P INTRODUCTION Having studied in the earlier chapters two different approaches, we shall in this chapter learn the third approach to the solution of kinetics of particles. This approach requires the use of Impulse Momentum Equation involving the parameters like force, mass, velocity and time. Using this equation eliminates the determination of acceleration giving direct results in most of the cases. In the second part of this chapter we shall deduce the Conservation of Momentum Equation from the basic Impulse Momentum Equation and use it to solve problems involving a system of particles subject to internal action and reaction forces and not involving any external forces on the system (i.e. such a system where momentum is conserved). Study of collision of particles forms the third part of this chapter. Here we shall learn the interesting phenomenon which takes place during a collision. The study reveals that there exists a certain relation between the velocities of the colliding particles before they collide to the velocities they acquire after impact. IMPULSE Consider a particle acted upon by a force F as shown in Fig. (a), for a duration of t sec. This force is said to impart an impulse on the particle and the magnitude of this impulse is the product of the force and the duration for which it acts. If the force F is constant (Fig. (b)), during the time it acts, then Impulse = F t …………[1(a)] If the force F is variable (Fig. (c)), the impulse between the time interval t1 and t2 is 2 1 t t Impulse = Fdt …………[1(b)] Impulse is a vector quantity and its unit is N.s Kinetics of Particles Impulse Momentum Method
  • 2. www.ekeeda.com Contact : 9029006464 Email : care@ekeeda.com 2 IMPULSIVE FORCE A large force when acts far a very small time and which causes a considerable change in a particle's momentum is called an impulsive force. For example, when a moving particle collides with another particle, the collision duration is very small, but the particles after collision have different magnitudes of velocities and in some cases even different directions of velocities, thereby indicating a considerable change in the momentum. Other examples of impulsive forces are, when a bat hits a ball, the action and reaction forces at the contact point are impulsive forces which impart a new momentum to the ball. Also when a spring loaded toy gun releases the bullet, the spring force is an impulsive force in this case. Impulsive forces are different from usual forces for the reason that the impulse generated by the impulsive forces is mainly due to the large force value, which acts for small time, whereas usual forces also generate impulse, where the duration (time) an equally important parameter, is large and equally contributes to the impulse generated.
  • 3. www.ekeeda.com Contact : 9029006464 Email : care@ekeeda.com 3 IMPULSE MOMENTUM EQUATION From Newton‟s Second Law Equation we have, F = ma or dv F = m dt  ……….since a = dv / dt or d(mv) F = dt  ………. makes no change since m is constant. Here the product mv is referred to as the linear momentum of the particle and may be defined as the amount of motion possessed by a moving body. It is a vector quantity and its SI units are kg.m/s or N.s Now F dt = d (mv) Integrating between the time interval t1 to t2 during which the velocity of the particle changes from v1 to v2. 2 2 1 1 t v 2 1 t v Fdt = d(mv) = mv - mv   2 1 t 1 2 t mv Fdt = mv  2 1 t t Fdt is the impulse on the particle, we therefore have 1 1-2 2mv + Impulse = mv ………. [2] Equation 12.2 is known as Impulse Momentum Equation. This equation gives rise to Principle of Impulse Momentum which may be stated as “for a particle or a system of particles acted, upon by forces during a time interval, the total impulse acting on the system is equal to the difference between the final momentum and initial momentum during that period”.
  • 4. www.ekeeda.com Contact : 9029006464 Email : care@ekeeda.com 4 APPLICATION OF IMPULSE MOMENTUM EQUATION Impulse Momentum liquation is a third equation other than the Newton‟s Second Law Equation and Work Energy Principle Equation, using which we can analyse the kinetics of particles. Impulse Momentum Equation involves parameters viz. force. mass, velocity and time. Thus the velocity of the particle at the new position may be worked out knowing the forces acting on the particle and the duration for which they act. A1so, if the initial and final velocities of the particle are known, the duration for which the particle is in motion can be found out. This method therefore eliminates the calculation of acceleration and many times use of the kinematics relations, to give direct results. We will further deduce the Conservation of Momentum Equation from the Impulse Momentum Equation and apply it to a system of particles where the momentum is conserved. To use the method of Impulse and Momentum, we need to draw. Three figures. The L.H.S. figure would show the initial momentum vector of the particle. The central figure shows the F.B.D. of the particle. The R.H.S. figure shows the final momentum vector of the particle. Drawing of these figures helps in writing the Impulse Momentum Equation. Since all terms in this equation are vector quantities, a proper sign convention for the direction need to be chosen before plugging in the values.
  • 5. www.ekeeda.com Contact : 9029006464 Email : care@ekeeda.com 5 Conservation of Momentum Equation Figure shows a man (B) standing at the end of a boat (A). The system of man and boat is initially at rest i.e. vA = 0 and vB = 0 If the man jumps off horizontally in the water with a velocity vB‟, he induces a backward motion to the boat, which now starts moving with a velocity vA‟. If the water resistance is neglected the question is, how is the motion of the boat induced? To jump off from the boat, the man exerts an impulsive force through his feet on the surface of the boat. This induces a reaction impulsive force to the man, which throws him in the water. Also since the water resistance is small, it may be neglected. Thus the impulsive force exerted by the man is the cause of the backward motion of boat. The interesting part here is that the impulsive force exerted by the man on the boat or the reaction impulsive force of the boat on the man are nothing but action and reaction forces acting for the same time interval. Due to this the net impulse in the direction of motion is zero. The Impulse Momentum Equation thereby reduces to Conservation of Momentum Equation. Applying this concept to the above example, we have mv1 + lmpulse1-2 = mv2 i.e. (mAvA + mBvB) + Impulse1-2 u = (mAv‟A + mBv‟B) 0 = mAvA ‟ + mBvB‟ or –mAvB ‟ = mBvB ‟ since mAvA = mBvB = 0 and Impulse,_, = 0, This relation indicates that knowing the masses of A and B and velocity of man (vB') as he jumps, we can find the velocity of boat (vA'). The negative sign attached to the magnitude of the velocity tells us that the boat moves in the opposite direction to that of man.
  • 6. www.ekeeda.com Contact : 9029006464 Email : care@ekeeda.com 6 The conservation of momentum phenomenon takes place in other similar situations such as when a bullet is fired from the gun and thereby the gun recoils backwards, or during the collision of two particles, the particles move with different velocities after the collision. In general we may say “for dynamic situations involving a system of particles, if the net impulse is zero, the momentum of the system is conserved”. The equation of Conservation of Momentum is therefore expressed as. Initial Momentum = Final Momentum …… [3]
  • 7. www.ekeeda.com Contact : 9029006464 Email : care@ekeeda.com 7 EXERCISE 1 1. A 1200 kg automobile is traveling at 90 kmph when brakes are fully applied, causing all four wheels to skid. If μk is 0.1, find the time required for the automobile to come to halt. 2. A dish slides 1200 mm on a level table before coming to rest. If μk = 0.18 between the dish and table, what was the time of travel. 3. A car at 72 kmph applies brakes and comes to rest in 8 sec. Find the minimum coefficient of friction between wheel and road. 4. A bullet of mass 1 gram has a velocity of 1000 m/s as it enters a feed block of wood. It comes to rest in 2 milliseconds after entering the block. Determine the average force that acted on the bullet and the distance penetrated by it. 5. A particle of mass 5 kg is acted upon by a force defined by a relation F = 60 t + 40 N. Find its velocity after 5 sec if it starts from rest and moves in a straight path. 6. A 380 gm football is kicked by a player so that it leaves the ground at an angle of 40° with the horizontal and lands on the ground 35 m away. Determine the impulse given to the ball. Also find the impulsive force if the contact was for 0.3 sec. 7. A 1500 kg car moving with a velocity of 10 kmph hits a compound wall and is brought to rest in 400 milliseconds. What is the average impulsive force exerted by the wall on the car bumper? 8. A ball of mass 100 g is moving towards a bat with a velocity of 25 m/s as shown in figure. When hit by a bat, the ball attains a velocity of 40 m/s. If the bat and ball are in contact for a period of 0.015 s. Determine the average impulse force exerted by the bat on the ball during the impact.
  • 8. www.ekeeda.com Contact : 9029006464 Email : care@ekeeda.com 8 9. A 2 kg mass rests on a smooth horizontal plane. It is struck with a 9N blow that lasts 0.02 second. Three seconds after the start of the first blow a second blow of 9N is delivered. This lasts for 0.01 second. What is the speed of the body after 4 seconds? Refer figure. 10.A 30 kg boy stands stationary on a 50 kg boat. If the boy jumps off the boat horizontally with a velocity of 3 m/s, determine the velocity of the boat just after the jump. a) A 30 kg boy is stationary on a 50 kg boat which is initially at rest. If the boy jumps off the boat horizontally with a velocity of 3 m/s relative to the boat, determine the velocity of the boat just after the jump and also the true velocity with which the boy jumps. Neglect water resistance. 11. Two men A (500 N) and B (700 N) lined up at one end of the boat (3000 N) and dived horizontally off the boat in succession with a velocity of 4 m/s relative to the boat. Find the velocity of the boat after the second man B had dived. Neglect water resistance.
  • 9. www.ekeeda.com Contact : 9029006464 Email : care@ekeeda.com 9 12. A 30 kg boy is standing on a 50 kg boat A which is initially at rest. If the boy jumps off horizontally with a speed of 2 m/s relative to the boat A on another identical stationary boat B, determine the speed of both the boats A and B. Neglect water resistance. IMPACT A collision of two bodies which takes place during a very small time interval and during which the colliding bodies exert relatively larger forces on each other is known as Impact. Line of Impact When two bodies collide, the line joining the common normals of the colliding bodies is known as Line of Impact. Refer figure. Types of Impact Impacts are basically divided into two categories viz. a Central Impact and an Eccentric Impact. When the mass centres of the colliding bodies lie on the Line of Impact, the Impact is said to be a Central Impact. When the mass centres of the colliding bodies are not located on the Line of Impact, we call such Impact to be an Eccentric Impact.
  • 10. www.ekeeda.com Contact : 9029006464 Email : care@ekeeda.com 10 Central Impact is further classified into Direct Impact and Oblique impact. In case of Direct Central Impact, the bodies travel along the Line of Impact i.e. their velocities are directed along the Line of Impact. On the other hand in case of Oblique Central Impact, the velocities of one or both the bodies are not directed along the Line of Impact.
  • 11. www.ekeeda.com Contact : 9029006464 Email : care@ekeeda.com 11 DIRECT CENTRAL IMPACT Let us now study the phenomenon of a Direct Central Impact. What really happens during an impact is quite interesting. Let us understand stage by stage as to what happens during a direct central impact. 1) Fig. (a) shows two particles A and B with velocities vA and vB. If vA is grater than vB, the impact will soon take place. 2) The period of impact is made of period of deformation and period of restitution. 3) During the period of deformation Fig (b), the two particles exert large impulsive force on each other. The deformation of both the particles continue till maximum deformation. At this stage both the particles are said to have momentarily united and move with common velocity v. Fig (c). 4) Now the period of restitution begins Fig (c). The two particles restore their shape during this period. Sometimes permanent deformations are also set in the particles. During this period the impulsive force exerted by the two particles is lesser than during the period of deformation. At the end of the period of restitution the two particles separate from each other. Fig. (d). 5) The two particles A and B now have new velocities vA‟ and vB‟ respectively. Fig. (e).
  • 12. www.ekeeda.com Contact : 9029006464 Email : care@ekeeda.com 12 Coefficient of Restitution Let us apply Impulse Momentum Equation in the x direction to the particle A during the period of deformation. Let P be the impulsive force exerted by particle B on A. At the start of period of deformation the velocity of particle A is vA and at the end of period of deformation its velocity changes to v, being the common velocity of A and B. 1 1-2 2mv +Impulse = mv A A Am v - Pdt = m v ………. (1) Here Pdt is the impulse due to the impulsive force P acting during the period of deformation. Now let us apply Impulse Momentum Equation to the particle A during the period of restitution. During this period a smaller impulsive force say R be exerted by particle B on A. At the start of period of restitution the velocity of A is v and changes to vA' at the end of the period of restitution. 1 1-2 2mv + Impulse = mv A A Am v - R dt = m v ' ………. (2) Here R dt is the impulse due to the impulsive force R acting during the period of restitution From equations (1) and (2) we have A A R dt v - v ' = v - vPdt   If R dt e = Pdt   then A A v - v ' e = v - v ………. (3)
  • 13. www.ekeeda.com Contact : 9029006464 Email : care@ekeeda.com 13 e is referred to as the Coefficient of Restitution and is defined as the ratio of the impulse exerted between the colliding particles during the period of restitution to the impulse exerted during the period of deformation. Similarly if the Impulse Momentum Equation is applied to the particle B, we get B B v ' - v e = v - v ……… (4) From basic algebra if B D B + D A = = , then A = C E C + E From equations (4) and (5) we therefore have, A B B A A B A B v - v ' + v '-v v ' - v ' e = e = v - v + v - v v - v  or  B A A Bv ' v ' e v v   ………. (5) we will refer equation 5 as Coefficient of Restitution Equation. The value of coefficient of restitution „e‟ lies between 0 and 1. It mainly depends on the nature of the bodies of collision. For example, the rebound velocity of a rubber ball which falls freely from a certain height on to the ground is different from that of a tennis ball which falls freely from the same height. A special case arises if e = 0 or if e = 1 If e = 0, the impact is referred to as a perfectly plastic impact. In such impact the two bodies move with same velocity after impact. The momentum is conserved but loss of energy takes place. If e = 1, the impact is referred to as a perfectly elastic impact. In such impact momentum is conserved‟ and there is also no loss of energy i.e. energy is also conserved. For all other impacts e lies between 0 and 1. In such impacts the momentum is conserved, but there is loss of energy during impact, as heat and sound is generated.
  • 14. www.ekeeda.com Contact : 9029006464 Email : care@ekeeda.com 14 Procedure to solve Direct Central Impact Problems Given velocities before impact i.e VA, VB and coefficient of restitution e and to find velocities after impact. 1. Step (1) During impact since there are no external forces acting on the colliding bodies, the momentum of the system is conserved, i.e. conservation of momentum is applicable, which is Initial Momentum = Final Momentum ' ' A A B B A A B Bm v m v m v m v   2. Step (2) Use Coefficient of Restitution Equation i.e.  ' ' B A A Bv v e v v   3. Step (3) solve the two equations to find the velocities vA' and vB' after impact. Note: Take proper sign conventions for the direction of velocities while using the Conservation of Momentum and Coefficient of Restitution Equations. Special Case of Direct Central Impact A special case happens when a ball has a direct central impact with a rigid body of infinite mass. For example, a ball hitting a wall or striking the ground. Consider Line of one such case of ball having a impact direct central impact with ground. Applying Coefficient of Restitution Equation, we get,  B A A B A A B B A A v ' v ' e v v 0 - v ' = e (v - 0) v = v ' 0 v ' = - e v       The - ve sign indicates that the motion of ball after impact is in the opposite direction  The magnitude of the velocity of a ball after a direct central impact with ground or wall is given by A Av ' = e v ……… equation for special case of direct impact.
  • 15. www.ekeeda.com Contact : 9029006464 Email : care@ekeeda.com 15 Relation between ‘e’ and Height of Bounce ‘h'’ Let a ball be dropped from a height „h‟ on the ground. Let h' be the height of rebound after „n‟ bounces. If „e‟ is the coefficient of restitution between the ball and the ground, then e is related to h' as 1 2nh' e = h       OBLIQUE CENTRAL IMPACT  When the velocities of either one or both colliding particles is not directed along the line of impact, the impact is said to be Oblique Central Impact. In such an impact not only the magnitudes of velocities after impact are unknown, but the new direction of travel is also unknown and needs to be worked out.  In an Oblique Central Impact the impulsive force acts along the line of impact. Thus velocity changes occur only along the line of impact and no change in velocity takes place in a direction perpendicular to the line of impact. Procedure to Solve Oblique Central Impact Problems Given: Initial velocities of particles A and B to be VA at an angle α and VB at an angle β , coefficient of restitution e. To find: Velocities vA' and vB' and new angles α ' and β ' after impact.
  • 16. www.ekeeda.com Contact : 9029006464 Email : care@ekeeda.com 16 Step 1) Let the line of impact be now called as n direction of impact. Let t be the direction perpendicular to the n direction. Step 2) Resolve the initial velocities vA and VB along the n and t direction so as to get their components vAn, vAt and vBn, vBt. Step 3) Work as a direct impact problem in the n direction, taking vAn and vBn as initial velocities. Using Conservation of Momentum and Coefficient of Restitution Equations, find velocity components vA'n and vB‟n after impact. Step 4) Work in the t direction. Since velocities don‟t change in the t direction, we have vA‟t = vAt and vB‟t = vBt Step 5) The magnitudes of velocities after impact are therefore given as   2 A A nv ' = v ' and     2 2 B B n B tv ' = v ' v ' The new direction of velocity is given as -1 A t A n v ' α' = tan v ' and -1 B t B n v ' β' = tan v ' Special Case of Oblique Central Impact A special case happens when a ball has oblique central impact with a rigid infinite mass such as a rigid wall or ground. Consider one such case of a ball having an oblique impact with the ground. Applying Coefficient of Restitution Equation in the n direction of impact, we get  B n A n An Bnv ' -v ' = e v - v
  • 17. www.ekeeda.com Contact : 9029006464 Email : care@ekeeda.com 17  A n An Bn B0 - v ' = e v - 0 v v 'n = 0  A n Anv ' = e v since velocities don‟t change in the t direction, we get A t A tv ' = v  The magnitude of the velocity components of a ball after oblique impact with ground or rigid wall is given by and A n An A t A t v ' = e v v ' = v    …… equations for special case of oblique impact. EXERCISE 2 1. Three identical cars A, B and C are ready for dispatch from a factory. At the instant the cars have their brakes released. An accidental forward push to car A causes it to move with a velocity of 2 m/s and hit car B. (a)Determine the speed of cars A and B just after the impact. (b)If a series of collision takes place between the three cars, determine the velocities of the three cars after all collisions are over. Take e = 0.7 between the bumpers. 2. Ball A of mass 0.6 kg moving to the right with a velocity of 4 m/s has a direct central impact with ball B of mass 0.3 kg moving to left with a velocity of 1 m/s. If after impact the velocity of ball B is observed to be 5 m/s to the right, determine the coefficient of restitution between the two balls. 3. A railway wagon weighing 400 kN and moving to the right with a velocity of 2 m/s, collides with another wagon weighing 200 kN and moving with a velocity of 5 m/s in the opposite direction. If the two wagons move together after impact, find the magnitude and direction of their common velocity. Also find the percentage loss of kinetic energy of the system. 4. A ball of mass 2kg impinges on a ball of mass 4 kg which is moving in the same direction as the first. The coefficient of restitution is % and the first ball is reduced to rest after the impact. Find the ratio between velocities of balls before the impact.
  • 18. www.ekeeda.com Contact : 9029006464 Email : care@ekeeda.com 18 5. A ball is dropped on to a smooth horizontal floor from a height of 4 m. On the second bounce it attains a height of 2.25 m. What is the coefficient of restitution between the ball and the floor? 6. A ball is thrown vertically downwards with a velocity v0 from a height of 1.2 m so that it hits the ground and just touches the ceiling after impact. If the ceiling is 4 m high from the ground find v0. Take e = 0.75. 7. A body A of mass 2 kg is projected upwards from the surface of the ground at t = 0 elocity 20 m/s. At the same time another body B of mass 2 kg is dropped along the same line from a height of 25 m. If they collide elastically, find the velocities of body A and B just after collision. 8. A smooth spherical ball A of mass 5 kg is moving in a horizontal plane from left to right with a velocity of 10 m/s. Another ball B of mass 6 kg traveling in a perpendicular direction with a velocity of 20 m/s collides with A in such a way that the line of impact is in the direction of motion of ball B. 9. Assuming e = 0.7, determine the velocities of balls A and B after impact. 10. The 9 kg ball moving down at 3m/sec strikes the 5.5kg ball moving at 2.5 m/sec as shown. The coefficient of restitution e = 0.8. Find the speeds vi and V2 after the impact
  • 19. www.ekeeda.com Contact : 9029006464 Email : care@ekeeda.com 19 11. Two identical spheres A and B approach each other with the velocities as shown. Determine the magnitude and direction of the velocity of each sphere after impact. Take e = 0.7 12. Two smooth spheres A and B having a mass of 2 kg and 4 kg respectively collide with initial velocities as shown in figure. If the coefficient of restitution for the spheres is e = 0.8, determine the velocities of each sphere after collision. 13. A bowler bowls a ball which strikes the ground at an angle of 60° with a speed of 20 m/s as shown. Find the velocity of the ball just after it strikes the ground. Assume smooth surfaces and e = 0.7 14. A ball is thrown against a frictionless wall. Its velocity before striking the wall is shown. If e =0.8, find the velocity after impact. 15. Two identical billiard balls collide with velocities as shown. Find the velocities of the balls after impact. Also find the percentage loss of kinetic energy. Take e = 0.9.
  • 20. www.ekeeda.com Contact : 9029006464 Email : care@ekeeda.com 20 16. Two smooth balls A (3 kg) and B (2 kg) strike with given velocities as shown. If e = 0.7 find the velocities of the balls after impact. 17. Two smooth balls A (3 kg) and B (4 kg) are moving with velocities as shown before they collide. After collision ball A rebounds in a direction at 40° counterclockwise with the horizontal axis. Determine the coefficient of restitution between the balls.
  • 21. www.ekeeda.com Contact : 9029006464 Email : care@ekeeda.com 21 COMBINATION PROBLEMS We have completed our study of the three different methods of solving kinetics of particles viz., Newton‟s Second Law, Work Energy Method and Impulse Momentum Method. We have also worked with the Conservation of Energy Principle and Conservation of Momentum Principle which were the offshoots of Work Energy Method and Impulse Momentum respectively. Problems on impact involving use of two equations viz, the Conservation of Momentum and Coefficient of Restitution Equations have been dealt with. So far we have used these methods in isolation, since the problem requirement was being satisfied with one method only. However certain problems may need application of more than one method to solve them. Such problems are referred to as Combination Problems. Combination Problems need to be first broken into parts, each part requiring the use of one of the methods at a time. While working with a particular part, the same procedure and equations are to be adopted as has been explained before. The value obtained from solving one part of the problem is used as a data for the next part and thus the entire Combination Problem is dealt with.
  • 22. www.ekeeda.com Contact : 9029006464 Email : care@ekeeda.com 22 EXERCISE 3 1. A shell of weight 200 N is fired from a gun with a velocity of 350 m/s. The gun and its carriage have a total weight of 12 kN. Find the stiffness of the spring which is required to bring the gun to a halt within 300 mm of the spring compression. 2. A sphere tied to a string of length L is released from rest from the horizontal position at A. The sphere swings as a pendulum and strikes a vertical wall at B. If e = 0.7, find the angle θ defining its total rebound. 3. A ball of 200 gm mass is propelled from A by a spring mechanism. The ball falls on a smooth floor and after rebounding at B falls in the cup at C. Determine the location x of the cup. The spring is initially compressed 100 mm. Take k = 3000 N/m and e = 0.75 4. Block A of mass 1.125 kg is released from rest in the position shown and slides without friction until it strikes the ball B of mass 1.8 kg of a simple pendulum. Knowing that coefficient of restitution between A and B is 0.9, determine a) the velocity of B immediately after impact b) the maximum angular displacement of the pendulum.
  • 23. www.ekeeda.com Contact : 9029006464 Email : care@ekeeda.com 23 5. A 3 kg sphere is released from rest and strikes a 5 kg block kept on a horizontal floor. If e = 0.7 between the block and sphere and μk = 0.3 between the block and ground, determine (a)the distance traveled by the block before it comes to rest. (b)the tension in the cable just after impact. 6. A 2 kg sphere A is released from rest when Aθ = 50° and strikes a 4 kg sphere B which is at rest. If e = 0.8 between the two spheres, determine the values of Aθ and Bθ corresponding to the highest position to which the spheres will rise after impact. Take length of both the pendulums to be 1 m. 7. A small steel ball is to be projected horizontally such that it bounces twice on the surface and lands into a cup placed at a distance of 8m as shown. If the coefficient of restitution for each impact is 0.8, determine the velocity of projection „u‟ of the ball. 8. A pile of 400 kg mass is being driven into ground with the help of a hammer of mass 1000 kg. Hammer falls through a constant height of 2.5 m. Assuming plastic impact between hammer and pile, find the number of blows required to drive the pile by 1 m when the resistance offered by the ground to penetration is 300 kN. 9. A pile hammer, weighing 15 kN drops from height of 600 mm on a pile of 7.5 kN. How deep does a single blow of hammer drive the pile if the resistance of the ground to pile is 140 kN? (Assume plastic impact and the ground resistance is constant) a) How many blows are required to drive the pile 1 m in the ground.
  • 24. www.ekeeda.com Contact : 9029006464 Email : care@ekeeda.com 24 10. A 3 kg mass falls on a 2 kg platform mounted on two springs. If k = 300 N/m of each spring, determine the maximum distance the platform moves down from its present static position after impact. Assume perfectly plastic impact. 11. A bullet of mass 30 gm moving horizontally with 400 m/s strikes a 2 kg wooden block suspended by a string 2.5 m long. To what maximum angle with vertical will the block and embedded bullet swing. 12. A particle of mass „m‟ starts from rest at A and slides down a smooth track ABCD held in a vertical plane. What should be the minimum height h so that the particle completes its journey on the track ABCD without falling off the track at C. 13. A ball slides down on a smooth inclined surface and strikes the ground at B. Determine the magnitude of velocity and direction of the ball after impact. Take e = 0.6 14. Two particles A (3 kg) and B (2 kg) are initially at rest 10 m apart on a 25° inclined plane. Particle B being ahead of A. If μk between A and incline is 0.15 and between B and incline is 0.25, determine the time taken and distance traveled by the two particles before they collide. If e = 0.75 find their velocities after collision.
  • 25. www.ekeeda.com Contact : 9029006464 Email : care@ekeeda.com 25 EXERCISE 4 Theory Questions Q.1. What is impulse and momentum? Explain its principle? Q.2. State and derive the Impulse Momentum Equation. Q.3. State the Law of Conservation of Momentum Principle. Q.4. What do you mean by impact, impulse and coefficient of restitution? Q.5. Write a short note on: Different types of impact and their characteristics. OR List the types of collisions. Q.6. Write a short note on Coefficient of Restitution. UNIVERSITY QUESTIONS 1. Two smooth balls collides as shown in figure. If mA = 1 kg, mB = 2 kg and e = 0-75. Find the velocities after impact. (10 Marks) 2. A ball of mass m kg hits an inclined smooth surface with a velocity AV =3m/s Find our velocity of rebound. (6 Marks) 3. If a ball is throw vertically down with a velocity of 10 m/s from a height of 3m. Find the maximum height it can reach after hitting the floor, if the coefficient of restitution is 0.7. (6 Marks)
  • 26. www.ekeeda.com Contact : 9029006464 Email : care@ekeeda.com 26 4. A collar of mass 1 kg is attached to a spring and slides without friction along a circular rod which lies in a horizontal plane. The spring is undeformed when the collar is at B. knowing that the collar is passing through the point D with a speed of 1.8 m/s, determine the speed of the collar when it passes through point C and B. Take stiffness of the spring, K = 250 N/m, Radius of the circular path = 300 mm and distance OA = 125 mm. (6 Marks) 5. A ball of mass „m‟ hits directly to a similar ball of mass „m‟ which is at rest. The velocity of first ball after impact is zero. Half of the initial kinetic energy is lost in impact. Find coefficient of restitution. (6 Marks)