1 / 15

Aerospacing Brett Carlson Justin Taylor Emily Titus

Boeing v. 2. Boeing v.2. Aerospacing Brett Carlson Justin Taylor Emily Titus . Contents . Outline What is a Rocket Usage and History of the Rocket Parts Design Orientation . Intentions Introduction Problem Analysis Results Conclusion Thank You. Outline.

walden
Télécharger la présentation

Aerospacing Brett Carlson Justin Taylor Emily Titus

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Boeing v. 2 Boeing v.2 Aerospacing Brett Carlson Justin Taylor Emily Titus

  2. Contents • Outline • What is a Rocket • Usage and History of the Rocket • Parts • Design • Orientation • Intentions • Introduction • Problem • Analysis • Results • Conclusion • Thank You

  3. Outline • Teach you about our rocket • Tell you our results • Problems • Learn about aerospace

  4. What is a Rocket • Third Law of Motion • Engines use fuel for propulsion • Does NOT need air (jet engines do) Saturn V

  5. Usage and History of the Rocket • Fireworks in China in 1200s • Made into military rockets in the next 700 years • Saturn V was a rocket that put men on the moon • Used to destroy satellites in space

  6. Why we Picked the parts • Elliptical is more aerodynamic the trapezoidal because there is no strait edges • 4 fins is the best stability, any other way is undistributed weight for the fins • Longer nose to be more aerodynamic • Horizantal • Shorter Body is less weight • Distance • Longer body means better stability

  7. Design Nose Elliptical Fin Body

  8. Orientation Saturn V

  9. Intentions • Reach the highest altitude with our vertical rocket • Reach the longest distance with our horizontal rocket • Summarize what we did in a Technical Paper • Have fun while building the prototypes of a real rocket • Make a killer presentation!

  10. Introduction • Aerospace: To design, analyze, model, simulate, and test aircrafts, space crafts, satellites, missiles, and rockets • NasaRocket Modeler • Best Rocket out of restrictions • Use design for better Rockets

  11. Problem • Build a proto-type of a rocket that goes to Mars • Successfully build a rocket that launches • Restricted and feeble materials • Build a rocket to go higher that 135 feet • Build a rocket to go further than 235 feet • 4 Days • Stability of the rocket • Weather

  12. Analysis • Used glue to harden the feeble paper body and nose • Had to find a way to secure the brittle balsa wood fins to the rocket • Used modeler to successfully launch simulated rockets farther than our goals

  13. Results The rockets will go as far as the simulator (Simulated Results) 9 foot range in the results 136.8 foot average 7 foot range in the results 240.6 foot average

  14. Conclusion • Our rocket will win • Rocket will go as far as the simulator • Real rocket will make it to Mars • The design could have some improvement

  15. Thank You "Brief History of Rockets." NASA - Title... Web. 15 June 2011. <http://www.grc.nasa.gov/WWW/k-12/TRC/Rockets/history_of_rockets.html>. "RocketModeler II 2.1f Beta." Space Flight Systems Directorate / Glenn Research Center. Web. 13 June 2011. <http://microgravity.grc.nasa.gov/education/rocket/rktsima.html>. "Four Forces on a Rocket." Space Flight Systems Directorate / Glenn Research Center. Web. 16 June 2011. <http://exploration.grc.nasa.gov/education/rocket/rktfor.html>. • Gina Lucas • NASA • University of Texas at Arlington • Ronak Patel • Dr. Carter Tiernan • Shivani Patel

More Related