Overview
Statistic | Value |
|---|---|
| Propellant Weight | 69.4 Lbs |
| Impulse | 65077 Ns |
| Max Pressure | 1440 PSI |
| Classification | P18000 |
| Delivered ISP | 211s |
| Grains | OW-152 #9-#16 |
This was the team's first P motor. It was designed to be around a P9000? but a currently unknown effect led to a much shorter burn time and higher than expected thrust. Current theories for the burnrate-increasing effect include erosivity, or more complete aluminum combustion leading to much higher temperatures. The second theory is supported by the slight bulge in the case as well as higher residency time of half of the aluminum particles.
Media
Link to Dropbox: here
Data
Raw Data: 237.TXT
ENG File: P18000.eng
Discussion
Timeline
Here's a reconstruction of events based on video and physical evidence collected after the test:
•T-0: Motor ignites
•T+.5: Erosive burning spike settles down, but motor is now burning at a much higher pressure than expected
•T+.5 - 2.9: Thrust curve follows typical BATES profile
•T+2.9: Aft grain burns out, casting tube is ejected
•T+2.9: Interaction with casting tube event along with elevated thermal and mechanical stresses causes nozzle failure
•T+2.9-6.2: Motor continues to burn at lower pressure/thrust due to fewer grains, leakage at nozzle break
•T+6.2: Second grain from aft end burns out, unprotected liner at aft end is ejected due to high velocity gas passing over it
•T+7.8: Motor shuts down
Unpredicted High Burn Rate
Why was the pressure so much higher than predicted? We think it may be because the longer motor caused more complete aluminum combustion that increased temperature/some other factor and led to an increase in the "a" value of the propellant. We tuned our characterization numbers in Burnsim and matched the actual thrust curve quite nicely with an "a" value of .026 (instead of the original .0169). Other possibilities are that this propellant doesn't fit our original burn rate law at high pressures, or that there was burning on the outside of the grains, although we think this is unlikely. If anybody has ideas, I'd love to hear them.
Nozzle Failure
The nozzle cracked axially at around 2.9 s into the burn. It was being exposed to 1.8x the design pressure when it failed, but maybe there were other factors that led to it failing, such as the casting tube being ejected? This is what the nozzle design looked like. The diverging section of the graphite is insulated from the aluminum nozzle carrier by a section of 98mm phenolic liner, and the convergent section is insulated by a piece of phenolic casting tube.
