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Chapter Objectives
Develop the equations of equilibrium for a rigid body
Concept of the free-body diagram for a rigid body
Solve rigid-body equilibrium problems using the equations of equilibrium
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Chapter Outline
Conditions for Rigid Equilibrium
Free-Body Diagrams
Equations of Equilibrium
Two and Three-Force Members
Free Body Diagrams
Constraints and Statical Determinacy
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4. 5.1 Conditions for Rigid-Body Equilibrium
The equilibrium of a body is expressed as
Consider summing moments about some other point, such as point A, we require
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5.2 Free Body Diagrams
Support Reactions
If a support prevents the translation of a body in a given direction, then a force is developed on the body in that direction.
If rotation is prevented, a couple moment is exerted on the body.
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5.2 Free Body Diagrams
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5.2 Free Body Diagrams
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5.2 Free Body Diagrams
Internal Forces
External and internal forces can act on a rigid body
For FBD, internal forces act between particles which are contained within the boundary of the FBD, are not represented
Particles outside this boundary exert external forces on the system
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5.2 Free Body Diagrams
Weight and Center of Gravity
Each particle has a specified weight
System can be represented by a single resultant force, known as weight W of the body
Location of the force application is known as the center of gravity
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5.2 Free Body Diagrams
Procedure for Drawing a FBD
1. Draw Outlined Shape
Imagine body to be isolated or cut free from its constraints
Draw outline shape
2. Show All Forces and Couple Moments
Identify all external forces and couple moments that act on the body
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5.2 Free Body Diagrams
3. Identify Each Loading and Give Dimensions
Indicate dimensions for calculation of forces
Known forces and couple moments should be properly labeled with their magnitudes and directions
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Example 5.1
Draw the free-body diagram of the uniform beam. The beam has a mass of 100kg.
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Solution
Free-Body Diagram
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Solution
Free-Body Diagram
Support at A is a fixed wall
Three forces acting on the beam at A denoted as Ax, Ay, Az, drawn in an arbitrary direction
Unknown magnitudes of these vectors
Assume sense of these vectors
For uniform beam,
Weight, W = 100(9.81) = 981N
acting through beam’s center of gravity, 3m from A
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15. 5.3 Equations of Equilibrium
Please refer to the Companion CD for the animation: Equilibrium of a Free Body
5.3 Equations of Equilibrium
For equilibrium of a rigid body in 2D,
∑Fx = 0; ∑Fy = 0; ∑MO = 0
∑Fx and ∑Fy represent sums of x and y components of all the forces
∑MO represents the sum of the couple moments and moments of the force components
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16. 5.3 Equations of Equilibrium
Please refer to the Companion CD for the animation: Equilibrium of a Free Body
5.3 Equations of Equilibrium
Alternative Sets of Equilibrium Equations
For coplanar equilibrium problems, ∑Fx = 0; ∑Fy = 0; ∑MO = 0
2 alternative sets of 3 independent equilibrium equations,
∑Fa = 0; ∑MA = 0; ∑MB = 0
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17. 5.3 Equations of Equilibrium
Please refer to the Companion CD for the animation: Equilibrium of a Free Body
5.3 Equations of Equilibrium
Procedure for Analysis
Free-Body Diagram
Force or couple moment having an unknown magnitude but known line of action can be assumed
Indicate the dimensions of the body necessary for computing the moments of forces
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18. 5.3 Equations of Equilibrium
Please refer to the Companion CD for the animation: Equilibrium of a Free Body
5.3 Equations of Equilibrium
Procedure for Analysis
Equations of Equilibrium
Apply ∑MO = 0 about a point O
Unknowns moments of are zero about O and a direct solution the third unknown can be obtained
Orient the x and y axes along the lines that will provide the simplest resolution of the forces into their x and y components
Negative result scalar is opposite to that was assumed on the FBD
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Example 5.5
Determine the horizontal and vertical components of reaction for the beam loaded. Neglect the weight of the beam in the calculations.
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Solution
Free Body Diagrams
600N represented by x and y components
200N force acts on the beam at B
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Solution
Equations of Equilibrium
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22. 5.4 Two- and Three-Force Members
Two-Force Members
When forces are applied at only two points on a member, the member is called a two-force member
Only force magnitude must be determined
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23. 5.4 Two- and Three-Force Members
When subjected to three forces, the forces are concurrent or parallel
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Example 5.13
The lever ABC is pin-supported at A and connected to a short link BD. If the weight of the members are negligible, determine the force of the pin on the lever at A.
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Solution
Free Body Diagrams
BD is a two-force member
Lever ABC is a three-force member
Equations of Equilibrium
Solving,
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5.5 Free-Body Diagrams
Support Reactions
As in the two-dimensional case:
A force is developed by a support
A couple moment is developed when rotation of the attached member is prevented
The force’s orientation is defined by the coordinate angles α, β and γ
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5.5 Free-Body Diagrams
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5.5 Free-Body Diagrams
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Example 5.14
Several examples of objects along with their associated free-body diagrams are shown. In all cases, the x, y and z axes are established and the unknown reaction components are indicated in the positive sense. The weight of the objects is neglected.
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Solution
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31. 5.6 Equations of Equilibrium
Vector Equations of Equilibrium
For two conditions for equilibrium of a rigid body in vector form,
∑F = ∑MO = 0
Scalar Equations of Equilibrium
If all external forces and couple moments are expressed in Cartesian vector form
∑F = ∑Fxi + ∑Fyj + ∑Fzk = 0
∑MO = ∑Mxi + ∑Myj + ∑Mzk = 0
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32. 5.7 Constraints for a Rigid Body
Redundant Constraints
More support than needed for equilibrium
Statically indeterminate: more unknown loadings than equations of equilibrium
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33. 5.7 Constraints for a Rigid Body
Improper Constraints
Instability caused by the improper constraining by the supports
When all reactive forces are concurrent at this point, the body is improperly constrained
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34. 5.7 Constraints for a Rigid Body
Procedure for Analysis
Free Body Diagram
Draw an outlined shape of the body
Show all the forces and couple moments acting on the body
Show all the unknown components having a positive sense
Indicate the dimensions of the body necessary for computing the moments of forces
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35. 5.7 Constraints for a Rigid Body
Procedure for Analysis
Equations of Equilibrium
Apply the six scalar equations of equilibrium or vector equations
Any set of non-orthogonal axes may be chosen for this purpose
Choose the direction of an axis for moment summation such that it insects the lines of action of as many unknown forces as possible
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Example 5.15
The homogenous plate has a mass of 100kg and is subjected to a force and couple moment along its edges. If it is supported in the horizontal plane by means of a roller at A, a ball and socket joint at N, and a cord at C, determine the components of reactions at the supports.
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Solution
Free Body Diagrams
Five unknown reactions acting on the plate
Each reaction assumed to act in a positive coordinate direction
Equations of Equilibrium
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Solution
Equations of Equilibrium
Components of force at B can be eliminated if x’, y’ and z’ axes are used
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Solution
Solving,
Az = 790N Bz = -217N TC = 707N
The negative sign indicates Bz acts downward
The plate is partially constrained as the supports cannot prevent it from turning about the z axis if a force is applied in the x-y plane
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QUIZ
1. If a support prevents translation of a body, then the support exerts a ___________ on the body.
A) Couple moment
B) Force
C) Both A and B.
D) None of the above
2. Internal forces are _________ shown on the free body diagram of a whole body.
A) Always
B) Often
C) Rarely
D) Never
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QUIZ
3. The beam and the cable (with a frictionless pulley at D) support an 80 kg load at C. In a FBD of only the beam, there are how many unknowns?
A) 2 forces and 1 couple moment
B) 3 forces and 1 couple moment
C) 3 forces
D) 4 forces
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QUIZ
4. Internal forces are not shown on a free-body diagram because the internal forces are_____.
A) Equal to zero
B) Equal and opposite and they do not affect the calculations
Negligibly small
D) Not important
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QUIZ
5. The three scalar equations  FX =  FY =  MO = 0, are ____ equations of equilibrium in two dimensions.
A) Incorrect B) The only correct
C) The most commonly used D) Not sufficient
6. A rigid body is subjected to forces. This body can be considered as a ______ member.
A) Single-force B) Two-force
C) Three-force D) Six-force
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QUIZ
For this beam, how many support reactions are there and is the problem statically determinate? A) (2, Yes) B) (2, No) C) (3, Yes) D) (3, No)
8. The beam AB is loaded as shown: a) how many support reactions are there on the beam, b) is this problem statically determinate, and c) is the structure stable?
A) (4, Yes, No) B) (4, No, Yes)
C) (5, Yes, No) D) (5, No, Yes) F F
Fixed support A B
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QUIZ
9. Which equation of equilibrium allows you to determine FB right away?
A)  FX = B)  FY = 0
C)  MA = 0
D) Any one of the above.
10. A beam is supported by a pin joint and a roller. How many support reactions are there and is the structure stable for all types of loadings?
A) (3, Yes) B) (3, No)
C) (4, Yes) D) (4, No) AX A B FB AY
100 lb
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QUIZ
If a support prevents rotation of a body about an axis, then the support exerts a ________ on the body about that axis. A) Couple moment B) Force C) Both A and B. D) None of the above.
When doing a 3-D problem analysis, you have ________ scalar equations of equilibrium.
3 B) 4
C) 5 D) 6
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QUIZ
13. The rod AB is supported using two cables at B and a ball-and-socket joint at A. How many unknown support reactions exist in this problem?
5 force and 1 moment reaction
B) 5 force reactions
C) 3 force and 3 moment reactions
D) 4 force and 2 moment reactions
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QUIZ
14. If an additional couple moment in the vertical direction is applied to rod AB at point C, then what will happen to the rod?
A) The rod remains in equilibrium as the cables provide the necessary support reactions.
B) The rod remains in equilibrium as the ball-and-socket joint will provide the necessary resistive reactions.
C) The rod becomes unstable as the cables cannot support compressive forces.
D) The rod becomes unstable since a moment about AB cannot be restricted.
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QUIZ
15. A plate is supported by a ball-and-socket joint at A, a roller joint at B, and a cable at C. How many unknown support reactions are there in this problem?
A) 4 forces and 2 moments
B) 6 forces
C) 5 forces
D) 4 forces and 1 moment
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QUIZ
16. What will be the easiest way to determine the force reaction BZ ?
A) Scalar equation  FZ = 0
B) Vector equation  MA = 0
C) Scalar equation  MZ = 0
D) Scalar equation  MY = 0
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