Development of NASA's Space Launch System (SLS) heavy lift rocket is shifting from the formulation phase into the implementation phase in 2014, a little more than three years after formal program approval. Current development is focused on delivering a vehicle capable of launching 70 metric tons (t) into low Earth orbit. This "Block 1" configuration will launch the Orion Multi-Purpose Crew Vehicle (MPCV) on its first autonomous flight beyond the Moon and back in December 2017, followed by its first crewed flight in 2021. SLS can evolve to a130-t lift capability and serve as a baseline for numerous robotic and human missions ranging from a Mars sample return to delivering the first astronauts to explore another planet. Benefits associated with its unprecedented mass and volume include reduced trip times and simplified payload design. Every SLS element achieved significant, tangible progress over the past year. Among the Program's many accomplishments are: manufacture of Core Stage test panels; testing of Solid Rocket Booster development hardware including thrust vector controls and avionics; planning for testing the RS-25 Core Stage engine; and more than 4,000 wind tunnel runs to refine vehicle configuration, trajectory, and guidance. The Program shipped its first flight hardware - the Multi-Purpose Crew Vehicle Stage Adapter (MSA) - to the United Launch Alliance for integration with the Delta IV heavy rocket that will launch an Orion test article in 2014 from NASA's Kennedy Space Center. Objectives of this Earth-orbit flight include validating the performance of Orion's heat shield and the MSA design, which will be manufactured again for SLS missions to deep space. The Program successfully completed Preliminary Design Review in 2013 and Key Decision Point C in early 2014. NASA has authorized the Program to move forward to Critical Design Review, scheduled for 2015 and a December 2017 first launch. The Program's success to date is due to prudent use of proven technology, infrastructure, and workforce from the Saturn and Space Shuttle programs, a streamlined management approach, and judicious use of new technologies. The result is a safe, affordable, sustainable, and evolutionary path to development of an unprecedented capability for future missions across the solar system. In an environment of economic challenges, the nationwide SLS team continues to meet ambitious budget and schedule targets. This paper will discuss SLS program and technical accomplishments over the past year and provide a look at the milestones and challenges ahead

Lyles, Garry

Development of the National Aeronautics and Space Administration's (NASA's) Space Launch System (SLS) heavy lift rocket is shifting from the formulation phase into the implementation phase in 2014, a little more than 3 years after formal program establishment. Current development is focused on delivering a vehicle capable of launching 70 metric tons (t) into low Earth orbit. This "Block 1" configuration will launch the Orion Multi-Purpose Crew Vehicle (MPCV) on its first autonomous flight beyond the Moon and back in December 2017, followed by its first crewed flight in 2021. SLS can evolve to a130t lift capability and serve as a baseline for numerous robotic and human missions ranging from a Mars sample return to delivering the first astronauts to explore another planet. Benefits associated with its unprecedented mass and volume include reduced trip times and simplified payload design. Every SLS element achieved significant, tangible progress over the past year. Among the Program's many accomplishments are: manufacture of core stage test barrels and domes; testing of Solid Rocket Booster development hardware including thrust vector controls and avionics; planning for RS- 25 core stage engine testing; and more than 4,000 wind tunnel runs to refine vehicle configuration, trajectory, and guidance. The Program shipped its first flight hardware - the Multi-Purpose Crew Vehicle Stage Adapter (MSA) - to the United Launch Alliance for integration with the Delta IV heavy rocket that will launch an Orion test article in 2014 from NASA's Kennedy Space Center. The Program successfully completed Preliminary Design Review in 2013 and will complete Key Decision Point C in 2014. NASA has authorized the Program to move forward to Critical Design Review, scheduled for 2015 and a December 2017 first launch. The Program's success to date is due to prudent use of proven technology, infrastructure, and workforce from the Saturn and Space Shuttle programs, a streamlined management approach, and judicious use of new technologies. The result is a safe, affordable, sustainable, and evolutionary path to development of an unprecedented capability for future missions across the solar system. In an environment of economic challenges, the nationwide SLS team continues to meet ambitious budget and schedule targets. This paper will discuss SLS Program and technical accomplishments over the past year and provide a look at the milestones and challenges ahead

NASA Technical Reports Server

NASA's Space Launch System Development Status

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Space Launch System Development Status 
Garry Lyles 
SLS Chief Engineer
NASA Marshall Space Flight Center 
Abstract
Development of NASA's Space Launch System (SLS) heavy lift rocket is shifting from 
the formulation phase into the implementation phase in 2014, a little more than three 
years after formal program approval. Current development is focused on delivering a 
vehicle capable of launching 70 metric tons (t) into low Earth orbit. This “Block 1” 
configuration will launch the Orion Multi-Purpose Crew Vehicle (MPCV) on its first 
autonomous flight beyond the Moon and back in December 2017, followed by its first 
crewed flight in 2021. SLS can evolve to a130-t lift capability and serve as a baseline for 
numerous robotic and human missions ranging from a Mars sample return to delivering 
the first astronauts to explore another planet. Benefits associated with its unprecedented 
mass and volume include reduced trip times and simplified payload design. Every SLS 
element achieved significant, tangible progress over the past year. Among the Program’s 
many accomplishments are: manufacture of Core Stage test panels; testing of Solid 
Rocket Booster development hardware including thrust vector controls and avionics; 
planning for testing the RS-25 Core Stage engine; and more than 4,000 wind tunnel runs 
to refine vehicle configuration, trajectory, and guidance. The Program shipped its first 
flight hardware – the Multi-Purpose Crew Vehicle Stage Adapter (MSA) – to the United 
Launch Alliance for integration with the Delta IV heavy rocket that will launch an Orion 
test article in 2014 from NASA’s Kennedy Space Center. Objectives of this Earth-orbit 
flight include validating the performance of Orion’s heat shield and the MSA design, 
which will be manufactured again for SLS missions to deep space. The Program 
successfully completed Preliminary Design Review in 2013 and Key Decision Point C in 
early 2014. NASA has authorized the Program to move forward to Critical Design 
Review, scheduled for 2015 and a December 2017 first launch. The Program’s success to 
date is due to prudent use of proven technology, infrastructure, and workforce from the 
Saturn and Space Shuttle programs, a streamlined management approach, and judicious 
use of new technologies. The result is a safe, affordable, sustainable, and evolutionary 
path to development of an unprecedented capability for future missions across the solar 
system. In an environment of economic challenges, the nationwide SLS team continues to 
meet ambitious budget and schedule targets. This paper will discuss SLS program and 
technical accomplishments over the past year and provide a look at the milestones and 
challenges ahead. 
https://ntrs.nasa.gov/search.jsp?R=20140010911 2019-08-31T19:23:33+00:00Z


Space Launch System Development Status

www.nasa.gov/sls
National Aeronautics and Space Administration
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NASA’s Space Launch System 
Development  Status
Space Propulsion 2014
May 22, 2014 
Garry Lyles, Chief Engineer
Space Launch System
.nasa.gov/sls
https://ntrs.nasa.gov/search.jsp?R=20140010995 2019-08-31T19:28:29+00:00Z
www.nasa.gov/sls
Earth
The Future of Exploration
Moon
239,000 mi
Mars
34,600,000 mi
International
Space Station
220 mi
Curiosity
President Obama’s Accomplishments for NASA
May 22, 2012
The Space Launch System [will] be the backbone of its manned spaceflight program 
for decades. It [will] be the most powerful rocket in NASA’s history…and puts NASA 
on a more sustainable path to continue our tradition of innovative space exploration.
70 t
Lagrangian Point L2
274,000 mi
www nasa gov/sls
Europa
390,400,000 mi
Near-Earth
Asteroid
~3,100,000 mi
www.nasa.gov/sls
SLS Driving Objectives
 Safe
• Human-rated to provide safe and reliable systems
• Protecting the public, NASA workforce, high-value 
equipment and property, and the environment from 
potential harm
 Affordable
• Maximum use of common elements and existing 
assets, infrastructure, and workforce
• Constrained budget environment
• Competitive opportunities for affordability on-ramps
 Sustainable
• Initial capability: 70 metric tons (t), 2017–2021
– Serves as primary transportation for Orion and
human exploration missions
• Evolved capability: 105 t and 130 t, post-2021
 Offers large volume for science missions and payloads
 Reduces trip times to get science results faster
 Minimizes risk of radiation exposure and orbital debris impacts
8395_AIAA_JPC_3
Optimum design for BEO missions of  national importance
www.nasa.gov/sls
Building on the U.S. Infrastructure
Orion, Multi-Purpose 
Crew Vehicle
(MPCV- LMCO)
Core Stage/Avionics
(Boeing)
Core Stage
Engines (RS-25)
(Aerojet Rocketdyne)
5-Segment Solid 
Rocket Booster
(SRB) (ATK)
Interim Cryogenic 
Propulsion Stage (ICPS)
(EELV 5m DCSS –
Boeing/ULA)
Launch Abort System
Upper Stage & Core Stage Commonality
• Same diameter (27.5 ft.) and basic design
• Manufacturing facilities, tooling, materials, & processes/practices
• Workforce
• Supply chain/industry base
• Transportation logistics
• Ground systems/launch infrastructure
• Propellants
Commonality of Core Stage
Commonality of Payload Interfaces
• Mechanical
• Avionics
• Software
Commonality of Engines
Cargo
Fairing
33 ft (10m) 
Upper
Stage
Block 1 
Initial Capability, 2017-21
70 metric ton Payload
Block 2 Capability
130 metric ton 
Payload
Evolutionary Path to Future Capabilities
• Minimizes unique configurations
• Allows incremental development
Advanced
Solid or
Liquid
(i.e., RP 
Engines)
Boosters
8459_SLS_Internal_.4
www.nasa.gov/sls
SLS Core Stage Welding Tools Progress
Building the world’s largest rocket in a state-of-the-art facility.
8548_NAC.5
www.nasa.gov/sls
SLS Avionics Progress
Integrated and powered up hardware, software, and operating 
systems for an inaugural run.
8548_NAC.6
www.nasa.gov/sls
SLS RS-25 Core Stage Engine Progress
Scheduled for summer 2014 at Stennis Space Center.
8548_NAC.7
www.nasa.gov/sls
SLS Booster Progress
Testing upgrades for the solid rocket boosters.
8548_NAC.8
www.nasa.gov/sls
Stages Progress
Launch Vehicle/Stage Adapter (LVSA)
• Manufacturing Contract Award is 
Projected for January 2014
• Critical Design Review Jan. 2015
8478_Marshall_Associati
Interim Cryogenic Propulsion Stage (ICPS)
• Modified Delta IV Upper Stage
• CDR Jan 2015
• Integration at KSC Jan 2017
MPCV/Stage Adapter (MSA)
• Design once, build/fly many times
• Shipped to KSC April 2014 to support 
Exploration Flight Test (EFT) 1 Dec 
2014
• CDR for Exploration Mission (EM)-1 
Jan 2015
www.nasa.gov/sls
SLS Systems Engineering and Integration
Conducted thousands of hours of testing across the country.
8548_NAC.10
www.nasa.gov/sls
SLS Development On Time, Within Budget
www nas MSFC_RSA_Update 
www.nasa.gov/sls
Conclusion
8548_NAC.12
www.nasa.gov/sls
www.facebook.com/nasasls
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