Your search keyword '"In-space propulsion technologies"' showing total 564 results

1. Initial Validation of Robotic Operations for In-Space Assembly of a Large Solar Electric Propulsion Transport Vehicle

Author

John T. Dorsey and Erik Komendera

Subjects

Core set, 020301 aerospace & aeronautics, 0209 industrial biotechnology, Engineering, Spacecraft, Ion thruster, business.industry, In-space propulsion technologies, 02 engineering and technology, Mars Exploration Program, Space exploration, 020901 industrial engineering & automation, 0203 mechanical engineering, Dexterous manipulation, Aerospace engineering, business, Research center

Abstract

Developing a capability for the assembly of large space structures has the potential to increase the capabilities and performance of future space missions and spacecraft while reducing their cost. One such application is a megawatt-class solar electric propulsion (SEP) tug, representing a critical transportation ability for the NASA lunar, Mars, and solar system exploration missions. A series of robotic assembly experiments were recently completed at Langley Research Center (LaRC) that demonstrate most of the assembly steps for the SEP tug concept. The assembly experiments used a core set of robotic capabilities: long-reach manipulation and dexterous manipulation. This paper describes cross-cutting capabilities and technologies for in-space assembly (ISA), applies the ISA approach to a SEP tug, describes the design and development of two assembly demonstration concepts, and summarizes results of two sets of assembly experiments that validate the SEP tug assembly steps.

Published

2017

2. Sensitivity Analysis of Hybrid Propulsion Transportation System for Human Mars Expeditions

Author

Ryan T. Joyce, Min Qu, Patrick Chai, Raymond G. Merrill, and Paul D. Kessler

Subjects

020301 aerospace & aeronautics, Engineering, Ion thruster, Spacecraft propulsion, Payload, business.industry, In-space propulsion technologies, 02 engineering and technology, Mars Exploration Program, Propulsion, 01 natural sciences, 0203 mechanical engineering, Electrically powered spacecraft propulsion, Marine propulsion, 0103 physical sciences, Aerospace engineering, business, 010303 astronomy & astrophysics

Abstract

The National Aeronautics and Space Administration continues to develop and refine various transportation options to successfully field a human Mars campaign. One of these transportation options is the Hybrid Transportation System which utilizes both solar electric propulsion and chemical propulsion. The Hybrid propulsion system utilizes chemical propulsion to perform high thrust maneuvers, where the delta-V is most optimal when ap- plied to save time and to leverage the Oberth effect. It then utilizes solar electric propulsion to augment the chemical burns throughout the interplanetary trajectory. This eliminates the need for the development of two separate vehicles for crew and cargo missions. Previous studies considered single point designs of the architecture, with fixed payload mass and propulsion system performance parameters. As the architecture matures, it is inevitable that the payload mass and the performance of the propulsion system will change. It is desirable to understand how these changes will impact the in-space transportation system's mass and power requirements. This study presents an in-depth sensitivity analysis of the Hybrid crew transportation system to payload mass growth and solar electric propulsion performance. This analysis is used to identify the breakpoints of the current architecture and to inform future architecture and campaign design decisions.

Published

2017

3. The Impact of Mission Duration on a Mars Orbital Mission

Author

Chel Stromgren, Kevin Earle, Bill Cirillo, Melanie L. Grande, Dale C. Arney, Christopher A. Jones, and Jordan Klovstad

Subjects

020301 aerospace & aeronautics, Design analysis, In-space propulsion technologies, In situ resource utilization, 02 engineering and technology, Mars Exploration Program, Exploration of Mars, 01 natural sciences, Space exploration, Astrobiology, Geography, 0203 mechanical engineering, Aeronautics, 0103 physical sciences, Duration (project management), 010303 astronomy & astrophysics

Published

2017

4. In-space Assembly Capability Assessment for Potential Human Exploration and Science Applications

Author

Craig D. Hutchinson, Dale C. Arney, Frederic H. Stillwagen, Patrick Chai, Robert W. Moses, Erica Rodgers, Sean P. Downs, James A. Dempsey, Matthew A. Stafford, Christopher A. Jones, Sharon A. Jefferies, and Henry Kwan

Subjects

Flexibility (engineering), 020301 aerospace & aeronautics, Engineering, Process (engineering), business.industry, In-space propulsion technologies, 02 engineering and technology, Exploration of Mars, 01 natural sciences, 0203 mechanical engineering, Robustness (computer science), 0103 physical sciences, Sustainability, Key (cryptography), Systems engineering, Systems design, business, 010303 astronomy & astrophysics, Simulation

Abstract

Human missions to Mars present several major challenges that must be overcome, including delivering multiple large mass and volume elements, keeping the crew safe and productive, meeting cost constraints, and ensuring a sustainable campaign. Traditional methods for executing human Mars missions minimize or eliminate in-space assembly, which provides a narrow range of options for addressing these challenges and limits the types of missions that can be performed. This paper discusses recent work to evaluate how the inclusion of in-space assembly in space mission architectural concepts could provide novel solutions to address these challenges by increasing operational flexibility, robustness, risk reduction, crew health and safety, and sustainability. A hierarchical framework is presented to characterize assembly strategies, assembly tasks, and the required capabilities to assemble mission systems in space. The framework is used to identify general mission system design considerations and assembly system characteristics by assembly strategy. These general approaches are then applied to identify potential in-space assembly applications to address each challenge. Through this process, several focus areas were identified where applications of in-space assembly could affect multiple challenges. Each focus area was developed to identify functions, potential assembly solutions and operations, key architectural trades, and potential considerations and implications of implementation. This paper helps to identify key areas to investigate were potentially significant gains in addressing the challenges with human missions to Mars may be realized, and creates a foundation on which to further develop and analyze in-space assembly concepts and assembly-based architectures.

Published

2017

5. 150 kW Class Solar Electric Propulsion Spacecraft Power Architecture Model

Author

Benjamin Loop, Jeffrey T. Csank, and Michael V. Aulisio

Subjects

Engineering, Spacecraft propulsion, Electrically powered spacecraft propulsion, Ion thruster, business.industry, Photovoltaic system, Solar vehicle, In-space propulsion technologies, ComputerApplications_COMPUTERSINOTHERSYSTEMS, NASA Deep Space Network, Variable Specific Impulse Magnetoplasma Rocket, Aerospace engineering, business

Abstract

The National Aeronautics and Space Administration (NASA) Solar Electric Propulsion Technology Demonstration Mission (SEP TDM), in conjunction with PC Krause and Associates, has created a Simulink-based power architecture model for a 50 kilo-Watt (kW) solar electric propulsion system. NASA has extended this model to investigate 150 kW solar electric propulsion systems. Increasing the power capability to 150 kW is an intermediate step to the anticipated power requirements for Mars and other deep space applications. The high-power solar electric propulsion capability has been identified as a critical part of NASA’s future beyond-low-Earth-orbit for human-crewed exploration missions. This paper presents four versions of a 150 kW architecture, simulation results, and a discussion of their merits.

Published

2017

6. Solar System Exploration Augmented by In-Situ Resource Utilization: Human Planetary Base Issues for Mercury and Saturn

Author

Bryan A. Palaszewski

Subjects

Physics, 010504 meteorology & atmospheric sciences, Spacecraft, business.industry, In-space propulsion technologies, In situ resource utilization, Propulsion, 010502 geochemistry & geophysics, 01 natural sciences, Space exploration, Astrobiology, Nuclear pulse propulsion, Electrically powered spacecraft propulsion, Enceladus, business, 0105 earth and related environmental sciences

Abstract

Human and robotic missions to Mercury and Saturn are presented and analyzed with a range of propulsion options. Historical studies of space exploration, planetary spacecraft, and astronomy, in-situ resource utilization (ISRU), and industrialization all point to the vastness of natural resources in the solar system. Advanced propulsion benefitted from these resources in many ways. While advanced propulsion systems were proposed in these historical studies, further investigation of nuclear options using high power nuclear thermal and nuclear pulse propulsion as well as advanced chemical propulsion can significantly enhance these scenarios. Updated analyses based on these historical visions are presented. Nuclear thermal propulsion and ISRU enhanced chemical propulsion landers are assessed for Mercury missions. At Saturn, nuclear pulse propulsion with alternate propellant feed systems and Saturn moon exploration with chemical propulsion and nuclear electric propulsion options are discussed. Issues with using in-situ resource utilization on Mercury missions are discussed. At Saturn, the best locations for exploration and the use of the moons Titan and Enceladus as central locations for Saturn moon exploration is assessed.

Published

2017

7. Architecture Sensitivity to Propulsion Choices for Human Mars Missions

Author

Claude R. Joyner, Roger Myers, Matthew R. Long, Timothy S. Kokan, Frederick Widman, James F. Horton, and Daniel J. Levack

Subjects

Engineering, business.industry, In-space propulsion technologies, Sensitivity (control systems), Aerospace engineering, Propulsion, Architecture, business, Exploration of Mars

Published

2016

8. Design and Development of a Methane Cryogenic Propulsion Stage for Human Mars Exploration

Author

Thomas K. Percy, Leslie Alexander, Tara Polsgrove, and Jason Turpin

Subjects

020301 aerospace & aeronautics, Engineering, Ion thruster, business.industry, Mars landing, In-space propulsion technologies, 02 engineering and technology, Mars Exploration Program, Propulsion, Exploration of Mars, 01 natural sciences, 0203 mechanical engineering, Orbit of Mars, 0103 physical sciences, Aerospace engineering, business, Interplanetary spaceflight, 010303 astronomy & astrophysics

Abstract

NASA is currently working on the Evolvabe Mars Campaign (EMC) study to outline transportation and mission options for human exploration of Mars. One of the key aspects of the EMC is leveraging current and planned near-term technology investments to build an affordable and evolvable approach to Mars exploration. This leveraging of investments includes the use of high-power Solar Electric Propulsion (SEP) systems, evolved from those currently under development in support of the Asteroid Redirect Mission (ARM), to deliver payloads to Mars. The EMC is considering several transportation options that combine solar electric and chemical propulsion technologies to deliver crew and cargo to Mars. In one primary architecture option, the SEP propulsion system is used to pre-deploy mission elements to Mars while a high-thrust chemical propulsion system is used to send crew on faster ballistic transfers between Earth and Mars. This high-thrust chemical system uses liquid oxygen - liquid methane main propulsion and reaction control systems integrated into the Methane Cryogenic Propulsion Stage (MCPS). Over the past year, there have been several studies completed to provide critical design and development information related to the MCPS. This paper is intended to provide a summary of these efforts. A summary of the current point of departure design for the MCPS is provided as well as an overview of the mission architecture and concept of operations that the MCPS is intended to support. To leverage the capabilities of solar electric propulsion to the greatest extent possible, the EMC architecture pre-deploys to Mars orbit the stages required for returning crew from Mars. While this changes the risk posture of the architecture, it can provide some mass savings by using higher-efficiency systems for interplanetary transfer. However, this does introduce significantly longer flight times to Mars which, in turn, increases the overall lifetime of the stages to as long as 2500 days. This unique aspect to the concept of operations introduces several challenges, specifically related to propellant storage and engine reliability. These challenges and some potential solutions are discussed. Specific focus is provided on two key technology areas; propulsion and cryogenic fluid management. In the area of propulsion development, the development of an integrated methane propulsion system that combines both main propulsion and reaction control is discussed. This includes an overview of potential development paths, areas where development for Mars applications are complementary to development efforts underway in other parts of the aerospace industry, and commonality between the MCPS methane propulsion applications and other Mars elements, including the Mars lander systems. This commonality is a key affordability aspect of the Evolvable Mars Campaign. A similar discussion is provided for cryogenic fluid management technologies including a discussion of how using cryo propulsion in the Mars transportation application not only provides performance benefits but also leverages decades of technology development investments made by NASA and its aerospace contractor community.

Published

2016

9. Commercial Options for Hybrid Chemical/Electric Propulsion Transportation System to Support Mars Exploration

Author

Jordan Klovstad, Kevin Larman, Dale C. Arney, Christopher A. Jones, and Patrick Chai

Subjects

020301 aerospace & aeronautics, Engineering, Petroleum engineering, business.industry, In-space propulsion technologies, 02 engineering and technology, Exploration of Mars, 01 natural sciences, 0203 mechanical engineering, Electrically powered spacecraft propulsion, 0103 physical sciences, Aerospace engineering, business, 010303 astronomy & astrophysics

Published

2016

10. Overview of Iodine Propellant Hall Thruster Development Activities at NASA Glenn Research Center

Author

Tyler A. Hickman, Kurt A. Polzin, John Dankanich, Timothy B. Smith, Gabriel F. Benavides, Thomas W. Haag, Hani Kamhawi, Lauren P. Lee, Lawrence Byrne, James Szabo, James L. Myers, and George J. Williams

Subjects

Propellant, 020301 aerospace & aeronautics, Engineering, Busek, business.industry, In-space propulsion technologies, 02 engineering and technology, Propulsion, 01 natural sciences, Electrostatic ion thruster, 010305 fluids & plasmas, Hall effect thruster, 0203 mechanical engineering, Electrically powered spacecraft propulsion, Aeronautics, 0103 physical sciences, Aerospace engineering, business, Research center

Abstract

NASA is continuing to invest in advancing Hall thruster technologies for implementation in commercial and government missions. There have been several recent iodine Hall propulsion system development activities performed by the team of the NASA Glenn Research Center, the NASA Marshall Space Flight Center, and Busek Co. Inc. In particular, the work focused on qualification of the 200 W Busek BHT-200-I and the continued development of the 600 W BHT-600-I Hall thruster propulsion systems. This paper presents an overview of these development activities and also reports on the results of short duration tests that were performed on the engineering model BHT-200-I and the development model BHT-600-I Hall thrusters.

Published

2016

11. Plasma Oscillation Characterization of NASA’s HERMeS Hall Thruster via High Speed Imaging

Author

Thomas W. Haag, Hani Kamhawi, and Wensheng Huang

Subjects

Physics, 020301 aerospace & aeronautics, Space technology, Ion thruster, Spacecraft, business.industry, In-space propulsion technologies, ComputerApplications_COMPUTERSINOTHERSYSTEMS, 02 engineering and technology, Mars Exploration Program, Propulsion, 01 natural sciences, 010305 fluids & plasmas, 0203 mechanical engineering, Electrically powered spacecraft propulsion, 0103 physical sciences, Specific impulse, Aerospace engineering, business

Abstract

For missions beyond low Earth orbit, spacecraft size and mass can be dominated by onboard chemical propulsion systems and propellants that may constitute more than 50 percent of the spacecraft mass. This impact can be substantially reduced through the utilization of Solar Electric Propulsion (SEP) due to its substantially higher specific impulse. Studies performed for NASA's Human Exploration and Operations Mission Directorate and Science Mission Directorate have demonstrated that a 50kW-class SEP capability can be enabling for both near term and future architectures and science missions. A high-power SEP element is integral to the Evolvable Mars Campaign, which presents an approach to establish an affordable evolutionary human exploration architecture. To enable SEP missions at the power levels required for these applications, an in-space demonstration of an operational 50kW-class SEP spacecraft has been proposed as a SEP Technology Demonstration Mission (TDM). In 2010 NASA's Space Technology Mission Directorate (STMD) began developing high-power electric propulsion technologies. The maturation of these critical technologies has made mission concepts utilizing high-power SEP viable.

Published

2016

12. Propulsion Estimates for High Energy Lunar Missions Using Future Propellants

Author

Bryan A. Palaszewski and Gary L. Bennett

Subjects

Propellant, Engineering, Fission-fragment rocket, Spacecraft propulsion, business.industry, Liquid-propellant rocket, Laser propulsion, In-space propulsion technologies, Rocket engine, Specific impulse, Aerospace engineering, business

Abstract

High energy propellants for human lunar missions are analyzed, focusing on very advanced ozone and atomic hydrogen. One of the most advanced launch vehicle propulsion systems, such as the Space Shuttle Main Engine (SSME), used hydrogen and oxygen and had a delivered specific impulse of 453 seconds. In the early days of the space program, other propellants (or so called metapropellants) were suggested, including atomic hydrogen and liquid ozone. Theoretical and experimental studies of atomic hydrogen and ozone were conducted beginning in the late 1940s. This propellant research may have provided screenwriters with the idea of an atomic hydrogen-ozone rocket engine in the 1950 movie, Rocketship X-M. This paper presents analyses showing that an atomic hydrogen-ozone rocket engine could produce a specific impulse over a wide range of specific impulse values reaching as high as 1,600 s. A series of single stage and multistage rocket vehicle analyses were conducted to find the minimum specific impulse needed to conduct high energy round trip lunar missions.

Published

2016

13. The Ion Propulsion System for the Asteroid Redirect Robotic Mission

Author

Walter Santiago, James E. Polk, Michael J. Sekerak, Richard R. Hofer, Hani Kamhawi, John Steven Snyder, and Daniel A. Herman

Subjects

020301 aerospace & aeronautics, Engineering, Space technology, Spacecraft, Ion thruster, business.industry, Photovoltaic system, In-space propulsion technologies, Rendezvous, ComputerApplications_COMPUTERSINOTHERSYSTEMS, 02 engineering and technology, 01 natural sciences, 010305 fluids & plasmas, 0203 mechanical engineering, Electrically powered spacecraft propulsion, Conceptual design, 0103 physical sciences, Aerospace engineering, business

Abstract

The Asteroid Redirect Robotic Mission is a Solar Electric Propulsion Technology Demonstration Mission (ARRM) whose main objectives are to develop and demonstrate a high-power solar electric propulsion capability for the Agency and return an asteroidal mass for rendezvous and characterization in a companion human-crewed mission. This high-power solar electric propulsion capability, or an extensible derivative of it, has been identified as a critical part of NASA'a future beyond-low-Earth-orbit, human-crewed exploration plans. Under the NASA Space Technology Mission Directorate the critical electric propulsion and solar array technologies are being developed. This paper presents the conceptual design of the ARRM ion propulsion system, the status of the NASA in-house thruster and power processing development activities, the status of the planned technology maturation for the mission through flight hardware delivery, and the status of the mission formulation and spacecraft acquisition.

Published

2016

14. Solar System Exploration Augmented by In-Situ Resource Utilization: Mercury and Saturn Propulsion Investigations

Author

Bryan A. Palaszewski

Subjects

Engineering, 010504 meteorology & atmospheric sciences, Spacecraft propulsion, business.industry, In-space propulsion technologies, In situ resource utilization, Nuclear power, Propulsion, 010502 geochemistry & geophysics, 01 natural sciences, Space exploration, Nuclear pulse propulsion, Marine propulsion, Aerospace engineering, business, 0105 earth and related environmental sciences

Abstract

Human and robotic missions to Mercury and Saturn are presented and analyzed with a range of propulsion options. Historical studies of space exploration, in-situ resource utilization (ISRU), and industrialization all point to the vastness of natural resources in the solar system. Advanced propulsion benefitted from these resources in many ways. While advanced propulsion systems were proposed in these historical studies, further investigation of nuclear options using high power nuclear thermal and nuclear pulse propulsion as well as advanced chemical propulsion can significantly enhance these scenarios. Updated analyses based on these historical visions will be presented. Nuclear thermal propulsion and ISRU enhanced chemical propulsion landers are assessed for Mercury missions. At Saturn, nuclear pulse propulsion with alternate propellant feed systems and Titan exploration with chemical propulsion options are discussed. In-situ resource utilization was found to be critical in making Mercury missions more amenable for human visits. At Saturn, refueling using local atmospheric mining was found to be difficult to impractical, while refueling the Saturn missions from Uranus was more practical and less complex.

Published

2016

15. Dual Propulsion System Design for Small Spacecraft

Author

Priya Malani, Narayanam G. Navya, Priyank Putambekar, Poorva Shrivastava, Kartik P. Naik, Akash Ratheesh, Loganathan Muthuswamy, and Jananee Dhanasekaran

Subjects

021110 strategic, defence & security studies, Unmanned spacecraft, Spacecraft propulsion, Spacecraft, business.industry, 0211 other engineering and technologies, In-space propulsion technologies, 02 engineering and technology, Propulsion, Spacecraft design, Dual (category theory), Electrically powered spacecraft propulsion, Environmental science, Aerospace engineering, business

Published

2016

16. Mars Hybrid Propulsion System Trajectory Analysis, Part I: Crew Missions

Author

Min Qu, Raymond G. Merrill, and Patrick Chai

Subjects

Martian, Engineering, Spacecraft propulsion, business.industry, Payload, Human spaceflight, In-space propulsion technologies, Mars Exploration Program, Aerospace engineering, Propulsion, business, Exploration of Mars

Abstract

NASAs Human spaceflight Architecture Team team is developing a reusable hybrid transportation architecture in which both chemical and electric propulsion systems are used to send crew and cargo to Mars destinations such as Phobos, Deimos, the surface of Mars, and other orbits around Mars. By combining chemical and electrical propulsion into a single spaceship and applying each where it is more effective, the hybrid architecture enables a series of Mars trajectories that are more fuel-efficient than an all chemical architecture without significant increases in flight times. This paper shows the feasibility of the hybrid transportation architecture to pre-deploy cargo to Mars and Phobos in support of the Evolvable Mars Campaign crew missions. The analysis shows that the hybrid propulsion stage is able to deliver all of the current manifested payload to Phobos and Mars through the first three crew missions. The conjunction class trajectory also allows the hybrid propulsion stage to return to Earth in a timely fashion so it can be reused for additional cargo deployment. The 1,100 days total trip time allows the hybrid propulsion stage to deliver cargo to Mars every other Earth-Mars transit opportunity. For the first two Mars surface mission in the Evolvable Mars Campaign, the short trip time allows the hybrid propulsion stage to be reused for three round-trip journeys to Mars, which matches the hybrid propulsion stage’s designed lifetime for three round-trip crew missions to the Martian sphere of influence.

Published

2015

17. An Integrated Hybrid Transportation Architecture for Human Mars Expeditions

Author

Raymond G. Merrill, Patrick Chai, Christopher A. Jones, D.R. Komar, and Min Qu

Subjects

Engineering, Electrically powered spacecraft propulsion, Conceptual design, business.industry, Human spaceflight, In-space propulsion technologies, ComputerApplications_COMPUTERSINOTHERSYSTEMS, Mars Exploration Program, Aerospace engineering, Propulsion, Architecture, business, Critical path method

Abstract

NASA's Human Spaceflight Architecture Team is developing a reusable hybrid transportation architecture that uses both chemical and electric propulsion systems on the same vehicle to send crew and cargo to Mars destinations such as Phobos, Deimos, the surface of Mars, and other orbits around Mars. By applying chemical and electrical propulsion where each is most effective, the hybrid architecture enables a series of Mars trajectories that are more fuel-efficient than an all chemical architecture without significant increases in flight times. This paper presents an integrated Hybrid in-space transportation architecture for piloted missions and delivery of cargo. A concept for a Mars campaign including orbital and Mars surface missions is described in detail including a system concept of operations and conceptual design. Specific constraints, margin, and pinch points are identified for the architecture and opportunities for critical path commercial and international collaboration are discussed.

Published

2015

18. Mars Ascent Vehicle Design for Human Exploration

Author

Tara Polsgrove, Michelle A. Rucker, Walter Stephens, Dan Thomas, and Steven Sutherlin

Subjects

Propellant, Engineering, Design analysis, Conceptual design, Ion thruster, business.industry, In-space propulsion technologies, ComputerApplications_COMPUTERSINOTHERSYSTEMS, Mars Exploration Program, Propulsion, Aerospace engineering, business, Exploration of Mars

Abstract

In NASA's evolvable Mars campaign, transportation architectures for human missions to Mars rely on a combination of solar electric propulsion and chemical propulsion systems. Minimizing the Mars ascent vehicle (MAV) mass is critical in reducing the overall lander mass and also eases the requirements placed on the transportation stages. This paper presents the results of a conceptual design study to obtain a minimal MAV configuration, including subsystem designs and mass summaries.

Published

2015

19. Solar Electric Propulsion Architecture for Mars Cargo for Affordable Exploration and Sustained Permanence

Author

Roger Myers, Claude R. Joyner, Timothy S. Kokan, Daniel J. Levack, and Joseph Cassady

Subjects

Engineering, Expendable launch system, Spacecraft, Aeronautics, Ion thruster, business.industry, Payload, In-space propulsion technologies, Mars Exploration Program, business, Exploration of Mars, Launch window

Abstract

Future exploration missions throughout the Solar System will require high efficiency propulsion technologies using moderate spacecraft power that are extensible to multiple mission areas and customers. Solar Electric Propulsion (SEP) has been proven at various power levels and propulsion unit design types and should be part of such a technology portfolio. Many of the SEP thrusters used for recent missions have established the high Technology Readiness Level for this technology. SEP’s high specific impulse (ISP) has a dramatic impact on reducing the required spacecraft propellant while increasing launch window flexibility, making the propulsion technology an ideal choice for delivering large unmanned cargo payloads for sustaining human Mars exploration. The future of human Mars exploration will see substantial benefit in terms of lower mission mass when SEP systems are employed in the architecture. It must be remembered that key design parameters (e.g., power, ISP, specific mass) need to be optimized in order to effectively deliver the highest payload mass possible within a given program. Architectures that have the local planetary exploration elements pre-deployed ahead of the human crew can have a significant impact on the design of the human exploration mission in terms of total mass available at Mars, the size of the crew spacecraft, and the number of total systems employed to create low risk transportation. This paper will discuss a recent Aerojet Rocketdyne (AR) study that examines the impact of SEP power levels, ISP, and stage size required for large (20+mt) cargo prepositioning missions to Mars orbit. The study also examines the impact on the crew vehicle size when different combinations of architecture elements are pre-positioned. The AR analysis has focused on finding the combination of right size launch capability and SEP vehicle power level that delivers large cargo but maintains reasonable trip times for pre-positioning. For near-term missions, we show that 50kWe SEP modules can be used either singly or in combination, enabling a path to lower cost human exploration missions. An approach that uses 40-50kWe SEP modules creates mission extensibility where these modules can also be used for cis-lunar missions and large science missions such as the Asteroid Redirect mission and geosynchronous Earth orbit commercial and military satellite delivery missions launched on existing expendable launch vehicles ensuring that the SEP modules have multiple applications. We show that this modular approach enables a dramatic reduction in total development and production costs for high power SEP and provides for a more gradual phasing of system development to fit within available budgets. 1 Fellow, Space Systems and Mission Analysis, PO Box 109680, M/S 712-67, AIAA Associate Fellow. 2 Executive Director, Space, 1300 Wilson Blvd., AIAA Associate Fellow. 3 Sr. Engineer, Mission Architecture, 555 Discovery Dr., AIAA Member. 4 Sr. Manager, Advanced Space and Launch, P.O. Box 7922 / MS RFB19, AIAA Member. 5 Executive Director, Advanced Space and Launch, 11411 139 Place, AIAA Fellow.

Published

2015

20. Solar Electric Propulsion Concepts for Human Space Exploration

Author

Carolyn R. Mercer, Michael J. Barrett, Steven R. Oleson, and Melissa L. McGuire

Subjects

Engineering, Electrically powered spacecraft propulsion, Ion thruster, business.industry, Photovoltaic system, In-space propulsion technologies, Cargo spacecraft, Aerospace engineering, Propulsion, Space Transportation System, business, Space exploration

Abstract

Advances in solar array and electric thruster technologies now offer the promise of new, very capable space transportation systems that will allow us to cost effectively explore the solar system. NASA has developed numerous solar electric propulsion spacecraft concepts with power levels ranging from tens to hundreds of kilowatts for robotic and piloted missions to asteroids and Mars. This paper describes nine electric and hybrid solar electric/chemical propulsion concepts developed over the last 5 years and discusses how they might be used for human exploration of the inner solar system.

Published

2015

21. Viability of a Reusable In-Space Transportation System

Author

Brian Nufer, John G. Martin, Sharon A. Jefferies, Roger A. Lepsch, Carey M. McCleskey, David R. Komar, David D. North, and Raymond G. Merrill

Subjects

Engineering, Spacecraft, business.industry, In-space propulsion technologies, ComputerApplications_COMPUTERSINOTHERSYSTEMS, Mars Exploration Program, Parking orbit, Reuse, Concept of operations, Systems engineering, Aerospace engineering, Space Transportation System, business, Reusability

Abstract

The National Aeronautics and Space Administration (NASA) is currently developing options for an Evolvable Mars Campaign (EMC) that expands human presence from Low Earth Orbit (LEO) into the solar system and to the surface of Mars. The Hybrid in-space transportation architecture is one option being investigated within the EMC. The architecture enables return of the entire in-space propulsion stage and habitat to cis-lunar space after a round trip to Mars. This concept of operations opens the door for a fully reusable Mars transportation system from cis-lunar space to a Mars parking orbit and back. This paper explores the reuse of in-space transportation systems, with a focus on the propulsion systems. It begins by examining why reusability should be pursued and defines reusability in space-flight context. A range of functions and enablers associated with preparing a system for reuse are identified and a vision for reusability is proposed that can be advanced and implemented as new capabilities are developed. Following this, past reusable spacecraft and servicing capabilities, as well as those currently in development are discussed. Using the Hybrid transportation architecture as an example, an assessment of the degree of reusability that can be incorporated into the architecture with current capabilities is provided and areas for development are identified that will enable greater levels of reuse in the future. Implications and implementation challenges specific to the architecture are also presented.

Published

2015

22. A Conceptual Mars Exploration Vehicle Architecture with Chemical Propulsion, Near-Term Technology, and High Modularity to Enable Near-Term Human Missions to Mars

Author

Mark G. Benton

Subjects

Engineering, Modularity (networks), business.industry, In-space propulsion technologies, Propulsion, Aerospace engineering, Architecture, business, Exploration of Mars, Term (time)

Published

2015

23. GPIM AF-M315E Propulsion System

Author

Ronald A. Spores, Robert K. Masse, Christopher H. McLean, and Scott Kimbrel

Subjects

Propellant, Space technology, Engineering, business.industry, Payload, Range (aeronautics), In-space propulsion technologies, Systems design, Aerospace engineering, Propulsion, business

Abstract

The NASA Space Technology mission Directorate's (STMD) Green Propellant Infusion Mission (GPIM) Technology Demonstration Mission (TDM) will demonstrate an operational AF-M315E green propellant propulsion system. Aerojet-Rocketdyne is responsible for the development of the propulsion system payload. This paper statuses the propulsion system module development, including thruster design and system design; Initial test results for the 1N engineering model thruster are presented. The culmination of this program will be high-performance, green AF-M315E propulsion system technology at TRL 7+, with components demonstrated to TRL 9, ready for direct infusion to a wide range of applications for the space user community.

Published

2015

24. NASA Propulsion Sub-System Concept Studies and Risk Reduction Activities for Resource Prospector Lander

Author

Huu P. Trinh

Subjects

Cost reduction, Engineering, business.industry, In-space propulsion technologies, Space Shuttle, Liquid rocket propellants, Thrust, Mars Exploration Program, Aerospace engineering, Propulsion, business, Exploration of Mars

Abstract

NASA's exploration roadmap is focused on developing technologies and performing precursor missions to advance the state of the art for eventual human missions to Mars. One of the key components of this roadmap is various robotic missions to Near-Earth Objects, the Moon, and Mars to fill in some of the strategic knowledge gaps. The Resource Prospector (RP) project is one of these robotic precursor activities in the roadmap. RP is a multi-center and multi-institution project to investigate the polar regions of the Moon in search of volatiles. The mission is rated Class D and is approximately 10 days, assuming a five day direct Earth to Moon transfer. Because of the mission cost constraint, a trade study of the propulsion concepts was conducted with a focus on available low-cost hardware for reducing cost in development, while technical risk, system mass, and technology advancement requirements were also taken into consideration. The propulsion system for the lander is composed of a braking stage providing a high thrust to match the lander's velocity with the lunar surface and a lander stage performing the final lunar descent. For the braking stage, liquid oxygen (LOX) and liquid methane (LCH4) propulsion systems, derived from the Morpheus experimental lander, and storable bi-propellant systems, including the 4th stage Peacekeeper (PK) propulsion components and Space Shuttle orbital maneuvering engine (OME), and a solid motor were considered for the study. For the lander stage, the trade study included miniaturized Divert Attitude Control System (DACS) thrusters (Missile Defense Agency (MDA) heritage), their enhanced thruster versions, ISE-100 and ISE-5, and commercial-off-the-shelf (COTS) hardware. The lowest cost configuration of using the solid motor and the PK components while meeting the requirements was selected. The reference concept of the lander is shown in Figure 1. In the current reference configuration, the solid stage is the primary provider of delta-V. It will generate 15,000-lbf of thrust with a single burn of ~ 80's seconds. The lander stage is a bi-propellant, pressure-regulated, pulsing liquid propulsion system to perform all other functions.

Published

2015

25. The NASA Advanced Exploration Systems Nuclear Thermal Propulsion Project

Author

Tony Kim, John Scott, Anthony Belvin, William J. Emrich, Steven Clement, Stanley K. Borowski, Doyce P. Mitchell, Glen Doughty, Michael G. Houts, Kevin P. Power, Robert Hickman, and Harold P. Gerrish

Subjects

Engineering, business.industry, Aviation, New product development, In-space propulsion technologies, Specific impulse, Aerospace engineering, Technology assessment, Nuclear propulsion, Propulsion, business, Space exploration

Abstract

The fundamental capability of Nuclear Thermal Propulsion (NTP) is game changing for space exploration. A first generation NTP system could provide high thrust at a specific impulse (Isp) above 900 s, roughly double that of state of the art chemical engines. Characteristics of fission and NTP indicate that useful first generation systems will provide a foundation for future systems with extremely high performance. The role of a first generation NTP in the development of advanced nuclear propulsion systems could be analogous to the role of the DC-3 in the development of advanced aviation systems.

Published

2015

26. Cryogenic Fluid Management Technology Development for Nuclear Thermal Propulsion

Author

Jonathan Stephens, Brian Taylor, Ali Hedayat, Robert Polsgrove, and Jarvis Caffrey

Subjects

Propellant, Engineering, Temperature control, business.industry, In-space propulsion technologies, NASA Deep Space Network, Technology assessment, Nuclear propulsion, Propulsion, Aerospace engineering, business, Space exploration

Abstract

The purpose of this paper is to investigate, facilitate a discussion and determine a path forward for technology development of cryogenic fluid management technology that is necessary for long duration deep space missions utilizing nuclear thermal propulsion systems. There are a number of challenges in managing cryogenic liquids that must be addressed before long durations missions into deep space, such as a trip to Mars can be successful. The leakage rate of hydrogen from pressure vessels, seals, lines and valves is a critical factor that must be controlled and minimized. For long duration missions, hydrogen leakage amounts to large increases in hydrogen and therefore vehicle mass. The size of a deep space vehicle, such as a mars transfer vehicle, must be kept small to control cost and the logistics of a multi launch, assembled in orbit vehicle. The boil off control of the cryogenic fluid is an additional obstacle to long duration missions. The boil off caused by heat absorption results in the growth of the propellant needs of the vehicle and therefore vehicle mass. This is a significant problem for a vehicle using nuclear (fission) propulsion systems. Radiation from the engines deposits large quantities of heat into the cryogenic fluid, greatly increasing boil off beyond that caused by environmental heat leakage. Addressing and resolving these challenges is critical to successful long duration space exploration. This paper discusses the state of the technology needed to address these challenges and discuss the path forward needed in technology development.

Published

2015

27. Performance Characterisation of a Hybrid Propulsion System for Cubesat Missions

Author

Aaron Knoll and O Ahmed

Subjects

Engineering, business.industry, In-space propulsion technologies, CubeSat, Aerospace engineering, business, Hybrid propulsion

Published

2015

28. Advanced Concept of the Space Electric Power System Integrated with the Propulsion

Author

Shunichi Okaya

Subjects

Electric power system, Engineering, business.industry, In-space propulsion technologies, Aerospace engineering, Propulsion, Space (mathematics), business

Published

2015

29. Solar System Exploration Augmented by In-Situ Resource Utilization: Human Mercury and Saturn Exploration

Author

Bryan A. Palaszewski

Subjects

Propellant, business.industry, In-space propulsion technologies, In situ resource utilization, Propulsion, Space exploration, Nuclear pulse propulsion, Astrobiology, symbols.namesake, Geography, symbols, Nuclear propulsion, Aerospace engineering, business, Titan (rocket family)

Abstract

Human and robotic missions to Mercury and Saturn are presented and analyzed. Unique elements of the local planetary environments are discussed and included in the analyses and assessments. Using historical studies of space exploration, in-situ resource utilization (ISRU), and industrialization all point to the vastness of natural resources in the solar system. Advanced propulsion benefitted from these resources in many way. While advanced propulsion systems were proposed in these historical studies, further investigation of nuclear options using high power nuclear thermal and nuclear pulse propulsion as well as advanced chemical propulsion can significantly enhance these scenarios. Updated analyses based on these historical visions will be presented. Nuclear thermal propulsion and ISRU enhanced chemical propulsion landers are assessed for Mercury missions. At Saturn, nuclear pulse propulsion with alternate propellant feed systems and Titan exploration with chemical propulsion options are discussed.

Published

2015

30. Benefits of Nuclear Electric Propulsion for the NASA Human Exploration of Mars Design Reference Architecture 5.0

Author

William C. Strobl, Richard P. Hora, and James Mildice

Subjects

Engineering, Electrically powered spacecraft propulsion, business.industry, In-space propulsion technologies, Mars Exploration Program, Reference architecture, Aerospace engineering, business

Published

2014

31. On the Design of Power and Propulsion Subsystems of All-Electric Telecommunication Satellites

Author

Atri Dutta, Alex Foster, Suwat Sreesawet, and Sainath Vijayan

Subjects

Engineering, Spacecraft, business.industry, Photovoltaic system, In-space propulsion technologies, Propulsion, Power budget, symbols.namesake, Van Allen radiation belt, Physics::Space Physics, Geostationary orbit, symbols, Astrophysics::Earth and Planetary Astrophysics, Aerospace engineering, Orbital maneuver, business, Telecommunications

Abstract

High power budget of telecommunication spacecraft can potentially allow the operation of multiple electric thrusters simultaneously during an orbital transfer to the Geostationary Earth orbit. In this paper, we consider the problem of electric orbit-raising during which the spacecraft uses more than one thruster type during the transfer. We develop a methodology to determine trajectories from arbitrary starting orbits to the GEO for the case when two different thruster types are used during the maneuver. We also develop a framework to analyze the solar array degradation caused by protons in the Van Allen radiation belts during orbit-raising. We demonstrate our methodology with the help of numerical examples that evaluate the trade-offs associated with using arcjets during the initial part of the transfer. We consider different cases of switching from arcjets to Hall thrusters during the maneuver and evaluate the requirements on shielding thickness in order to limit the radiation exposure for representative orbit-raising trajectories.

Published

2014

32. Habitat Concepts for Deep Space Exploration

Author

Brand N. Griffin and David Smitherman

Subjects

Geography, Deep space exploration, business.industry, International Space Station, In-space propulsion technologies, Space Launch System, Mars Exploration Program, NASA Deep Space Network, Aerospace engineering, Exploration of Mars, business, Space exploration, Remote sensing

Abstract

Future missions under consideration requiring human habitation beyond the International Space Station (ISS) include deep space habitats in the lunar vicinity to support asteroid retrieval missions, human and robotic lunar missions, satellite servicing, and Mars vehicle servicing missions. Habitat designs are also under consideration for missions beyond the Earth-Moon system, including transfers to near-Earth asteroids and Mars orbital destinations. A variety of habitat layouts have been considered, including those derived from the existing ISS designs and those that could be fabricated from the Space Launch System (SLS) propellant tanks. This paper presents a comparison showing several options for asteroid, lunar, and Mars mission habitats using ISS derived and SLS derived modules and identifies some of the advantages and disadvantages inherent in each. Key findings indicate that the larger SLS diameter modules offer built-in compatibility with the launch vehicle, single launch capability without on-orbit assembly, improved radiation protection, lighter structures per unit volume, and sufficient volume to accommodate consumables for long duration missions without resupply. The information provided with the findings includes mass and volume comparison data that should be helpful to future exploration mission planning efforts.

Published

2014

33. High-Power Solar Electric Propulsion for Future NASA Missions

Author

Kurt J. Hack and David H. Manzella

Subjects

Engineering, Spacecraft propulsion, Ion thruster, Electrically powered spacecraft propulsion, business.industry, Photovoltaic system, In-space propulsion technologies, Space Shuttle, ComputerApplications_COMPUTERSINOTHERSYSTEMS, NASA Deep Space Network, Aerospace engineering, business, Space exploration

Abstract

NASA has sought to utilize high-power solar electric propulsion as means of improving the affordability of in-space transportation for almost 50 years. Early efforts focused on 25 to 50 kilowatt systems that could be used with the Space Shuttle, while later efforts focused on systems nearly an order of magnitude higher power that could be used with heavy lift launch vehicles. These efforts never left the concept development phase in part because the technology required was not sufficiently mature. Since 2012 the NASA Space Technology Mission Directorate has had a coordinated plan to mature the requisite solar array and electric propulsion technology needed to implement a 30 to 50 kilowatt solar electric propulsion technology demonstration mission. Multiple solar electric propulsion technology demonstration mission concepts have been developed based on these maturing technologies with recent efforts focusing on an Asteroid Redirect Robotic Mission. If implemented, the Asteroid Redirect Vehicle will form the basis for a capability that can be cost-effectively evolved over time to provide solar electric propulsion transportation for a range of follow-on mission applications at power levels in excess of 100 kilowatts.

Published

2014

34. A High Power Solar Electric Propulsion - Chemical Mission for Human Exploration of Mars

Author

Laura M. Burke, Steven R. Oleson, and Michael C. Martini

Subjects

Physics, Ion thruster, Electrically powered spacecraft propulsion, Spacecraft propulsion, business.industry, In-space propulsion technologies, Mars Exploration Program, Aerospace engineering, Exploration of Mars, Orbit insertion, business, Interplanetary spaceflight

Abstract

Recently Solar Electric Propulsion (SEP) as a main propulsion system has been investigated as an option to support manned space missions to near-Earth destinations for the NASA Gateway spacecraft. High efficiency SEP systems are able to reduce the amount of propellant long duration chemical missions require, ultimately reducing the required mass delivered to Low Earth Orbit (LEO) by a launch vehicle. However, for long duration interplanetary Mars missions, using SEP as the sole propulsion source alone may not be feasible due to the long trip times to reach and insert into the destination orbit. By combining an SEP propulsion system with a chemical propulsion system the mission is able to utilize the high-efficiency SEP for sustained vehicle acceleration and deceleration in heliocentric space and the chemical system for orbit insertion maneuvers and trans-earth injection, eliminating the need for long duration spirals. By capturing chemically instead of with low-thrust SEP, Mars stay time increases by nearly 200 days. Additionally, the size the of chemical propulsion system can be significantly reduced from that of a standard Mars mission because the SEP system greatly decreases the Mars arrival and departure hyperbolic excess velocities (V(sub infinity)).

Published

2014

35. Plume Impingement Analysis for the European Service Module Propulsion System

Author

Nicola Lerardo, John T. Yim, and Fabien Sibe

Subjects

Service module, Engineering, Heat flux, Spacecraft propulsion, business.industry, Photovoltaic system, In-space propulsion technologies, Aerospace engineering, Orbital maneuver, Propulsion, Reaction control system, business, Marine engineering

Abstract

Plume impingement analyses were performed for the European Service Module (ESM) propulsion system Orbital Maneuvering System engine (OMS-E), auxiliary engines, and reaction control system (RCS) engines. The heat flux from plume impingement on the solar arrays and other surfaces are evaluated. This information is used to provide inputs for the ESM thermal analyses and help determine the optimal configuration for the RCS engines.

Published

2014

36. A Crewed Mission to Apophis Using a Hybrid Bimodal Nuclear Thermal Electric Propulsion (BNTEP) System

Author

Thomas W. Packard, David R. McCurdy, Laura M. Burke, and Stanley K. Borowski

Subjects

Engineering, Electrically powered spacecraft propulsion, Ion thruster, business.industry, Nuclear thermal rocket, Laser propulsion, In-space propulsion technologies, Specific impulse, Variable Specific Impulse Magnetoplasma Rocket, Aerospace engineering, Propulsion, business

Abstract

A BNTEP system is a dual propellant, hybrid propulsion concept that utilizes Bimodal Nuclear Thermal Rocket (BNTR) propulsion during high thrust operations, providing 10's of kilo-Newtons of thrust per engine at a high specific impulse (Isp) of 900 s, and an Electric Propulsion (EP) system during low thrust operations at even higher Isp of around 3000 s. Electrical power for the EP system is provided by the BNTR engines in combination with a Brayton Power Conversion (BPC) closed loop system, which can provide electrical power on the order of 100's of kWe. High thrust BNTR operation uses liquid hydrogen (LH2) as reactor coolant propellant expelled out a nozzle, while low thrust EP uses high pressure xenon expelled by an electric grid. By utilizing an optimized combination of low and high thrust propulsion, significant mass savings over a conventional NTR vehicle can be realized. Low thrust mission events, such as midcourse corrections (MCC), tank settling burns, some reaction control system (RCS) burns, and even a small portion at the end of the departure burn can be performed with EP. Crewed and robotic deep space missions to a near Earth asteroid (NEA) are best suited for this hybrid propulsion approach. For these mission scenarios, the Earth return V is typically small enough that EP alone is sufficient. A crewed mission to the NEA Apophis in the year 2028 with an expendable BNTEP transfer vehicle is presented. Assembly operations, launch element masses, and other key characteristics of the vehicle are described. A comparison with a conventional NTR vehicle performing the same mission is also provided. Finally, reusability of the BNTEP transfer vehicle is explored.

Published

2014

37. An Overview of the Concept of Operations for Assembly, Integration, Testing and Ground Servicing Developed for the MPCV-ESM Propulsion System

Author

Matthew C. Bielozer

Subjects

Engineering, Service module, Aeronautics, Integration testing, Adapter (computing), business.industry, Crew, In-space propulsion technologies, Propulsion, Space Shuttle Orbital Maneuvering System, business, Concept of operations

Abstract

A concept of operations for the Assembly, Integration and Testing (AIT) and the Ground Systems Development Operations (GSDO) of the European Service Module (ESM) propulsion system has been developed. The AIT concept of operations covers all fabrication, integration and testing activities in both Europe and in the United States. The GSDO Program develops the facilities, equipment, and procedures for the loading of hypergolic propellants, the filling of high-pressure gases, and contingency de-servicing operations for the ESM. NASA and ESA along with the Lockheed Martin and Airbus Space and Defense are currently working together for the EM-1 and EM-2 missions in which the ESM will be flown as part of the Orion Multi-Purpose Crew Vehicle (MPCV). The NASA/ESA SM propulsion team is collaborating with the AIT personnel from ESA/Airbus and NASA/Lockheed Martin to ensure successful integration of the European designed Service Module propulsion system, the Lockheed Martin designed Crew Module Adapter and the heritage Space Shuttle Orbital Maneuvering System Engines (OMS-E) being provided as Government Furnished Equipment (GFE). This paper will provide an overview of the current AIT and GSDO concept of operations for the ESM propulsion system.

Published

2014

38. Status of propulsion technology development under the NASA In-Space Propulsion Technology program

Author

David J. Anderson, John Dankanich, Hani Kamhawi, Michael J. Patterson, Eric J. Pencil, Luis R. Pinero, George C. Soulas, and Paul Woodmansee

Subjects

Engineering, Ion thruster, Spacecraft propulsion, Electrically powered spacecraft propulsion, business.industry, Laser propulsion, In-space propulsion technologies, Variable Specific Impulse Magnetoplasma Rocket, Technology assessment, Aerospace engineering, Propulsion, business

Abstract

Since 2001, the In-Space Propulsion Technology (ISPT) program has been developing and delivering in-space propulsion technologies for NASA's Science Mission Directorate (SMD). These in-space propulsion technologies are applicable, and potentially enabling for future NASA Discovery, New Frontiers, Flagship and sample return missions currently under consideration. The ISPT program is currently developing technology in three areas that include Propulsion System Technologies, Entry Vehicle Technologies, and Systems Mission Analysis. ISPT's propulsion technologies include: 1) the 0.6-7 kW NASA's Evolutionary Xenon Thruster (NEXT) gridded ion propulsion system; 2) a 0.3-3.9kW Hall-effect electric propulsion (HEP) system for low cost and sample return missions; 3) the Xenon Flow Control Module (XFCM); 4) ultra-lightweight propellant tank technologies (ULTT); and 5) propulsion technologies for a Mars Ascent Vehicle (MAV). The HEP system is composed of the High Voltage Hall Accelerator (HiVHAc) thruster, a power processing unit (PPU), and the XFCM. NEXT and the HiVHAc are throttle-able electric propulsion systems for planetary science missions. The XFCM and ULTT are two component technologies which being developed with nearer-term flight infusion in mind. Several of the ISPT technologies are related to sample return missions needs like: MAV propulsion and electric propulsion. And finally, one focus of the SystemsMission Analysis area is developing tools that aid the application or operation of these technologies on wide variety of mission concepts. This paper provides a brief overview of the ISPT program, describing the development status and technology infusion readiness.

Published

2014

39. Concept designs for NASA’s Solar Electric Propulsion Technology Demonstration Mission

Author

Daniel A. Herman, Melissa L. McGuire, Kurt J. Hack, and David H. Manzella

Subjects

Engineering, Electrically powered spacecraft propulsion, Ion thruster, Geostationary transfer orbit, Spacecraft, Payload, business.industry, Photovoltaic system, In-space propulsion technologies, Aerospace engineering, business, Spacecraft design

Abstract

Multiple Solar Electric Propulsion Technology Demonstration Mission were developed to assess vehicle performance and estimated mission cost. Concepts ranged from a 10,000 kilogram spacecraft capable of delivering 4000 kilogram of payload to one of the Earth Moon Lagrange points in support of future human-crewed outposts to a 180 kilogram spacecraft capable of performing an asteroid rendezvous mission after launched to a geostationary transfer orbit as a secondary payload. Low-cost and maximum Delta-V capability variants of a spacecraft concept based on utilizing a secondary payload adapter as the primary bus structure were developed as were concepts designed to be co-manifested with another spacecraft on a single launch vehicle. Each of the Solar Electric Propulsion Technology Demonstration Mission concepts developed included an estimated spacecraft cost. These data suggest estimated spacecraft costs of $200 million - $300 million if 30 kilowatt-class solar arrays and the corresponding electric propulsion system currently under development are used as the basis for sizing the mission concept regardless of launch vehicle costs. The most affordable mission concept developed based on subscale variants of the advanced solar arrays and electric propulsion technology currently under development by the NASA Space Technology Mission Directorate has an estimated cost of $50M and could provide a Delta-V capability comparable to much larger spacecraft concepts.

Published

2014

40. The possibilities of integrated propulsion system

Author

Andras B. Olah

Subjects

business.product_category, Spacecraft, Computer science, business.industry, Mode (statistics), In-space propulsion technologies, Propulsion, Jet engine, law.invention, Rocket, law, Aerospace engineering, business, Scramjet engine, Ramjet

Abstract

In this study an initial concept is described. This shows the possibility of connecting axially an ordinary jet engine, a ramjet engine and a scramjet engine. Furthermore rocket mode is also available in this design. The different modes can be changed by this integrated system as easily as the different modes, or nosecone stages can be changed by ordinary jet engines below and above the speed of sound. Such an engine, with the appropriate fuel can be a great step towards the one stage spacecrafts of the future, due to eliminating the problems of carrying many different engines with different fuels and oxidyzers.

Published

2014

41. Design of Hybrid-Electric Propulsion Systems for Light Aircraft

Author

Christian Friedrich and Paul Robertson

Subjects

Engineering, Electrically powered spacecraft propulsion, business.industry, In-space propulsion technologies, Aerospace engineering, business, Automotive engineering

Published

2014

42. Small Satellite Solar Thermal Propulsion System Design: An Engineering Model

Author

Mookesh Dhanasar, Isaiah Blankson, Frederick Ferguson, and William Edmonson

Subjects

Propellant, Spacecraft, business.industry, Photovoltaic system, In-space propulsion technologies, Propulsion, Physics::Space Physics, Thermal, Environmental science, Specific impulse, Astrophysics::Earth and Planetary Astrophysics, Aerospace engineering, business, Thermal energy

Abstract

This paper presents an initial investigation into the design of a solar thermal propulsion concept for an increasingly important class of spacecrafts. Small satellites have been receiving renewed attention over the last decade. The proposed heat exchanger solar thermal propulsion concept attempts to move away from traditional solar thermal propulsion concepts. In this concept thermal energy in the form of heat is moved from the solar array to the propellant. Excess thermal energy is radiated into space. Initial thrust force and specific impulse values obtained by the use of established mathematical relations, produce numerical values that are not only comparable with the traditional solar thermal concept, but also with other small satellite propulsion types. A small satellite with an on-board propulsion system will expand the capability of small-satellites for the use in formation flying and station keeping. It will also provide a viable option for de-orbit at the end of mission life, thereby contributing to the effective removal of orbital spacecrafts once have completed their missions.

Published

2014

43. Flight Dynamics Operations solution for full-Electric propulsion-based GEO missions

Author

Felipe Jimenez and Manuel Sansegundo

Subjects

Electrically powered spacecraft propulsion, Flight dynamics, Computer science, business.industry, Reliability (computer networking), In-space propulsion technologies, Satellite, Aerospace engineering, Propulsion, business, Collocation (remote sensing), Orbit determination

Abstract

Electric propulsion satellites are being increasingly demanded by satellite agencies, operators and manufacturers due to their high efficiency in terms of mass consumption. This low consumption capabilities permits to design lighter satellite platforms, which lead into saving great launcher costs. As part of Hispasat’s Hispasat AG1 (HAG1) mission, GMV has upgraded their focusgeo FDS solution which allows to flight an on station full-electric propulsion based satellite like HAG1 simplifying the complexity of operations for this kind of missions, which leads into increasing the safety and reliability of the computations performed. This new solution enhance most important challenges of this kind of missions such as Manoeuvre Optimization, collocation strategies, operations coordination with chemical propulsion satellites and Orbit Determination.

Published

2014

44. Operations of a Radioisotope-based Propulsion System Enabling CubeSat Exploration of the Outer Planets

Author

Adarsh Rajguru, Nathan Jerred, Steven Howe, and Troy Howe

Subjects

Engineering, Ion thruster, Payload, business.industry, In-space propulsion technologies, Energy transformation, CubeSat, NASA Deep Space Network, Propulsion, Aerospace engineering, business, Interplanetary spaceflight

Abstract

Exploration to the outer planets is an ongoing endeavor but in the current economical environment, cost reduction is the forefront of all concern. The success of small satellites such as CubeSats launched to Near-Earth Orbit has lead to examine their potential use to achieve cheaper science for deep space applications. However, to achieve lower cost missions; hardware, launch and operations costs must be minimized. Additionally, as we push towards smaller exploration beds with relative limited power sources, allowing for adequate communication back to Earth is imperative. Researchers at the Center for Space Nuclear Research are developing the potential of utilizing an advanced, radioisotope-based system. This system will be capable of providing both the propulsion power needed to reach the destination and the additional requirements needed to maintain communication while at location. Presented here are a basic trajectory analysis, communication link budget and concept of operations of a dual-mode (thermal and electric) radioisotope-based propulsion system, for a proposed mission to Enceladus (Saturnian icy moon) using a 6U CubeSat payload. The radioisotope system being proposed will be the integration of three sub-systems working together to achieve the overall mission. At the core of the system, stored thermal energy from radioisotope decay ismore » transferred to a passing propellant to achieve high thrust – useful for quick orbital maneuvering. An auxiliary closed-loop Brayton cycle can be operated in parallel to the thrusting mode to provide short bursts of high power for high data-rate communications back to Earth. Additionally, a thermal photovoltaic (TPV) energy conversion system will use radiation heat losses from the core. This in turn can provide the electrical energy needed to utilize the efficiency of ion propulsion to achieve quick interplanetary transit times. The intelligent operation to handle all functions of this system under optimized conditions adds to the complexity of the mission architecture.« less

Published

2014

45. Extensibility of Human Asteroid Mission to Mars and Other Destinations

Author

Roland M. Martinez, Heather D. Hinkel, Jonathan T. Bowie, Paul W. Chodas, Pedro Lopez, Mark A. McDonald, Bret G. Drake, Paul Abell, Kurt J. Hack, Jose M. Caram, and Daniel D. Mazanek

Subjects

Geography, Ion thruster, Aeronautics, Asteroid, Systems engineering, Mars landing, In-space propulsion technologies, Mars Exploration Program, NASA Deep Space Network, Exploration of Mars, Space exploration

Abstract

This paper will describe the benefits of execution of the Asteroid Redirect Mission as an early mission in deep space, demonstrating solar electric propulsion, deep space robotics, ground and on-board navigation, docking, and EVA. The paper will also discuss how staging in trans-lunar space and the elements associated with this mission are excellent building blocks for subsequent deep space missions to Mars or other destinations.

Published

2014

46. All Electric System Architecture for Aircraft and Propulsion

Author

Hitoshi Oyori and Noriko Morioka

Subjects

Power management, Computer science, Power electronics, Systems architecture, In-space propulsion technologies, ComputerApplications_COMPUTERSINOTHERSYSTEMS, Energy consumption, Electric power, Propulsion, Automotive engineering, Energy (signal processing)

Abstract

This paper describes a system architecture for future All Electric Aircraft (AEA). The proposed AEA system integrates electrical power management, which uses an HVDC grid system to control supply and demand of electrical power, and thermal management, which provides adjustable cooling of power electronics with an autonomous air-cooling system. The proposed system concept will achieve efficient and adequate energy and power management of the aircraft system, helping to reduce overall energy consumption and consequently reducing fuel burn of the aircraft.

Published

2014

47. Solar System Exploration Augmented by Lunar and Outer Planet Resource Utilization: Historical Perspectives and Future Possibilities

Author

Bryan A. Palaszewski

Subjects

Solar System, Outer planets, Geography, Neptune, In-space propulsion technologies, In situ resource utilization, Propulsion, Nuclear propulsion, Space exploration, Astrobiology

Abstract

Establishing a lunar presence and creating an industrial capability on the Moon may lead to important new discoveries for all of human kind. Historical studies of lunar exploration, in-situ resource utilization (ISRU) and industrialization all point to the vast resources on the Moon and its links to future human and robotic exploration. In the historical work, a broad range of technological innovations are described and analyzed. These studies depict program planning for future human missions throughout the solar system, lunar launched nuclear rockets, and future human settlements on the Moon, respectively. Updated analyses based on the visions presented are presented. While advanced propulsion systems were proposed in these historical studies, further investigation of nuclear options using high power nuclear thermal propulsion, nuclear surface power, as well as advanced chemical propulsion can significantly enhance these scenarios. Robotic and human outer planet exploration options are described in many detailed and extensive studies. Nuclear propulsion options for fast trips to the outer planets are discussed. To refuel such vehicles, atmospheric mining in the outer solar system has also been investigated as a means of fuel production for high energy propulsion and power. Fusion fuels such as Helium 3 (3He) and hydrogen can be wrested from the atmospheres of Uranus and Neptune and either returned to Earth or used in-situ for energy production. Helium 3 and hydrogen (deuterium, etc.) were the primary gases of interest with hydrogen being the primary propellant for nuclear thermal solid core and gas core rocket-based atmospheric flight. A series of analyses have investigated resource capturing aspects of atmospheric mining in the outer solar system. These analyses included the gas capturing rate, storage options, and different methods of direct use of the captured gases. While capturing 3He, large amounts of hydrogen and 4He are produced. With these two additional gases, the potential for fueling small and large fleets of additional exploration and exploitation vehicles exists.

Published

2014

48. RS-34 (Peacekeeper Post Boost Propulsion System) Orbital Debris Application Concept Study

Author

Elizabeth A. Esther and Christopher G. Burnside

Subjects

Propellant, Engineering, biology, business.industry, In-space propulsion technologies, Liquid rocket propellants, Propulsion, biology.organism_classification, Flight test, Aeronautics, Control system, business, Phoenix, Space debris

Abstract

The Advanced Concepts Office (ACO) at the NASA Marshall Space Flight Center (MSFC) lead a study to evaluate the Rocketdyne produced RS-34 propulsion system as it applies to an orbital debris removal design reference mission. The existing RS-34 propulsion system is a remaining asset from the de-commissioned United States Air Force Peacekeeper ICBM program; specifically the pressure-fed storable bi-propellant Stage IV Post Boost Propulsion System. MSFC gained experience with the RS-34 propulsion system on the successful Ares I-X flight test program flown in the Ares I-X Roll control system (RoCS). The heritage hardware proved extremely robust and reliable and sparked interest for further utilization on other potential in-space applications. Subsequently, MSFC is working closely with the USAF to obtain all the remaining RS-34 stages for re-use opportunities. Prior to pursuit of securing the hardware, MSFC commissioned the Advanced Concepts Office to understand the capability and potential applications for the RS-34 Phoenix stage as it benefits NASA, DoD, and commercial industry. Originally designed, the RS-34 Phoenix provided in-space six-degrees-of freedom operational maneuvering to deploy multiple payloads at various orbital locations. The RS-34 Concept Study, preceded by a utilization study to understand how the unique capabilities of the RS-34 Phoenix and its application to six candidate missions, sought to further understand application for an orbital debris design reference mission as the orbital debris removal mission was found to closely mimic the heritage RS-34 mission. The RS-34 Orbital Debris Application Concept Study sought to identify multiple configurations varying the degree of modification to trade for dry mass optimization and propellant load for overall capability and evaluation of several candidate missions. The results of the RS-34 Phoenix Utilization Study show that the system is technically sufficient to successfully support all of the missions analyzed. The results and benefits of the RS-34 Orbital Debris Application Concept Study are presented in this paper.

Published

2013

49. Gateway Space Exploration Missions Enabled by the Space Launch System

Author

Benjamin B. Donahue

Subjects

Engineering, Space technology, business.industry, Systems engineering, In-space propulsion technologies, Space Launch System, Gateway (computer program), Aerospace engineering, business, Space exploration

Published

2013

50. Nuclear Thermal Propulsion (NTP): A Proven, Growth Technology for 'Fast Transit' Human Missions to Mars

Author

David R. McCurdy, Stanley K. Borowski, and Thomas W. Packard

Subjects

Physics, business.industry, Nuclear thermal rocket, In-space propulsion technologies, Specific impulse, Mars Exploration Program, Transit (astronomy), Propulsion, Aerospace engineering, Nuclear propulsion, Exploration of Mars, business

Abstract

The "fast conjunction" long surface stay mission option was selected for NASA's recent Mars Design Reference Architecture (DRA) 5.0 study because it provided adequate time at Mars (approx. 540 days) for the crew to explore the planet's geological diversity while also reducing the "1-way" transit times to and from Mars to approx. 6 months. Short transit times are desirable in order to reduce the debilitating physiological effects on the human body that can result from prolonged exposure to the zero-gravity (0-gE) and radiation environments of space. Recent measurements from the RAD detector attached to the Curiosity rover indicate that astronauts would receive a radiation dose of approx. 0.66 Sv (approx. 66 rem)-the limiting value established by NASA-during their 1-year journey in deep space. Proven nuclear thermal rocket (NTR) technology, with its high thrust and high specific impulse (Isp approx. 900 s), can cut 1-way transit times by as much as 50 percent by increasing the propellant capacity of the Mars transfer vehicle (MTV). No large technology scale-ups in engine size are required for these short transit missions either since the smallest engine tested during the Rover program-the 25 klbf "Pewee" engine is sufficient when used in a clustered arrangement of three to four engines. The "Copernicus" crewed MTV developed for DRA 5.0 is a 0-gE design consisting of three basic components: (1) the NTP stage (NTPS); (2) the crewed payload element; and (3) an integrated "saddle truss" and LH2 propellant drop tank assembly that connects the two elements. With a propellant capacity of approx. 190 t, Copernicus can support 1-way transit times ranging from approx. 150 to 220 days over the 15-year synodic cycle. The paper examines the impact on vehicle design of decreasing transit times for the 2033 mission opportunity. With a fourth "upgraded" SLS/HLV launch, an "in-line" LH2 tank element can be added to Copernicus allowing 1-way transit times of 130 days. To achieve 100 to 120 day transit times, Copernicus' saddle truss/drop tank assembly is replaced by a "star truss" assembly with paired modular drop tanks to further increase the vehicle's propellant capacity. The HLV launch count increases (from approx. 5 to 7) and a fourth engine is needed to reduce total mission burn time and gravity losses. Using a "split mission" approach, the NTPS, in-line tank and the saddle truss/LH2 drop tank elements can be configured as a pre-deployed Earth Return Vehicle/propellant tanker supporting 90-day crewed mission transits. The split mission approach also eliminates the need for on-orbit assembly. Mission scenario descriptions, key features and operational characteristics for five different vehicle configurations are presented.

Published

2013