Engineering:Cygnus NG-20
Cygnus S.S. Patricia “Patty” Hilliard Robertson (NG-20), the spacecraft to be used in the mission, undergoing tests at Kennedy Space Center | |
Mission type | ISS logistics |
---|---|
Operator | Northrop Grumman |
COSPAR ID | 2024-021A |
Mission duration | 164 days, 15 hours and 34 minutes (in progress) |
Spacecraft properties | |
Spacecraft | S.S. Patricia “Patty” Hilliard Robertson |
Spacecraft type | Enhanced Cygnus |
Manufacturer |
|
Start of mission | |
Launch date | 30 January 2024, 17:07:15 UTC[1] |
Rocket | Falcon 9 Block 5 ♺, B1077.10 |
Launch site | CCSFS SLC-40 |
Contractor | Northrop Grumman |
End of mission | |
Disposal | Deorbited |
Decay date | 2024 (planned) |
Orbital parameters | |
Reference system | Geocentric orbit |
Regime | Low Earth orbit |
Inclination | 51.66° |
Berthing at the International Space Station | |
Berthing port | ''Unity nadir |
RMS capture | 1 February 2024, 09:59 UTC |
Berthing date | 1 February 2024, 12:14 UTC |
Time berthed | 162 days, 20 hours and 27 minutes (in progress) |
Cargo | |
Mass | 3,726 kilograms (8,214 lb) |
Pressurised | 3,712 kilograms (8,184 lb) |
Unpressurised | 14 kilograms (31 lb) |
Cygnus NG-20 mission patch |
NG-20 is the twentieth flight of the Cygnus robotic resupply spacecraft and its seventeenth flight to the International Space Station (ISS). It launched on 30 January 2024.[1][2][3][4] It is contracted to Northrop Grumman under the Commercial Resupply Services II (CRS-2) contract with NASA. The capsule launched aboard a SpaceX Falcon 9 rocket.
Orbital ATK (now Northrop Grumman Space Systems) and NASA jointly developed a new space transportation system to provide commercial cargo resupply services to the International Space Station (ISS). Under the Commercial Orbital Transportation Services (COTS) program, Orbital ATK designed, acquired, built, and assembled the Cygnus, an advanced spacecraft using a Pressurized Cargo Module (PCM) provided by industrial partner Thales Alenia Space and a Service Module based on the Orbital GEOStar satellite bus.[5]
NG-20 is the first launch of a Cygnus spacecraft after the exhaustion of the supply of Antares rockets, due to the Russian invasion of Ukraine, losing both the Russian rocket engine supplier and the Ukrainian booster stage supplier. The next two Cygnus missions will also use Falcon 9, while subsequent missions will use the next-generation Antares 300 series that is under development, which does not depend on Ukrainian or Russian parts.[6] Cygnus is the only cargo freighter to launch on four different orbital launchers, that is, Antares 100 series, Atlas V, Antares 200 series and Falcon 9 Block 5 rockets.
History
Cygnus NG-20 is the ninth Cygnus mission under the Commercial Resupply Services-2 contract.
Production and integration of Cygnus spacecraft were performed in Dulles, Virginia. The Cygnus service module is mated with the pressurized cargo module at the launch site, and mission operations are conducted from control centers in Dulles, Virginia and Houston, Texas .[5]
Spacecraft
This is the fifteenth flight of the Enhanced-sized Cygnus PCM.[3][7]
Manifest
The Cygnus spacecraft is loaded with cargo and supplies before its launch.[8]According to the manifest, the Cygnus spacecraft was loaded with up to 3,726 kg (3.726 t; 8,214 lb; 4.107 short tons; 586.7 st) of cargo.[9][8]
- Crew Supplies: 1,129 kg (2,489 lb)
- Science Investigations: 1,369 kg (3,018 lb)
- Spacewalk Equipment: 16 kg (35 lb)
- Vehicle Hardware: 1,131 kg (2,493 lb)
- Computer Resources: 67 kg (148 lb)
Research
Scientific investigations traveling in the Cygnus spacecraft include tests of a 3D metal printer, semiconductor manufacturing, and thermal protection systems for re-entry to Earth’s atmosphere.[9]
3D Printing in Space
An investigation from ESA (European Space Agency), Metal 3D Printer tests additive manufacturing or 3D printing of small metal parts in microgravity. This investigation provides us with an initial understanding of how such a printer behaves in space. A 3D printer can create many shapes, and we plan to print specimens, first to understand how printing in space may differ from printing on Earth and second to see what types of shapes we can print with this technology. In addition, this activity helps show how crew members can work safely and efficiently with printing metal parts in space.[9]
Results could improve understanding of the functionality, performance, and operations of metal 3D printing in space, as well as the quality, strength, and characteristics of the printed parts. Resupply presents a challenge for future long-duration human missions. Crew members could use 3D printing to create parts for maintenance of equipment on future long-duration spaceflight and on the Moon or Mars, reducing the need to pack spare parts or to predict every tool or object that might be needed, saving time and money at launch.[9]
Advances in metal 3D printing technology also could benefit potential applications on Earth, including manufacturing engines for the automotive, aeronautical, and maritime industries and creating shelters after natural disasters.[9]
Semiconductor Manufacturing in Microgravity
Manufacturing of Semiconductors and Thin-Film Integrated Coatings (MSTIC) examines how microgravity affects thin films that have a wide range of uses. This technology could enable autonomous manufacturing to replace the many machines and processes currently used to make a wide range of semiconductors, potentially leading to the development of more efficient and higher-performing electrical devices.[9]
Manufacturing semiconductor devices in microgravity also may improve their quality and reduce the materials, equipment, and labor required. On future long-duration missions, this technology could provide the capability to produce components and devices in space, reducing the need for resupply missions from Earth. The technology also has applications for devices that harvest energy and provide power on Earth.[9]
Modeling Atmospheric Re-Entry
Scientists who conduct research on the space station often return their experiments to Earth for additional analysis and study. But the conditions that spacecraft experience during atmospheric reentry, including extreme heat, can have unintended effects on their contents. Thermal protection systems used to shield spacecraft and their contents are based on numerical models that often lack validation from actual flight, which can lead to significant overestimates in the size of system needed and take up valuable space and mass. Kentucky Re-entry Probe Experiment-2 (KREPE-2), part of an effort to improve thermal protection system technology, uses three capsules outfitted with different heat shield materials and a variety of sensors to obtain data on actual reentry conditions.[9]
Building on the success of KREPE-1 launched on Cygnus NG-16, improved sensors are added to gather more measurements and improved the communication system to transmit more data. The capsules can be outfitted for other atmospheric re-entry experiments, supporting improvements in heat shielding for applications on Earth, such as protecting people and structures from wildfires.[9]
Remote Robotic Surgery
Robotic Surgery Tech Demo tests the performance of a small robot that can be remotely controlled from Earth to perform surgical procedures. Researchers plan to compare procedures in microgravity and on Earth to evaluate the effects of microgravity and time delays between space and ground.[9]
The robot uses two “hands” to grasp and cut rubber bands, which simulate surgical tissue and provide tension that is used to determine where and how to cut, according to Shane Farritor, chief technology officer at Virtual Incision Corp., developer of the investigation with the University of Nebraska.[9]
Longer space missions increase the likelihood that crew members may need surgical procedures, whether simple stiches or an emergency appendectomy. Results from this investigation could support development of robotic systems to perform these procedures. In addition, the availability of a surgeon in rural areas of the country declined nearly a third between 2001 and 2019. Miniaturization and the ability to remotely control the robot help make surgery available anywhere and anytime on Earth.[9]
NASA has sponsored research on miniature robots for more than 15 years. In 2006, remotely operated robots performed procedures in the underwater NASA’s Extreme Environment Mission Operations (NEEMO) 9 mission. In 2014, a miniature surgical robot performed simulated surgical tasks on the zero-g parabolic airplane.[9]
Growing Cartilage Tissue in Space
Compartment Cartilage Tissue Construct demonstrates two technologies, Janus Base Nano-Matrix and Janus Base Nanopiece. Nano-Matrix is an injectable material that provides a scaffold for formation of cartilage in microgravity, which can serve as a model for studying cartilage diseases. Nanopiece delivers an RNA (ribonucleic acid)-based therapy to combat diseases that cause cartilage degeneration.[9]
Cartilage has a limited ability to self-repair and osteoarthritis is a leading cause of disability in older patients on Earth. Microgravity can trigger cartilage degeneration that mimics the progression of aging-related osteoarthritis but happens more quickly, so research in microgravity could lead to faster development of effective therapies. Results from this investigation could advance cartilage regeneration as a treatment for joint damage and diseases on Earth and contribute to development of ways to maintain cartilage health on future missions to the Moon and Mars.[9]
Mission
SpaceX launched the Cygnus on 30 January 2024. SpaceX modified their fairing for this mission to add a ~5’x4’ door side hatch for late loads of cargo onto the Cygnus spacecraft via mobile cleanroom.[10]
See also
References
- ↑ 1.0 1.1 Clark, Stephen (25 October 2023). "Launch Schedule". Spaceflight Now. https://spaceflightnow.com/launch-schedule/.
- ↑ Gebhardt, Chris (1 June 2018). "Orbital ATK looks ahead to CRS-2 Cygnus flights, Antares on the commercial market". NASASpaceflight.com. https://www.nasaspaceflight.com/2018/06/orbital-atk-crs2-cygnus-flights-antares-commercial/.
- ↑ 3.0 3.1 Clark, Stephen (1 October 2020). "Northrop Grumman "optimistic" to receive more NASA cargo mission orders". Spaceflight Now. https://spaceflightnow.com/2020/10/01/northrop-grumman-optimistic-to-receive-more-nasa-cargo-mission-orders/.
- ↑ "Northrop Grumman shifting to Space Coast for future space station missions". 3 August 2023. https://finance.yahoo.com/news/northrop-grumman-shifting-space-coast-201200258.html?guccounter=1&guce_referrer=aHR0cHM6Ly93d3cuZ29vZ2xlLmNvbS8&guce_referrer_sig=AQAAAF5qj583tcWhHrVeQ9YlVCHq6BOqm00ASOHKsCUW85Hdmlic62jgK7D7dMjBrr_1-yy5IWUXTas6A4QNrSN3OFXyaWT5DbtfT85jSP32zfFS9C9zz-asm3WO6lu2V9DEdNc77FQCnT3Qd0AoHiav1krPYMeFjLxSAJjdG0fn9Q3n.
- ↑ 5.0 5.1 "Cygnus Spacecraft". Northrop Grumman. 6 January 2020. https://www.northropgrumman.com/space/cygnus-spacecraft/.
- ↑ "Northrop Grumman and Firefly to partner on upgraded Antares" (in en-US). 2022-08-08. https://spacenews.com/northrop-grumman-and-firefly-to-partner-on-upgraded-antares/.
- ↑ Leone, Dan (17 August 2015). "NASA Orders Two More ISS Cargo Missions From Orbital ATK". SpaceNews. http://spacenews.com/nasa-orders-two-more-iss-cargo-missions-from-orbital-atk/.
- ↑ 8.0 8.1 "Northrop Grumman Commercial Resupply". ISS Program Office. NASA. 1 July 2019. https://www.nasa.gov/mission_pages/station/structure/launch/northrop-grumman.html. This article incorporates text from this source, which is in the public domain.
- ↑ 9.00 9.01 9.02 9.03 9.04 9.05 9.06 9.07 9.08 9.09 9.10 9.11 9.12 9.13 9.14 "Overview for NASA’s Northrop Grumman 20th Commercial Resupply Mission - NASA" (in en-US). 2024-01-25. https://www.nasa.gov/missions/station/overview-for-nasas-northrop-grumman-20th-commercial-resupply-mission/.
- ↑ (in en) NASA, Northrop Grumman 20th Commercial Resupply Services Mission Prelaunch (Jan. 26, 2024), https://www.youtube.com/watch?v=BR_o4RJ7CMc, retrieved 2024-01-31
External links
Original source: https://en.wikipedia.org/wiki/Cygnus NG-20.
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