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Free Body Diagrams.

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Presentation on theme: "Free Body Diagrams."— Presentation transcript:

1 Free Body Diagrams

2 Objectives What is a Free Body Diagram

3 Our Concern We are concerned with applications that involve constant forces Constant forces result in constant accelerations and allow the use of the kinematic equations to analyze motion.

4 Variable Forces When there is a variable force, Newton’s second law holds for the instantaneous force and aceleration, but the acceleration will vary with time, requiring more advance mathematics.

5 Free Body Diagrams Free Body diagrams are illustrations of a physical situation. They depict the forces acting on an object. The arrows that are used to represent the force all originate from the same point. Usually the origin of the x-y axes. Sometimes we have to resolve force vectors into their components using trigonometry.

6 Free Body Diagrams In a FBD, the vector arrows do not have to be drawn exactly to scale. The diagram should clearly show whether there is a net force and whether forces balance each other in a particular direction. When the forces aren’t balanced, by Newton’s second law, there must be an acceleration.

7 Steps to Constructing a FBD
Make a sketch of the situation (typically a box or a point to represent the object) and identify the forces acting on each part of the system.

8 Steps to Constructing a FBD
Isolate the part of the system for which the FBD is to be constructed. Label the Cartesian axes.

9 Steps to Constructing a FBD
Draw properly oriented force vectors (including angles) on the diagram, emanating from the middle of the box or point. If there is an unbalanced force, assume a direction of acceleration and indicate it with an acceleration vector. Be sure to include only those forces that act on the isolated body of interest.

10 Steps to Constructing a FBD
Resolve any forces that are not directed along the x or y axis into x or y components.

11 Steps to Constructing a FBD
Use the FBD and force components to analyze the situation in terms of Newton’s second law of motion

12 From Here on Out You must always draw a FBD for all Force Problems!

13 Example Two masses are connected by a light string running over a light pulley of negligible friction. One mass (m1 = 5.0 kg) is on a frictionless 20 degree inclined plane, and the other (m2 = 1.5 kg) is freely suspended. What is the acceleration of the masses? What is the tension in the string?

14 Example A force of 10.0 N is applied at an angle of 30 degrees to the horizontal on a 1.25 kg block initially at rest on a frictionless surface. A) What is the magnitude of the blocks acceleration? B) What is the magnitude of the Normal Force?

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