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Tenth Edition
CHAPTER
10
VECTOR MECHANICS FOR ENGINEERS:
STATICS
Ferdinand P. Beer
E. Russell Johnston, Jr.
David F. Mazurek
Lecture Notes:
John Chen
Method of Virtual Work
California Polytechnic State University
© 2013 The McGraw-Hill Companies, Inc. All rights reserved.
Tenth
Edition
Vector Mechanics for Engineers: Statics
Contents
Introduction
Work of a Force
Work of a Couple
Principle of Virtual Work
Applications of the Principle of Virtual Work
Real Machines. Mechanical Efficiency
Sample Problem 10.1
Sample Problem 10.2
Sample Problem 10.3
Work of a Force During a Finite Displacement
Potential Energy
Potential Energy and Equilibrium
Stability and Equilibrium
Sample Problems 10.4
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Vector Mechanics for Engineers: Statics
Application
In certain cases, for example the analysis of a
system of connected rigid bodies, the method of
virtual work is a more efficient method than
applying equilibrium conditions.
© 2013 The McGraw-Hill Companies, Inc. All rights reserved.
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Vector Mechanics for Engineers: Statics
Introduction
• Principle of virtual work - if a particle, rigid body, or system of
rigid bodies which is in equilibrium under various forces is given
an arbitrary virtual displacement, the net work done by the external
forces during that displacement is zero.
• The principle of virtual work is particularly useful when applied
to the solution of problems involving the equilibrium of
machines or mechanisms consisting of several connected
members.
• If a particle, rigid body, or system of rigid bodies is in equilibrium,
then the derivative of its potential energy with respect to a variable
defining its position is zero.
• The stability of an equilibrium position can be determined from the
second derivative of the potential energy with respect to the position
variable.
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Vector Mechanics for Engineers: Statics
Work of a Force
 

dU  F  dr = work of the force F corresponding to

the displacement dr
dU  F ds cos
  0, dU   F ds
   , dU   F ds
  2 , dU  0
dU  Wdy
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Vector Mechanics for Engineers: Statics
Work of a Force
Forces which do no work:
• reaction at a frictionless pin due to rotation of a body
around the pin
• reaction at a frictionless surface due to motion of a
body along the surface
• weight of a body with cg moving horizontally
• friction force on a wheel moving without slipping
Sum of work done by several forces may be zero:
• bodies connected by a frictionless pin
• bodies connected by an inextensible cord
• internal forces holding together parts of a rigid body
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Vector Mechanics for Engineers: Statics
Work of a Couple
Small displacement of a rigid body:
• translation to A’B’
• rotation of B’ about A’ to B”
   

W   F  dr1  F  dr1  dr2 
 
 F  dr2  F ds2  F rd
 M d
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Vector Mechanics for Engineers: Statics
Principle of Virtual Work
• Imagine the small virtual displacement of particle which
is acted upon by several forces.
• The corresponding virtual work,
     
 


U  F1  r  F2  r  F3  r  F1  F2  F3  r
 
 R  r
Principle of Virtual Work:
• If a particle is in equilibrium, the total virtual work of forces
acting on the particle is zero for any virtual displacement.
• If a rigid body is in equilibrium, the total virtual work
of external forces acting on the body is zero for any
virtual displacement of the body.
• If a system of connected rigid bodies remains connected
during the virtual displacement, only the work of the
external forces need be considered.
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Vector Mechanics for Engineers: Statics
Applications of the Principle of Virtual Work
• Wish to determine the force of the vice on the
block for a given force P.
• Consider the work done by the external forces
for a virtual displacement . Only the forces P
and Q produce nonzero work.
U  0  UQ  U P  Q xB  P yC
x B  2l sin 
x B  2l cos 
yC  l cos
yC  l sin  
0  2Ql cos   Pl sin  
Q  12 P tan
• If the virtual displacement is consistent with the
constraints imposed by supports and connections,
only the work of loads, applied forces, and
friction forces need be considered.
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Vector Mechanics for Engineers: Statics
Real Machines. Mechanical Efficiency
  mechanical efficiency

output work of actual machine
output work of ideal machine
output work
input work
2Ql cos

Pl sin 
 1   cot 

• For an ideal machine without friction, the
output work is equal to the input work.
• When the effect of friction is
considered, the output work is reduced.
U  Qx B  PyC  Fx B  0
0  2Ql cos  Pl sin   Pl cos
Q  12 Ptan    
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Vector Mechanics for Engineers: Statics
Sample Problem 10.1
Determine the magnitude of the couple M required to
maintain the equilibrium of the mechanism.
SOLUTION:
• Apply the principle of virtual work
U  0  U M  U P
0  M  PxD
xD  3l cos
xD  3l sin 
0  M  P 3l sin  
M  3Pl sin 
• Note that no support reactions were needed to solve the
problem, nor was it necessary to take apart the machine at
any connection. A clear and accurate FBD is still highly
recommended, however.
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Vector Mechanics for Engineers: Statics
Sample Problem 10.2
Determine the expressions for  and for the tension in the
spring which correspond to the equilibrium position of the
spring. The unstretched length of the spring is h and the
constant of the spring is k. Neglect the weight of the
mechanism.
SOLUTION:
• Apply the principle of virtual work
U  U B  U F  0
0  PyB  FyC
yB  l sin 
yB  l cos
yC  2l sin 
yC  2l cos
F  ks
 k  yC  h 
 k 2l sin   h 
0  Pl cos   k 2l sin   h 2l cos 
P  2kh
4kl
F  12 P
sin  
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Vector Mechanics for Engineers: Statics
Sample Problem 10.3
SOLUTION:
• Create a free-body diagram for the platform
and linkage.
A hydraulic lift table consisting of two
identical linkages and hydraulic cylinders
is used to raise a 1000-kg crate. Members
EDB and CG are each of length 2a and
member AD is pinned to the midpoint of
EDB.
Determine the force exerted by each
cylinder in raising the crate for  = 60o, a
= 0.70 m, and L = 3.20 m.
• Apply the principle of virtual work for a
virtual displacement  recognizing that only
the weight and hydraulic cylinder do work.
U  0  QW  QFDH
• Based on the geometry, substitute expressions
for the virtual displacements and solve for the
force in the hydraulic cylinder.
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10 - 13
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Vector Mechanics for Engineers: Statics
Sample Problem 10.3
SOLUTION:
• Create a free-body diagram for the platform.
• Apply the principle of virtual work for a virtual
displacement 
U  0  QW  QFDH
0   12 Wy  FDH s

• Based on the geometry, substitute expressions for the
virtual displacements and solve for the force in the
hydraulic cylinder.
y  2a sin
y  2a cos 
s 2  a 2  L2  2aL cos 
2ss  2aLsin 
s 

0   12 W 2a cos   FDH
FDH  W
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s
cot
 
L
aL sin

s
aL sin

s
FDH  5.15 kN
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Vector Mechanics for Engineers: Statics
Work of a Force During a Finite Displacement
• Work of a force corresponding to an
infinitesimal displacement,
 
dU  F  dr
 F ds cos
• Work of a force corresponding to a finite
displacement,
U12 
s2
 F cos ds
s1
• Similarly, for the work of a couple,
dU  Md
U12  M  2  1 
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Vector Mechanics for Engineers: Statics
Work of a Force During a Finite Displacement
Work of a weight,
dU  Wdy
y2
U12    Wdy
y1
 Wy1  Wy 2
 Wy
Work of a spring,
dU   Fdx  kx dx
U12   12 F1  F2 x
x2
U12    kx dx
x1
 12 kx12  12 kx22
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Vector Mechanics for Engineers: Statics
Potential Energy
• Work of a weight
U12  Wy1  Wy 2
The work is independent of path and depends only on
Wy  Vg  potential energy of the body with

respect to the force of gravity W
   
U12  V g  V g
1
2
• Work of a spring,
U1 2  12 kx12  12 kx22
 Ve 1  Ve 2
Ve  potential energy of the bodywith
respect to the elastic force F
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Vector Mechanics for Engineers: Statics
Potential Energy
• When the differential work of a force is given by an
exact differential,
dU  dV
U12  V1  V2
 negative of change in potential energy
• Forces for which the work can be calculated from a change
in potential energy are conservative forces.
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Vector Mechanics for Engineers: Statics
Potential Energy and Equilibrium
• When the potential energy of a system is known,
the principle of virtual work becomes
dV
U  0  V   
d
dV
0
d
• For the structure shown,
V  Ve  Vg  12 kxB2  Wy C
 12 k 2l sin  2  W l cos 
• At the position of equilibrium,
dV
 0  l sin  4kl cos  W 
d
indicating two positions of equilibrium:
θ = 0, and θ = cos-1 (W/4kl)
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Vector Mechanics for Engineers: Statics
Stability of Equilibrium
dV
0
d
d 2V
0
2
d
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d 2V
0
2
d
Must examine higher
order derivatives.
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Vector Mechanics for Engineers: Statics
Sample Problem 10.4
SOLUTION:
• Derive an expression for the total potential
energy of the system.
V  Ve  Vg
• Determine the positions of equilibrium by
setting the derivative of the potential
energy to zero.
dV
0
d
Knowing that the spring BC is unstretched
when  = 0, determine the position or
positions of equilibrium and state whether
the equilibrium is stable, unstable, or
neutral.
• Evaluate the stability of the equilibrium
positions by determining the sign of the
second derivative of the potential energy.
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d 2V ?
 0
2
d
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Vector Mechanics for Engineers: Statics
Sample Problem 10.4
SOLUTION:
• Derive an expression for the total potential energy of the
system.
V  Ve Vg
 12 ks 2  mgy
 12 k a   mgbcos  
2
• Determine the positions of equilibrium by setting the
derivative of the potential energy to zero.

dV
 0  ka 2  mgbsin
d
sin 
2
4 kN m0.08m
2
ka


2
mgb
10kg 9.81m s 0.3m


 0.8699
 0
 Inc. All rights reserved.
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  0.902 rad  51.7
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Vector Mechanics for Engineers: Statics
Sample Problem 10.4
• Evaluate the stability of the equilibrium positions by
determining the sign of the second derivative of the
potential energy.
V  12 ka  mgbcos 
2
dV
 0  ka 2  mgbsin
d
 0
  0.902 rad  51.7


d 2V
 ka 2  mgbcos 
2
d


 4 kN m0.08m  10kg 9.81m s 2 0.3mcos 
2
 25.6  29.43cos 
at = 0:

at =
51.7o:
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d 2V
d
2
d 2V
d
2
 3.83  0
unstable
 7.36  0
stable
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