1 / 18

Rotational Motion Angular Quantities Angular Kinematics Rolling Motion

Rotational Motion Angular Quantities Angular Kinematics Rolling Motion. Chapter 8 Rotational Motion. We consider only rigid (non-squishy) bodies in this chapter.

kimberly-woods
Download Presentation

Rotational Motion Angular Quantities Angular Kinematics Rolling Motion

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Rotational Motion Angular Quantities Angular Kinematics Rolling Motion

  2. Chapter 8 Rotational Motion We consider only rigid (non-squishy) bodies in this chapter. We have already studied translational motion in considerable detail. We now know that the translational motion we have been describing is the motion of the center of mass. We have already studied translational motion in considerable detail. We begin this chapter by considering purely rotational motion (the center of mass does not change its xyz coordinates)… We begin this chapter by considering purely rotational motion (the center of mass does not change its xyz coordinates)… but soon we will consider objects which both rotate and translate.

  3. 8.1 Angular Quantities For rotational motion, we specify angles in radians instead of degrees. Look at a point P somewhere on a rotating circular disc. P is a distance r from the center of the disc. P r ℓ Choose the x-axis to be horizontal. Then the line from the center of the disc to P makes an angle  with the x-axis.  O x =ℓ/r, where ℓ is the length of the arc from the x-axis to P.

  4. P ℓ  O x If the angle is 360 degrees, the arc length is 2r, so 2 radians are equal to 360 degrees. This is how I remember the conversion factor between degrees and radians. Strictly speaking, radians are not a unit (angles are unitless). When you studied kinematics, you defined an object’s motion by specifying its position, velocity, and acceleration. Now we are about to study angular kinematics. We will define an object’s angular motion by specifying its angle (rotational position relative to some axis), angular velocity, and angular acceleration.

  5. If we call the z axis the axis of rotation, angular velocity is defined by avg=/t, where  is the angular displacement of a rotating object in the time t. Instantaneous angular velocity is =d/dt. “Wait a minute! Velocity is a vector! What is the direction of ?” Consider our rotating wheel. Here’s a point and its instantaneous linear velocity. Another. Another. And another. How do we define a unique direction for the angular velocity?

  6. The direction of  is along the z-axis, perpendicular to the wheel, and is given by the right hand rule. If we put the x and y axes in the plane of the wheel, then the wheel is rotating about an axis perpendicular to this plane. z  We usually call this the z-axis. To remind you that angular velocity has a direction, I’ll write z,avg=/t and z=d/dt. Our rules for vectors apply. You get to choose the direction of the z-axis. Whether z is positive or negative depends on the direction of rotation. this symbol indicates an arrow coming out of the screen

  7. If this business about direction is confusing, don’t worry. It is not particularly important this semester. You’ll learn to love the right hand rule if you are lucky enough to take the second semester of algebra-based physics! Note that all points on a rigid body rotate with the same angular velocity (they go around once in the same time). What about the tangential velocities of different points? We’ll get to that question in a minute.

  8. P ℓ   z x Angular velocity z,avg=/t and z=d/dt. You can probably figure out how angular acceleration is defined. z,avg=z/t, where z is the change in angular velocity of a rotating object in the time t. Instantaneous angular acceleration is z=dz/dt. The subscript z on  and  emphasizes the rotation is relative to some axis, which we typically label “z.” I should really put a subscript z on  because it is also measured relative to the z axis. To be consistent with Physics 23, I will leave it off.

  9. Because points on a rotating object also have an instantaneous linear motion, linear and angular motion must be connected. vtang r z . As your book shows, vtangential=rz and atangential=rz. Note that z and z are the same for all points on a rotating rigid body, but vtang and atang are not. Notation: vtangential=vtang=v. , , v and a are all magnitudes of vectors! z andz are vector components!

  10. Acceleration has both tangential and radial components. We know from before that ar=v2/r. Total acceleration is a=atangential+ar. vtang  z  r We often use frequency and period of rotation: f=/2 and T=1/f. Example 8.3. What are the linear speed and acceleration of a child seated 1.2 m from the center of a steadily rotating merry-go-round that makes one complete revolution in 4.0 s? z = 2/4 s-1 vtang = rz = (1.2 m) (/2 s-1) vtang = 0.6 m/s z = 0 (the angular velocity is not changing)

  11. a = 2.96 m/s2, towards center of merry-go-round vtang  z,avg=/t z,avg=z/t z  r vtang=rz atang=rz You can also use aradial = aR=Rz2 atang = rz = 0 aradial = ar = (0.6  m/s)2 / (1.2 m) ar = 2.96 m/s2 The total acceleration is the vector sum of the radial and tangential accelerations: New OSE’s introduced in this section:

  12. 8.2 Kinematic Equations for Uniformly Accelerated Rotational Motion Remember our equations of kinematics from chapter 2? Analogous equations hold for rotational motion. linear angular vx=v0x+axt z=0z+zt x=x0+v0xt+½axt2θ=θ0+0zt+½zt2 vx2=v0x2+2ax(x-x0) z2=z2+2z(θ-θ0) new OSE’s

  13. 0 0 Example 8.6. Through how many revolutions did the centrifuge motor of example 8.5 turn during its acceleration period? Assume constant angular acceleration. In example 8.5, a centrifuge motor goes from rest to 20,000 rpm in 5 minutes. First we need to calculate , as in example 8.5. z,avg=z/t z,avg=(f-i)/(tf-ti) f=(20000rev/min)(min/60s)(2 radians/rev) tf=(5 min)(60 s/min) z,avg=7.0 rad/s2

  14. 0 0 Next calculate the angle through which the centrifuge motor turns. θ=θ0+0zt+½zt2 θ=½ (7.0 rad/s2) (300 s)2 θ=3.15x105 radians There are 2 radians in each revolution so the number of revolutions, N, is N=(3.15x105 radians)(revolution/2 radians) N=5x104 revolutions). I chose to do the calculations numerically rather than symbolically for practice with angular conversions.

  15. 8.3 Rolling Motion Many rotational motion situations involve rolling objects. Rolling without slipping involves both rotation and translation.  Friction between the rolling object and the surface it rolls on is static, because the rolling object’s contact point with the surface is always instantaneously at rest. this point on the wheel is instantaneously at rest if the wheel does not slip (slide) the illustration of  in this diagram is misleading; the direction of  would actually be into the screen

  16. Your text discusses the rolling motion of a bicycle wheel by changing reference frames; the center of mass of the wheel is taken to be at rest with the ground moving past it. We skipped the sections on relative motion, so I won’t expect you to perform a detailed analysis of rolling motion by switching reference frames. However, you should be able to calculate how many revolutions the bicycle wheel makes in example 8.7.

  17. vtop=2vcm vcm vcm vcm vbot=0 Here are some things you need to know about rolling without slipping. The point on the rolling object in contact with the “ground” is instantaneously at rest. The center of the wheel moves with the speed of the center of mass. The point at the “top” of the rolling wheel moves with a speed twice the center of mass. The two side points at the level of the center of mass move vertically with the speed of the center of mass.

  18. vtop=2vcm vcm vcm vcm vbot=0 What is important for us is that if an object rolls without slipping, we can use our OSE’s for z and z, using the translational speed of the object. vCM=rz aCM=rz These relationships will be valuable when we study the kinetic energy of rotating objects.

More Related