NanoRacks CubeSat Deployer Mission 11 Status Update: Good Deploy!
NanoRacks began the first of two airlock cycles for the 11th and 12th NanoRacks CubeSat Deployer Missions (NRCSD-11, NRCSD-12) on May 16, 2017. We are pleased to update our customers, friends, and shareholders that the first round of deployments has been completed successfully.
NRCSD-11 and NRSD-12 were brought to the International Space Station on the Orbital ATK-7 mission, which launched on April 18, 2017 from the Kennedy Space Center in Cape Canaveral, Florida. This launch was our largest CubeSat mission to date, bringing 34 satellites into the Space Station, plus four CubeSats mounted on externally on the Cygnus spacecraft.
This week, our operations team worked with NASA Johnson Space Station, JAXA, and Astronauts Peggy Whitson and Jack Fisher on the installation of the NRCSD in preparations for the first deployment early morning on May 16th.
Below we share information about the 17 CubeSats deployed this past week as we at NanoRacks gear up for the second airlock cycle scheduled to begin on May 22, 2017, where we will deploy the NRCSD-12 satellites.
In this first cycle alone, the CubeSats deployed represent 10 different countries around the world.
To date, NanoRacks has deployed 154 CubeSats via the NanoRacks CubeSat Deployer on the International Space Station, and 165 CubeSats in total. We continue to show the unique value of using space stations for satellite deployments and appreciate everyone’s continued support.
Congratulations to all of the CubeSat teams, and good luck in your satellite operations!
-The NanoRacks Team
The QB50 Mission consists of dozens of universities located around the world – including Israel, Canada, Australia, Korea, Spain, Germany, France and more. Coordinated by the von Karman Institute and sponsored by the European Commission, the QB50 CubeSats will take advantage of the space station orbit to study the lower thermosphere (200-380 kilometers) collecting scientific climate data, in what is considered by experts a relatively unexplored part of Earth’s atmosphere.
The ISS portion of the QB50 Mission involves over 300 students and 50 professionals, which brings the program together.
The QB50 CubeSats deployed in this first airlock cycle:
SOMP2 – TU Dresden, Germany
HAVELSAT – Havelsan, Turkey
Columbia – University of Michigan, USA
PHOENIX – National Cheng Kung University, Taiwan
X-CubeSat – Ècole Polytechnique, France
QBEE – Open Cosmos Ltd. & University of Lulea, Sweden
ZA-AEROSAT – Stellenbosch Univesrity, South Africa
LINK – Korea Advanced Institute of Science and Technology, South Korea
UPSat – University of Patras and Libre Space Foundation, Greece
SpaceCube – Ècole des Mines Paristech, France
Hoopoe – Herzliya Science Center, Israel
ALTAIR – Millennium Space Systems
Millennium Space Systems’ NanoRacks-ALTAIR™ Pathfinder spacecraft establishes flight heritage for the majority of the ALTAIR Core product line spacecraft design and for payload support technologies. ALTAIR is the next generation affordable resilient space platform for low-Earth orbit (LEO), Geosynchronous Earth Orbit (GEO) and deep space missions. The key ALTAIR Core hardware designs are demonstrated and flown in their objective design configurations to retire technical risks, increase Technology Readiness Levels (TRLs) and gain flight heritage for future Department of Defense (DoD) and NASA space programs.
SHARC – Air Force Research Laboratory
The Air Force Research Laboratory’s SHARC CubeSat will demonstrate the capability for a CubeSat to perform critical calibration of over 120 Tri-Service C-Bad radars. These calibrations are needed to meet tracking requirements of orbital objects. This CubeSat demonstrates two technologies developed at AFRL/RV under the SBIR program: MMA HaWK deployable solar array and the BCT XACT ADCS System.
SG-Sat – University of Kentucky
The University of Kentucky’s SG-SAT (Stellar Gyroscope Satellite) captures images of star fields to orient a small satellite and test new software that predicts the satellite’s path as it experiences atmospheric drag. This CubeSat was developed from the work of students in the University of Kentucky College of Engineering Space Systems Lab under a Cooperative Agreement between NASA KY, NASA EPSCoR and the NASA International Space Station Research Program. This will be the third cubesat developed for launch by UK Engineering Space Systems
The SGSat project is supported by NASA EPSCoR (Established Program to Stimulate Competitive Research), a program through the NASA Office of Education that develops U.S. aerospace research and the aerospace STEM (science, technology, engineering and math) workforce. The project is administered by NASA Kentucky, hosted at UK to advance aerospace research and education across Kentucky. PI: Dr. James Lumpp, Professor, University of Kentucky College of Engineering
NASA ELaNa XVII Sponsored CubeSats
The following CubeSat missions were selected through the CubeSat Launch Initiative (CSLI) as part of the seventeenth installment of the Educational Launch of Nanosatellites (ELaNa) missions.
Over the past three years, more than 100 students have been involved in the design, development and construction of these CubeSats that will be deployed from the space station
via the commercially-developed NanoRacks CubeSat Deployer program.
CXBN-2 – Morehead State University
The Cosmic X-Ray Background NanoSat-2 (CXBN-2) CubeSat Mission developed by Morehead State University and its partners the Keldysh Institute (Moscow, Russia), the Maysville Community and Technical College (Morehead, KY) and KYSpace LLC (Lexington, KY) will increase the precision of measurements of the Cosmic X-Ray Background in the 30-50 keV range to a precision of <5%, thereby constraining models that attempt to explain the relative contribution of proposed sources lending insight into the underlying physics of the early universe. The mission addresses a fundamental science question that is central to our understanding of the structure, origin, and evolution of the universe by potentially lending insight into both the high-energy background radiation and into the evolution of primordial galaxies.
IceCube – NASA Goddard Spaceflight Center
IceCube’s mission is to demonstrate the technology of a sub-millimeter-wave radiometer for future cloud ice sensing. This technology will enable cloud ice measurements to be taken in the intermediate altitudes (5 km – 15 km), where no measurements currently exist. It will perform first-of-a-kind measurements of ice particles embedded within clouds. These measurements will advance atmospheric monitoring technology and also fill in critical gaps in understanding how cloud ice affects the weather and how cloud formations process atmospheric radiation.
CSUNSat1 – California State University Northridge, NASA JPL
The primary mission of CSUNSat1 is to space test an innovative low temperature-capable energy storage system, developed by JPL, raising its TRL level to 7 from 4 to 5. The success of this energy storage system will enable future missions, especially those in deep space to do more science while requiring less energy, mass and volume. This CubeSat was designed, built, programmed, and tested by a team of over 70 engineering and computer science students at California State University (CSUN). The primary source of funding for CSUNSat1 is NASA’s Small Spacecraft Technology Partnership program. For more information see http://www.csun.edu/cubesat.
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