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Resources
Resources
Slideshows: Unit 6 Energy and Momentum of Rotating Systems
Textbook: Chapters 7 & 8 in Mastering Physics (get online code for registration on about page of google classroom)
External Resources
http://www.rpi.edu/dept/phys/Dept2/APPhys1/torque/torque/node6.html a site with some basic torque practice and explanations.
Objectives
Objectives
Describe rotational motion
use angular displacement, angular velocity and angular acceleration to describe motion about a fixed axis
relate rotational motion to linear motion using the radius
use + or or - for counterclockwise or clockwise motion.
Torque Basics
Use representations of the relationship between force and torque.
Compare torques on an object caused by forces
Estimate torque on an object
In equilibrium
Design an experiment & analyze data testing a question about balanced torques in a rigid body system
Calculate torques in 2D while in static equilibrium (from a diagram or model)
Center of mass
analyze the motion of a system of 2 objects based on their center of mass
in the case of rotation, a force going through the center of mass causes no torque.
Unbalanced torques
Net torque causes acceleration
calculate angular acceleration from the net torque and rotational inertia of an object or rigid system
predict angular velocity changes when forces cause a net torque on an object rotating on a fixed axis.
Net Torque causes a change in momentum
Angular Momentum
basics
Use right hand rule to find direction of angular momentum (classify as + or -)
relate angular momentum to linear momentum by using the radius
relate angular momentum to rotational inertia and angular velocity
Consider the locations and velocities of individual parts of a system to describe & calculate the angular momentum of a system
In particular, calculate momentum for a system of a point mass and extended object
changing momentum
relate change in angular momentum to average torque and the amount of time the torque is applied.
zero net torque indicates momentum is conserved
changes in mass distribution can affect the angular speed of a system without changing momentum
Consider elliptical orbits in earth-satellite system
collisions can cause exchanges of angular momentum
predict the effects of a collision in terms of rotational behaviors by finding total momentum before and after a collision.
multiple objects rotating together can be treated as a single system with a combined momentum
find the change of angular momentum in unfamiliar circumstances & plan labs
Equations
Equations
In addition to the equations above (on the formula chart), you should memorize or be able to recreate the following:
use r to convert between angular and linear quantities (v = ωr, a = ⍺r, d=𝜃r)
Replace angular quantities in linear equations -- like v2 = v02 + 2a(x-x0).
Create simple definitions for average angular quantities, like average angular acceleration = change in angular velocity divided by time, as we did with linear quantities
Know that I = mr2 for point objects at the edge of a circle or hoops, I = 1/2 mr2 for disks or cylinders, and is even less (2/5mr2) for spheres.
Show that the angular momentum of a linearly traveling object can be found by L=mvr (or in other words, L=pr)
Viral Physics videos
Viral Physics videos
This is an amazing build project that actually uses what we talk about with torque, rotational energy, rotational inertia, and some really cool variations to create a near perfect transfer of energy.
This dude has come insane core strength to hold this pose. How would you analyze the forces/torques in this equilibrium situation?
Common Misconceptions
Common Misconceptions
Misconception: Any force acting on an object will produce a torque.
Principle: Force components perpendicular to the radius (or forces with moment arms) cause torque
Reasoning: Torque is a measurement of a tendency to change rotation and in order to do that a force must in a way where the line of action of the force does not pass through the center of mass of a free moving object or the pivot point of a fixed object. If it does pass through these points it will affect the whole object equally and not cause rotation, where if it acts to one side or other of the pivot or center, it will cause that side to move along with the force while the other side pivots around the other way.
Misconception: Objects moving in a straight line can not have angular momentum.
Principle: If an object can give angular momentum to a second object, it must have angular momentum to begin with.
Reasoning: Many systems/objects can be evaluated multiple ways. Straight line motion, if considered from a point of rotation that matters for the system, can can be described in terms of how many radians/s it moves as opposed to m/s. While the angular velocity will be increasing as it gets closer to the pivot, the r value will be decreasing and as a result the overall angular momentum of the object a remains constant L=mvr (as shown in the diagram where p=mv and D is the shortest R of the path. This is only meaningful if the angular momentum is going to be transferred to a second object; otherwise it is not intuitive.
Misconception: Torque is the same as force and is in same direction.
Principle: Torque is a tendency to rotate caused by force with a direction that is 90 degrees to the force and moment arm as determined by the right hand rule.
Reasoning: The direction of torque is not terribly important until you talk about changing angular momentum, in which case we see weird stuff like gyroscopic precession (google it and be amazed). This behavior is explained most directly by assigning the direction for angular momentum and torque according to the right hand rule.
Misconception: The direction of angular momentum is in direction of linear momentum.
Principle: The direction of angular momentum is determined by the right hand rule.
Reasoning: Use the same diagram as above for either angular speed or angular momentum, but alter it by using your fingers to represent the movement ov the rotating object, as opposed to the force acting on it. It will always be a direction that is 90 degrees to the plane of rotation, which is weird, but required for things like gyroscopic precession to make sense.
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