What force is acting when the roller coaster is moving down?

Gravity always pulls downward with the same strength, and, in the case of a roller coaster, it pulls downward on the cars wherever they are on the track. Near the bottom of a loop, gravity pulls in a direction away from the center of the loop circle.



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A roller coaster does not have an engine to generate energy. The climb up the first hill is accomplished by a lift or cable that pulls the train up. This builds up a supply of potential energy that will be used to go down the hill as the train is pulled by gravity.

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A roller coaster is a machine that uses gravity and inertia to send a train of cars along a winding track. The combination of gravity and inertia, along with g-forces and centripetal acceleration give the body certain sensations as the coaster moves up, down, and around the track.

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The potential energy of the roller coaster when it is at the top of a hill is converted into kinetic energy as the roller coaster speeds down the hill. As the roller coaster goes up another hill, it slows down. The kinetic energy is converted into potential energy.

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Two of the most significant are friction and air resistance. As you ride a roller coaster, its wheels rub along the rails, creating heat as a result of friction. This friction slows the roller coaster gradually, as does the air that you fly through as you ride the ride.

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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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The roller coaster cars gain potential energy as they are pulled to the top of the first hill. As the cars descend the potential energy is converted to kinetic energy. The coaster cars have the maximum kinetic energy they will ever have throughout the ride.

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For example, a rollercoaster car at the top of a hill has potential energy because it has the ability to move downward. This potential energy is converted into kinetic energy, or the energy of motion, when the rollercoaster car starts to move.

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Rollercoaster trains have no engine or no power source of their own. Instead, they rely on a supply of potential energy that is converted to kinetic energy. Traditionally, a rollercoaster relies on gravitational potential energy – the energy it possesses due to its height.

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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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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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Is going down a roller coaster kinetic or potential energy? The roller coaster cars gain potential energy as they are pulled to the top of the first hill. As the cars descend the potential energy is converted to kinetic energy. The coaster cars have the maximum kinetic energy they will ever have throughout the ride.

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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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That first drop generates sufficient energy to propel the coaster car throughout the rest of the ride. By cranking the roller coaster's cars up to the top of a hill, the cars store a large amount of gravitational potential energy.

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