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University of Florida PDR Presentation
Vehicle Design
Diameter: 5.86”Length: 135”Static Stability Margin: 1.4Total Weight: 23.6 lbs
Payload Bay
Inside Rocket Separated From Rocket
Vehicle Materials
• Airframe: phenolic tube with fiberglass reinforcement
• Fins: 1/8” G-10 fiberglass• Bulkheads and Centering Rings: Birch Plywood• Shock Cord: 5/8” Tubular Nylon• Motor Retention: Aluminum sleeve
Vehicle Safety and Testing
• Structures verification– Fin load testing– Coupler joints– Motor retention testing
• Stability verification– RockSim– MATLAB
Recovery System Design
Rocket Drogue: 24” round Descent Rate: 80 ft/s
Rocket Main: 84” round Descent Rate: 21 ft/s
Payload Drogue: Heavy Duty StreamersDescent Rate: Undetermined
Payload Main: 60” roundDescent Rate: 19.5 ft/s
Recovery Safety and Testing
• Black powder charge ground testing• Parachute and streamer descent rate
verification• Payload bay separation testing• Payload landing testing• Flight computer & GPS testing in Avionics Bay
and Payload Bay
Motor Choice• Cesaroni K590– Average Thrust = 591 N; Max Thrust = 724 N– Total Impulse = 1336.5 Ns– T.W. Ratio = 5.635
Motor Safety and Testing
• Static Motor Testing– Tests our ability to assemble a K590 Motor– Tests the burn profile of the motor to check with
RockSim and online predictions
Flight Simulations
MATLAB vs. RockSim
Why use MATLAB?
• MATLAB can easily be used in optimization– RockSim may only be optimized through tedious
iteration. Time-consuming and inflexible• Design space visualization– 3D/4D plots
Preliminary Results
• MATLAB 1DOF is surprisingly accurate when RockSim simulates a wind speed of zero
Future Work
• MATLAB model will be extended to 3DOF• Compared with RockSim for various wind
speeds• RockSim and MATLAB models compared to
launch data. Best-fit determined
Payload Design
• Two 1/8" G-10 fiberglass cards mated with XBee Pro 900 transmitter in between– One card holds: R-DAS Tiny, PerfectFlite
altimeters, two batteries– Second card holds: GPS, transmitter card,
temperature and humidity sensor, JPEG trigger• Camera attached to inside of payload bay
looking out
Payload Design
Science Value of Payload Experiment• To test modern hydrologic theory– Comparing the theoretical total long and short
wave radiation to recorded data
• To establish an accurate measurement of the environmental lapse rate for temperature and pressure
Predictions from Hydrologic Theory
6:00 AM 7:59 AM 9:59 AM 11:59 AM 1:59 PM 3:59 PM 5:59 PM0.0
20.0
40.0
60.0
80.0
100.0
120.0
140.0
Long Wave Radiation in April 2010, Huntsville, Alabama
4/10/20104/11/20104/12/20104/13/20104/14/20104/15/20104/16/20104/17/2010Average
Time
Long
Wav
e Ra
diati
on (W
/m2)
6:00 AM 7:59 AM 9:59 AM 11:59 AM 1:59 PM 3:59 PM 5:59 PM0.0
100.0200.0300.0400.0500.0600.0700.0800.0
Short Wave Radiation in April 2010, Huntsville, Alabama
4/10/20104/11/20104/12/20104/13/20104/14/20104/15/20104/16/20104/17/2010Average
Time
Shor
t Wav
e Ra
diati
on (W
/m2)
Lapse Rates
• Temperature lapse rate estimated to be somewhere between 6°C/km and 10°C/km• Pressure lapse rate found from Perfect Gas
Law
Source: Figure 3.2.2 from Applied Hydrology by Chow, Ven T., David R. Maidment, and Larry W. Mays. International ed. New York: McGraw-Hill, 20051988. Print.
Payload Testing
• Solar cell has range of 430 to 1100 nm. Test the voltage-to-W/m2-conversion-constant
• UV sensor voltage-to-W/m2-conversion-constant
• Sensor-to-RDAS configuration• Note: Will need IR sensor to measure “long
wave” radiation ( > 4 μm)
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