November 7, 2014
Length: 99.875 inches Diameter: 6.00 inches Mass: 277.42 oz. / 17.34lbs. Span: 13.50 inches Center of Gravity: 56.3919 inches Center of Pressure: 64.0575 Safety Margin: 1.28
Flight Sequence
Dual Deployment Drogue chute and main chute Black powder charges will be calculated using vernk.com and verified with ground testing
Dual deployment system Two MAWD altimeters used for redundancy Measures barometric pressure “Mach” delay for safety Deploys drogue parachute at apogee Deploys main parachute at 3000 ft AGL and payload parachute at 1000ft AGL Will be programmed and Pre-tested for scale launch
Airframe – carbon fiber superior strength to weight ratio Ease of workability Fins – birch plywood in carbon fiber Combines the strength of both materials for a more rigid, strong, and lightweight fin Bulk-Head/Centering ring – 0.5 inch birch plywood Cabinet quality grain, few knots, and locally available
Nosecone West Systems Epoxy Will be purchased to insure proper functionality West Systems Epoxy Used to bind the above materials together as well as some hardware (bolts, nuts, threaded rods)
Fins – symmetric shape and quantity allows for ease of construction, trapezoidal shape limits potential damage to fins upon landing Diameter – 6” diameter allows for ease of assembly and plenty of work space. Also allows for better utilization of scrap components, and expansion of internal components if necessary
AGSE Design
Payload securing
Is this design limiting? Critique Score 1/5 1 = Bad 5 = Good Comments Is this design safe? 4 This design will allow for ease of construction and eliminate safety concerns associated with more complex construction methods Is this design limiting? Altitude is expected to be reached and the design will accommodate larger motors and payload components Does this design meet the requirements of the payload/rocket? 3 This current rocket design satisfies the requirements for the projected payload. Will this design land safely? Parachute sizes, impact absorbing design? The current size rocket and parachutes have the rocket descending rapidly under drogue, but slowing to under 25 ft/s under main. Does this design maximize performance? The rocket has been designed to accommodate the payload as well as larger motors as the design is refined. Are the materials selected the best for this scenario? Carbon fiber is a strong yet lightweight material that we have had success with in years prior. Past experience with phenolic tubing has yielded structural failure. Any additional comments? ------- Conduct additional tests and review plan to ensure continued safety
Minimum velocity for stable flight: 25.63 ft/s Exit rail velocity: 32.81 ft/s A series of 3 rail beads will be used to ensure the rocket reaches adequate speed off of the rail while maintaining proper orientation
A series of sub-scale launches are planned and will be conducted to verify design Construction and test of the sub-scale will take place from 11/23-12/14 Planning for construction of full-scale starting 12/14 At least one test flight with the final rocket will take place
54.0 mm diameter allows for easy down- scaling Manufacturer: AeroTech Mfr. Designation: K513FJ Motor Type: reload Diameter: 54.0mm Length: 41.0cm Total Weight: 1647g Average Thrust: 556.8N Maximum Thrust: 658.3N Total impulse: 1496.3Ns Burn Time: 2.8s Justifications 54.0 mm diameter allows for easy down- scaling Black Max Propellant provides the high visibility tracking of dense black exhaust
S1: 340N/11.22lbs( S2: 307/132.62oz
The handling of the motors, including purchasing and assembly, will be under the supervision of our NDRA members. North Dakota Rocketry Association (NDRA) Section #628 Certified NDRA team mentor: Dr. Tim Y. #76791 Level 2 We are planning to test fire the K513FJ motor in our static ground test. We are not planning a test of the sub-scale motor.
Sub-scale launch – November 22nd Full-scale test flight #1 – February 22nd to March 8th Full-scale test flight #2 – March 18th to April 6th Final launch – April 10th
Rocket launch Rocket recovery Payload Reaching an altitude of 3000 feet at apogee. Rocket recovery The recovery system deploying properly at the appropriate altitude and recovering the rocket on the ground such that it is deemed reusable for future launches Payload The payload should be ejected from the rocket at 1,000 feet and return to the ground with its own parachute.
Physics Day at UND - November 12, 2012 This is a program for local middle school to high school students to learn about the many different facets of physics. We gave a presentation about rocketry Introduced them to the USLI program and shared our past history with the competition Reached about around 200 students.
Outreach at Grand Forks Area middle school Our team is in the process of scheduling a date to visit the local middle schools. For an entire day, we will teach a science class. Give a brief lecture about rocketry Prior to us visiting, we will have the students design rockets out of 2 liter pop bottles. We will supervise and moderate the launch water rockets Have a Q & A session on why some rockets did work and other did not. Expect to reach about 30-80 students.
Scheduled for February Astronomy Talk Scheduled for February Hour long lecture Aimed at introductory level astronomy students Content could include: History of Rocketry By the date of the talk, we might be able to give a demonstration of our AGSE
*The center of gravity is forward of the center of pressure (closer to the nosecone)