Monthly Archives - March 2018

The physics of a roller coaster loop

 
Each year millions of people will visit amusement parks in order to ride some of the fastest, highest, most extreme roller coasters. These machines thrill us because of their ability to accelerate us from a standstill to unbelievable speeds in a matter of seconds while changing from one direction to the next in an instant.
There is so much physics going on in the loop of a roller coaster. Angular velocity, centripetal acceleration, conservation of energy, and more! In this Cool Demo, we are going to look at how we can collect the data by using a Hot Wheels track and by placing a PocketLab Voyager on the Hot Wheels car.
By placing magnets at each connecting section of the track you can now generate “gate” times with PocketLab’s magnetometer. Using a 3D printer you can print a new set of connectors that are designed to house a small magnet. ( 3D print files are available to download in the resource section) When the car passes over these sections of the track you will be able to see a change in the magnetic field. Using this change and time we can come up with “timing gates” at each of these sections, and knowing the distance the car has traveled we can calculate the speed of the car.
The most obvious section of a roller coaster, or in this case, the Hot Wheels track is the loop. Although the loop of the Hot Wheel track is a circle, in reality, roller coaster loops have a tear-dropped shape that is geometrically referred to as a clothoid.
As the car passes through the loop, you can see the track bends into a tear-dropped shape. Once the car passes through the loop we are able to measure the angular velocity or the rate of change of the angular rotations, as it’s moving through that loop using the PocketLab’s Gyroscope.
Roller coaster rides are notorious for creating g-forces. The PocketLab also has an accelerometer, so as the car passes through the loop you can also measure the g-forces a person would be experiencing if they were traveling in the car. Traveling around a circle creates a centripetal force that the rider experiences as a g-force. The force is a function of speed and radius.

The Flip Flap Railway was built in 1895 and was the first roller coaster to have a loop. It was “famous” for its extreme g-forces that it produced on its riders of approximately 12 gs. The circular nature of the coaster’s loop along with its small diameter of 25 feet caused riders to experience neck injuries from whiplash. There are some interesting accounts where riders are hanging on for dear life in a death grip on the sides of the railcar and surviving a 12g ride which is absolutely nuts! Modern looping roller coasters all use teardrop-shaped loops to reduce the g-forces. The Flip Flap Railway was the last coaster to use a truly circular loop.

 
Looking at the Data:
  1. The time it took the car to travel through the loop = 0.34 seconds.
  2. The average angular velocity (gyroscope) through the loop = 1,170 degrees/seconds
  3. The average acceleration through the loop = 3.7 g
Data analysis:

Looking at the angular velocity inside the loop can be done in two ways:

  1. We can calculate the average loop velocity using our timing gates. (The time we exit the loop – the time we enter the loop and using the circumference of our track. Plugging in the geometry in our time we get 1.9 meters per second as our average velocity.
  2. Using the (1.9 m/s) velocity we can calculate the average angular velocity of 18.5 radians per second or 1060 degrees per second.

To get the g-force we need to calculate the following:

  1. Taking the timing gate data to calculate the G-Forces that would be felt inside the loop; (18.5 radians per second)²(0.1 meters per second) = 3.9 g.

The PocketLab Voyager has an array of sensors built into a small package. This allows you to measure data in scenarios such as this Hot Wheels Loop track experiment. Simply connect it to your smartphone or tablet through Bluetooth and you will be able to see the data live in the palm of your hands. On-board memory is also included for when you the PocketLab Voyager is out of Bluetooth range. The best thing about PocketLab Voyager is that that it comes packaged with some many features compared to equipment that costs thousands more.

Download lab resources:
  1. Click here to download – 3D print file (track connector Magnet Single)
  2. Click here to download – 3D print file (double track connector loop)
  3. Click here to download – Hot Wheels Loop Experiment Instruction

Explore the world around you with the sensors built into the PocketLab Voyager:

  • Measure Acceleration
  • Angular Velocity
  • Magnetic Field
  • Range Finder
  • Altitude
  • Barometric Pressure
  • Ambient Temperature
  • Humidity
  • Light
  • Dew Point
  • Heat Index

More Labs using PocketLab Voyager:

If you enjoyed this lab using a Hot Wheels track, we have two more you can download using a Constant Velocity Car and Air Powered Projectile.

  1. Click here to download – PocketLab Voyager with Constant Velocity Lab
  2. Click here to download – PocketLab Voyager with Air Powered projectile

 


Recommended Tools

 

PocketLab Voyager

In Stock SKU: P4-1000
$148.00
 

Constant Velocity Car (Carts)

In Stock SKU: 44-1090
$8.50
 

Air-Powered Projectile Classroom Set

In Stock SKU: P4-2230
$585.00
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