Transcript Roller Coasters

ROLLER
COASTERS
http://www.youtube.com/watch?v=jRoilxK_0RA
By: Alize Habib
Ahmed Daniyal Mirza
Selin Narin
CIRCULAR MOTION
What is a theme park without a roller coaster?
•
You may think that the thrill of riding a roller coaster is derived from
the high speeds one experiences, however, the excitement of riding a
roller coaster lies in the feelings of weightlessness, weightiness and
the acceleration one experiences.
•
Curved paths such as banked turns and loops are essential in a
roller coaster and centripetal acceleration is part of moving in a
curved path. Centripetal acceleration and thus circular motion are
therefore essential to the successful functioning of roller
coasters.
CENTRIPETAL ACCELERATION
•
Centripetal acceleration has two aspects:
1. It is always directed towards the center of the circular path.
2.) It is always in a direction perpendicular to the speed.
Velocity v and acceleration a in uniform
circular motion at angular rate ω; the speed
is constant, but the velocity is always tangent
to the orbit; the acceleration has constant
magnitude, but always points toward the
center of rotation
• Acceleration can result from a change in speed and a change in direction:
 The change in speed occurs when the roller coaster moves from the bottom of
the loop to the top of the loop (it being fastest at the bottom and slowest at the
top).
 The change in direction occurs as the roller coaster moves right-ward, upward,
left-ward and then downward.
• In this case, there will also be a slight acceleration tangent to the track
positively or negatively affecting the speed of the roller coaster.
• For a roller moving at constant speed, the acceleration will only be centripetal
CENTRIPETAL FORCE
• For the roller coaster to successfully move through a loop,
there must be a sufficient centripetal force.
• This force is always in the direction of the centripetal
acceleration, and is the net force that results from
adding/subtracting the gravitational force to/from the normal
reaction force acting on the roller coaster from the track.
• The gravitational force is always acting downwards (away
from the centrer of the circular path) and can be found
using F = mg.
• The normal reaction force must be enough to overcome the
gravitational force for there to be a resulting centripetal
force that enables the roller coaster to complete the loop.
NEW INSIGHT
1. How does a roller coaster stay in a circular path?
Centripetal Force enables the roller coaster to move through the circular path without
falling to the ground.
2. How can a roller coaster can hang you upside down and not fall from gravity
Right on top of a loop, we feel pressed to our seat, rather than feeling a gravitational
attraction towards earth. This feeling, caused by centripetal force acting on us, releases
our bodies from the dominant force of gravity(except when we are at the top, because
at the top gravity and the centripetal force are acting together) is what makes the
rollercoaster experience unique and desired.
3. Why do we love roller coasters?
Most cars can obtain the same speed as a roller coaster, therefore, it isn’t the speed that
thrills us - it is the acceleration as we move left, right, up and down.
WORKS CITED
Harris, Tom. “How Roller Coatsers Work.” science.howstuffworks.com. howstuffworks,
n.d. Web. 29 November 2011.
“Applications of Circular Motion.” thephysicsclassroom.com. Thephysicsclassroom,
n.d. Web. 29 November 2011.
“Roller Coaster G-Forces.” thephysicsclassroom.com. Thephysicsclassroom, n.d. Web.
29 November 2011.