What are the forces on amusement park rides?

Gravity and inertia are big players when it comes to how you experience the ride. The force of gravity is measured in g-forces. Most of the time, you are experiencing 1 g, the normal force gravity exerts on you. However, motion can change how you experience the force of gravity.



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When you go around a turn, you feel pushed against the outside of the car. This force is centripetal force and helps keep you in your seat. In the loop-the-loop upside down design, it's inertia that keeps you in your seat. Inertia is the force that presses your body to the outside of the loop as the train spins around.

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In roller coasters, the two forms of energy that are most important are gravitational potential energy and kinetic energy. Gravitational potential energy is the energy that an object has because of its height and is equal to the object's mass multiplied by its height multiplied by the gravitational constant (PE = mgh).

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Basic mathematical subjects such as calculus help determine the height needed to allow the car to get up the next hill, the maximum speed, and the angles of ascent and descent. These calculations also help make sure that the roller coaster is safe. No doubt about it--math keeps you on track.

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The coaster will roll on indefinitely, or until of course the end of the track, where unbalanced forces like friction between the track and the wheels slow the coaster ultimately to a stop. The riders, which have inertia, are also acted on by unbalanced forces throughout the ride, causing them to change their motion.

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In roller coasters, the two forms of energy that are most important are gravitational potential energy and kinetic energy.

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Traditionally, a rollercoaster relies on gravitational potential energy – the energy it possesses due to its height. It is pulled to the top of a big hill, the highest point of the ride, and released.

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When you go around a turn, you feel pushed against the outside of the car. This force is centripetal force and helps keep you in your seat. In the loop-the-loop upside down design, it's inertia that keeps you in your seat. Inertia is the force that presses your body to the outside of the loop as the train spins around.

MORE DETAILS

The coaster will roll on indefinitely, or until of course the end of the track, where unbalanced forces like friction between the track and the wheels slow the coaster ultimately to a stop. The riders, which have inertia, are also acted on by unbalanced forces throughout the ride, causing them to change their motion.

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CoasterForce is a large free-to-join, unbiased and independent theme park and roller coaster enthusiast community. CoasterForce's mission is to encourage everybody, regardless of their level of enthusiasm, to visit as many theme parks as they can.

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The force of gravity pulling a roller coaster down hill causes the roller coaster to go faster and faster, it is accelerating. The force of gravity causes a roller coaster to go slower and slower when it climbs a hill, the roller coaster is decelerating or going slower.

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In roller coasters, the two forms of energy that are most important are gravitational potential energy and kinetic energy.

MORE DETAILS

Basic mathematical subjects such as calculus help determine the height needed to allow the car to get up the next hill, the maximum speed, and the angles of ascent and descent. These calculations also help make sure that the roller coaster is safe. No doubt about it--math keeps you on track.

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This force can be the force of gravity when the roller coaster is moving down then there is an equal and opposite body pushing the body upwards. The forces don't cancel each other and act on different bodies. The force of gravity acts on the roller coaster while the opposite reaction force acts on the track.

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