J. Peraire
16.07 Dynamics
Fall 2004
Version 1.1
Lecture D19 - 2D Rigid Body Dynamics: Work and Energy
In this lecture, we will revisit the principle of work and energy introduced in lecture D7 for particle dynamics,
and extend it to 2D rigid body dynamics.
Kinetic Energy for a 2D Rigid Body
We start by recalling the kinetic energy expression for a system of particles derived in lecture D17,
T = 12mv2G +
nsummationdisplay
i=1
1
2mi ˙r
′
i
2 ,
where n is the total number of particles, mi denotes the mass of particle i, and r′i is the position vector of
particle i with respect to the center of mass, G. Also, m = summationtextni=1 mi is the total mass of the system, and
vG is the velocity of the center of mass. The above expression states that the kinetic energy of a system of
particles equals the kinetic energy of a particle of mass m moving with the velocity of the center of mass,
plus the kinetic energy due to the motion of the particles relative to the center of mass, G.
For a 2D rigid body, the velocity of all particles relative to the center of mass is a pure rotation. Thus, we
can write
˙r′i = ω ×r′i.
Therefore, we have
nsummationdisplay
i=1
1
2mi ˙r
′
i
2 =
nsummationdisplay
i=1
1
2mi(ω ×r
′
i) · (ω ×r
′
i) =
nsummationdisplay
i=1
1
2mir
′
i
2ω2 ,
where we have used the fact that ω and r′i are perpendicular. The term summationtextni=1 mir′i2 is easily recognized as
the moment of inertia, IG, about the center of mass, G. Therefore, for a 2D rigid body, the kinetic energy
is simply,
T = 12mv2G + 12IGω2 . (1)
1
When the body is rotating about a fixed point O, we can write IO = IG +mr2G and
T = 12mv2G + 12(IO ?mr2G)ω2 = 12IOω2 ,
since vG = ωrG.
The above expression is also applicable in the more general case when there is no fixed point in the motion,
provided that O is replaced by the instantaneous center of rotation. Thus, in general,
T = 12ICω2 .
We shall see that, when the instantaneous center of rotation is known, the use of the above expression does
simplify the algebra considerably.
Work
Recall that the work done by a force, F, over an infinitesimal displacement, dr, is dW = F · dr. If Ftotali
denotes the resultant of all forces acting on particle i, then we can write,
dWi = Ftotali ·dri = midvidt ·dri = mivi ·dvi = d(12miv2i ) = d(Ti) ,
where we have assumed that the velocity is measured relative to an inertial reference frame, and, hence,
Ftotali = miai . The above equation states that the work done on particle i by the resultant force Ftotali is
equal to the change in its kinetic energy.
The total work done on particle i, when moving from position 1 to position 2, is
(Wi)1?2 =
integraldisplay 2
1
dWi ,
and, summing over all particles, we obtain the principle of work and energy for systems of particles,
T1 +
nsummationdisplay
i=1
(Wi)1?2 = T2 . (2)
The force acting on each particle will be the sum of the internal forces caused by the other particles, and
the external forces. We now consider separately the work done by the internal and external forces.
Internal Forces
We shall assume, once again, that the internal forces due to interactions between particles act along the lines
joining the particles, thereby satisfying Newton’s third law. Thus, if fij denotes the force that particle j
exerts on particle i, we have that fij is parallel to ri ?rj, and satisfies fij = ?fji.
Let us now look at two particles, i and j, undergoing an infinitesimal rigid body motion, and consider the
term,
fij ·dri +fji ·drj . (3)
2
If we write drj = dri +d(rj ?ri), then,
fij ·dri +fji ·drj = fij ·(dri ?dri) ?fij ·d(rj ?ri) = ?fij ·d(rj ?ri).
It turns out that fij · d(rj ? ri) is zero, since d(rj ? ri) is perpendicular to rj ? ri, and hence it is also
perpendicular to fij. The orthogonality between d(rj?ri) and rj?ri follows from the fact that the distance
between any two particles in a rigid body must remain constant (i.e. (rj ?ri)·(rj ?ri) = (rj ?ri)2 = const;
thus differentiating, we have 2d(rj ?ri) ·(rj ?ri) = 0).
We conclude that, since all the work done by the internal forces can be written as a sum of terms of the
form 3, then the contribution of all the internal forces to the term summationtextni=1(Wi)1?2 in equation 2, is zero.
External Forces
We have established in the previous section that only the external forces to the rigid body are capable of
doing any work. Thus, the total work done on the body will be
nsummationdisplay
i=1
(Wi)1?2 =
nsummationdisplay
i=1
integraldisplay (ri)2
(ri)1
Fi ·dr ,
where Fi is the sum of all the external forces acting on particle i.
Work done by couples
If the sum of the external forces acting on the rigid body is zero, it is still possible to have non-zero work.
Consider, for instance, a moment M = Fa acting on a rigid body. If the body undergoes a pure translation,
it is clear that all the points in the body experience the same displacement, and, hence, the total work done
by a couple is zero. On the other hand, if the body experiences a rotation dθ, then the work done by the
couple is
dW = F a2dθ +F a2dθ = F adθ = Mdθ .
If M is constant, the work is simply W1?2 = M(θ2 ?θ1)
3
Conservative Forces
When the forces can be derived from a potential energy function, V , we say the forces are conservative. In
such cases, we have that F = ??V , and the work and energy relation in equation 2 takes a particularly
simple form. Recall that a necessary, but not sufficient, condition for a force to be conservative is that it
must be a function of position only, i.e. F(r) and V (r). Common examples of conservative forces are gravity
(a constant force independent of the height), gravitational attraction between two bodies (a force inversely
proportional to the squared distance between the bodies), and the force of a perfectly elastic spring.
The work done by a conservative force between position r1 and r2 is
W1?2 =
integraldisplay r2
r1
F ·dr = [?V]r2r1 = V(r1)?V (r2) = V1 ?V2 .
Thus, if we call WNC1?2 the work done by all the external forces which are non conservative, we can write the
general expression,
T1 +V1 +WNC1?2 = T2 +V2 .
Of course, if all the forces that do work are conservative, we obtain conservation of total energy, which can
be expressed as,
T +V = constant .
Gravity Potential for a Rigid Body
In this case, the potential Vi associated with particle i is simply Vi = migzi, where zi is the height of particle
i above some reference height. The force acting on particle i will then be Fi = ??Vi. The work done on
the whole body will be
nsummationdisplay
i=1
integraldisplay r2i
r1i
fi ·dri =
nsummationdisplay
i=1
((Vi)1 ?(Vi)2) =
nsummationdisplay
i=1
mig((zi)1 ?(zi)2 = V1 ?V2 ,
where the gravity potential for the rigid body is simply,
V =
nsummationdisplay
i=1
migzi = mgzG ,
where zG is the z coordinate of the center of mass.
Example Cylinder on a Ramp
We consider a homogeneous cylinder released from rest at the top of a ramp of angle φ, and use conservation
of energy to derive an expression for the velocity of the cylinder.
4
Conservation of energy implies that T+V = Tinitial+Vinitial. Initially, the kinetic energy is zero, Tinitial = 0.
Thus, for a later time, the kinetic energy is given by
T = Vinitial ?V = mgssinφ ,
where s is the distance traveled down the ramp. The kinetic energy is simply T = 12ICω2, where IC =
IG + mR2 is the moment of inertia about the instantaneous center of rotation C, and ω is the angular
velocity. Thus, ICω2 = 2mgssinφ , or,
v2 = 2gssinφ1 + (I
G/mR2)
,
since ω = v/R.
Equilibrium and Stability
If all the forces acting on the body are conservative, then the potential energy can be used very effectively
to determine the equilibrium positions of a system and the nature of the stability at these positions. Let us
assume that all the forces acting on the system can be derived from a potential energy function, V. It is
clear that if F = ??V = 0 for some position, this will be a point of equilibrium in the sense that if the
body is at rest (kinetic energy zero), then there will be no forces (and hence, no acceleration) to change
the equilibrium, since the resultant force F is zero. Once equilibrium has been established, the stability of
the equilibrium point can be determine by examining the shape of the potential function. If the potential
function has a minimum at the equilibrium point, then the equilibrium will be stable. This means that if
the potential energy is at a minimum, there is no potential energy left that can be traded for kinetic energy.
Analogously, if the potential energy is at a maximum, then the equilibrium point is unstable.
Example Equilibrium and Stability
A cylinder of radius R, for which the center of gravity, G, is at a distance d from the geometric center, C,
lies on a rough plane inclined at an angle φ.
5
Since gravity is the only external force acting on the cylinder that is capable of doing any work, we can
examine the equilibrium and stability of the system by considering the potential energy function. We have
zC = zC0 ?Rθsinφ, where zC0 is the value of zC when θ = 0. Thus, since d = |CG|, we have,
V = mgzG = mg(zC +dsinθ) = mg(zC0 ?Rθsinφ+dsinθ) .
The equilibrium points are given by ?V = 0, but, in this case, since the position of the system is uniquely
determined by a single coordinate, e.g. θ, we can write
?V = dVdθ?θ ,
which implies that, for equilibrium, dV/dθ = mg(?Rsinφ + dcosθ) = 0, or, cosθ = (Rsinφ)/d. If
d < Rsinφ, there will be no equilibrium positions. On the other hand, if d ≥ Rsinφ, then θeq. =
cos?1[(Rsinφ)/d] is an equilibrium point. We note that if θeq. is an equilibrium point, then ?θeq. is also an
equilibrium point (i.e. cosθ = cos(?θ)).
In order to study the stability of the equilibrium points, we need to determine whether the potential energy
is a maximum or a minimum at these points. Since d2V/dθ2 = ?mgdsinθ, we have that when θeq. < 0,
then d2V/dθ2 > 0 and the potential energy is a minimum at that point. Consequently, for θeq. < 0, the
equilibrium is stable. On the other hand, for θeq. > 0, the equilibrium point is unstable.
ADDITIONAL READING
J.L. Meriam and L.G. Kraige, Engineering Mechanics, DYNAMICS, 5th Edition
6/6, 6/7
6