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Sect. 10.4: Rotational Kinetic Energy
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Translation-Rotation Analogues & Connections
Displacement x θ Velocity v ω Acceleration a α Mass m ? Kinetic Energy (K) (½)mv2 ? CONNECTIONS s = rθ, v = rω, at= rα, ac = (v2/r) = ω2r
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Sect. 10.4: Rotational Kinetic Energy
Translational motion (Chs. 7 & 8): K = (½)mv2 Rigid body rotation, angular velocity ω. Rigid means Every point has the same ω. Object is made of particles, masses mi. For each mi at a distance ri from the rotation axis: vi = riω. So, each mass mi has kinetic energy Ki = (½)mi(vi)2. So, The Rotational Kinetic Energy is: KR = ∑[(½)mi(vi)2] = (½)∑mi(ri)2ω2 = (½)∑mi(ri)2ω2 ω2 goes outside the sum, since it’s the same everywhere in the body Define the moment of inertia of the object, I ∑mi(ri)2 KR = (½)Iω2 (Analogous to (½)mv2)
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Translation-Rotation Analogues & Connections
Displacement x θ Velocity v ω Acceleration a α Force (Torque) F τ Mass (moment of inertia) m I Kinetic Energy (K) (½)mv (½)Iω2 CONNECTIONS s = rθ, v = rω, at= rα, ac = (v2/r) = ω2r
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Example 10.3: Four Rotating Objects
4 tiny spheres on ends of 2 massless rods. Arranged in the x-y plane as shown. Sphere radii are very small. Masses are treated as point masses. Calculate moment of inertia I when (A) The system is rotated about the y axis, as in Fig. a. (B) The system is rotated in the x-y plane as in Fig. b. Figure 10.8: (Example 10.3) Four spheres form an unusual baton. (a) The baton is rotated about the y axis. (b) The baton is rotated about the z axis.
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Bottom line for rotational kinetic energy
Analogy between the kinetic energies associated with linear motion: K = (½)mv2, & the kinetic energy associated with rotational motion: KR = (½)Iω2. NOTE: Rotational kinetic energy is not a new type of energy. But the form of this kinetic energy is different because it applies to a rotating object. Of course, the units of rotational kinetic energy are Joules (J)
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Sect. 10.5: Moments of Inertia
Definition of moment of inertia: I ∑mi(ri)2 Dimensions of I are ML2 & its SI units are kg.m2 Use calculus to calculate the moment of inertia of an object: Assume it is divided into many small volume elements, each of mass Δmi. Rewrite expression for I in terms of Δmi. & take the limit as Δmi 0. So Make a small volume segment assumption & the sum changes to an integral: ρ ≡ density of the object. If ρ is constant, the integral can be evaluated with known geometry, otherwise its variation with position must be known. With this assumption, I can be calculated for simple geometries.
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Notes on Densities ρ Volume Mass Density
Solid mass m in volume V: r = mass per unit volume: r = (m/V) Surface Mass Density Mass m on a thin surface of thickness t: σ = mass per unit thickness: σ = rt Linear Mass Density Mass m in a rod of length L & cross sectional area A: λ = mass per unit length: λ = (m/L) = rA
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Moment of Inertia of a Uniform Thin Hoop
This is a thin hoop, so all mass elements are the same distance from the center
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Moment of Inertia of a Uniform Thin Rod
The hatched area has mass dm = λdx = (M/L)dx Linear Mass Density: Mass per unit length of a rod of uniform cross-sectional area λ = M/L = ρA So, the moment of inertia is
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Moment of Inertia of a Uniform Solid Cylinder
Divide cylinder into concentric shells of radius r, thickness dr, length L. Volume Mass Density: ρ = (m/V) Then, I becomes:
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Moments of Inertia of Some Rigid Objects
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The Parallel Axis Theorem
NOTE! I depends on the rotation axis! Suppose we need I for rotation about the off-center axis in the figure: d If the axis of interest is a distance d from a parallel axis through the center of mass, the moment of inertia has the form:
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Moment of Inertia of a Rod Rotating Around an End
We’ve seen: Moment of inertia ICM of a rod of length L about the center of mass is: What is the moment of inertia I about one end of the rod? Shift rotation axis by D = (½)L & use Parallel Axis Theorem:
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