1. Equilibrium�Chapter 4
2. Chapter Topics Discuss equilibrium, including:
The concept of static equilibrium (SE)
Force and moment conditions for SE
Center of mass
Segmental method for human center of mass
Hydrostatics and flotation
3. Bodies at Rest A body at rest or in uniform motion is in equilibrium
External forces must give zero resultant.
4. Behold, a new definition for Force! A vector quantity that tends to cause movement in material objects
5. Types of Equilibrium Stable
A slight disturbance generates a restoring force to return the equilibrium
Unstable
A slight disturbance leads to an increasing departure from equilibrium
Neutral
A disturbance simply moves the object to a new position
6. Stable/Unstable/Neutral?
7. Friction Many common objects are in equilibrium because of the effects of friction forces
Example?
8. Friction and Equilibrium Objects at rest on a surface are held by static friction.
Surfaces moving with respect to each other are met with sliding friction or kinetic friction.
Which is greater?
9. Friction and Equilibrium contd Examples of friction:
Slowing of a golf ball across a green
Stationary object on an inclined plane
Walking and not falling over
10. Friction and Equilibrium contd Examples of low friction:
Ice skating
Skiing
11. Coefficient of Friction Depends on the surfaces of both of the bodies in contact with one another
Simple experiment: at what angle does an object start to slide down a slope
Mechanical principle:
12. Question Is friction essential for a body to be in equilibrium?
13. Moments
Moment of a force: a measure of the turning effect of a force
14. Moments of Force Moment of force about a point is the tendency of the force to turn the body to which it is applied about that point
Also known as torque
F d
d = length of moment arm
Perpendicular distance between point and line of action of the force
Given in Nm
16. Example (page 81) A man supports a weight of 250 N with his arms at right angles to his body. He holds the weight with both hands level with his shoulders. If is arms are 75 cm long, what is the moment of the force?
17. Example contd Moment = F x d
= 250 N x 0.75 m
= 187.5 Nm
18. BE CAREFUL! The books answer is incomplete. A moment is a vector, so the answer should have a direction!
19. Practice The following problems would be useful to review as you prepare for the first exam.
Page 49: Problems 1, 2, 4, 6
Page 50: Problems 7, 8, 11b, 13
Page 73: Problem 1
Page 74: Problem 5
Page 75: Problems 11, 13, 17a, 17b
Page 104: Problems 1, 2
Page 106: Problem 8
Answers are in the back of the book
20. Point of Application of Resultant Force
21. Where does the resultant force act?�� Solution comes from sum of moments for equilibrium
22. Where does the resultant force act?�� What one force at what one location would produce equilibrium by balancing all the distributed forces?
23. Sum of moments Choose a point, and sum the clockwise and ccw moments about that point. For example, sum moments about point A, taking the opposite sense of P+Q to assume equilibrium
24. Example and Case Study, pg. 82-83
25. Center of Gravity (CoG)
A point within or near the object through which the resultant weight of the object passes
26. Center of Mass (CoM)
A point at which the object's mass can be assumed, for many purposes, to be concentrated
27. Whole Body CoM How would you calculate it?
Giovani Alfonso Borelli (1608-1679)
Case study 4.3
29. Consistency of CoM as a % of height Page 85:
Height range: 158-188 cm
CoM range 54.4-55.89 %ht
30. Force Couples Whats the sum of the horizontal forces?
Do they therefore have no mechanical effect?
31. Couples A pair of equal parallel forces acting in opposite senses, and not in the same line, is called a couple
Object will tend to rotate and is therefore not in equilibrium
32. Falling Over
33. CoM of a Stationary Body Objects will balance on pivots if CoG is directly over the pivot.
Works mainly for straight objects.
Example: a cricket bat
35. CoM of a Stationary Body contd Position of CoG for a bat:
36. Similar expression for body segments total arm COM = 0.53 from proximal
GH to ulnar styloid
total leg COM = ____ from proximal
Greater trochanter to medial malleolus
37. Equilibrium Under Three Forces Parallel forces:
The sum of the forces must be zero
Equilibrium requires that BOTH ?F and ?M each equal zero
38. Equilibrium Under Three Forces contd A uniform beam AB, 6 m long, weighing 400 N, is supported at the end A at point C. Point C is 2 m from B. Find the reaction forces at supports A and C.
40. Equilibrium Under Three Forces contd R1 + R2 = 400 N
SM about A
Moment due to 400N force at G:
400 x AG = 400 x 3 = 1200 Nm CW
Moment due to R2 at C:
R2 x AC = R2 x 4m CCW
41. Equilibrium Under Three Forces contd Equate the moments (for equilibrium)
1200 = 4R2
R2 = 1200/4 = 300 N
R1 = 400 - R2 = 400 - 300 = 100 N
42. Now, solve the problem by summing moments to determine R1
43. Equilibrium Under Three Forces contd Nonparallel forces:
Consider three forces D, E, and F in equilibrium.
45. Equilibrium Under Three Forces contd Triangle forces rule:
Three nonparallel forces in equilibrium
Represented in size and direction by three sides of the triangle taken in order
46. Alternative Measure the horizontal and vertical components of each vector
47. Hydrostatics and Flotation
48. Pressure as a Function of Depth Increasing depth gives increasing pressure.
Liquid density is:
Pressure at depth h in N/m2 given by:
49. Upthrust on Immersed Body Pressure increases with depth.
The underside of the object experiences greater force than the top side.
51. Upthrust on Immersed Body contd Principle of Archimedes:
When a solid body is wholly or partially immersed in fluid, it experiences an upthrust equal to the weight of the mass of displaced fluid.
52. Upthrust on Immersed Body contd For floating body in water:
Upthrust force = Weight of body
U = W
For sinking body in water:
Upthrust force < Weight of body
U < W
53. Factors: Density and Shape Less dense than water: always float
More dense than water: only float if shaped such that the object can displace at least its own weight in water
54. Specific Gravity SG = Mass of certain volume of substance Mass of equal volume of water
SG = Weight of certain volume of substance Weight of equal volume of water
55. Specific Gravity contd Water at temperature 4C
Density is 999.97 kg/m3
Human body: close, but not homogenous!
56. Center of Mass in Humans
57. Estimating Center of Mass Use the segmental method if you know:
Position of the end points of all of the bodys segments
Mass of each segment
Location of CoM within each segment
58. Estimating Center of Mass contd 14 body segments:
Trunk
Head and neck
Right and left thighs
Right and left lower legs
59. Estimating Center of Mass contd 14 body segments contd
Right and left feet
Right and left upper arms
Right and left lower arms
Right and left hands
Each segment has its own CoM
60. Calcuation is based on the moment attributable to the weight of each segment about the x and y axes.
65. Free-body Diagrams Include forces acting on the body only
Exclude forces that the body exerts on its surroundings and internal forces
66. What is the system?
How can you determine
R1 & R2 ?
67. Draw the FBD of:
The bucket
The left arm
The head
68. Calculation of Joint Moments Just like with summing forces with a free-body diagram, calculate and sum moments
Consider Figure 4-20.
69. FBD: foot segment SM about a
70. Summary Certain physical conditions are necessary to maintain static equilibrium
Force balance: SF=0
Moment balance: SM=0
Additional principles associated with equilibrium
Center of mass
Hydrostatics
