Space Exploration Technologies (SpaceX) announces that its Merlin 1D engine has achieved a full mission duration firing and multiple restarts at target thrust and specific impulse (Isp). The engine firing was for 185 seconds with 147,000 pounds of thrust, the full duration and power required for a Falcon 9 rocket launch. The tests took place at SpaceX's rocket development facility in McGregor, Texas. The Merlin 1D engines will first see flight on Falcon 9 Flight 6, expected to launch in 2013.
These coatings offer protection against rust, scratches and moisture and improve adhesion: Surfaces with a nano coating. A new plasma process enables these coatings to be applied more easily and cost-efficiently - on an industrial scale. Read more
May 16th 2010 around 13:30: 90 minutes after planned launch time, the Danish experimental rocket engine, Heat-1X-P, built by a team of amateur rocket enthusiasts, fired off on a concrete field located at an industrial area in Copenhagen.
The second test of the RCS on XA-0.1B-750. Ian commands it to rotate itself 90 degrees and hold that position. After it has rotated, the twist on the chain tries to make it move back, and it resists. It over-corrects a bit because the vehicle weighs less than the computer was told. The XA-0.1B-750 is a single engine VTVL rocket vehicle with a 750lb-force main engine and four cold gas RCS engines, as demonstrated in this video. The vehicle is a prototype of a larger vehicle that will be able to take 100kg of payload to 120km and return it to the launch site.
Engineers and food scientists are teaming up to develop a new type of gelled fuel the consistency of orange marmalade designed to improve the safety, performance and range of rockets for space and military applications.
"This is a very multidisciplinary project" - Stephen Heister, the Purdue University professor of aeronautics and astronautics who is leading one of two teams on the project, which is funded by the U.S. Army Research Office.
Gels are inherently safer than liquids because they don't leak, and they also would allow the military to better control rockets than is possible with solid fuels now used. Motors running on gelled fuels could be throttled up and down and controlled more precisely than conventional rockets that use solid propellants.
Theres a strange wave phenomenon thats plagued rocket scientists for years, a lurking threat with the power to destroy an engine at almost any time. For decades, scientists have had a limited understanding of how or why it happens because they could not replicate or investigate the problem under controlled laboratory conditions. Scientists generally believe that these powerful and unstable sound waves, created by energy supplied by the combustion process, were the cause of rocket failures in several U.S. and Russian rockets. Scientists have also observed these mysterious oscillations in other propulsion and power-generating systems such as missiles and gas turbines. Now, researchers at the Georgia Institute of Technology have developed a liquid rocket engine simulator and imaging techniques that can help demystify the cause of these explosive sound waves and bring scientists a little closer to being able to understand and prevent them. The Georgia Tech research team was able to clearly demonstrate that the phenomenon manifests itself in the form of spinning acoustic waves that gain destructive power as they rotate around the rockets combustion chamber.
On January 16, 2007, a dazzling blue flame blasted across the sands of the Mojave desert. In many respects, it looked like an ordinary rocket engine test, but this was different. While most NASA rockets are powered by liquid oxygen and hydrogen or solid chemicals, "we were testing a methane engine," says project manager Terri Tramel of NASA's Marshall Space Flight Centre (MSFC). Read more
Purdue University engineers are conducting research to help NASA develop rockets faster and less expensively for future missions to Mars and the moon. The NASA-funded research at Purdue focuses on liquid-fuelled rockets. Specifically, the work deals with understanding how fuel and a component called the oxidizer interact inside the rocket engine's fuel injectors to cause unstable combustion. The instability results in extreme bursts of heat and pressure fluctuations that could lead to accidents and hardware damage.
Purdue engineers involved in the research earned a best paper award in July from the American Institute of Aeronautics and Astronautics.
"Combustion instability is a complex phenomenon that has hindered rocket development since the beginning of the Space Age. We have to learn more about instability before future engines can be developed and used for space flight. Predicting combustion instability is one of the most difficult aspects of developing a rocket engine" - Nicholas Nugent, doctoral student in Purdue's School of Aeronautics and Astronautics.
The paper's findings demonstrate that an experiment can be specifically designed to study instabilities occurring spontaneously, as they do in real engines.
"There haven't been many, if any, experiments in the past that have been able to achieve an instability without actually forcing it by introducing artificial influences not ordinarily seen in the operation of a rocket engine" - James Sisco., doctoral student.
The paper was written by Nugent, Sisco, former student Kevin J. Miller and William Anderson, an assistant professor in the School of Aeronautics and Astronautics. Miller now works for Space Exploration Technologies Inc., or SpaceX, in El Segundo, California. The Purdue engineers have completed further research and presented new findings in July during the American Institute of Aeronautics and Astronautics' joint propulsion conference in Sacramento, California Findings for which the best paper award was received were presented at last year's joint propulsion conference in Tucson, Arizona, US.
"The main purpose of the work is to generate combustion and instability data so that other researchers can develop better computational models for designing rocket engines. We are generating benchmark data that will improve the design analysis of all types of rocket engines" - Nicholas Nugent.
Charles Merkle, the Reilly Professor of Engineering, is leading a research group at Purdue focusing on creating such models. Without effective simulations, engineers must rely on trial and error, which is costly, time consuming and potentially dangerous.
"Without good models, you have to do a lot of testing, and you increase the chances of accidents. If you do more computational modelling up front, you have less risk of damaging very expensive hardware, reducing the amount of testing needed and getting more out of each test" - Nicholas Nugent.
Heat from combustion naturally fluctuates inside the combustion chamber. At the same time, the combustion chamber generates resonant sound waves that cause "acoustic pressure," which also fluctuates. When heat and pressure fluctuations coincide, the combined result can be devastating, causing accidents and damage to rocket engines.
"The interactions between combustion and chamber acoustics are very complex. We are trying to measure and understand the dynamic characteristics of the phenomena. What mechanisms and physical processes occurring after you inject the propellants are causing heat release?" - Nicholas Nugent.
Data are collected using pressure and heat sensors inside the chamber, and the researchers also take high-speed video of the combustion process to analyse instability. In the earlier experiments detailed in the first paper, the engineers used a carefully designed injector and varied the length of the combustion chamber to see how changing acoustics affected the heat-driven pressure fluctuations. Findings in the new research paper indicate that simulations from a model created by researchers led by Merkle matched experimental results from laboratory experiments. Future work will use optical sensors to measure more precisely the dynamic interactions between combustion fluctuations and fluctuations in acoustic pressure.
"Now that we have an experiment that can spontaneously produce instabilities, we will take the research to the next level by adding more instrumentation and looking at specific areas that we think are the root causes of the instability" - Nicholas Nugent.
The U.S. Air Force also may benefit from the research results because the experiment used an injector similar to those employed in advanced, high-performance rockets that use kerosene fuel. These rockets require less time to prepare for launch than conventional rockets, meaning they could be quickly sent on military missions. Unlike the space shuttle engines, which require a foam-insulated tank for the cryogenically cooled liquid hydrogen propellant, the "oxidiser-rich stage-combustion cycle" engines on which the experiment is based use a kerosene fuel that can be stored at room temperature. Using kerosene would enable engineers to create sleeker, more compact and lighter rockets that pack the same power as liquid hydrogen rockets.
"Liquid kerosene is about 100 times more dense than hydrogen, so you use much smaller tanks. With kerosene, the diameter of the rocket is smaller, causing the weight and aerodynamic drag to go down, so it makes a really nice fuel for lifting rockets off the ground. Furthermore, ground operations are greatly simplified because kerosene is much easier to handle than liquid hydrogen" - William Anderson.
The work is based at the High Pressure Laboratory, one of six facilities at Purdue's Maurice J. Zucrow Laboratories. The lab is operated jointly by the School of Aeronautics and Astronautics and the School of Mechanical Engineering. Researchers are using the facility for work sponsored by NASA, the Air Force, U.S. Army, other federal agencies and aerospace companies. The rocket-testing facility within the High Pressure Lab, built in 1965, was upgraded in 2001 and became fully operational in 2003. The Zucrow labs are named after Maurice J. Zucrow, a Purdue mechanical engineering alumnus who, in 1928, earned the first doctoral degree in an engineering field granted by Purdue. His research in rocket propulsion inspired the construction of the first facility at Zucrow Labs in 1948. Since then, the Zucrow labs have evolved into a complex of six facilities on a 24-acre site west of campus where engineers perform a wide range of propulsion-related research in rockets, jet engines and other internal combustion engines. The research is funded through NASA's Constellation University Institute Program, which supports rocket research at universities around the nation.