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Section 8.3 Equilibrium Define center of mass.

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1 Section 8.3 Equilibrium Define center of mass.
 Objectives Define center of mass. Explain how the location of the center of mass affects the stability of an object. Define the conditions for equilibrium. Describe how rotating frames of reference give rise to apparent forces.

2 THE CENTER OF MASS Center of Mass – the point on the object that moves in the same way that a point particle would move. To find the center of mass of an object, suspend the object from any point, when the object stops swinging, the center of mass is along the Vertical Line drawn from the suspension point. (Figure 8-11b) Then suspend the object from another point and draw a second Vertical Line. The Center of Mass is at the Point where the 2 lines cross (Figure 8-11c). A human’s center of mass is NOT fixed because we are flexible. A human’s center of mass is slightly below the navel. The path of the center of mass is a PARABOLA for a ballet dancer in a leap.

3 CENTER OF MASS AND STABILITY
A tall, narrow box tips more easily than a low, broad box. An object is said to be Stable if an external force is required to tip it. The broader the base the more stable the object. The lower the location of an object’s center of mass, the greater the stability. If the center of mass is outside the base of an object, it is unstable and will roll over without additional torque. If the center of mass is above the base of the object, then it is stable.

4 CONDITIONS FOR EQUILIBRIUM
An object is said to be in Static Equilibrium if both its Velocity and Angular Velocity are zero or constant. For an object to be in Static Equilibrium you need 2 things 1. It must be in Translational Equilibrium, that is the net force exerted on the object must be zero. 2. It must be in Rotational Equilibrium, that is the net Torque exerted on the object must be zero. SKIP Example Problem 5 p Practice Problems p. 215 # 36-39

5 ROTATING FRAMES OF REFERENCE
Newton’s laws do not apply for accelerated (Rotating) frames of reference.

6 CENTRIFUGAL FORCE Centrifugal Force – the apparent force that seems to pull on a moving object, but does not exert a physical outward push on it and is observed only in rotating frames of reference. (Chap. 6 also) Centripetal Acceleration is proportional to the distance from the axis of rotation and depends on the square of the angular velocity. Thus if you double the rotational frequency, the acceleration increases by a factor of 4.

7 THE CORIOLIS FORCE Coriolis Force – the apparent force that seems to deflect a moving object from its path and is observed only in rotating frames of references. Because of the Coriolis Force winds rotate counterclockwise around a Low Pressure systems in the Northern Hemisphere and they rotate clockwise around Low Pressure systems in the Southern Hemisphere. SKIP 8.3 Section Review p. 217 # 40-46 8.3 Problems

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