The Physics of Roller Coaster

i: Introduction You are afraid to walk up the stairs of iron and walk on the platform. You do not want to proceed, but your friend is jealous of you and says, "This is not that fast." You entered the seat and lowered the harness. No, this is not the latest, largest technical frontier. This is a roller coaster. The first wheel roller coaster since 1804 called "Les Montagnes Russes" - Since being built in Paris in France, roller coasters have been the main reason for adventure and fancy of children and children.

Analysis of the roller coaster In order to fully understand the relationship between the physics and the roller coaster, it is important to first explain and explain the basic structure of the roller coaster. Simply put, a roller coaster is like a passenger train. To explain, the roller coaster is made up of a series of connecting cars moving on track. However, unlike a train, the roller coaster does not have an engine, rather it has its own power source. - There is no doubt that a roller coaster is the king of an amusement park. Regardless of whether you prefer old-fashioned, rattling wooden roller coasters, it is filled with positive and negative G's and pretty unstable feelings. Or you can prepare the latest tube steel roller coaster in advance. Faster roller coaster including speed of death, hairpin rotation, and of course loops

Traveling on a roller coaster is an exciting experience including rich physical properties. Part of the roller coaster physics is work and energy physics. Cycling usually begins with the chain and motor (or other mechanical device) applying force to the car train and lifting the train to the top of the mountain. When the car is lifted to the top of the mountain, gravity will take over and the rest of the car will be the experience of energy conversion. At the top of the mountain, the car has plenty of potential energy. Potential Energy - Vertical Position Energy - It depends on the mass of the object and the height of the object. The great potential energy of a car is due to the fact that they rise from the ground. When a car falls into the first drop, they lose the majority of their potential energy that is consistent with their height loss. Then the car gains kinetic energy

One way of thinking about potential energy and kinetic energy is to shoot a car with a roller coaster. As the car moves along the roller coaster, you gain position energy. It has the greatest potential energy at the top of the roller coaster. As the car moves along the roller coaster, you get speed and kinetic energy. At the same time, it is growing momentum, and we are losing potential energy. At the bottom of the roller coaster, the car has the maximum speed and maximum kinetic energy, but it is also the smallest potential energy.