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Chapter 10 Rotational Motion and Torque
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10.1- Angular Position, Velocity and Acceleration For a rigid rotating object a point P will rotate in a circle of radius r away from the axis of rotation.
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10.1 The location of point P can be described in polar coordinates (r, θ). The circular distance traveled is called the arc length according to When θ is measured in radians (1 radian is the angle swept by an arc length equal to the radius).
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10.1 Angles measured in radians, degrees, revolutions 2π rad = 360o = 1 rev Angular displacement- the change in angular position
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10.1 Angular Velocity- the rate of change in angular displacement – For constant rotations or averages – For Angular Position as function of time Measured in rad/s or rev/s
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10.1 Quick Quizzes p 294 Angular Acceleration- the rate of change of angular velocity or
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10.1 Angular Velocity/Acceleration Vector Directions- Right Hand Rule Generally CCW is positive, CW is negative Acceleration direction Points the same direction as ω, if ω is increasing, antiparallel if ω decreases
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10.1 Quick Quiz p. 296
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10.2 Rotational Kinematics Tracking the increasing and decreasing rotation can be done with the same relationships as increasing and decreasing linear motion. Remember Δx Δθ v ω a α
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10.2 Quick Quiz p. 297 Example 10.1
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10.3 Angular and Linear Quantities When an object rotates on any axis, every particle in that object travels in a circle of constant radius (distance from axis) The motion of each point can be described linearly about the circular path Tangential Velocity-
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10.3 Tangential Acceleration- We also know there is a centripetal acceleration
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10.3 The resultant acceleration- Quick Quizzes p. 298 Examples 10.2
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10.4 Rotational Kinetic Energy- the kinetic energy of a single particle in a rotating object is… The Total Kinetic Energy would be the sum of all K i Which can be rewritten...
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10.4 This is a new term we will call Moment of Inertia Moment of Inertia has Dimensions ML 2 and units kg. m 2 (~ rotational counterpart to mass) Rotational Kinetic Energy-
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10.4 Quick Quiz p. 301 Examples 10.3, 10.4
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10.5 Calculating Moments of Inertia We can evaluate the moment of inertia of an extended object by adding up the M.o.I. for an infinite number of small particles.
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10.5 Its generally easier to calculate based on the volume of elements rather than mass so using for small elements…. We have… If ρ is constant, the integral can be completed based on the geometric shape of the object.
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10.5 Volumetric Density- ρ (mass per unit volume) Surface Mass Density- σ (mass per unit area) – (Sheet of uniform thickness (t) σ = ρt) Linear Mass Density- λ (mass per unit length) – (Rod of uniform cross sectional area (A) λ = M/L = ρA) See Board Diagrams
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10.5 Example 10.5-10.7 Common M.o.I. for high symmetry shapes (p. 304) Parallel Axis Theorem
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10.5 Example 10.8
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10.6 Torque Torque- the tendency of a force to cause rotation about an axis Where r is the distance from the axis of rotation and Fsinφ is the perpendicular component of the force Where F is the force and d is the “moment arm.”
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10.6 Moment Arm- (lever arm) the perpendicular distance from the axis of rotation to the “line of action”
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10.6 Torque is a vector has dimensions ML 2 T -2 which are the same as work, units will also be N. m Even though they have the same dimensions and units, they are two very different concepts. Work is a scalar product of two vectors Torque is a vector product of two vectors
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10.6 The direction of the torque vector follows the right hand rule for rotation, and CCW torques will be considered positive, CW torques negative. Quick Quizzes p. 307 Example 10.9
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10.7 Torque and Angular Acceleration Consider a tangential and radial force on a particle. The F t causes a tangential acceleration.
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10.7 We can also look at the torque caused by the tangential force. And since…
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10.7 Newton’s 2 nd Law (Rotational Analog) Quick Quiz p. 309 Review Examples 10.10-10.13
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10.8 Work, Power, and Energy Rotational Analogs for Work, Power, and Energy – Work – Energy – Work-KE Theorem – Power
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10.8 Quick Quiz p. 314 Examples 10.14, 10.15
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10.9 Rolling Motion For an object rolling in a straight line path the translational motion of its center of mass can be related to its angular displacment, velocity and acceleration. Condition for Pure Rolling Motion- no slipping – If there is no slip, then every point on the outside of the wheel contacts the ground and following relationships hold.
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10.9
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Linear distance traveled (translational displacment)- CofM Velocity (trans. vel.)- CofM Accel. (trans. accel.)-
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10.9
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Total Kinetic Energy for a rolling object K tot = K r + K cm (using just translational speed) (using just angular speed)
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10.9 Friction must be present to give the torque causing rotation, but does not cause a loss of energy because the point of contact does not slide on the surface. With zero friction the object would slide, not roll. Quick Quizzes p. 319 Example 10.16
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