What is the physics behind roller coaster loops?

For a roller coaster, gravity pulls down on the cars and its riders with a constant force, whether they move uphill, downhill, or through a loop. The rigid steel tracks, together with gravity, provide the centripetal force needed to keep the cars on the arching path as they move through the loop.



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If the tracks tilt up, gravity applies a downward force on the back of the coaster, so it decelerates. Since an object in motion tends to stay in motion (Newton's first law of motion), the coaster car will maintain a forward velocity even when it is moving up the track, opposite the force of gravity.

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When the coaster moves down a hill and starts its way up a new hill, the kinetic energy changes back to potential energy until it is released again when the coaster travels down the hill it just climbed. Gravity and inertia are big players when it comes to how you experience the ride.

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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.

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Roller coasters are driven almost entirely by inertial, gravitational, and centripetal forces. There are three main components to the typical roller coaster: chain lift, catapult-launch lift, and the brakes. The chain lift is the component that pulls all the carts to the “top” of the roller coaster.

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As the coaster gains height, it loses speed. With this lower speed, the curvature of the track can be decreased to keep the needed centrifugal acceleration. We know that the centripetal acceleration is proportional to v2/r, as the velocity reduces then we can decrease the radius to keep the acceleration a constant.

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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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The roller coaster train reaches its maximum speed and maximum centripetal acceleration at the bottom of the loop, which can be obtained from energy considerations. In this way, the maximum centripetal acceleration is found to be 5g (upwards) at the bottom of a circular loop, if it is g downwards in the highest point.

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Roller coasters are designed to run on two basic scientific principles: 1) gravity and 2) the transfer of energy. On Earth, gravity is the force that pulls objects toward the ground. The transfer of energy is what causes objects at rest to move and objects in motion to slow or stop.

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14 Fun Facts About Roller Coasters
  • The American roller coaster was invented to save America from Satan. ...
  • One of the earliest coasters in America carried coal before it carried thrill seekers. ...
  • “Russian mountains” predated roller coasters—and Catherine the Great improved them. ...
  • Roller coaster loops are never circular.


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10 Things You Never Knew About Roller Coasters
  • If all countries were as cold as Russia, roller coasters may not exist. ...
  • The world's fastest roller coaster is very fast. ...
  • The U.S.'s first roller coaster was very slow. ...
  • There's a roller coaster still in use that's over 100 years old.


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