Rotational Motion
Transcription
Rotational Motion
Rotational Motion Angular Quantities In purely rotational motion, all points on the object move in circles around the axis of rotation (“O”). The radius of the circle is r. All points on a straight line drawn through the axis move through the same angle in the same time. The angle θ in radians is defined: (8-1a) where l is the arc length. Example: A particular bird’s eye can just distinguish objects that subtend an angle no smaller than about 3x10-4 rad. a) How many degrees is this? b) How small an object can the bird just distinguish when flying at a height of 100 m? Solution: a) 3600=2π rad, therefore it is: 3x10-4 (360/2π)= 0.0170 b) l=rϴ l= (100 m)(3x10-4 rad)=3x10-2 m= 3 cm Angular displacement: The average angular velocity is defined as the total angular displacement divided by time: The instantaneous angular velocity: units:( radians/s, or s-1) *Radians are dimensionless, as they are defined by the ratio of two lengths* The angular acceleration is the rate at which the angular velocity changes with time: The instantaneous acceleration:units: (radians/ s2, or s-2) Every point on a rotating body has an angular velocity ω and a linear velocity v. They are related: Therefore, objects farther from the axis of rotation will move faster. Example: A rotating carousel has one child sitting on a horse near the outer edge and another child seated on a lion halfway out from the center. How do their linear and angular speeds compare? Answer: The rotate with the same rate ( i.e. their times for a complete revolution are the same, ω= constant). The child sitting on the horse rotates at a greater radius, therefore his speed would be greater (v=rω) Example: In the preceding question, how would the centripetal acceleration of each child (at different radii) compare? Answer: As shown in the following slide, for a constant angular speed the centripetal acceleration increases with radius. In fact it depends on the r2. If the angular velocity of a rotating object changes, it has a tangential acceleration: Even if the angular velocity is constant, each point on the object has a centripetal acceleration: Here is the correspondence between linear and rotational quantities: The frequency is the number of complete revolutions per second: Frequencies are measured in hertz. The period is the time one revolution takes: Example: a) What is the linear speed of a child seated 1.2 m from the center of steadily rotating merrygo-round that makes one complete revolution in 4.0s? b) What is her acceleration? Solution: a) f=1/T= 1 rev/ 4/0s = 0.25 rev/s= 0.25 Hz ω= 2πf=2(π)(0.25)= 1.6 rad/s v=rω= (1.2m)(1.6 rad/s)= 1.9 m/s b) Since ω= constant, atan= 0 aR= ω2r=(1.6)2(1.2)= 3.0 m/s2 Kinematics for Uniformly Accelerated Rotational Motion The equations of motion for constant angular acceleration are the same as those for linear motion, with the substitution of the angular quantities for the linear ones. Example: a) A centrifuge rotor is accelerated from rest to 20,000 rpm in 5.0 min. What is its average angular acceleration over this time period? Solution: ω=2πf=(2π)[(20000)/(60)]= 2100 rad/s Δω ω − ω 0 2100 rad/s-0 = 7.0 rad/s2 α= = = Δt Δt 300s b) Through how many revolutions has the centrifuge rotor on part a) turned during its acceleration period (5 minutes or 300 s)? Solution: It rotated from rest ω0=0. The final angular speed was ω= 2100 rad/s. The angular acceleration was α= 7.0 rad/s2. 1 2 θ = ω 0 t + α t = 0+ 0.5(7)(300)2= 3.15x105 rad 2 The number of revolutions = 3.15x105/(2π)= 5.0x104 rev Rolling Motion (Without Slipping) In (a), a wheel is rolling without slipping. The point P, touching the ground, is instantaneously at rest, and the center moves with velocity v. In (b) the same wheel is seen from a reference frame where C is at rest. Now point P is moving with velocity –v. The linear speed of the wheel is related to its angular speed: Example: A bicycle slows down from 8.40 m/s to rest over a distance of 115 m. Both wheels of the bike have diameter of 68.0 cm. Determine: a) The initial angular velocity of the wheels. b) The total number of revolutions each wheel rotates in coming to rest. c) The angular acceleration of the wheels. d) The time it took to come to a stop. Solution: υ0 a) ω 0 = = 8.40/0.340= 24.7 rad/s r b) A complete revolution corresponds to 2π radians. A complete revolution would correspond to linear distance equivalent to the circumference of the circle ( 2πr) The number of revolutions is = 115/[2π(0.34)]= 53.8 rev 2 2 ω − ω 0 c) α = = (0- 24.72)/[2(2π)(53.8)] = -0.902 rad/s2 2θ d) You could find the linear acceleration (a) from a=rα , then use a kinematic equation to solve for t: υ = υ 0 + at Or one could just use the known angular quantities. ω − ω0 =[0 – 24.7]/[-0.902]= 27.4 s t= α Rotational Dynamics Torque & Rotational Inertia Knowing that we see that , and τ = rF for a single particle. What about an extended object? As the angular acceleration is the same every particle that makes up the whole object, we can write: The quantity is called the rotational inertia (or moment of inertia) of an object. Στ = Iα One notices that the comparison between Force and Torque ( and mass and inertia). The rotational inertia in the torque equation is similar to mass in newton’s 2nd law: F = ma τ = Iα Net Net The distribution of mass matters (for rotational inertia)– the two objects have the same mass, but the one on the left has a greater rotational inertia, as so much of its mass is far from the axis of rotation. Can you guess what type of shape might have the greatest rotational inertia? Think of a mass distribution that could maximize the rotational inertia. The rotational inertia of an object depends not only on its mass distribution but also the location of the axis of rotation – compare (f) and (g), for example. Example: Two weights of mass 5.0 kg and 7.0 kg are mounted 4.0 m apart on a light rod (whose mass can be ignored). Calculate the moment of inertia of the system: a) When rotated about an axis halfway between the weights. b) When the system rotates about an axis 0.50 m to the left of the 5.0 kg mass. 0.5m 4.0 m b) a) 7.0 kg 5.0 kg axis of rotation 4.0 m 5.0 kg axis of rotation Recall: , where r is the perpindicular distance from the axis of rotation. 7.0 kg Solution: a) I= (5.0 kg)(2.0m)2 + (7.0 kg)(2.0 m)2 = 48 kg・m2 b) I= (5.0 kg)(0.50m)2 + (7.0 kg)(4.5 m)2 = 143 kg・m2 Again it is worth pointing out that the rotational inertia of an object (often called a rigid body) depends on the its axis of rotation. Solving Problems in Rotational Dynamics 1. Draw a diagram. 2. Decide what the system comprises. 3. Draw a free-body diagram for each object under consideration, including all the forces acting on it and where they act. 4. Find the axis of rotation; calculate the torques around it. 5. Apply Newton’s second law for rotation. If the rotational inertia is not provided, you need to find it before proceeding with this step. 6. Apply Newton’s second law for translation and other laws and principles as needed. 7. Solve. 8. Check your answer for units and correct order of magnitude. Rotational Kinetic Energy The kinetic energy of a rotating object is given by By substituting the rotational quantities, we find that the rotational kinetic energy can be written: A object that has both translational and rotational motion also has both translational and rotational kinetic energy: Example: What will be the speed of a solid sphere of mass M and radius R when it reaches the bottom of an incline if it starts from rest at a vertical height H an rolls without slipping? R H ϴ Solution: Using conservation of energy once can state the following 1 1 2 1 1 2 2 2 M υ1 + mgh1 + Iω1 = M υ 2 + mgh2 + Iω 2 2 2 2 2 One is comparing the total energy at the top of the incline to that at the bottom (h2=0). What is new, is the accounting of the rotational energy. 2 υ Given: I Sphere = MR 2 , υ = rω, ω = 5 r In terms of the variables given one can state: 2 $ ! ! $ 1 1 2 υ MgH = M υ 22 + # MR 2 &# 22 & %" R % 2 2"5 Solving for υ2: 10 υ2 = gH 7 When using conservation of energy, both rotational and translational kinetic energy must be taken into account. All these objects have the same potential energy at the top, but the time it takes them to get down the incline depends on how much rotational inertia they have. The torque does work as it moves the wheel through an angle θ: Angular Momentum and Its Conservation In analogy with linear momentum, we can define angular momentum L: For a point mass L=rp= rmv. The angular momentum of a point mass is actually the vector cross product of r and the linear momentum(enrichment). L=r×p We can then write the total torque as being the rate of change of angular momentum. If the net torque on an object is zero, the total angular momentum is constant. Therefore, systems that can change their rotational inertia through internal forces will also change their rate of rotation: Example: A mass m attached to the end of a string revolves in a circle on a frictionless tabletop. The other end of the string passes through a hole in the table. Initially, the mass revolves with a speed v1=2.4 m/s in a circle of radius r1=0.80 m. The string is then pulled very slowly through the hole so the radius is reduced to r2=0.48 m. What is the speed , v2, of the mass now? Solution: Angular momentum is conserved in this case even with the addition of the force (torque) with the string. The additional torque created by the increase in tension of the string is zero about the axis of rotation since ϴ=0 (lever arm length=0). Conservation of angular momentum states: L = I1ω1 = I 2ω 2 We will consider this to be a point mass then: 2 2 mr ω = mr ∴ 1 1 2 ω2 r1 υ 2 = υ1 r2 also I = mr 2 υ = rω = 4.0 m/s A more direct way could have been used. For a point mass L=rp=rmv. One obtains r1v1=r2v2 immediately. Vector Nature of Angular Quantities The angular velocity vector points along the axis of rotation; its direction is found using a right hand rule: Angular acceleration and angular momentum vectors also point along the axis of rotation.