Survey
* Your assessment is very important for improving the workof artificial intelligence, which forms the content of this project
Download Roller Coaster Physics
Document related concepts
Transcript
Roller Coaster Physics Minimum Kinetic Energy Maximum Kinetic Energy The bottom of the first hill should have the greatest kinetic energy. As the roller coaster train begins its descent from the lift hill, its velocity increases. This causes the train to gain kinetic energy, which is the energy of motion. The faster the train moves, the more kinetic energy the train gains. This is shown by the equation for kinetic energy: K = 1/2mv2 Where K is kinetic energy, m is mass in kilograms, and v is velocity in meters per second Maximum Velocity Minimum Velocity Velocity is speed with direction. The faster you go the greater in a given direction the velocity. Maximum Potential Energy Minimum Potential Energy PE = mgh The highest point of a roller coaster has the highest potential energy. Where PE is potential energy, m is mass in kilograms, g is acceleration due to gravity, and h is the distance above the ground in meters. Because mass and gravity are constant for the train, if the height of the train above the ground is increased, the potential energy must also increase. This means that the potential energy for the roller coaster system is greatest at the highest point on the track: the top of the lift hill. Maximum “g” Force or Maximum Compression in Seat Minimum “g” Force or Maximum Air Time (Flying out of your seat) A force of 1 G is the usual force of the Earth’s gravitational pull that a person feels when they are at rest on the Earth’s surface; in other words, it can be described as a person’s normal weight. When a person feels weightless, as in free fall or in space, they are experiencing 0 G’s. When the roller coaster train is going down a hill, the passengers usually undergo somewhere between 0 and 1 G. However, if the top of the hill is curved more narrowly than a parabola, the passengers will experience negative G’s as they rise above the seat and get pushed down by the lap bar. This is because gravity and the passengers’ inertia would have them fall in a parabolic arc. G-forces greater than 1 can be felt at the bottom of hills as the train changes direction. In this case the train is pushing up on the passengers with more than the force of gravity because it is changing their direction of movement from down to up.
