Rocket Lab has announced their next Electron mission, one that will feature a diverse range of payloads from the United States, France and New Zealand.
The mission, which will be Rocket Lab’s 16th Electron launch, will lift-off from Launch Complex 1 on New Zealand’s Māhia Peninsula during a 14-day launch window that opens on November 16 NZT / November 15 UTC.
Rocket Lab’s Electron launch vehicle will loft 30 satellites to a Sun-Synchronous Orbit (SSO) at 500 km altitude for a range of customers, including TriSept, Unseenlabs, Swarm Technologies, Te Pūnaha Ātea – Auckland Space Institute, and Gabe Newell, the co-founder of global gaming software company Valve.
The satellites span a range of operations, from TriSept’s tech demonstration of new tether systems designed to accelerate spacecraft reentry and reduce orbital debris, through to the next generation of maritime surveillance satellites for Unseenlabs, as well as communications satellites for Swarm Technolgies. The mission will also deploy New Zealand’s first student-built satellite, the APSS-1 satellite for Te Pūnaha Ātea – Auckland Space Institute at The University of Auckland.
A mass simulator will also be fixed to this mission’s Kick Stage in the form of a 3D printed gnome created for Valve’s Gabe Newell by multi-award-winning design studio Weta Workshop, the creative studio behind Lord of the Rings, Avatar and Mulan. The unique space component is additively manufactured into the shape of Half-Life gaming icon Gnome Chompski.
The mission serves as an homage to the innovation and creativity of gamers worldwide and also aims to test and qualify a novel 3D printing technique that could be employed for future spacecraft components. Mr. Newell, will be donating one dollar to the Paediatric Intensive Care Unit at Starship Children’s Hospital for every person who watches the launch online at www.rocketlabusa.com/live-stream.
Despite launching together as a rideshare, each satellite will be deployed to a unique orbit thanks to Rocket Lab’s Kick Stage. Once the Electron launch vehicle’s second stage reaches orbit, the Kick Stage separates and takes over as a space tug to conduct the final leg of the journey, providing propulsion and pointing to deliver multiple satellites to precise, individual orbits.
Executive Comment
Peter Beck, Rocket Lab’s founder and CEO, said, “Small satellite operators shouldn’t have to compromise on orbits when flying on a rideshare mission, and we’re excited to provide tailored access to space for 30 satellites on this mission. It’s why we created the Kick Stage to enable custom orbits on every mission, and eliminate the added complexity, time, and cost of having to develop your own spacecraft propulsion or using a third-party space tug.”
About the payloads
Payload: DRAGRACER — Organization: TriSept
The DRAGRACER mission will test the effectiveness of new tether technologies designed to accelerate spacecraft reentry and reduce orbital debris at the conclusion of space missions. TriSept has completed the integration of a pair of qualified Millennium Space Systems 6U small satellites, one featuring the tether drag device and one without. The controlled spacecraft should deorbit in approximately 45 days, while the second spacecraft is expected to remain in orbit for seven to nine years, according to Tethers Unlimited, developer of the 70-meter-long (230 feet) Terminator Tape aboard the control satellite.
Payload: BRO-2 and BRO-3 — Organization: Unseenlabs
BRO-2 and BRO-3 are the second and third satellites in French company Unseenlabs’ planned constellation of about 20 satellites dedicated to maritime surveillance. The first BRO satellite was launched to orbit by Rocket Lab in August 2019. Unseenlabs’ constellation enables improved monitoring of activities at sea, such as illegal fishing and anti-environmental behavior. Thanks to a unique proprietary technology, the BRO satellites are the first to be able to independently and precisely locate and fingerprint Radio Frequency (RF) emitters all around the globe, day or night, in any weather condition, and without requiring any special embarked tracking device. With three satellites in orbit, Unseenlabs’ clients can now benefit from the shortest revisit time available on the satellite RF geolocation market.
Payload: APSS-1 — Organization: Te Pūnaha Ātea – Auckland Space Institute, The University of Auckland
The student-built Waka Āmiorangi Aotearoa APSS-1 satellite is designed to monitor electrical activity in Earth’s upper atmosphere to test whether ionospheric disturbances can predict earthquakes. The data from this mission will deliver deeper knowledge of these hard-to-access altitudes and drive understanding of how phenomena such as solar wind and geophysical events affect this atmospheric region.
Payload: Spacebees — Organization: Swarm Technologies
Swarm will launch the latest 24 1/4U SpaceBEE satellites to continue building out its planned constellation of 150 satellites to provide affordable satellite communications services to IoT devices in remote regions around the world. Swarm’s uniquely small satellites enable the company to provide network services and user hardware at the industry’s lowest cost and deliver maximum value to customers across a range of industries including maritime shipping, agriculture, energy, and ground transportation. The SpaceBEES will be integrated into two of Rocket Lab’s 12U Maxwell CubeSat dispensers for orbital deployment.
Mass Simulator: Gnome Chompski — Organization: Gabe Newell, Founder of Valve Software
Manufactured with support from multi-award-winning design studio Weta Workshop, the unique space component is additively manufactured from titanium and printed in the shape of Half-Life gaming icon Gnome Chompski. The mission serves as an homage to the innovation and creativity of gamers worldwide, and also aims to test and qualify a novel 3D printing technique that could be employed for future spacecraft components. The 150 mm gnome will remain attached to the Kick Stage during all mission phases and will burn up upon re-entry into Earth’s atmosphere during the de-orbiting process.