rocket
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New space startup bluShift wants to bring a new kind of propellant to the small satellite launching market, with rockets powered by bio-derived rocket fuels. These differ from traditional fuels in that they offer safety advantages during handling, and ecological advantages during production and use. The startup has been working on its solid rocket biofuel since its founding in 2014, and has received grants from the Maine Technology Institute and NASA’s Small Business Innovation Research (SBIR) program to refine its fuel formula and rocket engine design to help it get to this point.
The company achieved a milestone on Sunday with its first rocket launch — a low-altitude flight of a small sounding rocket, called Stardust 1.0. It’s a single-stage prototype, which can only carry 18 lbs of payload and is designed to achieve suborbital space. That may not seem like much, but it is enough to put small research equipment up into suborbital space, at costs that put launches within range for small companies and academic institutions.
Image Credits: Knack Factory/Courtesy Aerospace
Stardust 1.0 is designed to be reusable, though it’s still a prototype, and the company is also working on Stardust 2.0, which is a second prototype that’s expected to increase the payload capacity and act as the primary building block for its subsequent production commercial rockets, including Starless Rogue, a two-stage launcher for suborbital missions, and Red Dwarf, a three-stage, 66-lb capacity launch vehicle that can reach low Earth orbit.
Sunday’s launch looked like it might not have been on track to go well at first, with an initial attempt seeing the rocket’s ignition light — but without a takeoff. After resetting for a second try, there wasn’t any ignition. Finally the rocket did take off late in the day, with a flight that the company said “went perfectly” on a follow-up call with media.
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Rocket launch startup Astra has joined an elite group of companies that can say their vehicle has actually made it to orbital space — earlier than expected. The company’s Rocket 3.2 test rocket (yes, it’s a rocket called “Rocket”) passed the Karman line, the separation point 100 km (62 miles) up that most consider the barrier between Earth’s atmosphere and space, during a launch today from Kodiak, Alaska.
This is the second in this series of orbital flight tests by Astra; it flew its Rocket 3.1 test vehicle in September, but while that flight was successful by the company’s own definition, since it lifted off and provided a lot of data, it didn’t reach space or orbit. Both the 3.1 and 3.2 rockets are part of a planned three-launch series that Astra said would be designed to reach orbital altitudes by the end of the trio of attempts.
Astra is a small satellite launch startup that builds its rockets in California’s East Bay, at a factory it established there which is designed to ultimately produce its launchers in volume. Their model uses smaller craft than existing options like either SpaceX or Rocket Lab, but aims to provide responsive, short turnaround launch services at a relatively low cost — a bus to space rather than a hired limousine. They compete more directly with something like Virgin Orbit, which has yet to reach space with its launch craft.
The view from Astra’s Rocket 3.2 second stage from space.
This marks a tremendous win and milestone for Astra’s rocket program, made even more impressive by the relatively short turnaround between their rocket loss error in September, which the company determined was a result of a problem in its onboard guidance system. Correcting the mistake and getting back to an active, and successful launch, within three months, is a tremendous technical achievement, even in the best of times, and the company faced additional challenges because of COVID-19.
Astra was not expecting to make it as far as it did today — the startup has defined seven stages of reaching orbital flight for its development program; today it expected to achieve 1) count and liftoff; and 2) reaching Max Q, the point of maximum dynamic pressure undergone by a rocket in flight in Earth’s atmosphere. Third, they were looking to achieve nominal main-engine cutoff for first stage — and this is where they would’ve pegged success today, but the “rocket continued to perform,” according to CEO and founder Chris Kemp on a call following the launch.
Rocket 3.2 then performed a successful stage separation, and then the second stage passed through the Karman line, reaching outer space. After that, it went farther still, achieving a successful upper-stage ignition, and a nominal upper-stage engine shut off six minutes later. Even then, the rocket reached 390 km, which is its target orbital height, but then reached a velocity of 7.2 km per hours, just one half km/hour less than the 7.68 km required for orbital velocity.
Astra emphasized that the mix for the propellant for this stage is basically only to be nailed down while testing in situ in space, so they say this will just require some upper-stage propellant mixtures to achieve that extra velocity, and Kemp said they’re confident they can do that in the next couple of months, and start reliving payloads early next year. This won’t require any hardware or software changes, the company noted, just a tweak in the variables involved.
Image Credits: John Kraus for Astra (opens in a new window)
He added that this is a big win for the underlying theory behind Astra’s approach, which focuses on using significant amounts of automation in order to reduce costs.
“We’ve only been in business for about four years, and this team only has about 100 people today,” Kemp said. “This team was able to overcome tremendous challenges on the way to this success. We had a member of the team quarantining, and tested positive on the way to Kodiak, which meant they had to quarantine the entire team, and then sent an entire backup team to replace them.” This was possible because they only use five people on the launch team.
“We now are at a point where just five people can go up, and set up the entire launch site and rocket, and launch in just a couple of days,” Kemp said. The team is literally just five people — including labor, rocket unloading, setup and everything on-site — the rest is run remotely from mission control in California via the cloud.
Now they will do some tuning for Rocket 3.3, which is currently in California at the Astra factory, before soon attempting that final orbital test flight with a payload on board to deploy. After that, they intend to continue to iterate with each version of Rocket launched, focusing on reducing costs and improving performance through rapid evolution of the design and technology.
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Alameda-based rocket launch startup Astra finally got the chance to launch its first orbital test mission from its Alaska-based facility on Saturday, after the attempt had been delayed multiple times due to weather and other issues. The 8:19 PM PT lift-off of Astra’s ‘Rocket 3.1’ test vehicle went well – but the flight ended relatively shortly after that, during the first-stage engine burn and long before reaching orbit.
Astra wasn’t expecting to actually reach orbit on this particular flight – it has always said that its goal is to reach orbit within three test flights of Rocket, and prior to this first mission, said that the main goal was to have a good first-stage burn on this one specifically. This wasn’t a nominal first-stage burn, of course, since that’s when the failure occurred, but the company still noted in a blog post that “the rocket performed very well” according to their first reviews of the data.
— Jennifer Culton (@CultonJennifer) September 12, 2020
The mission ended early because of what appears to be a bit of unwanted back-and-forth wobbling in the rocket as it ascended, Astra said, which caused an engine shutdown by the vehicle’s automated safety system. That’s actually also good news, since it means the steps Astra has taken to ensure safe failures are also working as designed. You can see in the video above that the light of the rocket’s engines simply go out during flight, and then some time later there’s a fireball from its impact on the ground.
It’s worth noting that most first flights of entirely new rockets don’t go entirely as planned – including those by SpaceX, whose founder and CEO Elon Musk expressed his encouragement to the Astra team on Twitter. Likewise, Rocket Lab’s Peter Beck also chimed in with support. Not to mention that Astra has been operating under extreme conditions, with just a six-person team on the ground in Alaska to deploy the launch system, which was set up in under a week, due to the COVID-19 crisis.
Astra will definitely be able to get a lot of valuable data out of this launch that it can use to put towards improving the chances of its next try going well. The company notes that it expects to review said data “over the next several weeks” as it proceeds towards the second flight in this series of three attempts. Rocket 3.2, the test article for that mission, is already completed and awaiting that try.
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One of the newer companies attempting to join the rarified group of private space launch startups actually flying payloads to orbit has redirected its entire UK-based manufacturing capacity towards COVID-19 response. Skyrora, which is based in Edinburgh, Scotland, is answering the call of the UK government and the NHS to manufacturers to do what they can to provide much-needed healthcare equipment for frontline responders amid the coronavirus crisis.
Skyrorary says that the entirety of its UK operations, including all human resources and its working capital are now dedicated to COVID-19 response. The startup, which was founded in 2017, had been working towards test flights of its first spacecraft, making progress including an early successful engine test using its experimental, more eco-friendly rocket fuel that was completed in February.
For now, though, Skyrora will be focusing full on building hand sanitizer, its first effort to support the COVID-19 response. The company has already produce their initial batch using WHO guidelines and requirements, and now aims to scale up its production efforts to the point where it can manufacture the sanitizer at a rate of over 10,000 250 ml bottles per week.
There’s actually a pretty close link between rocketry and hand sanitizer: Ethanol, the form of alcohol that provides the fundamental disinfecting ingredient for hand sanitizer, has been used in early rocket fuel. Skyrora’s ‘Ecosene’ fuel is a type of kerosene, however, which is a much more common modern aviation and rocket fuel.
In addition to sanitizer, Skyrora is now in talks with the Scottish Government to see where 3D-printed protective face masks might have a beneficial impact on ensuring health worker safety. It’s testing initial prototypes now, and will look to mass produce the protective equipment after those tests verify its output.
Plenty of companies are pitching in where they can, including by shifting their production lines and manufacturing capacity towards areas of greatest need. It’s definitely an ‘all-hands-on-deck’ moment, but there’s definitely a question of what happens to businesses that shift their focus this dramatically once the emergency passes, especially for young startups in emerging industries.
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The launch is scheduled for 11:00 am EDT on July 18, 2018.
Blue Origin is about to perform a critical rocket test. For the first time, Jeff Bezos’ rocket company will send its New Shepard rocket to its red line at the edge of space and then fire the escape motor on the capsule that will carry passengers. If this test goes well, Blue Origin’s New Shepard program could become operational as early as this year.
This is the ninth mission for the New Shepard program and the third time this reusable rocket was used.
About 20 seconds (and 100 feet) after the New Shepard booster and the crew capsule separates, the motor on the capsule will fire with 70K foot pounds of thrust, sending the capsule 50,000 km higher than it has gone before. After the motor fires, parachutes will hopefully deploy, allowing the capsule to return safely to solid ground. Separately, the booster will hopefully return to Earth and land so it can be reused again.
Inside the capsule is a crash dummy loaded with instruments to measure the forces of the rocket launch. Bezos dubbed the dummy “Mannequin Skywalker” because even the richest man in modern history is a nerd. Mannequin Skywalker will experience around 3Gs during the launch, a Blue Origin representative said.
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Rocket Lab, the New Zealand-based rocket company that is looking to further amplify the commercial space frenzy, is launching its first fully paid payload atop an Electron rocket tonight — technically tomorrow morning at the launch site. If successful, it will mark a significant new development in the highly competitive world of commercial launches.
Liftoff is planned for 2:10 in the morning local time in New Zealand, or 7:10 Pacific time in the U.S.; the live stream will start about 20 minutes before that.
The Electron rocket is a far smaller one than the Falcon 9s we see so frequently these days, with a nominal payload of 150 kilograms, just a fraction of the many tons that we see sent up by SpaceX. But that’s the whole point, Rocket Lab’s founder, CEO and chief engineer Peter Beck told me recently.
“You can go buy a spot on a big launch vehicle, but they’re not very frequent. With a small rocket you can choose your orbit and choose your schedule,” he said. “That’s what we’re driving at here: regular and reliable access to space.”
An Electron rocket launching during a previous test.
Just like not every car on the road has to be a big rig, not every rocket needs to be a Saturn V. 150 kilos is more than enough to fill with paying customers and cover the cost of launch. And Beck told me there is no shortage whatsoever of paying customers.
“The most important part of the mission is the timing in which we manifested it,” he explained (manifesting meaning having a payload added to the manifest). “We went from nothing manifested to a full payload in about 12 weeks.”
For comparison, some missions or payloads will wait literally years before there’s an opportunity to get to the orbit they need. Loading up just a few weeks ahead of time is unusual, to say the least.
Today’s launch will carry satellites from Spire, Tyvak/GeoOptics, students at UC Irvine, and High Performance Space Structure Systems; you can see the specifics of these on the manifest (PDF). It’s not the first time an Electron has taken a paid payload to orbit, but it is the first fully commercialized launch.
Rocket Lab has no ambitions for interplanetary travel, sending people to space, or anything like that. It just wants to take 150 kilograms to orbit as often as it can, as inexpensively as it can.
“We’re not interested in building a bigger rocket, we’re interested in building more of this one,” Beck said. “The vehicle is fully dialed in; we started from day one with this vehicle designed from a production approach. We’re fully vertically integrated, we don’t have any contractors, we do everything in house. We’ve been scaling up the factories enormously.”
“We’re looking for a one-a-month cadence this year, then next year one every two weeks,” he continued. “Frequency is the key — it’s the choke point in space right now.”
Ultimately the plan is to get a rocket lifting off every few days. And if you think that will be enough to meet demand, just wait a couple years.
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