SSC Demo-1

SSC Demo-1
	Scale model of the Dream Chaser Cargo System with the Shooting Star module
Names	Dream Chaser Demo-1
Mission type	Flight test, ISS resupply
Operator	Sierra Nevada Corporation
Website	sierraspace.com/dream-chaser-spaceplane
Mission duration	45 days (planned)
Spacecraft properties
Spacecraft	Dream Chaser Tenacity
Spacecraft type	Dream Chaser
Manufacturer	Sierra Nevada; Lockheed Martin ;
Start of mission
Launch date	May 2025 (planned)
Rocket	Vulcan Centaur VC4L
Launch site	Cape Canaveral, SLC‑41
Contractor	United Launch Alliance
End of mission
Landing site	Kennedy, SLF Runway 15/33
Orbital parameters
Reference system	Geocentric orbit
Regime	Low Earth orbit
Inclination	51.6°
Berthing at ISS
Berthing port	Harmony nadir or Unity nadir
	Commercial Resupply Services ← CRS SpX-31 CRS SpX-32 → Dream Chaser flights ← Drop Test 2 CRS-1 →

Last updated October 16, 2024

SSC Demo-1, also known as Dream Chaser Demo-1, is the planned first flight of the Sierra Space robotic resupply spacecraft Dream Chaser to the International Space Station (ISS) under the CRS-2 contract with NASA. The demonstration mission is planned for launch no earlier than May 2025.^[1]

In April 2021 the Dream Chaser division of the Sierra Nevada Corporation (SNC) was spun-off, creating the fully independent Sierra Space Corporation (SSC), which assumed full oversight over the Dream Chaser program. The company developed a new reusable spacecraft to provide commercial cargo resupply services to the International Space Station (ISS), based on decades of lifting body programs. Under the Commercial Orbital Transportation System (COTS) program, the company designed Dream Chaser with industrial partner Lockheed Martin.

The company also designed the accompanying Shooting Star cargo module with subcontractor Applied Composites.^[3] At the end of mission, the Shooting Star will destructively reenter the atmosphere and the Dream Chaser will land at the Kennedy Space Center's Shuttle Landing Facility.

Spacecraft

The Dream Chaser Cargo System will fly cargo resupply missions to the ISS under NASA's Commercial Resupply Services-2 program. This system features the Shooting Star, an expendable cargo module with solar panels, and the Dream Chaser, a reusable lifting body capable of returning 1,750 kg (3,860 lb) of pressurized cargo to Earth while undergoing maximum re-entry forces of 1.5 g.^[4]^[5]

The Dream Chaser design is derived from NASA's HL-20 Personnel Launch System spaceplane concept from the 1990s, which in turn is descended from over 20,000 hours and six decades of experimental lifting body vehicles, including the X-20 Dyna-Soar, Northrop M2-F2, Northrop M2-F3, Northrop HL-10, Martin X-24A and X-24B, and Martin X-23 PRIME.^[6]^[7]^[8]^[9]

The vehicle to be used in SSC Demo-1 is named Tenacity.^[10]^[11] The Shooting Star carries pressurized and unpressurized cargo, and serves as the power supply for the Dream Chaser.^[5] The Shooting Star will have a cargo capacity of 4,536 kg (10,000 lb). Its design is similar to the Exoliner cargo container shown in Lockheed Martin's Jupiter proposal for NASA's CRS-2.

Mission

SSC Demo-1 is the Dream Chaser demonstration mission under the Commercial Resupply Services-2 (CRS-2) contract with NASA. Production and integration of the Dream Chaser spacecraft is performed in Texas, Colorado, and Florida. The Dream Chaser is mated with the Shooting Star at the launch site, and mission operations are conducted from control centers in Colorado and Houston, Texas. Sierra Nevada selected ULA's Vulcan Centaur as its launch vehicle for this Demo-1 mission and the six contracted NASA CRS-2 missions.^[12]^[13]^[14]

Notes

↑ VC4L designates that this is a Vulcan Centaur with four solid rocket boosters and a long payload fairing.

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References

1 2 3 Garcia, Mark (15 October 2024). "Crew-8 Awaits Splashdown; Expedition 72 Stays Focused on Science". NASA . Retrieved 16 October 2024. The first flight of Sierra Space's Dream Chaser to the International Space Station is now scheduled for no earlier than May 2025 [...] will carry cargo to the orbiting laboratory and stay on board for approximately 45 days on its first mission.
↑ "Vulcan". United Launch Alliance . 2020. Retrieved 19 January 2022. Peregrine will fly on a VC2S, Dream Chaser will fly on a VC4L.
↑ "SNC'S Dream Chaser® Spaceplane's Shooting Star Arrives in Colorado for Integration" (Press release). SNC. 14 May 2020. Retrieved 12 August 2020.
↑ "Sierra Nevada Hopes Dream Chaser Finds "Sweet Spot" of ISS Cargo Competition". SpaceNews. 18 March 2015. Retrieved 11 March 2020.
1 2 Gebhardt, Chris (19 November 2019). "SNC Names Dream Chaser cargo module". NASASpaceFlight.com.
↑ H. Phillips, Edward (15 July 1991). "Langley Refines Design, Begins Human Factors Tests of Personnel Launch System". Aviation Week & Space Technology. p. 52. ...The HL-20's baseline design has evolved from manned lifting bodies flown for the Defense Dept, during the 1960s and owes much of its overall layout to the Martin X-24A...
↑ R. Dale, Reed (1997). "Wingless Flight The Lifting Body Story" (PDF). NASA. p. 180. Archived from the original (PDF) on 18 December 2014. ... The NASA lifting-body program has been well documented in about 100 technical reports on the program's 222 flights and 20,000 hours of wind-tunnel tests. Many of these publications are unclassified. The Soviet Union purchased copies of these reports from NASA Headquarters in Washington, D.C., then designed its own lifting body. In 1982, the Soviets flight-tested an unpiloted, 10-foot-long, subscale version of their lifting body, the BOR-4, including a maneuvering re-entry over the Indian Ocean from space orbit. The flight test of the BOR-4 closely resembled that of our PRIME (X-23) vehicle in 1966... This article incorporates text from this source, which is in the public domain.
↑ R. Asker, James (24 September 1990). "NASA Design for Manned Spacecraft. Draws on Soviet Subscale Spaceplane". Aviation Week & Space Technology. p. 28. ... A mock-up of the proposed "space taxi", called the HL-20 Personnel Launch System, closely resembles a Soviet subscale spaceplane flown on four orbital missions in the 1980s... However, Piland, chief of the space systems division at the Langley Research Center, was quick to point out the Soviet test vehicle seems to have evolved from U. S. lifting-body configurations flown from 1966 to 1975 — such as Northrop's HL-10, M2-F2 and M2-F3 and Martin's X-24A and X-24B...
↑ Wallace, Lance E. (1996). "Flights of Discovery: 50 Years at the NASA Dryden Flight Research Center" (PDF). NASA. p. 72. Archived from the original (PDF) on 17 February 2015. ... The lifting-body program came to an official end in 1975. Yet like a Phoenix rising from the ashes, the concept has appeared several times since then in proposed NASA spacecraft. When the Langley Research Center revealed its HL-20 design for an emergency crew return vehicle or small mini-Shuttle in 1990, the shape was remarkably similar to the HL-10 and X-24A designs... This article incorporates text from this source, which is in the public domain.
↑ "SNC's Dream Chaser Tenacity Spaceplane" (Press release). SNC. 1 May 2020. Retrieved 12 August 2020.
↑ Reed, Nola Taylor (12 August 2020). "Meet 'Tenacity': 1st Dream Chaser space plane gets a name". SPACE.com. Retrieved 12 August 2020.
↑ "SNC selects ULA for Dream Chaser spacecraft launches". United Launch Alliance (ULA). 14 August 2019.
↑ Foust, Jeff (14 August 2019). "SNC Selects ULA Vulcan for Dream Chaser Missions". SpaceNews.
↑ Bergin, Chris (16 October 2019). "Cargo Dream Chaser solidifies ULA deal for Vulcan". NASASpaceFlight.com. Retrieved 2 September 2020.

External links

Dream Chaser at Sierra Space

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[VC4L-2] VC4L designates that this is a Vulcan Centaur with four solid rocket boosters and a long payload fairing.

[nasa-20241015-1] 1 2 3 Garcia, Mark (15 October 2024). "Crew-8 Awaits Splashdown; Expedition 72 Stays Focused on Science". NASA . Retrieved 16 October 2024. The first flight of Sierra Space's Dream Chaser to the International Space Station is now scheduled for no earlier than May 2025 [...] will carry cargo to the orbiting laboratory and stay on board for approximately 45 days on its first mission.

[3] "Vulcan". United Launch Alliance . 2020. Retrieved 19 January 2022. Peregrine will fly on a VC2S, Dream Chaser will fly on a VC4L.

[4] "SNC'S Dream Chaser® Spaceplane's Shooting Star Arrives in Colorado for Integration" (Press release). SNC. 14 May 2020. Retrieved 12 August 2020.

[DCCS-5] "Sierra Nevada Hopes Dream Chaser Finds "Sweet Spot" of ISS Cargo Competition". SpaceNews. 18 March 2015. Retrieved 11 March 2020.

[nsf-20191119-6] 1 2 Gebhardt, Chris (19 November 2019). "SNC Names Dream Chaser cargo module". NASASpaceFlight.com.

[AWST-19910715-7] H. Phillips, Edward (15 July 1991). "Langley Refines Design, Begins Human Factors Tests of Personnel Launch System". Aviation Week & Space Technology. p. 52. ...The HL-20's baseline design has evolved from manned lifting bodies flown for the Defense Dept, during the 1960s and owes much of its overall layout to the Martin X-24A...

[WF-1997-8] R. Dale, Reed (1997). "Wingless Flight The Lifting Body Story" (PDF). NASA. p. 180. Archived from the original (PDF) on 18 December 2014. ... The NASA lifting-body program has been well documented in about 100 technical reports on the program's 222 flights and 20,000 hours of wind-tunnel tests. Many of these publications are unclassified. The Soviet Union purchased copies of these reports from NASA Headquarters in Washington, D.C., then designed its own lifting body. In 1982, the Soviets flight-tested an unpiloted, 10-foot-long, subscale version of their lifting body, the BOR-4, including a maneuvering re-entry over the Indian Ocean from space orbit. The flight test of the BOR-4 closely resembled that of our PRIME (X-23) vehicle in 1966... This article incorporates text from this source, which is in the public domain.

[AWST-19900924-9] R. Asker, James (24 September 1990). "NASA Design for Manned Spacecraft. Draws on Soviet Subscale Spaceplane". Aviation Week & Space Technology. p. 28. ... A mock-up of the proposed "space taxi", called the HL-20 Personnel Launch System, closely resembles a Soviet subscale spaceplane flown on four orbital missions in the 1980s... However, Piland, chief of the space systems division at the Langley Research Center, was quick to point out the Soviet test vehicle seems to have evolved from U. S. lifting-body configurations flown from 1966 to 1975 — such as Northrop's HL-10, M2-F2 and M2-F3 and Martin's X-24A and X-24B...

[dryden-50-1996-10] Wallace, Lance E. (1996). "Flights of Discovery: 50 Years at the NASA Dryden Flight Research Center" (PDF). NASA. p. 72. Archived from the original (PDF) on 17 February 2015. ... The lifting-body program came to an official end in 1975. Yet like a Phoenix rising from the ashes, the concept has appeared several times since then in proposed NASA spacecraft. When the Langley Research Center revealed its HL-20 design for an emergency crew return vehicle or small mini-Shuttle in 1990, the shape was remarkably similar to the HL-10 and X-24A designs... This article incorporates text from this source, which is in the public domain.

[11] "SNC's Dream Chaser Tenacity Spaceplane" (Press release). SNC. 1 May 2020. Retrieved 12 August 2020.

[12] Reed, Nola Taylor (12 August 2020). "Meet 'Tenacity': 1st Dream Chaser space plane gets a name". SPACE.com. Retrieved 12 August 2020.

[ula-20190814-13] "SNC selects ULA for Dream Chaser spacecraft launches". United Launch Alliance (ULA). 14 August 2019.

[spn-20190814-14] Foust, Jeff (14 August 2019). "SNC Selects ULA Vulcan for Dream Chaser Missions". SpaceNews.

[nsf-201908-15] Bergin, Chris (16 October 2019). "Cargo Dream Chaser solidifies ULA deal for Vulcan". NASASpaceFlight.com. Retrieved 2 September 2020.

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v t e Dream Chaser
COTS CRS Uncrewed spaceflights to the ISS
Launch vehicles	Vulcan Centaur
Operator	Sierra Space Corporation
Missions	SSC Demo-1 (2025)
Related vehicles	Cygnus SpaceX Dragon SpaceX Dragon 2

v t e Uncrewed spaceflights to the International Space Station
See also: {{ Crewed ISS flights }} {{ ISS expeditions }}
2000–2004	2000 2R / Zvezda 1P 2P 3P 2001 4P 5P SO1 / Pirs 6P 2002 7P 8P 9P 2003 10P 11P 12P 2004 13P 14P 15P 16P
2005–2009	2005 17P 18P 19P 20P 2006 21P 22P 23P 2007 24P 25P 26P 27P 2008 28P ATV-1 29P 30P 31P 2009 32P 33P 34P HTV-1 35P MIM2 / Poisk
2010–2014	2010 36P 37P 38P 39P 40P 2011 HTV-2 41P ATV-2 42P 43P 44P† 45P 2012 46P ATV-3 47P SpX-D HTV-3 48P SpX-1 49P 2013 50P SpX-2 51P ATV-4 52P HTV-4 Orb-D1 53P 2014 Orb-1 54P 55P SpX-3 Orb-2 56P ATV-5 SpX-4 Orb-3† 57P
2015–2019	2015 SpX-5 58P SpX-6 59P† SpX-7† 60P HTV-5 61P OA-4 62P 2016 OA-6 63P SpX-8 64P SpX-9 OA-5 65P† HTV-6 2017 SpX-10 66P OA-7 SpX-11 67P SpX-12 68P OA-8E SpX-13 2018 69P SpX-14 OA-9E SpX-15 70P HTV-7 71P NG-10 SpX-16 2019 SpX-DM1 72P NG-11 SpX-17 SpX-18 73P 60S HTV-8 NG-12 SpX-19 74P Boe-OFT†
2020–2024	2020 NG-13 SpX-20 75P HTV-9 76P NG-14 SpX-21 2021 77P NG-15 SpX-22 78P Nauka NG-16 SpX-23 79P M-UM / Prichal SpX-24 2022 80P NG-17 Boe-OFT 2 81P SpX-25 82P NG-18 SpX-26 2023 83P SpX-27 84P SpX-28 NG-19 85P SpX-29 86P 2024 NG-20 87P SpX-30 88P NG-21 89P
Future	2024 SpX-31 90P 2025 SpX-32 NG-22 SNC Demo-1 HTV-X1 SNC-1 2030 ISS Deorbit Vehicle
Spacecraft	Roscosmos Progress ESA ATV (past) JAXA HTV NASA CRS SpaceX Dragon 1 (past) SpaceX Dragon 2 Northrop Grumman Cygnus Sierra Nevada Dream Chaser (future) ISS Deorbit Vehicle
Ongoing spaceflights in underline Future spaceflights in italics † - mission failed to reach ISS