Practice makes perfect. Neil Armstrong & Buzz Aldrin go through the steps with the Lunar Lander during preparation for Apollo 11, 1969. Backup crew for the first mission to the moon were Jim Lovell, Fred Haise & William Anders. Armstrong & Aldrin spent 21 & ½ hours at Tranquility Base before joining Command Module Pilot Michael Collins who was in lunar orbit in Columbia.
Astronauts on a cloudy day. Alan Bean, Pete Conrad & Richard Gordon hop out of the shuttle bus & step towards the 363-foot tall Saturn V rocket in preparation for Apollo 12, Nov 1969. Conrad & Bean spent 31 hours on the lunar surface while Gordon orbited 45 times above in the Command Module. The spacecraft was nearly identical to that of Apollo 11 with the exception being that hammocks were added to the Lunar Module so that Bean & Conrad could rest more comfortably when not out moonwalking. The mission lasted a total of 10 days & 4 hours.
Currently seated, soon to fly. Pete Conrad & Richard Gordon take a load off their feet prior to their near 3-day Gemini 11 mission, Sept 1966. The pair performed the 1st ever direct-ascent rendezvous with an AGT (Agena Target Vehicle) as they docked with it just 94 minutes after launch (& during the 1st orbit). Gordon also performed a pair of EVAs on the mission for a total of 2 hours & 41 min. The duo went on to fly to the moon together during Apollo 12 in Nov 1969. Conrad became the 3rd human to walk on the lunar surface on the mission while Gordon orbited above in the Command Module. A historic pair of astronauts.
From Racing Suits to Robotic Gloves: How to Gear Up with NASA Technology
Did you know you are surrounded by NASA technology? From your apartment building to the doctor’s office, and even in your cellphone camera, there is more space in your life than you think!
In the latest edition of Spinoff, we are introducing dozens of new ways NASA technology could cross your path. Whether you need an extra “hand” on the production line or a weatherproof jacket, check out how to gear up with technology made for space.
Robots are crucial to exploring space and other planets – they could even support astronauts and form the advance party for places humans have yet to reach. But the human machine is hard to replicate.
A collaboration with General Motors helped us build Robonaut 2 – and the design for this robot’s hands has been adapted into a robotic glove that helps manufacturing employees, such as automobile workers, reduce injuries and improve quality control.
The Swedish company Bioservo used the Robo-Glove technology to create the world’s first industrial-strength robotic glove for factory workers who perform repetitive manual tasks.
The Ironhand glove adds force to the user’s grip with artificial tendons and pressure sensors on the palm and the fingers.
The result? Reduced strain on the user’s own tendons and muscles, meaning fewer workplace stress injuries and better comfort for workers.
Spacesuits need major insulation and temperature control to protect astronauts on extravehicular activities, aka spacewalks. To help solve this, we created a phase-change material with help from the Triangle Research and Development Corporation.
With funding from a NASA Small Business Innovation Research contract, Triangle incorporated the material into a fabric glove insert that could maintain a steady temperature by absorbing and releasing heat, ensuring it feels just right.
While the invention never made it to orbit, it did make it into the driver’s seat.
Outlast Technologies exclusively licensed the material from Triangle and has incorporated it into outdoor gear, bedding, and now – auto racing suits with help from Cambridge, England-based Walero.
Due to extreme temperatures in the cockpit, drivers in almost every major racing championship wear Walero for its cooling properties. Cristiana Oprea (pictured) wears it while driving for the European Rally Championship. Credit: Walero
The race undergarments, bonded with fire-retardant material for added protection, help drivers maintain a lower core temperature and heart rate, which means fewer mistakes and better lap times.
The suits have been sold to both amateur racers and professional NASCAR drivers.
The superinsulating material that makes up space blankets is one of our most ubiquitous spinoffs. Found everywhere from inside the walls and roofs of buildingstocryogenic tanks and MRI machines, radiant barrier technology was first created to insulate spacesuits and spacecraft. And now this NASA spinoff can be found in weatherproof jackets as well.
Inspired by her passion to run following a series of surgeries to help correct a life-threatening injury, Hema Nambiar launched her Larchmont, New York, start-up company 13-One. To create her jacket, she worked with Advanced Flexible Materials Inc.’s brand Heatsheets. The brand was already marketing products like the space blankets traditionally distributed after races to prevent dangerous drops in temperature.
The 13-One jackets are designed to be warm and weatherproof, but their thin, reflective lining lets them also be lightweight and easily portable. Credit: Lourenso Ramautar, Out of New York Studio
The resulting line of jackets has a black exterior and a lining to reflect body heat. They weigh less than a pound, are wind- and water-resistant, and easily pack into a small, built-in pouch.
Want to check out more NASA spinoffs? Be sure to find us on spinoff.nasa.gov and on Twitter.
Interested in licensing your own NASA technologies? Check out the NASA Technology Transfer program at technology.nasa.gov.
