1. Engineering Mechanics: Statics
Chapter 4:
Force System Resultants
Engineering Mechanics: Statics

2. Chapter Objectives
To discuss the concept of the moment of a force and show how to calculate it in two and three dimensions.
To provide a method for finding the moment of a force about a specified axis.
To define the moment of a couple.
To present methods for determining the resultants of non-concurrent force systems.
To indicate how to reduce a simple distributed loading to a resultant force having a specified location.

3. Chapter Outline Moment of a Force – Scalar Formation Cross Product
Moment of Force – Vector Formulation
Principle of Moments
Moment of a Force about a Specified Axis

4. Chapter Outline Moment of a Couple Equivalent System
Resultants of a Force and Couple System
Reduction of a Simple Distributed Loading

5. 4.1 Moment of a Force – Scalar Formation
Moment of a force about a point or axis – a
measure of the tendency of the force to
cause a body to rotate about the point or axis
Case 1
Consider horizontal force Fx,
which acts perpendicular to
the handle of the wrench and
is located dy from the point O

6. 4.1 Moment of a Force – Scalar Formation
Fx tends to turn the pipe about the z axis
The larger the force or the distance dy, the greater the turning effect
Torque – tendency of
rotation caused by Fx
or simple moment (Mo) z

7. 4.1 Moment of a Force – Scalar Formation
Moment axis (z) is perpendicular to shaded
plane (x-y)
Fx and dy lies on the shaded plane (x-y)
Moment axis (z) intersects
the plane at point O

8. 4.1 Moment of a Force – Scalar Formation
Case 2
Apply force Fz to the wrench
Pipe does not rotate about z axis
Tendency to rotate about x axis
The pipe may not actually
rotate Fz creates tendency
for rotation so moment
(Mo) x is produced

9. 4.1 Moment of a Force – Scalar Formation
Case 2
Moment axis (x) is perpendicular to shaded
plane (y-z)
Fz and dy lies on the shaded plane (y-z)

10. 4.1 Moment of a Force – Scalar Formation
Case 3
Apply force Fy to the wrench
No moment is produced about point O
Lack of tendency to rotate
as line of action passes
through O

11. 4.1 Moment of a Force – Scalar Formation
In General
Consider the force F and the point O which lies in the shaded plane
The moment MO about point O,
or about an axis passing
through O and perpendicular
to the plane, is a vector quantity
Moment MO has its specified
magnitude and direction

12. 4.1 Moment of a Force – Scalar Formation
Magnitude
For magnitude of MO,
MO = Fd
where d = moment arm or perpendicular distance from the axis at point O to its line of action of the force
Units for moment is N.m

13. 4.1 Moment of a Force – Scalar Formation
Direction
Direction of MO is specified by using “right hand rule”
- fingers of the right hand are curled to follow the sense of rotation when force rotates about point O

14. 4.1 Moment of a Force – Scalar Formation
Direction
- Thumb points along the moment axis to give the direction and sense of the moment vector
- Moment vector is upwards and perpendicular to the shaded plane

15. 4.1 Moment of a Force – Scalar Formation
Direction
MO is shown by a vector arrow
with a curl to distinguish it from
force vector
Example (Fig b)
MO is represented by the counterclockwise curl, which indicates the action of F

16. 4.1 Moment of a Force – Scalar Formation
Direction
Arrowhead shows the sense of rotation caused by F
Using the right hand rule, the direction and sense of the moment vector points out of the page
In 2D problems, moment of the force is found about a point O

17. 4.1 Moment of a Force – Scalar Formation
Direction
Moment acts about an axis perpendicular to the plane containing F and d
Moment axis intersects
the plane at point O

18. 4.1 Moment of a Force – Scalar Formation
Resultant Moment of a System of
Coplanar Forces
Resultant moment, MRo = addition of the moments of all the forces algebraically since all moment forces are collinear
MRo = ∑Fd
taking clockwise to be positive

19. 4.1 Moment of a Force – Scalar Formation
Resultant Moment of a System of
Coplanar Forces
A clockwise curl is written along the equation to indicate that a positive moment if directed along the
+ z axis and negative
along the – z axis

20. 4.1 Moment of a Force – Scalar Formation
Moment of a force does not always cause rotation
Force F tends to rotate the beam clockwise about A with moment
MA = FdA
Force F tends to rotate the beam counterclockwise about B with moment
MB = FdB
Hence support at A prevents
the rotation

21. 4.1 Moment of a Force – Scalar Formation
Example 4.1
For each case, determine the moment of the
force about point O

22. 4.1 Moment of a Force – Scalar Formation
Solution
Line of action is extended as a dashed line to establish moment arm d
Tendency to rotate is indicated and the orbit is shown as a colored curl

23. 4.1 Moment of a Force – Scalar Formation
Solution

24. 4.1 Moment of a Force – Scalar Formation
Example 4.2
Determine the moments of
the 800N force acting on the
frame about points A, B, C
and D.

25. 4.1 Moment of a Force – Scalar Formation
Solution
Scalar Analysis
Line of action of F passes through C

26. 4.2 Cross Product
Cross product of two vectors A and B yields C, which is written as
C = A X B
Read as “C equals A cross B”

27. 4.2 Cross Product Magnitude
Magnitude of C is defined as the product of the magnitudes of A and B and the sine of the angle θ between their tails
For angle θ, 0° ≤ θ ≤ 180°
Therefore,
C = AB sinθ

28. 4.2 Cross Product Direction
Vector C has a direction that is perpendicular to the plane containing A and B such that C is specified by the right hand rule
- Curling the fingers of the right
hand form vector A (cross) to
vector B
- Thumb points in the direction of
vector C

29. 4.2 Cross Product
Expressing vector C when magnitude and direction are known
C = A X B = (AB sinθ)uC
where scalar AB sinθ defines the magnitude of vector C unit vector uC defines the direction of vector C

30. 4.2 Cross Product Laws of Operations 1. Commutative law is not valid
A X B ≠ B X A
Rather,
A X B = - B X A
Shown by the right hand rule
Cross product A X B yields a vector opposite in direction to C
B X A = -C

31. 4.2 Cross Product Laws of Operations 2. Multiplication by a Scalar
a( A X B ) = (aA) X B = A X (aB) = ( A X B )a
3. Distributive Law
A X ( B + D ) = ( A X B ) + ( A X D )
Proper order of the cross product must be maintained since they are not commutative

32. 4.2 Cross Product Cartesian Vector Formulation
Use C = AB sinθ on pair of Cartesian unit vectors
Example
For i X j, (i)(j)(sin90°)
= (1)(1)(1) = 1

33. 4.2 Cross Product Laws of Operations In a similar manner,
i X j = k i X k = -j i X i = 0
j X k = i j X i = -k j X j = 0
k X i = j k X j = -i k X k = 0
Use the circle for the results.
Crossing CCW yield positive
and CW yields negative results

34. 4.2 Cross Product Laws of Operations
Consider cross product of vector A and B
A X B = (Axi + Ayj + Azk) X (Bxi + Byj + Bzk)
= AxBx (i X i) + AxBy (i X j) + AxBz (i X k)
+ AyBx (j X i) + AyBy (j X j) + AyBz (j X k) AzBx (k X i) +AzBy (k X j) +AzBz (k X k)
= (AyBz – AzBy)i – (AxBz - AzBx)j + (AxBy – AyBx)k

35. 4.2 Cross Product
Laws of Operations
In determinant form,

36. 4.3 Moment of Force - Vector Formulation
Moment of force F about point O can be expressed using cross product
MO = r X F
where r represents position
vector from O to any point
lying on the line of action
of F

37. 4.3 Moment of Force - Vector Formulation
Magnitude
For magnitude of cross product,
MO = rF sinθ
where θ is the angle measured between tails of r and F
Treat r as a sliding vector. Since d = r sinθ,
MO = rF sinθ = F (rsinθ) = Fd

38. 4.3 Moment of Force - Vector Formulation
Direction
Direction and sense of MO are determined by right-hand rule
- Extend r to the dashed position
- Curl fingers from r towards F
- Direction of MO is the same
as the direction of the thumb

39. 4.3 Moment of Force - Vector Formulation
Direction
*Note:
- “curl” of the fingers indicates the sense of rotation
- Maintain proper order of r
and F since cross product
is not commutative

40. 4.3 Moment of Force - Vector Formulation
Principle of Transmissibility
For force F applied at any point A, moment created about O is MO = rA x F
F has the properties of a sliding vector and
therefore act at any point
along its line of action and
still create the same
moment about O

41. 4.3 Moment of Force - Vector Formulation
Cartesian Vector Formulation
For force expressed in Cartesian
form,
where rx, ry, rz represent the x, y, z
components of the position vector
and Fx, Fy, Fz represent that of the
force vector

42. 4.3 Moment of Force - Vector Formulation
Cartesian Vector Formulation
With the determinant expended,
MO = (ryFz – rzFy)i – (rxFz - rzFx)j + (rxFy – yFx)k
MO is always perpendicular to
the plane containing r and F
Computation of moment by cross
product is better than scalar for
3D problems

43. 4.3 Moment of Force - Vector Formulation
Cartesian Vector Formulation
Resultant moment of forces about point O can be determined by vector addition
MRo = ∑(r x F)

44. 4.3 Moment of Force - Vector Formulation
Moment of force F about point A, pulling on cable BC at any point along its line of action, will remain constant
Given the perpendicular distance from A to cable is rd
MA = rdF
In 3D problems,
MA = rBC x F

45. 4.3 Moment of Force - Vector Formulation
Example 4.4
The pole is subjected to a 60N force that is directed from C to B. Determine the magnitude of the moment created by this force about the support at A.

46. 4.3 Moment of Force - Vector Formulation
Solution
Either one of the two position vectors can be used for the solution, since MA = rB x F or MA = rC x F
Position vectors are represented as
rB = {1i + 3j + 2k} m and
rC = {3i + 4j} m
Force F has magnitude 60N
and is directed from C to B

47. 4.3 Moment of Force - Vector Formulation
Solution
Substitute into determinant formulation

48. 4.3 Moment of Force - Vector Formulation
Solution Or
Substitute into determinant formulation
For magnitude,

49. 4.4 Principles of Moments Also known as Varignon’s Theorem
“Moment of a force about a point is equal to the sum of the moments of the forces’ components about the point”
For F = F1 + F2,
MO = r X F1 + r X F2
= r X (F1 + F2)
= r X F

50. 4.4 Principles of Moments
The guy cable exerts a force F on the pole and creates a moment about the base at A
MA = Fd
If the force is replaced by Fx and Fy at point B where the cable acts on the pole, the sum of moment about point A yields the same resultant moment

51. 4.4 Principles of Moments Fy create zero moment about A MA = Fxh
Apply principle of transmissibility and slide the force where line of action intersects the ground at C, Fx create zero moment about A
MA = Fyb

52. 4.4 Principles of Moments Example 4.6
The force F acts at the end of the angle
bracket. Determine the moment of the force
about point O.

53. 4.4 Principles of Moments Solution Method 1
MO = 400sin30°N(0.2m)-400cos30°N(0.4m)
= -98.6N.m
= 98.6N.m (CCW)
As a Cartesian vector,
MO = {-98.6k}N.m

54. 4.4 Principles of Moments Solution Method 2:
Express as Cartesian vector
r = {0.4i – 0.2j}N
F = {400sin30°i – 400cos30°j}N
= {200.0i – 346.4j}N
For moment,

55. 4.6 Moment of a Couple Couple - two parallel forces
- same magnitude but opposite direction
- separated by perpendicular distance d
Resultant force = 0
Tendency to rotate in specified direction
Couple moment = sum of
moments of both couple
forces about any arbitrary point

56. 4.6 Moment of a Couple Example
Position vectors rA and rA are directed from O to
A and B, lying on the line of action of F and –F
Couple moment about O
M = rA X (-F) + rA X (F)
Couple moment about A
M = r X F
since moment of –F about A = 0

57. 4.6 Moment of a Couple A couple moment is a free vector
- It can act at any point since M depends only on the position vector r directed between forces and not position vectors rA and rB, directed from O to the forces
- Unlike moment of force, it do not require a definite point or axis

58. 4.6 Moment of a Couple Scalar Formulation Magnitude of couple moment
M = Fd
Direction and sense are determined by right hand rule
In all cases, M acts perpendicular to plane containing the forces

59. 4.6 Moment of a Couple Vector Formulation For couple moment, M = r X F
If moments are taken about point A, moment of –F is zero about this point
r is crossed with the force to which it is directed

60. 4.6 Moment of a Couple Equivalent Couples
Two couples are equivalent if they produce the same moment
Since moment produced by the couple is always perpendicular to the plane containing the forces, forces of equal couples either lie on the same plane or plane parallel to one another

61. 4.6 Moment of a Couple Resultant Couple Moment
Couple moments are free vectors
and may be applied to any point P
and added vectorially
For resultant moment of two
couples at point P,
MR = M1 + M2
For more than 2 moments,
MR = ∑(r X F)

62. 4.6 Moment of a Couple
Frictional forces (floor) on the blades of the machine creates a moment Mc that tends to turn it
An equal and opposite moment must be applied by the operator to prevent turning
Couple moment Mc = Fd is applied on the handle

63. 4.6 Moment of a Couple Example 4.10
A couple acts on the gear teeth. Replace it
by an equivalent couple having a pair of
forces that cat through points A and B.

64. 4.6 Moment of a Couple Solution Magnitude of couple
M = Fd = (40)(0.6) = 24N.m
Direction out of the page since
forces tend to rotate CW
M is a free vector and can
be placed anywhere

65. 4.6 Moment of a Couple Solution To preserve CCW motion,
vertical forces acting through points A and B must be directed as shown
For magnitude of each force,
M = Fd
24N.m = F(0.2m)
F = 120N

66. 4.7 Equivalent System
A force has the effect of both translating and rotating a body
The extent of the effect depends on how and where the force is applied
We can simplify a system of forces and moments into a single resultant and moment acting at a specified point O
A system of forces and moments is then equivalent to the single resultant force and moment acting at a specified point O

67. 4.7 Equivalent System Point O is on the Line of Action
Consider body subjected to force F applied to point A
Apply force to point O without altering external effects on body
- Apply equal but opposite forces F and –F at O

68. 4.7 Equivalent System Point O is on the Line of Action
- Two forces indicated by the slash across them can be cancelled, leaving force at point O
- An equivalent system has be maintained between each of the diagrams, shown by the equal signs

69. 4.7 Equivalent System Point O is on the Line of Action
- Force has been simply transmitted along its line of action from point A to point O
- External effects remain unchanged after force is moved
- Internal effects depend on location of F

70. 4.7 Equivalent System Point O is Not on the Line of Action
F is to be moved to point ) without altering the external effects on the body
Apply equal and opposite forces at point O
The two forces indicated by a slash across them, form a couple that has a moment perpendicular to F

71. 4.7 Equivalent System Point O is Not on the Line of Action
The moment is defined by cross product
M = r X F
Couple moment is free vector and can be applied to any point P on the body

72. 4.8 Resultants of a Force and Couple System
Consider a rigid body
Since O does not lies on the line of action, an equivalent effect is produced if the forces are moved to point O and the corresponding moments are
M1 = r1 X F1 and M2 = r2 X F2
For resultant forces and moments,
FR = F1 + F2 and MR = M1 + M2

73. 4.8 Resultants of a Force and Couple System
Equivalency is maintained thus each force and couple system cause the same external effects
Both magnitude and direction of FR do not depend on the location of point O
MRo depends on location of point O since M1 and M2 are determined using position vectors r1 and r2
MRo is a free vector and can acts on any point on the body

74. 4.8 Resultants of a Force and Couple System
Simplifying any force and couple system,
FR = ∑F
MR = ∑MC + ∑MO
If the force system lies on the x-y plane and any couple moments are perpendicular to this plane,
FRx = ∑Fx
FRy = ∑Fy
MRo = ∑MC + ∑MO

75. 4.8 Resultants of a Force and Couple System
Procedure for Analysis
When applying the following equations,
FR = ∑F
MR = ∑MC + ∑MO
FRx = ∑Fx
FRy = ∑Fy
MRo = ∑MC + ∑MO
Establish the coordinate axes with the origin located at the point O and the axes having a selected orientation

76. 4.8 Resultants of a Force and Couple System
Procedure for Analysis
Force Summation
For coplanar force system, resolve each force into x and y components
If the component is directed along the positive x or y axis, it represent a positive scalar
If the component is directed along the negative x or y axis, it represent a negative scalar
In 3D problems, represent forces as Cartesian vector before force summation

77. 4.8 Resultants of a Force and Couple System
Procedure for Analysis
Moment Summation
For moment of coplanar force system about point O, use Principle of Moment
Determine the moments of each components rather than of the force itself
In 3D problems, use vector cross product to determine moment of each force
Position vectors extend from point O to any point on the line of action of each force

78. 4.8 Resultants of a Force and Couple System
Example 4.14
Replace the forces acting on the brace by an
equivalent resultant force and couple moment
acting at point A.

79. 4.8 Resultants of a Force and Couple System
Solution
Force Summation
For x and y components of resultant force,

80. 4.8 Resultants of a Force and Couple System
Solution
For magnitude of resultant force
For direction of resultant force

81. 4.8 Resultants of a Force and Couple System
Solution
Moment Summation
Summation of moments about point A,
When MRA and FR act on point A,
they will produce the same
external effect or reactions at the support

82. 4.9 Reduction of a Simple Distributed Loading
Large surface area of a body may be subjected to distributed loadings such as those caused by wind, fluids, or weight of material supported over body’s surface
Intensity of these loadings at each point on the surface is defined as the pressure p
Pressure is measured in pascals (Pa)
1 Pa = 1N/m2

83. 4.9 Reduction of a Simple Distributed Loading
Most common case of distributed pressure loading is uniform loading along one axis of a flat rectangular body
Direction of the intensity of the pressure load is
indicated by arrows shown on the load-intensity diagram
Entire loading on the plate is a
system of parallel forces,
infinite in number, each
acting on a separate
differential area of the plate

84. 4.9 Reduction of a Simple Distributed Loading
Loading function p = p(x) Pa, is a function of x since pressure is uniform along the y axis
Multiply the loading function by the width
w = p(x)N/m2]a m = w(x) N/m
Loading function is a measure
of load distribution along line
y = 0, which is in the symmetry
of the loading
Measured as force per unit
length rather than per unit area

85. 4.9 Reduction of a Simple Distributed Loading
Load-intensity diagram for w = w(x) can be represented by a system of coplanar parallel
This system of forces can be simplified into a single resultant force FR
and its location can be
specified

86. 4.9 Reduction of a Simple Distributed Loading
Magnitude of Resultant Force
FR = ∑F
Integration is used for infinite number of parallel forces dF acting along the plate
For entire plate length,
Magnitude of resultant force is equal to the total area A under the loading diagram w = w(x)

87. 4.9 Reduction of a Simple Distributed Loading
Location of Resultant Force
MR = ∑MO
Location of the line of action of FR can be determined by equating the moments of the force resultant and the force distribution about point O
dF produces a moment of
xdF = x w(x) dx about O
For the entire plate,

88. 4.9 Reduction of a Simple Distributed Loading
Location of Resultant Force
Solving,
Resultant force has a line of action which passes through the centroid C (geometric center) of the area defined by the distributed loading diagram w(x)

89. 4.9 Reduction of a Simple Distributed Loading
Location of Resultant Force
Consider 3D pressure loading p(x), the resultant force has a magnitude equal to the volume under the distributed-loading curve p = p(x) and a line of action which passes through the centroid (geometric center) of this volume
Distribution diagram can be
in any form of shapes such
as rectangle, triangle etc

90. 4.9 Reduction of a Simple Distributed Loading
Beam supporting this stack of lumber is subjected to a uniform distributed loading, and so the load-intensity diagram has a rectangular shape
If the load-intensity is wo, resultant is determined from the are of the rectangle
FR = wob

91. 4.9 Reduction of a Simple Distributed Loading
Line of action passes through the centroid or center of the rectangle, = a + b/2
Resultant is equivalent to the distributed load
Both loadings produce same “external” effects or support reactions on the beam

92. 4.9 Reduction of a Simple Distributed Loading
Example 4.20
Determine the magnitude and location of the
equivalent resultant force acting on the shaft

93. 4.9 Reduction of a Simple Distributed Loading
Solution
For the colored differential area element,
For resultant force

94. 4.9 Reduction of a Simple Distributed Loading
Solution
For location of line of action,
Checking,

95. 4.9 Reduction of a Simple Distributed Loading
Example 4.21
A distributed loading of p = 800x Pa acts
over the top surface of the beam. Determine
the magnitude and location of the equivalent
force.

96. 4.9 Reduction of a Simple Distributed Loading
Solution
Loading function of p = 800x Pa indicates that the load intensity varies uniformly from p = 0 at x = 0 to p = 7200Pa at x = 9m
For loading,
w = (800x N/m2)(0.2m) = (160x) N/m
Magnitude of resultant force
= area under the triangle
FR = ½(9m)(1440N/m)
= 6480 N = 6.48 kN

97. 4.9 Reduction of a Simple Distributed Loading
Solution
Resultant force acts through the centroid of the volume of the loading diagram p = p(x)
FR intersects the x-y plane at point (6m, 0)
Magnitude of resultant force
= volume under the triangle
FR = V = ½(7200N/m2)(0.2m)
= 6.48 kN

98. 4.9 Reduction of a Simple Distributed Loading
Example 4.22
The granular material exerts the distributed
loading on the beam. Determine the magnitude
and location of the equivalent resultant of this
load

99. 4.9 Reduction of a Simple Distributed Loading
Solution
Area of loading diagram is trapezoid
Magnitude of each force = associated area
F1 = ½(9m)(50kN/m) = 225kN
F2 = ½(9m)(100kN/m) = 450kN
Line of these parallel forces act
through the centroid of associated
areas and insect beams at

100. 4.9 Reduction of a Simple Distributed Loading
Solution
Two parallel Forces F1 and F2 can be reduced to a single resultant force FR
For magnitude of resultant force,
For location of resultant force,

101. 4.9 Reduction of a Simple Distributed Loading
Solution
*Note:
Trapezoidal area can be divided into two triangular areas,
F1 = ½(9m)(100kN/m) = 450kN
F2 = ½(9m)(50kN/m) = 225kN