NASA has successfully tested its donut-shaped inflatable heat shield technology that works like a parachute and will enable a spacecraft to land safely when it descends through the high temperature atmosphere of a planet such as Mars.
Before NASA uses its new inflatable technology for slowing spacecraft that are entering the atmospheres of other planets, it will first need to be packed into the tight confines of a rocket.
Engineers at NASA’s Langley Research Centre in US, put the technology to the test by packing a 9-foot diameter donut-shaped test article, also known as a torus, to simulate what would happen before a space mission.
- Parachutes for NASA’s Orion spacecraft passes key flight simulation test
- NASA prepares to fly probe into Sun’s scorching atmosphere
- NASA’s mini-satellites successfully steer towards Mars
- NASA’s InSight lander on path to Mars
- NASA sending robotic geologist to Mars to dig super deep
- NASA’s InSight mission to study heart of Mars; set for May 5 launch
Called the Hypersonic Inflatable Aerodynamic Decelerator, or HIAD, it works like a parachute, using the drag of a planet’s atmosphere to slow the space vehicle as it descends toward the surface, researchers said.
Slowing the spacecraft protects it from the intense heat of atmospheric entry, and allows it to land more softly.
“During testing, we used a vacuum pump to compress the test article into a small space,” said Keith Johnson, a lead engineer for the project.
“We packed and unpacked it and did thorough inspections to check for leaks and damage to the Zylon and Teflon materials. We repeated this three times,” said Johnson.
The technology will enable the delivery of heavy cargo, science instruments and people to other worlds. It could also be used to retrieve cargo from the International Space Station (ISS) and return it to Earth.
According to test engineer Sean Hancock, HIAD was packed the same way each time to see how the material would handle folding, packing, and compressing.
Doing so helps engineers understand how it would perform after exposure to handling, storage and deployment during a space flight mission, researchers said.
“The test included all the components for the latest inflatable torus design, so it was a good final check to prove that the materials can tolerate packing,” Johnson said.
“After demonstrating the design and materials, we can focus on extending this to a larger scale,” he said.
After successful testing, NASA engineers can move forward in the development of creating a larger HIAD that can withstand the stress of being tightly packed in a rocket and the high temperatures experienced when it descends through the atmosphere of a planet such as Mars.
“All these tests build on each other to help demonstrate the performance of the system, and in the end, we’ll have a complete system that will be tested to show that it can meet the requirements for a space flight mission whether it’s going to be returning a vehicle to Earth or future Mars missions,” Johnson said.