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Rigid Body
Particle
Object without extent Point in space Solid body with small dimensions
Rigid Body
An object which does not change its shape Considered as an aggregation of particles Distance between two points is a constant Suffer negligible deformation when subjected
to external forces Motion made up of translation and rotation
Motion of a Rigid Body
Translational– Every particle has the same instantaneous velocity
Rotational– Every particle has a common axis of rotation
Centre of Mass
Centre of mass of a system of discrete particles:
rmr
m
i ii
n
ii
n
1
1
,
Centre of mass for a body of continuous distribution:
rrdm
M
M
0 ,
It is the point as if all its mass is concentrated there
Located at the point of symmetry
Conditions of Equilibrium
For particle– Resultant force = 0
For rigid body– Resultant force = 0 and– Total moments = 0
Toppling
An object will not topple over if its centre of mass lies vertically over some point within the area of the base
Figure
Stability
Stable Equilibrium– The body tends to return to its original equilibrium p
osition after being slightly displaced– Disturbance gives greater gravitational potential ene
rgy– Figure
Unstable Equilibrium
The body does not tend to return to its original position after a small displacement
Disturbance reduces the gravitational potential energy
Neutral Equilibrium
The body remains in its new position after being displaced
No change in gravitational potential energy
Rotational Motion about an Axis
The farther is the point from the axis, the greater is the speed of rotation (v r)
Angular speed, , is the same for all particles
Rotational K.E.
The term is known as the moment of inertia
2
2
1mvERot
22
2
2
1
)(2
1
mr
rm
2mrI
2
2
1 IERot
Moment of Inertia (1)
Unit: kg m2 A measure of the reluctance of the body to its
rotational motion Depends on the mass, shape and size of the
body. Depends on the choice of axis For a continuous distribution of matter:
dmrI 2
Experimental Demonstration of the Energy Stored in a Rotating Object
Moment of Inertia (2)
A body composed of discrete point masses
i
iirmI ,2
A body composed of a continuous distribution of masses
I r dmM
2
0,
Moment of Inertia (3)
A body composed of several components:– Algebraic sum of the moment of inertia of all its
components
A scalar quantity Depends on
– mass– the way the mass is distributed– the axis of rotation
Radius of Gyration
If the moment of inertia I = Mk2, where M is the total mass of the body, then k is called the radius of gyration about the axis
Moment of Inertia of Common Bodies (1)
Thin uniform rod of mass m and length l– M.I. about an axis through its c
entre perpendicular to its length
I ml112
2
– M.I. about an axis through one end perpendicular to its length
I ml13
2
Moment of Inertia of Common Bodies (2)
Uniform rectangular laminar of mass m, breadth a and length b– About an axis through its centre parallel to its bread
thI mb
112
2
– About an axis through its centre parallel to its length
I ma112
2
Moment of Inertia of Common Bodies (3)
– About an axis through its centre perpendicular to its plane
I m a b 112
2 2( )
Uniform circular ring of mass m and radius R– About an axis through its centre perpendicular to its
plane
Moment of Inertia of Common Bodies (4)
I mR 2
Uniform circular disc of mass m and radius R– About an axis through its centre perpendicular to its plan
e
Moment of Inertia of Common Bodies (5)
2
2
1mRI
– The same expression can be applied to a cylinder of mass m and radius R
Uniform solid sphere of mass m and radius R
Moment of Inertia of Common Bodies (6)
I mR25
2
Theorems on Moment of Inertia (1)
Parallel Axes Theorem
I I MdG 2
Perpendicular Axes Theorem
Theorems on Moment of Inertia (2)
I I Ix y
Torque (1)
A measure of the moment of a force acting on a rigid body
– T = F·r Also known as a couple A vector quantity: direction
given by the right hand cork-screw rule
Depends on– Magnitude of force– Axis of rotation
Work done by a torque– Constant torque: W = T
– Variable torque:
Torque (2)
W Td
0
Kinetic Energies of a rigid body (1)
Translational K.E.
KE Mvtran 12
2
Rotational K.E. – It is the sum of the k.e. of all particles comprising the body– For a particle of mass m rotating with angular velocity :
KE m rrot 122( )
If a body of mass M and moment of inertia IG a
bout the centre of mass possesses both translational and rotational k.e., then
Kinetic Energies of a rigid body (2)
12
2 mr=
2
2
1 I
22
2
1
2
1 GIMvKE
Moment of inertia of a flywheel (1)
Determination of I of a flywheel
– Mount a flywheel– Make a chalk mark– Measure the axle diameter
by using slide calipers– Hang some weights to the
axle through a cord– Wind up the weights to a
height h above the ground– Release the weights and
start a stop watch at the same time
Moment of inertia of a flywheel (2)
– Measure:– the number of revolutions n of the flywheel before the
weights reach the floor– the number of revolutions N of the flywheel after the
weights have reached the floor and before the flywheel comes to rest
Theory
Moment of inertia of a flywheel (3)
axlethe at
friction against
done
flywheel
the by gained
energykinetic
ightfalling we
theby gained
energykinetic
ightfalling wethe by
lostenergy potentialwork
nfImvmgh 22
2
1
2
1
nfImr 222
2
1
2
1
where f = work done against friction per revolution
….. (1)
– When the flywheel comes to rest: Loss in k.e. = work done against friction
Moment of inertia of a flywheel (4)
NfI 2
2
1 ….. (2)
(2) In (1)
]1[2
1
2
1 22
N
nImvmgh
)]1([2
12
2
N
n
r
Imv …. (3)
Moment of inertia of a flywheel (5)
– The hanging weights take time t to fall from rest through a vertical height h
Total vertical displacement = average vertical velocity time
tv
h
2
0
t
hv
2
Knowing v, I can be calculated from (3)
Applications of flywheels
In motor vehicle engines In toy cars
Angular momentum
The angular momentum of a particle rotating about an axis is the moment of its linear momentum about that axis.
A mr ( )2
2mr
I
Conservation of angular momentum (1)
The angular momentum about an axis of a given rotating body or system of bodies is constant, if the net torque on the object is zero
As)(
Idt
d
dt
dIT
– If T = 0, I = constant
Examples– High diver jumping from a jumping board
Conservation of angular momentum (2)
– Dancer on skates
Conservation of angular momentum (3)
Experimental verification using a bicycle wheel
– Mass dropped on to a rotating turntable
Application– Determination of the moment of inertia of a turntable
Set the turntable rotating with an angular velocity Drop a small mass to the platform, changes to a lower
value ’ If there is no frictional couple, the angular momentum is
conserved, I = I’ ’ = (I + mr2) ’
, ’ can be determined by measuring the time taken for the table to make a given number of revolutions and I can then be solved
Conservation of angular momentum (4)
Rotational motion about a fixed axis (1)
T = I d’Alembert’s Principle
– The rate of change of angular momentum of a rigid body rotating about a fixed axis equals the moment about that axis of the external forces acting on the body
)()( FpIdt
d
Rotational motion about a fixed axis (2)
Iddt
T
i.e. I = T
Compound pendulum (1)
Applying the d’Alembert’s Principle to the rigid body
Iddt
Mghs
2
2
sin .
I M k hs ( )2 2But
where k is the radius of gyration about its centre of mass G
For small oscillations
Compound pendulum (2)
M k hddt
Mgh( ) sin ,2 22
2
ddt
ghk h
2
2 2 2
SHM with period
hg
hkT
22
2
It has the same period of oscillation as the simple pendulum of length
Compound pendulum (3)
lk h
h
2 2
l is called the length of the equivalent simple pendulum
The point O, where OS passes through G and has the length of the equivalent simple pendulum, is called the centre of oscillation
S and O are conjugate to each other
The period T is a minimum when h = k (see expt. results)
Compound pendulum (4)
Torsional pendulum
I
c
where c = torsional constant
I = moment of inertia
SHM with period
c
IT 2
Rolling objects (1)
r
T
r
T
dv
2
P has two components:– v parallel to the ground– r(=v) perpendicular to the
radius OP
If P coincides with Q, the two velocity components are oppositely directed. Thus Q is instantaneously at rest
Rolling objects (2)
Hence, for pure rolling, there is no work done against friction at the point of contact
Rolling objects (3)
Kinetic energy of a rolling object
Total kinetic energy= translational K.E. + rotational K.E.
= 22
2
1
2
1 Imv
Stable Equilibrium
No toppling
Compound pendulum
