Rocket Lab is preparing to launch their fifth Electron mission of 2020 — a rideshare for Planet Labs and Spaceflight Industries named “In Focus,” a reference to Electron’s payload of 10 Earth-imaging satellites. The flight will target a 500 kilometer sun-synchronous orbit, ideal for Earth observation missions as the high inclination means the satellites can cover large portions of the Earth surface while the Sun maintains the same position in the sky each time the satellites pass over a specific location.
The 15th flight of an Electron rocket from Rocket Lab’s private launch facility on the Māhia Peninsula in New Zealand is targeted for a launch window that opens on 28 October at 21:21 UTC (17:21 EDT), or 29 October at 10:21 local time in New Zealand.
Ten payloads in total will be deployed from the Curie engine powered Kick Stage of Electron: Canon’s CE-SAT-IIB and nine of Planet’s Flock 4e’ SuperDoves.
Built by Canon Electronics, CE-SAT-IIB is a second generation technical demonstration satellite developed to test the company’s imaging equipment in space.
The 35.5 kilogram satellite comes equipped with several lenses, including a middle-size telescope — attached to a 200 millimeter “super high sensitivity camera” designed for night photography of Earth, according to Canon.
The spacecraft also contains an EOS M100 secondary telephoto lens, as well as a wide-angle PowerShot camera.
Many of the satellite’s critical components, including the sun sensor, star tracker, inertial measurement unit (IMU), reaction wheel, and the on-board computer were all developed and manufactured in-house by Canon.
CE-SAT-IIB’s launch was arranged through Virginia-based Spaceflight Inc., a satellite rideshare provider.
Joining CE-SAT-IIB on the mission are nine of Planet’s SuperDove cubesats that will join the company’s constellation that provides daily images of Earth’s surface — the largest constellation of its kind.
The SuperDoves will deploy from Rocket Lab’s Maxwell dispensers and will be used for numerous purposes, including observing Earth’s climate, aiding farmers, tracking wildfires, mapping forests, tracking and identifying illegal fishing activity, and supporting disaster response.
Preparations and Launch
On 8 October, Rocket Lab conducted a successful wet dress rehearsal (WDR) of the Electron designated for the mission. During this process, the rocket was filled with its RP-1 kerosene and liquid oxygen and the launch team conducted a normal countdown right up until engine ignition.
The countdown to launch began at T-6 hours at 11:14 EDT (15:14 UTC) when the road to the launch complex was closed.
Electron was taken vertical around T-4 hours, ahead of pad clear and then the start of fueling operations at T-2 hours.
At the same time, the marine hazard zones around the launch complex and downrange under Electron’s flight path will be closed; the airspace surrounding the launch site will be restricted beginning at T-30 minutes.
At T-18 minutes, the Launch Director will conduct a go/no go poll of all launch operators in order to continue the countdown. Passing 2 minutes before launch, the team will hand off control of the countdown to Electron’s onboard computers.
At T-2 seconds, the nine Rutherford engines on Electron’s first stage will ignite and reach full thrust, a process that occurs almost instantly due to their electric-driven turbopumps.
After passing all engine start health checks, the launch pad’s hold-downs will release Electron for a short, vertical climb before the vehicle begins its pitch program.
After 2 minutes and 31 seconds of powered flight, the Rutherford engines on the first stage will shutdown.
Shortly after, pneumatic pushers will separate the first and second stages, followed by ignition of the second stage’s vacuum-optimized Rutherford engine.
Back on the second stage, payload fairing separation is planned for 3 minutes and 9 seconds into flight.
At 6 minutes 23 seconds, Electron’s second stage will perform its unique “hot swap,” where the first round of batteries used to power the vacuum-optimized Rutherford engine’s turbopump are instantly swapped over to a new set of batteries and the old ones jettisoned from the stage.
Electron will reach its initial parking orbit at T+8:54 when the second stage will shut off. About 10 seconds later, Electron’s Kick Stage will separate.
Target launch time:
UTC: 21:14, Oct 28
PT: 14:14, Oct 28
ET: 17:14, Oct 28
NZT: 10:14, Oct 29 pic.twitter.com/Mkbw2hsTjv
— Rocket Lab (@RocketLab) October 27, 2020
At T+51:06, the Curie engine on the stage will ignite, followed by shutdown about two minutes later. One hour after launch, all payloads will be deployed from Electron, which Rocket Lab will confirm via social media and a press release.
After the “In Focus” mission, the company will likely launch the long-awaited STP-27RM flight for the U.S. Air Force from their newly constructed Launch Complex-2 at the Mid-Atlantic Regional Spaceport (MARS) on Wallops Island, Virginia.
The following mission, flight 17, will mark the highly-anticipated first attempt to recover Electron’s booster stage. This recovery operation will mirror the initial attempts to recover the Falcon 9, where the booster was purposely soft-landed in the ocean.
For the water landing, Electron’s first stage will be equipped with a Reaction Control System as well as a parafoil which will slow the vehicle down for a gentle splash down in the Pacific.
A recovery team will be waiting near the splashdown location to retrieve the booster.
Once Rocket Lab is comfortable with how the thrusters and parafoil control the booster, the company will commit to the full recovery plan — which features a helicopter grabbing the booster out of the air as it descends toward the ocean. The helicopter will then fly the booster back to recovery forces.
Meanwhile, on 14 October, NASA selected several companies to develop technologies as part of their fifth “Tipping Point” solicitation. Among those companies is Eta Space, which will partner with Rocket Lab to use the Photon spacecraft to demonstrate “a suite of cryogenic fluid management tech, including active & passive thermal control, liquid acquisition, pressure control, & cryogenic transfer,” according to Rocket Lab.
NASA’s recent “Tipping Point” awards will help companies develop technologies required for the agency’s Artemis program, intended to return humans to the Moon as early as 2024.
Additionally, Rocket Lab is still on track to launch back-to-back missions from LC-1A and -1B at the Māhia Peninsula launch site. These twin missions for the U.S. National Reconnaissance Office (NRO) will liftoff just a few weeks apart from each other on the neighboring launch pads in New Zealand.
The twin NRO flights are scheduled for Quarter 2 of 2021.
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