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University of Florida IntimiGATOR PDR

University of Florida IntimiGATOR PDR. Outline. Project Organization Vehicle Design Payload Design Recovery System Component Testing Subscale Flight Simulations Outreach Future Work. Project Organization. Outline. Project Organization Vehicle Design Payload Design Recovery System

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University of Florida IntimiGATOR PDR

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  1. University of Florida IntimiGATORPDR

  2. Outline • Project Organization • Vehicle Design • Payload Design • Recovery System • Component Testing • Subscale Flight • Simulations • Outreach • Future Work

  3. Project Organization

  4. Outline • Project Organization • Vehicle Design • Payload Design • Recovery System • Component Testing • Subscale Flight • Simulations • Outreach • Future Work

  5. Material and Dimensions • Material: Blue tube • Diameter: 6 inches • Length: 115 inches • Weight: 29 lbs

  6. System Breakdown

  7. Static Stability Margin CG CP • The center of pressure (CP) is located 89.16" from the nose tip • The center of gravity (CG) is located 71.73" from the nose tip • The static stability margin is 2.87 which is within the stable range of 1 to 3

  8. Fins 1-Slots in fin align with barrel bolts2-Fin slides forward and down3-Set screw holds fin in place Fins and mount made from ABS plastic on a rapid prototype machine

  9. Outline • Project Organization • Vehicle Design • Payload Design • Recovery System • Component Testing • Subscale Flight • Simulations • Outreach • Future Work

  10. Science Mission Directorate Payload • Rests in the upper airframe on top of the piston • Ejects from the rocket at apogee • Dual deployment recovery

  11. Science Mission Directorate Payload • Payload legs spring open upon ejection • Electronics requiring sunlight are mounted on the lid • Body made from blue tube in order to not interfere with measurements

  12. Science Mission Directorate Payload Design • 1 Arduino Microcontroller to sample analog sensors and read output from Weatherboard and GPS • Analog sensors will be compared to the pre-programmed output from the Weatherboard • All data is sent back to ground station via the XBEE Pro 900 • Camera attached to inside of payload bay looking out

  13. Lateral Flight Dynamics Payload • Purpose: • Introduce a determinable roll rate during flight • Evaluate roll dampening using rollerons • Ailerons deflect with an impulse to induce roll • Uses rollerons to in-actively dampen roll rate • Compares the rockets natural dampening to that of rollerons

  14. Lateral Flight Dynamics Payload • All components are locally manufactured Wheel on Mill Finished Wheel Casing

  15. Lateral Flight Dynamics • Uses pneumatic actuators to unlock rollerons and deflect ailerons • Rollerons are locked using a cager Rolleron Cager Aileron Aileron Actuator

  16. Flow Angularity Payload • Purpose is to use pressure transducers to determine orientation of rocket • Transducer on nose cone tip measures stagnation pressure • Dynamic pressure varies based on pitch and yaw • Significant calibration necessary • Wind tunnel testing to create non-dimensional coefficients • Gyroscope onboard to cross-check data

  17. Flow Angularity and Boundary Layer Development Payload Integration Plan • Self contained unit in nose cone • Pressure transducers, microprocessor, battery supply, analog data storage device • Transducers mounted flush with the surface of the nose cone • All other electronics mounted to a bulkhead at the nose cone’s base • Still allows ejection through nose cone • Useful data ends at apogee

  18. Outline • Vehicle Design • Payload Design • Recovery System • Component Testing • Subscale Flight • Simulations • Outreach • Future Work

  19. Recovery • Dual Deployment on Vehicle and SMD Payload • Drogue released at apogee (both) • Main released at 700 ft (both)

  20. Vehicle Recovery • Drogue Parachute 36 inches in diameter • Descent velocity of 65 ft/s • Main parachute 96 inches in diameter • Descent velocity 18 ft/s

  21. Vehicle Recovery Systems • Drogue parachute directly below nosecone • Released during first separation event • Main parachute housed in middle airframe between avionics bay and pneumatics bay • Released during second separation event • Separation between pneumatics bay and middle airframe

  22. SMD Payload Recovery • Drogue Parachute 36 inches in diameter • Descent rate of 25 ft/s • Main Parachute 36 inches in diameter • Descent rate of 12.5 ft/s

  23. SMD Payload Recovery Systems • Drogue released during first separation event • Housed directly below vehicle main parachute • Main released from parachute housing during secondary payload separation event • Main parachute will be stored in housing and ejected using a piston system

  24. SMD Main Parachute Housing

  25. Outline • Project Organization • Vehicle Design • Payload Design • Recovery System • Component Testing • Subscale Flight • Simulations • Outreach • Future Work

  26. Component Tests

  27. Outline • Project Organization • Vehicle Design • Payload Design • Recovery System • Component Testing • Subscale Flight • Simulations • Outreach • Future Work

  28. Planned Flight • December 10th, Bunnell, FL • Testing: • Fin mount assembly • SMD Payload main parachute deployment • Dual separation • Live data transmission

  29. Outline • Project Organization • Vehicle Design • Payload Design • Recovery System • Component Testing • Subscale Flight • Simulations • Outreach • Future Work

  30. Flight Simulations • Used RockSim and MATLAB to simulate the rocket’s flight • MATLAB code is 1-DOF that uses ode45 • Allows the user to vary coefficient of drag for different parts of the rocket • After wind tunnel testing, can get fairly accurate CD values that can be used in the program

  31. Preliminary Results • MATLAB code is compared with RockSim • Maximum altitude approximately 200 ft. lower than RockSim but still slightly higher than a mile

  32. Outline • Project Organization • Vehicle Design • Payload Design • Recovery System • Component Testing • Subscale Flight • Simulations • Outreach • Future Work

  33. Community Outreach • Gainesville High School • 400 students throughout the school’s 6 periods • Interactive PowerPoint Presentation covering the basics of rocketry • Derivations of relatable equations • Model rocket launches

  34. Community Outreach • PK Yonge Developmental and Research School • 150 6th grade students • Interactive PowerPoint Presentation with videos • Model rocket launches

  35. Outline • Project Organization • Vehicle Design • Payload Design • Recovery System • Component Testing • Subscale Flight • Simulations • Outreach • Future Work

  36. Future Work • Use wind tunnel data and subscale launch data to further refine MATLAB code • Use RockSim to simulate various wind conditions and launch angles • Design for a static stability margin between 1 and 3

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