This unit in physics I learned about…
Rotational and Tangential Velocity:
We began our unit by differentiating between tangential and rotational velocities.
Tangential Velocity: How much distance you cover
Rotational Velocity: Number of rotations per unit of time
We learned, for example, that when on a merry-go-round, the outside travels a greater distance vs. the inside. Therefore, since the outside has a greater distance to travel in the same time that the inside
travels, its tangential speed will be larger. Both outside and inside will have the same rotational speeds because they're rotating the same number of times, just at different speeds. We learned the same concept with a different example shown in the picture to the right. With the two gears, one has 24 prongs and the other, 12. This is a 2:1 ratio, and that means that the smaller gear, in two rotation, goes around twice as much as the larger gear which only went around once. This means that: The large gear has a smaller rotational speed vs the smalls gears large rotational speed. The tangential speeds for both gears are the same because any point along the edge of rather gear will cover the same distance in the same time interval.
Train wheels are made in a way that self corrects themselves. The larger part of the wheel is on the inside and the skinny part in on the outside. This is because when the train starts to go off track, the larger part of the wheel will be on the track at the same time that the small part is. The larger part of the wheel has a greater distance to cover in the same time as the small wheel, therefore it will move faster, and thus move itself back on track.
Rotational Inertia and Conservation of Angular Momentum:
The main thing to remember about rotational inertia is that there is a larger rotational inertia if the mass is farther away from the axis. This explains why ice skaters pull in their arms to spin faster.
Rotational Inertia: Property of an object to resist changes in the spin
Spinning velocity is all about the distribution mass. When an ice skaters arms are away from her axis of rotation, she will slow down, and she will have a large rotational inertia. But when an ice skater pulls her arms in toward her axis of rotation, she will move fast and have a smaller rotational inertia.
Angular momentum before = angular momentum after
This means that if you have your arms away from your axis of rotation, you will have a small rotational velocity and a large rotational inertia. Therefore, when you pull your arms towards you, your rotational inertia and rotational velocity will have to be opposite of the before (spinning with arms away) in order to have both momentums equal. So the equation will look something like this:
Rotational Velocity x Rotational Inertia = Rotational Velocity x Rotational Inertia
In the video form the movie Ice Princess, the ice skater demonstrates her rotational velocity increasing when she pulls her arms in vs when her arms are away from her. (Start at :35)
Rotational and Tangential Velocity:
We began our unit by differentiating between tangential and rotational velocities.
Tangential Velocity: How much distance you cover
Rotational Velocity: Number of rotations per unit of time
We learned, for example, that when on a merry-go-round, the outside travels a greater distance vs. the inside. Therefore, since the outside has a greater distance to travel in the same time that the inside
Train wheels are made in a way that self corrects themselves. The larger part of the wheel is on the inside and the skinny part in on the outside. This is because when the train starts to go off track, the larger part of the wheel will be on the track at the same time that the small part is. The larger part of the wheel has a greater distance to cover in the same time as the small wheel, therefore it will move faster, and thus move itself back on track.
Rotational Inertia and Conservation of Angular Momentum:
The main thing to remember about rotational inertia is that there is a larger rotational inertia if the mass is farther away from the axis. This explains why ice skaters pull in their arms to spin faster.
Rotational Inertia: Property of an object to resist changes in the spin
Spinning velocity is all about the distribution mass. When an ice skaters arms are away from her axis of rotation, she will slow down, and she will have a large rotational inertia. But when an ice skater pulls her arms in toward her axis of rotation, she will move fast and have a smaller rotational inertia.
Angular momentum before = angular momentum after
This means that if you have your arms away from your axis of rotation, you will have a small rotational velocity and a large rotational inertia. Therefore, when you pull your arms towards you, your rotational inertia and rotational velocity will have to be opposite of the before (spinning with arms away) in order to have both momentums equal. So the equation will look something like this:
Rotational Velocity x Rotational Inertia = Rotational Velocity x Rotational Inertia
In the video form the movie Ice Princess, the ice skater demonstrates her rotational velocity increasing when she pulls her arms in vs when her arms are away from her. (Start at :35)
Torque and Center of Mass:
Torque = force x lever arm (distance form axis of rotation)
When you are trying to unscrew a screw with a wrench, what do you do to make it easier? There are two things that can help this, one is to add more force, and the other is to increase the lever arm, or do both. By doing these things, you will increase your torque and thus, make it easier to unscrew the screw.
The center of mass is the average position of an objects mass. So in the picture to the left, the three boxes have different centers of mass, and this either makes it easier of harder to push them over. For A and B the center of gravity is within the base of support, therefore the boxes will not fall over. But box
In the example below, a long stick is balanced. To find how many meters the ball is away form the fulcrum to make the system balanced, we use these steps and equations:
counter clockwise torque = clockwise torque
lever arm x force = lever arm x force --> before and after
1x = 2(4)
x = 8m
These steps are the same to find the weight of the meter stick, just plugging in different numbers.
Centripetal/Centrifigual Force:
Centripetal force: Center seeking force that keeps you going into a curve.
Centrifugal force: center fleeing force (fictional)
An example that we learned that helps to understand centripetal forces is: You are riding on a bus and suddenly wake up form your nap because the bus just turned. The force that causes you to slam into the person sitting next to you is the centripetal force. This is because the bus is moving towards the center, and you are still moving straight, so you hit the person next to you. Nothing causes me to hit the person, only the fact that I was moving one way and the bus was moving the other.
An example to understand centrifugal force is: when the water flies out of a washing machine, there is no centripetal force, therefore the water moves in a straight line path and moves out of the washing machine.
The reason why a racetrack is elevated in because the cars need more centripetal force than friction or they would fly off the track into the stands. So in the picture, the fgravity is going straight down and the fsupport is going perpendicular to the car. When these vector are added together, the direction formed is in the direction of the center, thus the centripetal force. This force and the velocity going straight help the car to go in a curved path.
Difficulties this unit…
I found it hard to wrap my head around centripetal and centrifugal forces. But I was able to get past this by asking my piers and also going online and looking up videos about it and watching my piers blogs postings on it to gain there feedback and ideas about it. I was able to persist through the mass of a meter stick lab with my group by thinking about all the equations that we had learned thus far and putting it all together. This helped me to gain confidence, and this new found confidence has helped me to understand the unit better than other units before. My goals for the next unit are to improve my open note quiz grades by taking much better notes. The open note quizzes are very important because they help me to see where I am and what I need to know. But this will be easier if I already understand because of the helpful noted I take before.
Connections…
This unit, I was able to make a connection in the real world one day on the weekend when I was playing soccer with a friend. The friend I was playing with is very tall and I was able to knock him over because of physics. Because he did not have his feet spread apart to widen his base of support, and bend his knees to bring his center of gravity closer to the ground, I was able to knock him over. I found this the most interesting and personal even though I continued to find physics all over in the world around me.
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