Eighth
Edition
Vector Mechanics for Engineers: Statics
CE 102 Statics
Chapter 2
Statics of Particles
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2-1
Eighth
Edition
Vector Mechanics for Engineers: Statics
Contents
Introduction
Resultant of Two Forces
Vectors
Addition of Vectors
Resultant of Several Concurrent
Forces
Sample Problem 2.1
Sample Problem 2.2
Rectangular Components of a Force:
Unit Vectors
Addition of Forces by Summing
Components
Sample Problem 2.3
Equilibrium of a Particle
Free-Body Diagrams
Sample Problem 2.4
Sample Problem 2.5
Rectangular Components in Space
Sample Problem 2.6
© 2007 The McGraw-Hill Companies, Inc. All rights reserved.
2-2
Eighth
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Vector Mechanics for Engineers: Statics
Introduction
• The objective for the current chapter is to investigate the effects of forces
on particles:
- replacing multiple forces acting on a particle with a single
equivalent or resultant force,
- relations between forces acting on a particle that is in a
state of equilibrium.
• The focus on particles does not imply a restriction to miniscule bodies.
Rather, the study is restricted to analyses in which the size and shape of
the bodies is not significant so that all forces may be assumed to be
applied at a single point.
© 2007 The McGraw-Hill Companies, Inc. All rights reserved.
2-3
Eighth
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Vector Mechanics for Engineers: Statics
Resultant of Two Forces
• force: action of one body on another;
characterized by its point of application,
magnitude, line of action, and sense.
• Experimental evidence shows that the
combined effect of two forces may be
represented by a single resultant force.
• The resultant is equivalent to the diagonal of
a parallelogram which contains the two
forces in adjacent legs.
• Force is a vector quantity.
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2-4
Eighth
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Vector Mechanics for Engineers: Statics
Vectors
• Vector: parameters possessing magnitude and direction
which add according to the parallelogram law. Examples:
displacements, velocities, accelerations.
• Scalar: parameters possessing magnitude but not
direction. Examples: mass, volume, temperature
• Vector classifications:
- Fixed or bound vectors have well defined points of
application that cannot be changed without affecting
an analysis.
- Free vectors may be freely moved in space without
changing their effect on an analysis.
- Sliding vectors may be applied anywhere along their
line of action without affecting an analysis.
• Equal vectors have the same magnitude and direction.
• Negative vector of a given vector has the same magnitude
and the opposite direction.
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2-5
Eighth
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Vector Mechanics for Engineers: Statics
Addition of Vectors
• Trapezoid rule for vector addition
• Triangle rule for vector addition
• Law of cosines,
C
B
C
B
R 2  P 2  Q 2  2 PQ cos B
  
R  PQ
• Law of sines,
sin A sin B sin C


Q
R
A
• Vector addition is commutative,
   
PQ  Q P
• Vector subtraction
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2-6
Eighth
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Vector Mechanics for Engineers: Statics
Addition of Vectors
• Addition of three or more vectors through
repeated application of the triangle rule
• The polygon rule for the addition of three or
more vectors.
• Vector addition is associative,
  
     
P  Q  S  P  Q   S  P  Q  S 
• Multiplication of a vector by a scalar
© 2007 The McGraw-Hill Companies, Inc. All rights reserved.
2-7
Eighth
Edition
Vector Mechanics for Engineers: Statics
Resultant of Several Concurrent Forces
• Concurrent forces: set of forces which all
pass through the same point.
A set of concurrent forces applied to a
particle may be replaced by a single
resultant force which is the vector sum of the
applied forces.
• Vector force components: two or more force
vectors which, together, have the same effect
as a single force vector.
© 2007 The McGraw-Hill Companies, Inc. All rights reserved.
2-8
Eighth
Edition
Vector Mechanics for Engineers: Statics
Sample Problem 2.1
SOLUTION:
The two forces act on a bolt at
A. Determine their resultant.
• Graphical solution - construct a
parallelogram with sides in the same
direction as P and Q and lengths in
proportion. Graphically evaluate the
resultant which is equivalent in direction
and proportional in magnitude to the the
diagonal.
• Trigonometric solution - use the triangle
rule for vector addition in conjunction
with the law of cosines and law of sines
to find the resultant.
© 2007 The McGraw-Hill Companies, Inc. All rights reserved.
2-9
Eighth
Edition
Vector Mechanics for Engineers: Statics
Sample Problem 2.1
• Graphical solution - A parallelogram with sides
equal to P and Q is drawn to scale. The
magnitude and direction of the resultant or of
the diagonal to the parallelogram are measured,
R  98 N   35
• Graphical solution - A triangle is drawn with P
and Q head-to-tail and to scale. The magnitude
and direction of the resultant or of the third side
of the triangle are measured,
R  98 N   35
© 2007 The McGraw-Hill Companies, Inc. All rights reserved.
2 - 10
Eighth
Edition
Vector Mechanics for Engineers: Statics
Sample Problem 2.1
• Trigonometric solution - Apply the triangle rule.
From the Law of Cosines,
R 2  P 2  Q 2  2 PQ cos B
 40N 2  60N 2  240N 60N  cos155
R  97.73N
From the Law of Sines,
sin A sin B

Q
R
sin A  sin B
Q
R
 sin 155
A  15.04
  20  A
  35.04
© 2007 The McGraw-Hill Companies, Inc. All rights reserved.
60N
97.73N
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Vector Mechanics for Engineers: Statics
Sample Problem 2.2
SOLUTION:
• Find a graphical solution by applying the
Parallelogram Rule for vector addition. The
parallelogram has sides in the directions of
the two ropes and a diagonal in the direction
of the barge axis and length proportional to
5000 N.
A barge is pulled by two tugboats.
If the resultant of the forces
exerted by the tugboats is 5000 N
directed along the axis of the
barge, determine
a) the tension in each of the ropes
for  = 45o,
b) the value of  for which the
tension in rope 2 is a minimum.
• Find a trigonometric solution by applying
the Triangle Rule for vector addition. With
the magnitude and direction of the resultant
known and the directions of the other two
sides parallel to the ropes given, apply the
Law of Sines to find the rope tensions.
• The angle for minimum tension in rope 2 is
determined by applying the Triangle Rule
and observing the effect of variations in .
© 2007 The McGraw-Hill Companies, Inc. All rights reserved.
2 - 12
Eighth
Edition
Vector Mechanics for Engineers: Statics
Sample Problem 2.2
• Graphical solution - Parallelogram Rule
with known resultant direction and
magnitude, known directions for sides.
T1  3700 N T2  2600 N
• Trigonometric solution - Triangle Rule
with Law of Sines
T1
T2
5000 N


sin 45 sin 30 sin 105
T1  3660 N T2  2590 N
© 2007 The McGraw-Hill Companies, Inc. All rights reserved.
2 - 13
Eighth
Edition
Vector Mechanics for Engineers: Statics
Sample Problem 2.2
• The angle for minimum tension in rope 2 is
determined by applying the Triangle Rule
and observing the effect of variations in .
• The minimum tension in rope 2 occurs when
T1 and T2 are perpendicular.
T2  5000 N sin 30
T2  2500 N
T1  5000 N  cos 30
T1  4330 N
  90  30
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  60
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Vector Mechanics for Engineers: Statics
Rectangular Components of a Force: Unit Vectors
• May resolve a force vector into perpendicular
components so that the resulting parallelogram is a
rectangle. Fx and Fy are referred to as rectangular
vector components and
 

F  Fx  Fy


• Define perpendicular unit vectors i and j which are
parallel to the x and y axes.
• Vector components may be expressed as products of
the unit vectors with the scalar magnitudes of the
vector components.



F  Fx i  Fy j

Fx and Fy are referred to as the scalar components of F
© 2007 The McGraw-Hill Companies, Inc. All rights reserved.
2 - 15
Eighth
Edition
Vector Mechanics for Engineers: Statics
Addition of Forces by Summing Components
• Wish to find the resultant of 3 or more
concurrent forces,
   
R  PQS
• Resolve each force into rectangular components








Rx i  R y j  Px i  Py j  Qx i  Q y j  S x i  S y j


 Px  Qx  S x i  Py  Q y  S y  j
• The scalar components of the resultant are
equal to the sum of the corresponding scalar
components of the given forces.
R y  Py  Q y  S y
Rx  Px  Qx  S x
  Fx
  Fy
• To find the resultant magnitude and direction,
2
2
1 R y
R  Rx  R y
  tan
Rx
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2 - 16
Eighth
Edition
Vector Mechanics for Engineers: Statics
Sample Problem 2.3
SOLUTION:
• Resolve each force into rectangular
components.
• Determine the components of the
resultant by adding the corresponding
force components.
Four forces act on bolt A as shown.
Determine the resultant of the force
on the bolt.
• Calculate the magnitude and direction
of the resultant.
© 2007 The McGraw-Hill Companies, Inc. All rights reserved.
2 - 17
Eighth
Edition
Vector Mechanics for Engineers: Statics
Sample Problem 2.3
SOLUTION:
• Resolve each force into rectangular components.
force mag

F1 150

F2
80

F3 110

F4 100
x  comp
y  comp
 129.9
 75.0
 27.4
 75.2
0
 110.0
 96.6
 25.9
Rx  199.1 R y  14.3
• Determine the components of the resultant by
adding the corresponding force components.
• Calculate the magnitude and direction.
R  199.12  14.32
14.3 N
tan 
199.1 N
© 2007 The McGraw-Hill Companies, Inc. All rights reserved.
R  199.6 N
  4.1
2 - 18
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Vector Mechanics for Engineers: Statics
Equilibrium of a Particle
• When the resultant of all forces acting on a particle is zero, the particle is
in equilibrium.
• Newton’s First Law: If the resultant force on a particle is zero, the particle will
remain at rest or will continue at constant speed in a straight line.
• Particle acted upon by
two forces:
- equal magnitude
- same line of action
- opposite sense
• Particle acted upon by three or more forces:
- graphical solution yields a closed polygon
- algebraic solution


R  F  0
 Fx  0
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 Fy  0
2 - 19
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Vector Mechanics for Engineers: Statics
Free-Body Diagrams
Space Diagram: A sketch showing
the physical conditions of the
problem.
Free-Body Diagram: A sketch showing
only the forces on the selected particle.
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2 - 20
Eighth
Edition
Vector Mechanics for Engineers: Statics
Sample Problem 2.4
SOLUTION:
• Construct a free-body diagram for the
particle at the junction of the rope and
cable.
• Apply the conditions for equilibrium by
creating a closed polygon from the
forces applied to the particle.
In a ship-unloading operation, a
3500-N automobile is supported by
a cable. A rope is tied to the cable
and pulled to center the automobile
over its intended position. What is
the tension in the rope?
• Apply trigonometric relations to
determine the unknown force
magnitudes.
© 2007 The McGraw-Hill Companies, Inc. All rights reserved.
2 - 21
Eighth
Edition
Vector Mechanics for Engineers: Statics
Sample Problem 2.4
SOLUTION:
• Construct a free-body diagram for the
particle at A.
• Apply the conditions for equilibrium.
• Solve for the unknown force magnitudes.
TAC
TAB
3500 N


sin 120 sin 2 sin 58
TAB  3570 N
TAC  144 N
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2 - 22
Eighth
Edition
Vector Mechanics for Engineers: Statics
Sample Problem 2.5
SOLUTION:
• Choosing the hull as the free body,
draw a free-body diagram.
• Express the condition for equilibrium
for the hull by writing that the sum of
all forces must be zero.
It is desired to determine the drag force
at a given speed on a prototype sailboat
hull. A model is placed in a test
channel and three cables are used to
align its bow on the channel centerline.
For a given speed, the tension is 40 N
in cable AB and 60 N in cable AE.
• Resolve the vector equilibrium
equation into two component
equations. Solve for the two unknown
cable tensions.
Determine the drag force exerted on the
hull and the tension in cable AC.
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2 - 23
Eighth
Edition
Vector Mechanics for Engineers: Statics
Sample Problem 2.5
SOLUTION:
• Choosing the hull as the free body, draw a
free-body diagram.
7m
 1.75
4m
  60.25
tan  
1.5 m
 0.375
4m
  20.56
tan  
• Express the condition for equilibrium
for the hull by writing that the sum of
all forces must be zero.
 



R  T AB  T AC  T AE  FD  0
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2 - 24
Eighth
Edition
Vector Mechanics for Engineers: Statics
Sample Problem 2.5
• Resolve the vector equilibrium equation into
two component equations. Solve for the two
unknown cable tensions.












T AB
40 N sin 60.26 i 40 N cos 60.26 j


 34.73 N i  19.84 N  j



T AC  T AC sin 20.56 i  T AC cos 20.56 j


 0.3512 T AC i  0.9363T AC j


T  60 N j


FD  FD i

R0

  34.73  0.3512 T AC  FD i

 19.84  0.9363T AC  60 j
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2 - 25
Eighth
Edition
Vector Mechanics for Engineers: Statics
Sample Problem 2.5

R0

  34.73  0.3512T AC  FD  i

 19.84  0.9363T AC  60 j
This equation is satisfied only if each component
of the resultant is equal to zero.
 Fx  0 0  34.73  0.3512TAC  FD
 Fy  0 0  19.84  0.9363TAC  60
TAC  42.9 N
FD  19.66 N
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2 - 26
Eighth
Edition
Vector Mechanics for Engineers: Statics
Rectangular Components in Space

• The vector F is
contained in the
plane OBAC.

• Resolve F into
horizontal and vertical
components.
Fy  F cos y
Fh  F sin  y
© 2007 The McGraw-Hill Companies, Inc. All rights reserved.
• Resolve Fh into
rectangular components.
Fx  Fh cos f
 F sin  y cos f
F z  Fh sin f
 F sin  y sin f
2 - 27
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Vector Mechanics for Engineers: Statics
Rectangular Components in Space

• With the angles between F and the axes,
Fx  F cos x Fy  F cos y Fz  F cos z




F  Fx i  Fy j  Fz k



 F cos x i  cos y j  cos z k 

 F




  cos x i  cos y j  cos z k


•  is a unit vector along the line of action of F
and cos x , cos
  y , and cos z are the direction
cosines for F
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2 - 28
Eighth
Edition
Vector Mechanics for Engineers: Statics
Rectangular Components in Space
Direction of the force is defined by
the location of two points,
M  x1 , y1 , z1  and N  x2 , y 2 , z 2 

d  vector joining M and N



 d xi  d y j  d z k
d x  x2  x1 d y  y 2  y1 d z  z 2  z1


F  F

 1


  d x i  d y j  d z k 
d
Fd y
Fd x
Fd z
Fx 
Fy 
Fz 
d
d
d
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2 - 29
Eighth
Edition
Vector Mechanics for Engineers: Statics
Sample Problem 2.6
SOLUTION:
• Based on the relative locations of the
points A and B, determine the unit
vector pointing from A towards B.
• Apply the unit vector to determine the
components of the force acting on A.
The tension in the guy wire is 2500 N.
Determine:
• Noting that the components of the unit
vector are the direction cosines for the
vector, calculate the corresponding
angles.
a) components Fx, Fy, Fz of the force
acting on the bolt at A,
b) the angles x, y, z defining the
direction of the force
© 2007 The McGraw-Hill Companies, Inc. All rights reserved.
2 - 30
Eighth
Edition
Vector Mechanics for Engineers: Statics
Sample Problem 2.6
SOLUTION:
• Determine the unit vector pointing from A
towards B.



AB   40 m  i  80 m  j  30 m k
AB 
 40 m 2  80 m 2  30 m 2
 94.3 m
  40    80    30  
 
i  
 j 
k
94
.
3
94
.
3
94
.
3

 
 




 0.424 i  0.848 j  0.318k

• Determine the components of the force.


F  F



 2500 N  0.424 i  0.848 j  0.318k 



  1060 N i  2120 N  j  795 N k
© 2007 The McGraw-Hill Companies, Inc. All rights reserved.
2 - 31
Eighth
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Vector Mechanics for Engineers: Statics
Sample Problem 2.6
• Noting that the components of the unit vector are
the direction cosines for the vector, calculate the
corresponding angles.




  cos x i  cos y j  cos z k



 0.424 i  0.848 j  0.318k
 x  115.1
 y  32.0 
 z  71.5
© 2007 The McGraw-Hill Companies, Inc. All rights reserved.
2 - 32
Problem 2.7
240 lb
A
30o

75 lb
50o
75 lb
The direction of the 75-lb
forces may vary, but the
angle between the forces
is always 50o. Determine
the value of  for which
the resultant of the forces
acting at A is directed
horizontally to the left.
33
Problem 2.7
Solving Problems on Your Own
240 lb
A
30o

75 lb
50o
75 lb
The direction of the 75-lb
forces may vary, but the
angle between the forces
is always 50o. Determine
the value of  for which
the resultant of the forces
acting at A is directed
horizontally to the left.
1. Determine the resultant R of two or more forces.
2. Draw a parallelogram with the applied forces as two adjacent
sides and the resultant as the included diagonal.
3. Set the resultant, or sum of the forces, directed horizontally.
34
Problem 2.7 Solution
240 lb
30o

75 lb
Determine the resultant R of two
or more forces.
A
We first Replace the two 75-lb
forces by their resultant R1, using
the triangle rule.
50o
75 lb

25o
50o
25o
R1
R1 = 2(75 lb) cos25o = 135.95 lb
R1 = 135.95 lb
 +25o
35
Problem 2.7 Solution
Draw a parallelogram with the applied forces as two adjacent
sides and the resultant as the included diagonal.
Set the resultant, or sum of the forces, directed horizontally.
R2
30o
240 lb
+25o
R1 = 135.95 lb
Consider the resultant R2
of R1 and the 240-lb force
and recall that R2 must be
horizontal and directed to
the left.
Law of sines:
sin(30o)
sin(+25o)
=
240 lb
135.95 lb
o
(240
lb)
sin(30
)
o
sin(+25 ) =
135.95 lb
 + 25o = 61.97o
= 0.88270
 = 37.0o
36
Problem 2.8
y
360 mm
C
D
450 mm
O
500 mm
B
z
A
320 mm
600 mm
x
A container of weight
W = 1165 N is supported
by three cables as shown.
Determine the tension in
each cable.
37
Problem 2.8
y
Solving Problems on Your Own
360 mm
C
D
450 mm
O
500 mm
B
z
A
320 mm
600 mm
x
A container of weight
W = 1165 N is supported
by three cables as shown.
Determine the tension in
each cable.
1. Draw a free-body diagram of the particle. This diagram shows
the particle and all the forces acting on it.
2. Resolve each of the forces into rectangular components.
Follow the method outlined in the text.
F
F = F  = (dx i + dy j + dz k)
d
38
Problem 2.8
y
360 mm
C
D
Solving Problems on Your Own
450 mm
O
500 mm
B
z
A
320 mm
600 mm
x
A container of weight
W = 1165 N is supported
by three cables as shown.
Determine the tension in
each cable.
3. Set the resultant, or sum, of the forces exerted on the particle
equal to zero. You will obtain a vectorial equation consisting
of terms containing the unit vectors i, j, and k. Three scalar
equations result, which can be solved for the unknowns.
39
Problem 2.8 Solution
Draw a free-body diagram of the particle.
y
360 mm
C
D
SF=0
O
TAC
500 mm
z
450 mm
B
TAD
A
320 mm
TAB
600 mm
TAB + TAC + TAD + W = 0
x
W = _ (1165 N) j
AB = (450 mm)i + (600 mm)j
AB = 750 mm
AC = (600 mm)j _ (320mm)k
AC = 680 mm
AD = (_500 mm)i + (600 mm)j + (360 mm)k
40
AD = 860 mm
Problem 2.8 Solution
y
360 mm
C
D
O
TAC
500 mm
TAD
z
Resolve each of the forces
into rectangular components.
450 mm
A
W = _ (1165 N) j
TAC = TAC AC = TAC
B
320 mm
TAB
600 mm
x
AB
=
AB
TAB = TAB AB = TAB
600
450
j TAB =
i+
=
750
750
= (0.6 i + 0.8 j) TAB
(
)
600 _ 320
AC
15 j _ 8 k
= 680 j
TAC
k TAC =
680
17
AC
17
(
) (
)
AD
500
600
360
k TAD =
i+
TAD = TAD AD = TAD
=
j+
860
860
860
AD
25
30
18
k TAD
i+
=
j+
43
43
41
43
(
(
)
)
Problem 2.8 Solution
y
360 mm
C
D
O
TAC
500 mm
z
Set the resultant, or sum, of
the forces exerted on the
particle equal to zero.
450 mm
TAD
A
W = _ (1165 N) j
B
320 mm
TAB
0.6 TAB _ 25 TAD = 0
43
600 mm
x
Substitution into S F = 0,
factor i, j, k and set their
coefficients to zero:
TAB = 0.9690 TAD
15
30 T _
0.8 TAB + TAC +
AD 1165 N = 0
17
43
_
18 T = 0
8
T +
43 AD
17 AC
+
TAC = 0.8895 TAD
(1)
(2)
(3)
42
Problem 2.8 Solution
y
360 mm
C
D
O
TAC
500 mm
z
450 mm
TAD
A
W = _ (1165 N) j
B
320 mm
TAB
600 mm
Substitution for TAB and
TAC from (1) and (3)
into (2):
x
15
30
x 0.8895 +
)TAD _ 1165 N = 0
17
43
TAD = 516 N
2.2578 TAD _ 1165 N = 0
( 0.8 x 0.9690 +
From (1): TAB = 0.9690 (516 N)
TAB = 500 N
From (3): TAC = 0.8895 (516 N)
TAC = 459 N43
Problem 2.9
y
A
Cable AB is 65 ft long, and
the tension in that cable is
3900 lb. Determine (a) the
x, y, and z components of
the force exerted by the
cable on the anchor B, (b)
the angles x, y, and z
defining the direction of
that force.
56 ft
D

O
B
20o
50o
z
C
x
44
Problem 2.9
y
Solving Problems on Your Own
A
56 ft
D

O
B
20o
50o
z
C
x
Cable AB is 65 ft long, and
the tension in that cable is
3900 lb. Determine (a) the
x, y, and z components of
the force exerted by the
cable on the anchor B, (b)
the angles x, y, and z
defining the direction of
that force.
1. Determine the rectangular components of a force defined by
its magnitude and direction. If the direction of the force F is
defined by the angles y and f, projections of F through these
angles or their components will yield the components of F.
45
Problem 2.9
y
Solving Problems on Your Own
A
Cable AB is 65 ft long, and
the tension in that cable is
3900 lb. Determine (a) the
x, y, and z components of
the force exerted by the
cable on the anchor B, (b)
the angles x, y, and z
defining the direction of
that force.
56 ft
D

O
B
20o
50o
z
C
x
2. Determine the direction cosines of the line of action of a force.
The direction cosines of the line of action of a force F are
determined by dividing the components of the force by F.
Fx
Fy
Fz
cos x= F
cos y= F
cos z= F
46
A
Problem 2.9 Solution
y
65 ft
y
56 ft
Determine the direction cosines of
the line of action of a force.
From triangle AOB:
F
Fy
cos y = 56 ft = 0.86154
65 ft
y = 30.51o
Fx
B
O
20o Fz
(a) Fx = _ F sin y cos 20o
= _ (3900 lb) sin 30.51o cos 20o
Fx = _1861 lb
z
x
Fy = + F cos y = (3900 lb)(0.86154)
Fy = + 3360 lb
Fz = + (3900 lb) sin 30.51o sin 20o
Fz = + 677 lb
47
Problem 2.9 Solution
y
A
65 ft
y
56 ft
Determine the direction cosines
of the line of action of a force.
F
Fy
Fx
B
O
_
Fx
1861 lb
=
(b) cos x =
F
3900 lb
cos x = _ 0.4771
x = 118.5o
20o Fz
From above (a):
y = 30.5o
x
Fz
cos z =
F
677 lb
= +
= + 0.1736
3900 lb
z = 80.0o
48
Problem 2.10
B
A
9 ft
8.5 ft
5 ft
12 ft
C
396 lb
Two cables are tied
together at C and
loaded as shown.
determine the tension
(a) in cable AC,
(b) in cable BC.
7.5 ft
49
Problem 2.10
B
A
Solving Problems on Your Own
9 ft
8.5 ft
5 ft
12 ft
C
396 lb
7.5 ft
Two cables are tied
together at C and
loaded as shown.
determine the tension
(a) in cable AC,
(b) in cable BC.
1. Draw a free-body diagram of the particle. This diagram shows
the particle and all the forces acting on it.
2. Set the resultant, or sum, of the forces exerted on the particle
equal to zero. You will obtain a vectorial equation consisting
of terms containing the unit vectors i, j, and k. Three scalar
equations result, which can be solved for the unknowns.
50
Problem 2.10 Solution
FREE BODY C:
y
Draw a free-body diagram
of the particle.
TBC
TAC
4
3.5
12
7.5
x
Set the resultant, or sum, of
the forces exerted on the
particle equal to zero.
396 lb
S Fx = 0 :
7.5
12 T
TBC = 0
+
AC
8.5
12.5
TBC = 1.088 TAC
S Fy = 0 :
3.5
4
T
12.5 AC + 8.5 TBC
396 lb = 0
51
y
Problem 2.10 Solution
TBC
TAC
4
3.5
12
7.5
x
396 lb
(a) Substitute for TBC:
3.5
4
_
TAC +
(1.088
T
)
396 lb = 0
AC
8.5
12.5
(b)
(0.280 + 0.512) TAC _ 396 lb = 0
TAC = 500 lb
TBC = 1.088 (500 lb)
TBC = 544 lb
52
Problem 2.11
y
x
P
A
O
20 in
Q
z
z
B
x
Collars A and B are connected
by a 25-in.-long wire and can
slide freely on frictionless rods.
If a 60-lb force Q is applied to
collar B as shown, Determine
(a) the tension in the wire when
x = 9 in., (b) the corresponding
magnitude of the force P required
to maintain the equilibrium of
the system.
53
Problem 2.11
y
x
Solving Problems on Your Own
P
A
O
20 in
Q
z
z
B
x
Collars A and B are connected
by a 25-in.-long wire and can
slide freely on frictionless rods.
If a 60-lb force Q is applied to
collar B as shown, Determine
(a) the tension in the wire when
x = 9 in., (b) the corresponding
magnitude of the force P required
to maintain the equilibrium of
the system.
1. Draw a free-body diagram of the particle. This diagram shows
the particle and all the forces acting on it.
54
Problem 2.11
y
x
Solving Problems on Your Own
P
A
O
20 in
Q
z
z
B
x
Collars A and B are connected
by a 25-in.-long wire and can
slide freely on frictionless rods.
If a 60-lb force Q is applied to
collar B as shown, Determine
(a) the tension in the wire when
x = 9 in., (b) the corresponding
magnitude of the force P required
to maintain the equilibrium of
the system.
2. Set the resultant, or sum, of the forces exerted on the particle
equal to zero. You will obtain a vectorial equation consisting
of terms containing the unit vectors i, j, and k. Three scalar
equations result, which can be solved for the unknowns.
55
Problem 2.11 Solution
y
x
P
AB
A
= AB
AB =
_
x i _ (20 in) j + z k
25 in
Draw a free-body diagram of the particle.
O
20 in
Q
z
B
z
x
Free Body: Collar A
Ny j
S F = 0: P i + Ny j + Nz k + TAB AB = 0
A
Pi
Nz k
TAB AB
Substitute for AB and set coefficients
of i equal to zero:
P
_
TAB x
= 0
25
(1)
56
_
Ny j
B
TAB AB
Problem 2.11 Solution
Free Body: Collar B
S F = 0: (60 lb) k + Nx i + Ny j _ TAB AB = 0
Substitute for AB and set coefficients
of k equal to zero:
Nx i
Q = (60 lb) k
60
_
TAB z
25
= 0
(2)
(a) Since x = 9 in.: (9 in)2 + (20 in) 2 + z 2 = (25 in) 2
From eq. (2):
60
_
TAB (12)
25
= 0
(125.0 lb)(9 in)
(b) From eq. (1): P =
25 in
z = 12 in
TAB = 125.0 lb
P = 45.0 lb
57