course_planning:183_projects:f19_project_7

Project 7: Part A: The Leaning Tower of P-cubed

  • Choosing an appropriate solution
  • Local gravitational potential energy
  • Energy conservation
  • Work
  • Non-constant forces

Universal Studios in association with the Carver Media Group has created a travelling version of the Wizarding World of Harry Potter. All of the rides in this new amusement park are all either animal or solar powered in order to be more environmentally friendly. You and your colleagues have been asked by your employer (CMG) to travel with the park and to fix any issues that might come up.

At one of the traveling park's first stops (Pittsburgh, PA) the Gryffin-Drop Tower was incorrectly set up. Instead of standing perfectly vertical, the 40m tall tower is leaning at an angle of 10 degrees. The drop tower is powered by hippogriffs attached to a large pulley using harnesses. Each hippogriff can pull with a maximum force of 3,500N. The drop car weighs 4500kg and seats 30 people. The tower is steel, and where the drop car touches the tower is also steel.

Your boss wants to know: How many more hippogriffs will it take to raise the slanted cart?

There is a hippogriff breeder (Andrew) in Pittsburgh, who is also a biology professor at Carnegie Mellon University, who is willing to rent you as many hippogriffs as you need for the 2 weeks you will be in Pittsburgh. The hippogriffs will each cost \$20/hr. The ride is open for an average 16 hours everyday.

One of the park engineers, Mary Lyon, says that it would cost approximately \$10,000 to take down and reassemble the tower correctly in the 24 hours before the park opens.

Your boss also wants to know: Will it cost more to fix the problem or to rent the hippogriffs for two weeks?

Project 7: Part B: Breakneck -- The new roller-coaster at Michigan's Adventure

You are a team of engineers and scientists who are in the process of designing Michigan's Adventures exciting a new attraction “Breakneck”. This ride involves a roller-coaster like car that can hold 8 passengers, with a mass of 700 kg. This car starts by effectively free falling 60m. The track curves at the bottom so that the car can slide up an 8-m-high hill before hitting a horizontal straightaway 50m long. In the middle of the straightaway is a section of track that is used to slow the car down. You can have the car brake over any or all of the 10m length of that section.

Then at the end of the straightaway, a spring-like device hooks under the car. This device changes the car’s direction just in time to prevent it from apparently falling over the end of the track, sending it back over the braking section again, stopping neatly at the end of the braking area. The car should stop at the end of the braking section, on the way back towards the launch pad.

Your tasks are (a) to decide on an appropriate braking force and length of the braking region needed on the straightaway to stop the car at the right location, and (b) the effective spring constant of the turnaround device. The car has special accelerometers mounted which relay that information, and adjust the braking force to provide the acceleration you request. The most important piece of information for these devices is that a person can safely sustain accelerations of 3-4 “g’s” for a brief time, but not more than that.

Learning Goals Week 7

problem_8_diagram.jpg

  • course_planning/183_projects/f19_project_7.txt
  • Last modified: 2019/10/17 16:36
  • by hallstein