How rollercoasters affect your body - Brian D. Avery

TED-Ed
29 Oct 201805:02

Summary

TLDRThe video script delves into the physics of roller coasters, highlighting how they've evolved to be both thrilling and safe. It explains the role of gravity and G-forces in creating sensations of weightlessness and 'airtime'. Early coasters like the Flip-Flap Railway caused injuries due to extreme G-forces. Modern designs carefully balance these forces to prevent such issues, using advanced restraints and engineering to ensure a safer, yet exhilarating ride.

Takeaways

  • 🎢 The Flip Flap Railway, America's first looping coaster, was notorious for causing severe whiplash and neck injuries due to its high gravitational forces.
  • 🌍 Roller coasters rely on gravity to propel riders, converting potential energy on ascents into kinetic energy on descents.
  • 🔍 Early coaster designs focused on preventing the coaster from getting stuck, often leading to overcompensation in speed and braking.
  • 🚀 'G force' is a unit used to measure the gravitational force experienced by riders, with modern coasters aiming to stay within a safe range of around 5 Gs.
  • 🩸 High G forces can lead to health issues like light-headedness, blackouts, and 'redouts', caused by the redistribution of blood in the body.
  • 🤸‍♂️ Negative Gs can create a sensation of weightlessness, which, while generally harmless, can contribute to motion sickness.
  • 🧍‍♂️ Modern coasters use belts and harnesses to prevent ejections and provide support during periods of intense G-force.
  • 🛠️ Coaster engineers balance competing forces to create a thrilling ride without causing physical harm, avoiding extreme changes in speed and direction.
  • 🏗️ Modern roller coasters are designed to be sturdier, taking into account the multiplied weight of passengers at high G forces.
  • 💻 Advanced tools like 3D modeling and simulation software have made it possible to create safer and more thrilling roller coasters.

Q & A

  • What was the Flip Flap Railway known for?

    -The Flip Flap Railway was known for being America's first-ever looping coaster, offering a thrilling ride but also causing numerous cases of severe whiplash, neck injury, and even ejections due to its signature loop.

  • How do roller coasters primarily operate?

    -Roller coasters primarily operate using gravitational energy. They are propelled around their tracks almost entirely by the force of gravity, building potential energy on ascents and expending kinetic energy on descents.

  • What is the significance of 'g force' in roller coasters?

    -'G force' is a unit used to measure the force of gravity experienced by riders. One G is the normal gravitational pull on Earth, but roller coasters can subject riders to multiple Gs, affecting their physical sensations and safety.

  • Why were early roller coasters like the Flip-Flap dangerous?

    -Early roller coasters were dangerous because they routinely reached up to 12 Gs, causing blood to rush from the brain to the feet, leading to light-headedness, blackouts, and in some cases, ejections.

  • What is 'airtime' in the context of roller coasters?

    -Airtime refers to the sensation riders experience when they momentarily become weightless, typically during seat separation. It's a thrilling aspect of roller coasters but also a potential safety concern if not properly managed.

  • How do modern roller coasters prevent injuries that were common in older designs?

    -Modern roller coasters prevent injuries through the use of numerous belts and harnesses, careful engineering to avoid extreme changes in speed and direction, and sturdier construction that considers the multiplied weight of passengers at high G-forces.

  • What role does 3D modeling and simulation software play in modern roller coaster design?

    -3D modeling and simulation software allows designers to test and refine roller coaster designs before construction, ensuring that they are both thrilling and safe within the limits of human tolerance.

  • How do roller coaster engineers manage the competing forces of gravity and safety?

    -Roller coaster engineers manage competing forces by carefully balancing periods of intense pressure with periods of no pressure, avoiding quick transitions between positive and negative G-forces to minimize the risk of whiplash and other injuries.

  • What is the maximum G-force that the human body can typically handle on a roller coaster?

    -The human body can typically handle up to roughly 5 Gs on a roller coaster. Beyond this, the effects of gravity become increasingly uncomfortable and dangerous.

  • How do roller coasters affect the rider's vision during high G-force experiences?

    -During high G-force experiences, riders may experience greyed out vision or temporary blindness due to oxygen deprivation in the retinal cells, or 'redout' where blood floods the skull, causing vision to turn red.

  • What are some of the non-physical effects of riding a roller coaster?

    -Non-physical effects of riding a roller coaster include the adrenaline rush, which can be both thrilling and cause stress, and motion sickness, which can result from the inner ear's fluid being suspended during short-term weightlessness.

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