When Virgin Orbit, a satellite-launch company based in California, sought to
expand its horizons, it was only natural for the company to think about
NASA’s largest rocket engine test site – Stennis Space Center near Bay St.
Louis, Mississippi.
With an established, positive reputation, specialized infrastructure
equipped to test high-power rocket engines, and a 55-year track record in
propulsion testing, Stennis Space Center offered a unique set of benefits,
including test stands that can simulate an entire rocket engine, which
allows their partners to test single components rather than shipping an
entire engine on site.
In November 2020, through a Space Act Agreement that enables NASA to enter
partnerships with organizations, Virgin Orbit secured a partnership with
Stennis to reimburse the center for any testing costs. As a result, they
were given the opportunity to utilize Stennis’ experience and expertise,
allowing them to avoid building their own testing facilities while gaining
valuable hands-on experience.
The Virgin Orbit’s test campaign had team members focused on the
75,000-pound force Thrust Chamber Assembly (TCA), which consists of an
injector, combustion chamber, and nozzle. The TCA is not an entire engine.
Instead, it is where the propellants are mixed, combusted, and exhausted.
The objective is to test different propellant injector configurations to
determine which configuration will maximize performance and efficiency. Most
of the main engine can be simulated with the test stand itself.
“With excellent support from the NASA SSC team, Virgin Orbit successfully
completed the test campaign and collected invaluable data on key injector
parameters and their effects on engine performance,” said Vishal Doshi, a
senior propulsion design engineer at Virgin Orbit.
This testing took place on the E-1 Test Stand, Cell 1, configured for the
new test in the beginning of 2021. The hot fire series began March 30 and
lasted until the final testing day July 20.
“Commercial projects are fast-paced, help us learn new things, and give us
an opportunity to help with the commercialization of space,” said Paul
Rydeen, NASA project manager at Stennis.
Originally, there were 30 tests scheduled involving 10 different injector
configurations at a minimum of three tests each. However, the project was
later expanded to 14 injector configurations and many more tests.
When the Virgin Orbit team became familiar with the testing process, they
were able to establish a rhythm that led them to success, allowing them to
accomplish as many as four tests per day. Each of these tests would
typically last a total duration of 12.1 seconds. With 87 hot fire tests
performed over the testing period, the combined test time totaled 974.391
seconds.
“Virgin Orbit has been working with the Stennis test team since late 2020 on
a variety of complex engine related activities,” said Tom Alexiou, program
manager for Virgin Orbit’s evolved launch vehicle. “Their support of
us has been exemplary in all facets of the program. We continue to maintain
an excellent working relationship and look forward to our latest N3.2 engine
development testing program that will take us into 2022.”
The testing at Stennis directly contributed to the design changes appearing
on the Newton 3 engine – a first stage engine that uses Rocket Propellent-1
and liquid oxygen as propellants. A typical run time for this stage is three
minutes with a max speed of 8,000 miles-per-hour. Virgin Orbit uses Newton 3
to propel the LauncherOne rocket, a two-stage, orbital, air-launched vehicle
carried to the upper atmosphere and released over the Pacific Ocean. This
rocket holds the title of the first orbital class, air-launched,
liquid-fueled rocket to successfully reach space.