NASA is a step closer to the first flight test of the rocket that will send humans on their way to the moon as part of the agency’s Constellation Program.
Hardware critical for the Ares I-X rocket test was completed this week at Langley Research Center in Hampton, Va. The flight of Ares I-X will be an important step toward verifying analysis tools and techniques needed to develop Ares I, the propulsion part of the next-generation U.S. spacecraft system that will include the Orion space capsule.
The Langley-designed and built hardware is engineered to represent the Orion crew module and a launch abort system that increases crew safety. (Please see Space & Missile Defense Report, Monday, March 17, 2008.)
In late January, the rocket elements will be shipped from Langley to Kennedy Space Center in Florida. This hardware and other elements from around the country will be integrated into the Ares I-X rocket, the first in a series of unpiloted test vehicles.
The test launch is scheduled to lift off from Kennedy this summer. It will climb about 25 miles in altitude during a two-minute powered flight, continuously measuring vehicle aerodynamics, controls and performance of the rocket’s first stage.
The launch will culminate with a test of the separation of the first stage from the rocket and deployment of the accompanying parachute system that will return the first stage to Earth for data and hardware recovery.
“This launch will tell us what we got right and what we got wrong in the design and analysis phase,” said Jonathan Cruz, deputy project manager at Langley for the Ares I-X crew module and launch abort system. “We have a lot of confidence, but we need those two minutes of flight data before NASA can continue to the next phase of rocket development.”
The simulated crew module and launch abort system will complete the nose of the rocket. About 150 sensors on the hardware will measure aerodynamic pressure and temperature at the nose of the rocket and contribute to measurements of vehicle acceleration and angle of attack. The data will help NASA understand whether the design is safe and stable in flight, a question that must be answered before astronauts begin traveling into orbit and beyond.
To ensure the rocket’s flight characteristics are understood fully, extreme care was taken to fabricate the simulated crew module and launch abort tower precisely. To compare flight results with preflight predictions confidently, these full-scale hardware components needed to be accurate reflections of the shape and physical properties of the models used in computer analyses and wind tunnel tests.
The simulated crew module is a full-scale representation of the vehicle that will ferry astronauts to the International Space Station by 2015, to the moon in the 2020s and, ultimately, to points beyond.
The conical module has the same basic shape as the Apollo module, but is approximately five meters in diameter larger. The launch abort system simulator is 46 feet in length. It will fit over the crew module and tower above it, forming the nose of the rocket.
Researchers and managers at Langley worked to overcome multiple challenges as the Orion crew module and launch abort system simulators took shape. One team performed fabrication and assembly work in conjunction with an off-site contractor, and another team installed the sensors once the crew module and launch abort tower were completed.
“We are a highly matrixed team — a lot of people from various organizations — that had to work together successfully on a tight schedule,” explained Kevin Brown, project manager at Langley for the Ares I-X crew module and launch abort system project.