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2. Sustaining Mature Entry System Technologies Crucial for Future In-Situ Venus Missions

Author

Venakatapathy, Ethiraj, Cassell, Alan, Ellerby, Don, Feldman, Jay, Gasch, Matt, Hash, David, Hwang, Helen, Muppidi, Suman, Stackpoole, Mairead, and Wercinski, Paul

Subjects
Spacecraft Design, Testing And Performance
Abstract

Severe entry environments at Venus are a key challenge for all missions employing probes, landers, areal platforms, aerocapture and atmospheric skimming. Three specific mature technologies, PICA, HEEET, and ADEPT, are enablers for Venus in-situ missions but are at risk of atrophy or loss if not maintained. All three technologies were NASA-developed in partnership with US industry and rely on both organizations for intellectual property. These technologies are needed only for NASA missions and lack applicability elsewhere. NASA has experienced the loss of prior TPS technologies due to lack of use, including Apollo’s Avcoat (re-created at enormous expense for Orion) and Pioneer-Venus’ heritage carbon phenolic. Given the low flight cadence for planetary entry missions overall and the lack of non-NASA uses for these technologies, there is a real concern for the sustainment of key entry technologies.

Published
2019

5. ADEPT Sounding Rocket One (SR-1) Flight Test

Author

Cassell, Alan, Wercinski, Paul, and Venkatapathy, Ethiraj

Subjects
Spacecraft Design, Testing And Performance
Abstract

A sounding rocket flight test was conducted on a mechanically-deployed entry vehicle (DEV) known as the Adaptable Deployable Entry and Placement Technology (ADEPT). This flight test was a major milestone in a technology development campaign for ADEPT: the application of ADEPT for small secondary payloads. The test was conducted above White Sands Missile Range (WSMR), New Mexico on a SpaceLoft XL rocket on September 12, 2018. The first objective of the SR-1 flight test was to demonstrate that ADEPT could transform from a compact stowed configuration, separate from the launch vehicle, and successfully deploy exo-atmospherically into the desired low ballistic coefficient entry configuration. The second objective was to characterize the aerodynamic performance of the deployed configuration in order to evaluate the faceted blunt body geometry dynamic stability characteristics as it decelerated from supersonic to subsonic speeds.The ADEPT DEV had several sensors on-board and also leveraged third-party data sources for post-flight analysis and trajectory reconstruction. Based upon data review, the launch vehicle met exo-atmospheric delivery performance requirements of spin rate, no re-contact, separation velocity, and delivery altitude. The unique ADEPT forebody geometry (blunted octagonal pyramid, 0.7 m diameter at the rib tips) and aftbody configuration has never flown before. The forebody half cone angle at the ribs is 70 deg, while the half cone angle mid gore is 68.5 deg. The aftbody, where the 3U CubeSat 'payload' resides is a rectangular prism that extends ~ ½ the minimum forebody diameter behind the nose. Understanding DEV blunt body dynamic stability performance is critical for determining how they can be employed for atmospheric entry, descent and landing.The primary data products were used to perform flight mechanics analysis and reconstruct the as-flown trajectory. On-board video recovered post-flight demonstrated that the DEV achieved and maintained the desired entry configuration. Post-flight analyses showed that the vehicle met the threshold of achieving stable flight below Mach = 0.8. The ADEPT project has focused on ballistic, axisymmetric shapes as the logical 'first step' in mission infusion applications. With the current maturation and development of the ballistic (non-lifting) 1 m class ADEPT, the next step in ADEPT maturation is the focus on configurations that are capable of generating lift in order to accomplish aerocapture and precision landing mission capabilities. ADEPT is particularly attractive for evaluating various guidance and control approaches as the deployable structure enables attachment points for various actuation methods such as control surfaces, moving mass elements, or RCS thrusters. The ADEPT sounding rocket flight test provided a low-cost means of achieving significant system level maturity for the 1 m class ADEPT configuration. A description of the technology, system components, flight test execution, and conclusions will be described.

Published
2019

6. ADEPT Sounding Rocket One Flight Test Overview

Author

Cassell, Alan, Wercinski, Paul, Yount, Bryan, Nishioka, Owen, Williams, Joseph, Dutta, Soumyo, and Korzun, Ashley

Subjects
Spacecraft Design, Testing And Performance
Abstract

On September 12th 2018, a sounding rocket flight test was conducted on a mechanically-deployed atmospheric entry system known as the Adaptable Deployable Entry and Placement Technology (ADEPT). The purpose of the Sounding Rocket One (SR-1) test was to gather critical flight data for evaluating the vehicle's in-space deployment performance and supersonic stability. This flight test was a major milestone in a technology development campaign for ADEPT: the application of ADEPT for small secondary payloads. The test was conducted above White Sands Missile Range (WSMR), New Mexico on a SpaceLoft XL rocket manufactured by UP Aerospace. This paper describes the system components, test execution, and test conclusions.

Published
2019

7. ADEPT Sounding Rocket One Flight Test Overview

Author

Cassell, Alan M, Wercinski, Paul F, Smith, Brandon P, Yount, Bryan C, Ghassemieh, Shakib M, Nishioka, Owen S, Kruger, Carl E, Brivkalns, Chad A, Makino, Alberto, Wu, Shang C, Mai, Nghia N, McDaniel, Ryan D, Guarneros Luna, Ali, Williams, Joseph D, Hoang, Dzung T, Rowan, Richard L, Dutta, Soumyo, Korzun, Ashley M, Green, Justin S, Tynis, Jake A, and Karlgaard, Chris

Subjects
Launch Vehicles And Launch Operations
Abstract

On September 12th, 2018, a sounding rocket flight test was conducted on a mechanically-deployed atmospheric entry system known as the Adaptable Deployable Entry and Placement Technology (ADEPT). The purpose of the Sounding Rocket One (SR-1) test was to gather critical flight data for evaluating the vehicle's in-space deployment performance and supersonic stability. This flight test was a major milestone in a technology development campaign for Nano-ADEPT: the application of ADEPT for small secondary payloads. The test was conducted above White Sands Missile Range, New Mexico on a SpaceLoft XL rocket manufactured by UP Aerospace. This paper describes the system components, hardware development campaign, test execution, and test conclusions.

Published
2019

8. ADEPT for Interplanetary Small Satellite Missions

Author

Cassell, Alan, Wercinski, Paul, and Venkatapathy, Raj

Subjects
Spacecraft Design, Testing And Performance
Abstract

There is growing interest for utilizing Small Satellites beyond low Earth orbit. A number of secondary CubeSat payload missions are planned at Mars, cis-Lunar Space, near Earth objects, and moons of the Gas Giants. Use of smaller systems may enable utilization of otherwise unused capacity of larger "host" missions. Development of re-entry systems that leverage and accommodate Small Satellite technology will substantially expand the range of mission applications by offering the capability for high speed entry or aerocapture at destinations with atmospheres. Deployable entry vehicles (DEVs) offer benefits over traditional rigid aeroshells including volume, mass and payload form factor. The Adaptive Deployable Entry and Placement Technology (ADEPT) offers such a delivery capability for Small Sat or CubeSat orbiter(s), in-situ elements, or landers. The ADEPT system can package with off the shelf CubeSat deployment systems (1U-16U) to offer a delivery capability for a single CubeSat or constellations. Furthermore, ADEPT can deliver the same science payload to a destination with a stowed diameter a factor of 3-4 times smaller than an equivalent rigid aeroshell, alleviating volumetric constraints on the secondary payload accommodation or primary carrier spacecraft bus. This paper will describe ADEPT's current development status and define various interplanetary mission concepts in order to provide guidelines for potential Small Satellite payload developers and mission implementers.

Published
2019

12. SmallSat aerocapture to enable a new paradigm of planetay missions

Author

Roelke, Evan, Werner, Michael, Braun, Robert, Allen, Gary, Wilder, Paul, Aftomis, Michael, Wercinski, Paul, Beck, Robin, Venkatapathy, Ethiraj, Jesick, Mark, Ravich, Joshua, Strauss, Bill, Nelessen, Adam, and Austin, Alex

Abstract

This paper presents a technology development initiative focused on delivering SmallSats to orbit a variety of bodies using aerocapture. Aerocapture uses the drag of a single pass through the atmosphere to capture into orbit instead of relying on large quantities of rocket fuel. Using drag modulation flight control, an aerocapture vehicle adjusts its drag area during atmospheric flight through a single-stage jettison of a drag skirt, allowing it to target a particular science orbit in the presence of atmospheric uncertainties. A team from JPL, NASA Ames, and CU Boulder has worked to address the key challenges and determine the feasibility of an aerocapture system for SmallSats less than 180kg. Key challenges include the ability to accurately target an orbit, stability through atmospheric flight and the jettison event, and aerothermal stresses due to high heat rates.

Published
2019

13. Adaptive Deployable Entry Placement Technology (ADEPT) Development for Small Sat Class Venus Missions

Author

Cassell, Alan M, Wercinski, Paul F, Venkatapathy, Ethiraj, Aftosmis, Michael J, and Wilder, Michael C

Subjects
Spacecraft Design, Testing And Performance
Abstract

The Adaptable, Deployable Entry and Placement Technology (ADEPT) is a novel approach for entry vehicle design. Similar to an umbrella, it is stowed during launch and deployed prior to entry. ADEPT employs a high performance, 3-D woven, carbon fabric to serve as the primary surface of the mechanically deployed system. The successful ADEPT sounding rocket flight test matured the 1-meter Class ADEPT in the areas of deployment and structural integrity, and provided aerodynamic flight characteristics of the ADEPT open-back configuration from Mach 3 to Mach 0.3. Aerocapture uses the aerodynamic drag from a single hyperbolic atmospheric pass to provide the delta-V needed for orbit insertion. Studies suggest that, compared to propulsive orbit insertion, aerocapture could increase delivered payload by 70 percent at Venus. Drag modulation aerocapture, which shows promise of being simpler and more cost-effective than the more-often studied lift modulation methods, uses in-flight transformations of an entry vehicle's drag area to control the amount of deceleration produced during an atmospheric pass. In single-event drag modulation, a drag device is jettisoned after the appropriate deceleration. ADEPT, due to its unique ability to fold and unfold, is being considered for this SmallSat class payload mission applications.

Published
2018

15. Studies in Support of Venus Aerocapture Utilizing Drag Modulation

Author

Beck, Robin, Venkatapathy, Ethiraj, Aftosmis, Michael, Allen, Gary, Wercinski, Paul, and Wilder, Mike

Subjects
Spacecraft Design, Testing And Performance
Abstract

Aerocapture has been extensively studied and these studies have shown the benefit for planetary exploration missions. While the traditional approach to aerocapture with lifting configurations and lift-guided modulations have been assessed to be technologically feasible, aerocapture using purely drag modulation was proposed and studied by Prof. Braun and his students. These studies show that if one can assess the feasibility of aerocapture using drag modulation at Venus, and develop tall pole technologies needed at Venus, then this concept is much easier to execute at all other relevant destinations. Based on the above finding, partnered proposals were submitted by Adam Nelessen at JPL and Ethiraj Venkatapathy at Ames in collaboration with Prof. Braun at the University of Colorado, Boulder (UCB). Under this partnership, Ames Research Center (ARC) is working to address some of the key entry technology challenges associated with drag modulation aerocapture at Venus. Drag modulation aerocapture is a simple, scalable, and likely cost-effective way to enhance planetary science missions. The approach envisioned is to design a small spacecraft, that would most likely be a secondary payload, with a removable drag skirt. The vehicle would enter the atmosphere at Venus with a low ballistic coefficient, decelerate rapidly, drop the skirt resulting in a smaller vehicle with a higher ballistic coefficient which would skip out of the atmosphere and enter into a desired orbit. ARC's role in this collaboration is multifold. First of which is to perform design studies on various pre- and post-jettison geometries utilizing a 3-DOF trajectory code to determine the aerodynamics and aerothermodynamics of the vehicles and evaluate viable thermal protection material system designs. Once these design studies are complete, Ames will then perform higher fidelity CFD and TPS sizing to further design the vehicles. Second, the multi-body separation dynamics of the drag modulation event will be explored using both CFD simulations (CART3-D and US3D) as well as possible ballistic range testing. ARC's tools and expertise have been used to assess and advise on the selection of the separating configuration. In addition to the preliminary evaluation, ARC will provide tools and expertise to UCB team members to further assess aerodynamic interactions between the separating bodies and provide guidance as to the feasibility of stable transition.

Published
2018

18. ADEPT SR-1 Development and Testing

Author

Smith, Brandon, Williams, Joseph, Wercinski, Paul, Cassell, Alan, Yount, Bryan, Nishioka, Owen, Ghassemieh, Shakib, Kruger, Carl, Brivkalns, Chad, and Guarneros Luna, Ali

Subjects
Engineering (General)
Abstract

The Adaptable Deployable Entry and Placement Technology (ADEPT) Sounding Rocket One (SR-1) fight test will be the first sub-orbital flight of Nano-ADEPT. Nano-ADEPT is a deployable heatshield for secondary payload missions desiring to re-enter the Earth's atmosphere or deliver small science payloads to Mars or Venus. Two units have been built and tested in preparation of launch: one designated the "Spare" unit and one the "Flight" unit. The general development approach has been to perform all procedures on the Spare prior to performing them on Flight. This approach has served the project well, allowing for procedures to be rapidly developed and tested on spare hardware where mistakes are less consequential. Conversely, when schedule constraints have come up, the approach has allowed the project to rapidly pivot to an approach where Flight drives the critical path rather than Spare. This approach has enabled relatively rapid development of Flight where technical risk is balanced with schedule realism. This presentation will describe the various tests that have been performed on Nano-ADEPT Spare and Flight units to prepare for the sub-orbital flight. The purpose is to communicate the development approach we took for this low-cost, moderate-risk flight test and hopefully engage the EDL community in a wider discussion of risk-balanced approaches toward flight hardware development of secondary payload atmospheric entry systems.

Published
2018

20. TPS for Outer Planets

Author

Venkatapathy, Ethiraj, Ellerby, D, Gage, P, Gasch, M, Hwang, H, Prabhu, D, Stackpoole, M, and Wercinski, Paul

Subjects
Engineering (General), Space Transportation And Safety
Abstract

This invited talk will provide an assessment of the TPS needs for Outer Planet In-situ missions to destinations with atmosphere. The talk will outline the drivers for TPS from destination, science, mission architecture and entry environment. An assessment of the readiness of the TPS, both currently available and under development, for Saturn, Titan, Uranus and Neptune are provided. The challenges related to sustainability of the TPS for future missions are discussed.

Published
2018

21. Venus Entry Challenges and Solutions for Aerial Platform Deployment

Author

Venkatapathy, Ethiraj, Ellerby, Don, Wercinski, Paul, and Gage, Peter

Subjects
Astrodynamics, Spacecraft Design, Testing And Performance
Abstract

Venus presents unique challenges for entry and deployment of aerial platforms. This invited presentation addresses the challenges and the solution including rigid and deployable systems.

Published
2017

22. NASA's Advanced TPS Materials and Technology Development: Multi-Functional Materials and Systems for Space Exploration

Author

Venkatapathy, Ethiraj, Feldman, Jay, Ellerby, Donald T, Wercinski, Paul F, and Beck, Robin A S

Subjects
Space Transportation And Safety
Abstract

NASA's future missions will be more demanding. They require materials to be mass efficient, robust, multi-functional, scalable and able to be integrated with other subsystems to enable innovative missions to accomplish future science missions. Thermal protection systems and materials (TPSM) are critical for the robotic and human exploration of the solar system when it involves entry. TPSM is a single string system with no back-up. Mass efficiency and robustness are required. Integration of TPSM with the aeroshell is both a challenge and an opportunity. Since 2010, NASA's Space Technology Mission Directorate has invested in innovative new materials and systems across a spectrum of game changing technologies. In this keynote address, we plan to highlight and present our successful approaches utilized in developing four different materials and system technologies that use innovative new manufacturing techniques to meet mission needs. 3-D weaving and felt manufacturing allowed us to successfully propose new ways of addressing TPSM challenges. In the 3-D MAT project, we developed and delivered a multi-functional TPS materials solution, in under three years that is an enabler for Lunar Capable Orion Spacecraft. Under the HEEET project, we are developing a robust heat-shield that can withstand extreme entry conditions, both thermally and mechanically, for entry at Venus, Saturn or higher speed sample return missions. The improved efficiency of HEEET allows science missions entry at much reduced G'loads enabling delicate science instruments to be used. The ADEPT concept is a foldable and deployable entry system and the critical component is a multi-functional fabric that is foldable and deployable and also functions as a mechanical aeroshell and a TPS. The fourth technology we will highlight involves felt to address integration challenges of rigid ablative system such as PICA that was used on MSL. The felt technology allows us to develop a compliant TPS for easy integration. The above four technology developments have focused on mission infusion as the success criteria. These technologies are in different stages of mission infusion. These innovations have led to new mission concepts to be proposed in the future. In our keynote address we will present approaches we have employed throughout the project to create the bridge to transition from low TRL to mission infusion and to overcome the traditional TRL valley of death.

Published
2017

24. The Adaptable, Deployable Entry and Placement Technology (ADEPT)

Author

Wercinski, Paul

Subjects
Spacecraft Design, Testing And Performance
Abstract

The initial system-level development of the nano-ADEPT architecture will culminate in the launch of a 0.7 meter deployed diameter ADEPT sounding rocket flight experiment named, SR-1. Launch is planned for August 2017. The test will utilize the NASA Flight Opportunities Program sounding rocket platform provided by UP Aerospace to launch SR-1 to an apogee over 100 km and achieve re-entry conditions with a peak velocity near Mach 3. The SR-1 flight experiment will demonstrate most of the primary end-to-end mission stages including: launch in a stowed configuration, separation and deployment in exo-atmospheric conditions, and passive ballistic re-entry of a 70-degree half-angle faceted cone geometry.

Published
2017

26. ADEPT Sounding Rocket One (SR-1)Flight Experiment Overview

Author

Wercinski, Paul, Smith, B, Yount, B, Cassell, A, Kruger, C, Brivkalns, C, Makino, A, Duttta, S, Ghassemieh, S, Wu, S, Battazzo, S, Nishioka, O, and Venkatapathy, E

Subjects
Launch Vehicles And Launch Operations, Engineering (General)
Abstract

The SR-1 flight experiment will demonstrate most of the primary end-to-end mission stages including: launch in a stowed configuration, separation and deployment in exo-atmospheric conditions, and passive ballistic re-entry of a 70-degree half-angle faceted cone geometry.

Published
2017

27. ADEPT SR-1 Flight Experiment

Author

Wercinski, Paul F

Subjects
Engineering (General)
Abstract

The ADEPT architecture represents a completely new approach for entry vehicle design using a high-performance carbon fabric to serve as the primary drag surface of the mechanically deployed decelerator and to protect the payload from hypersonic aerothermal heating during entry. The initial system-level development of the nano-ADEPT architecture will culminate in the launch of a 0.7-m deployed diameter ADEPT sounding rocket flight experiment. The SR-1 sounding rocket flight experiment is a critical milestone in the technology maturation plan for ADEPT and will generate performance data on in-space deployment and aerodynamic stability.

Published
2017

28. System Level Aerothermal Testing for the Adaptive Deployable Entry and Placement Technology (ADEPT)

Author

Cassell, Alan, Gorbunov, Sergey, Yount, Bryan, Prabhu, Dinesh, de Jong, Maxim, Boghozian, Tane, Hui, Frank, Chen, Y.-K, Kruger, Carl, Poteet, Carl, and Wercinski, Paul

Subjects
Fluid Mechanics And Thermodynamics, Spacecraft Design, Testing And Performance
Abstract

The Adaptive Deployable Entry and Placement Technology (ADEPT), a mechanically deployable entry vehicle technology, has been under development at NASA since 2011. As part of the technical maturation of ADEPT, designs capable of delivering small payloads (10 kg) are being considered to rapidly mature sub 1 m deployed diameter designs. The unique capability of ADEPT for small payloads comes from its ability to stow within a slender volume and deploy to achieve a mass efficient drag surface with a high heat rate capability. The low ballistic coefficient results in entry heating and mechanical loads that can be met by a revolutionary three-dimensionally woven carbon fabric supported by a deployable skeleton structure. This carbon fabric has test proven capability as both primary structure and payload thermal protection system. In order to rapidly advance ADEPTs technical maturation, the project is developing test methods that enable thermostructural design requirement verification of ADEPT designs at the system level using ground test facilities. Results from these tests are also relevant to larger class missions and help us define areas of focused component level testing in order to mature material and thermal response design codes. The ability to ground test sub 1 m diameter ADEPT configurations at or near full-scale provides significant value to the rapid maturation of this class of deployable entry vehicles. This paper will summarize arc jet test results, highlight design challenges, provide a summary of lessons learned and discuss future test approaches based upon this methodology.

Published
2016

30. ADEPT - A Mechanically Deployable Entry System Technology in Development at NASA

Author

Venkatapathy, Ethiraj, Wercinski, Paul, Cassell, Alan, Smith, Brandon, and Yount, Bryan

Subjects
Astrodynamics, Spacecraft Design, Testing And Performance
Abstract

The proposed presentation will give an overview of a mechanically deployable entry system concept development with a comprehensive summary of the ground tests and design development completed to-date, and current plans for a small-scale flight test in the near future.

Published
2016

31. Nano-ADEPT Aeroloads Wind Tunnel Test

Author

Smith, Brandon, Yount, Bryan, Kruger, Carl, Brivkalns, Chad, Makino, Alberto, Cassell, Alan, Zarchi, Kerry, McDaniel, Ryan, Ross, James, Wercinski, Paul, Venkatapathy, Ethiraj, Swanson, Gregory, and Gold, Nili

Subjects
Astrodynamics
Abstract

A wind tunnel test of the Adaptable Deployable Entry and Placement Technology (ADEPT) was conducted in April 2015 at the US Army's 7 by10 Foot Wind Tunnel located at NASA Ames Research Center. Key geometric features of the fabric test article were a 0.7 meter deployed base diameter, a 70 degree half-angle forebody cone angle, eight ribs, and a nose-to-base radius ratio of 0.7. The primary objective of this wind tunnel test was to obtain static deflected shape and pressure distributions while varying pretension at dynamic pressures and angles of attack relevant to entry conditions at Earth, Mars, and Venus. Other objectives included obtaining aerodynamic force and moment data and determining the presence and magnitude of any dynamic aeroelastic behavior (buzz/flutter) in the fabric trailing edge. All instrumentation systems worked as planned and a rich data set was obtained. This paper describes the test articles, instrumentation systems, data products, and test results. Four notable conclusions are drawn. First, test data support adopting a pre-tension lower bound of 10 foot pounds per inch for Nano-ADEPT mission applications in order to minimize the impact of static deflection. Second, test results indicate that the fabric conditioning process needs to be reevaluated. Third, no flutter/buzz of the fabric was observed for any test condition and should also not occur at hypersonic speeds. Fourth, translating one of the gores caused ADEPT to generate lift without the need for a center of gravity offset. At hypersonic speeds, the lift generated by actuating ADEPT gores could be used for vehicle control.

Published
2016

32. Development Challenges of Game-Changing Entry System Technologies From Concept to Mission Infusion

Author

Venkatapathy, Ethiraj, Beck, Robin, Ellerby, Don, Feldman, Jay, Gage, Peter, Munk, Michelle, and Wercinski, Paul

Subjects
Space Transportation And Safety, Spacecraft Design, Testing And Performance, Engineering (General)
Abstract

Realization within the US and NASA that future exploration both Human and Robotic will require innovative new technologies led to the creation of the Space Technology Mission Directorate and investment in game changing technologies with high pay-off. Some of these investments will see success and others, due to many of the constraints, will not attain their goal. The co-authors of this proposed presentation have been involved from concept to mission infusion aspects of entry technologies that are game changing. The four example technologies used to describe the challenges experienced along the pathways to success are at different levels of maturity. They are Conformal, 3-D MAT, HEEET and ADEPT. The four examples in many ways capture broad aspects of the challenges of maturation and illustrate what led some to be exceptionally successful and how others had to be altered in order remain viable game changing technologies.

Published
2016

35. Development Challenges of Game-Changing Entry System Technologies from Concept to Mission Infusion

Author

Venkatapathy, Ethiraj, Beck, Robin, Ellerby, Don, Feldman, Jay, Gage, Peter, Munk, Michelle, and Wercinski, Paul

Subjects
Space Transportation And Safety, Engineering (General)
Abstract

Realization within the US and NASA that future exploration both Human and Robotic will require innovative new technologies led to the creation of the Space Technology Mission Directorate and investment in game changing technologies with high pay-off. Some of these investments will see success and others, due to many of the constraints, will not attain their goal. The co-authors of this proposed presentation have been involved from concept to mission infusion aspects of entry technologies that are game changing. The four example technologies used to describe the challenges experienced along the pathways to success are at different levels of maturity. They are Conformal, 3-D MAT, HEEET and ADEPT. The four examples in many ways capture broad aspects of the challenges of maturation and illustrate what led some to be exceptionally successful and how others had to be altered in order remain viable game changing technologies. Subsystem technologies for robotic and human missions

Published
2015

36. ADEPT

Author

Wercinski, Paul

Subjects
Spacecraft Design, Testing And Performance
Published
2015

37. Adaptable Deployable Entry & Placement Technology (ADEPT) for Cubesat Delivery to Mars Surface

Author

Wercinski, Paul

Subjects
Engineering (General)
Abstract

The Adaptable, Deployable Entry and Placement Technology (ADEPT), uses a mechanical skeleton to deploy a revolutionary carbon fabric system that serves as both heat shield and primary structure during atmospheric entry. The NASA ADEPT project, currently funded by the Game Changing Development Program in STMD is currently focused on 1m class hypersonic decelerators for the delivery of very small payloads ( 5 kg) to locations of interest in an effort to leverage low-cost platforms to rapidly mature the technology while simultaneously delivering high-value science. Preliminary mission design and aerothermal performance testing in arcjets have shown the ADEPT system is quite capable of safe delivery of cubesats to Mars surface. The ability of the ADEPT to transit to Mars in a stowed configuration (similar to an umbrella) provides options for integration with the Mars 2020 cruise stage, even to consider multiple ADEPTs. System-level test campaigns are underway for FY15 execution or planning for FY16. These include deployment testing, wind tunnel testing, system-level arc jet testing, and a sounding rocket flight test. The goal is system level maturation (TRL 6) at a 1m class Mars design reference mission configuration.

Published
2014

38. Aerocapture as an Enhancing Option for Ice Giants Missions

Author

Dutta, Soumyo, primary, Perez-Ayucar, Miguel, additional, Fedele, Alberto, additional, Gardi, Roberto, additional, Calabuig, Guillermo Dominguez, additional, Schuster, Stephan, additional, Lebreton, Jean-Pierre, additional, Ali, Hisham K, additional, Sayanagi, Kunio, additional, Ozmen, Isil Sakraker, additional, Reimer, Thomas, additional, Sotin, Christophe, additional, Scully, Jennifer, additional, Lu, Ye, additional, Reddy, Sachin Alexander, additional, Arnold, James O., additional, Feldman, Jay, additional, Jha, Vandana, additional, Wright, Michael, additional, Hill, Jeffrey P, additional, Ellerby, Donald T., additional, Wilder, Michael, additional, Alunni, Antonella, additional, D'Souza, Sarah, additional, Johnson, Breanna, additional, Sostaric, Ronald R., additional, Matz, Daniel A., additional, Moses, Robert W, additional, Young, Cindy, additional, Girija, Athul P., additional, Saikia, Sarag J., additional, Lu, Ping, additional, Hormigo, Tiago, additional, Afonso, Gonçalo, additional, Jelloian, Christopher, additional, Albert, Samuel W., additional, Hume, Shayna, additional, Bailet, Gilles, additional, Putnam, Zachary, additional, Falcone, Giusy, additional, Kluever, Craig, additional, Rea, Jeremy R., additional, Cohen, Ian J., additional, Trawny, Nikolas, additional, Chen, George T., additional, Spencer, David A., additional, Allen, Gary A., additional, Dillman, Robert, additional, Austin, Alex, additional, Venkatapahty, Ethiraj, additional, Munk, Michelle, additional, Cutts, James A., additional, Lobbia, Marcus A., additional, Nelessen, Adam P., additional, Bhaskaran, Shyam, additional, Powell, Richard, additional, Deshmukh, Rohan, additional, Tackett, Benjamin, additional, Wercinski, Paul, additional, Lugo, Rafael, additional, and Cassell, Alan M., additional

Published
2021
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39. Enabling and Enhancing Science Exploration Across the Solar System: Aerocapture Technology for SmallSat to Flagship Missions

Author

Austin, Alex, primary, Afonso, Gonçalo, additional, Albert, Samuel, additional, Ali, Hisham, additional, Alunni, Antonella, additional, Arnold, James, additional, Bailet, Gilles, additional, Beauchamp, Patricia, additional, Cassell, Alan, additional, Cutts, Jim, additional, Deshmukh, Rohan, additional, Dillman, Robert, additional, D'Souza, Sarah, additional, Dutta, Soumyo, additional, Edwards, Charles, additional, Ellerby, Donald, additional, Elliott, John, additional, Falcone, Giusy, additional, Fedele, Alberto, additional, Feldman, Jay, additional, Freeman, Anthony, additional, Gardi, Roberto, additional, Girija, Athul, additional, Hill, Jeffrey, additional, Hormigo, Tiago, additional, Hume, Shayna, additional, Jelloian, Christopher, additional, Jha, Vandana, additional, Johnson, Breanna, additional, Kluever, Craig, additional, Lebreton, Jean-Pierre, additional, Lobbia, Marcus, additional, Lu, Ping, additional, Lu, Ye, additional, Lugo, Rafael, additional, Matz, Daniel, additional, Moses, Robert, additional, Munk, Michelle, additional, Nelessen, Adam, additional, Özmen, Isil Sakraker, additional, Pérez-Ayúcar, Miguel, additional, Powell, Richard, additional, Putnam, Zachary, additional, Rea, Jeremy, additional, Reddy, Sachin Alexander, additional, Reimer, Thomas, additional, Saikia, Sarag, additional, Sayanagi, Kunio, additional, Schuster, Stephan, additional, Scully, Jennifer, additional, Skulsky, David, additional, Sostaric, Ronald, additional, Sotin, Christophe, additional, Tackett, Ben, additional, Venkatapathy, Ethiraj, additional, Wercinski, Paul, additional, Wilder, Michael, additional, Wright, Michael, additional, and Young, Cindy, additional

Published
2021
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41. Conformal Ablative Thermal Protection System for Planetary and Human Exploration Missions:An Overview of the Technology Maturation Effort

Author

Beck, Robin A S, Arnold, James O, Gasch, Matthew J, Stackpoole, Margaret M, Prabhu, Dinesh K, Szalai, Christine E, Wercinski, Paul F, and Venkatapathy, Ethiraj

Subjects
Composite Materials
Abstract

The Office of Chief Technologist, NASA identified the need for research and technology development in part from NASAs Strategic Goal 3.3 of the NASA Strategic Plan to develop and demonstrate the critical technologies that will make NASAs exploration, science, and discovery missions more affordable and more capable. Furthermore, the Game Changing Development Program is a primary avenue to achieve the Agencys 2011 strategic goal to Create the innovative new space technologies for our exploration, science, and economic future. The National Research Council (NRC) Space Technology Roadmaps and Priorities report highlights six challenges and they are: Mass to Surface, Surface Access, Precision Landing, Surface Hazard Detection and Avoidance, Safety and Mission Assurance, and Affordability. In order for NASA to meet these challenges, the report recommends immediate focus on Rigid and Flexible Thermal Protection Systems. Rigid TPS systems such as Avcoat or SLA are honeycomb based and PICA is in the form of tiles. The honeycomb systems are manufactured using techniques that require filling of each (38 cell) by hand, and in a limited amount of time all of the cells must be filled and the heatshield must be cured. The tile systems such as PICA pose a different challenge as the low strain-to-failure and manufacturing size limitations require large number of small tiles with gap-fillers between the tiles. Recent investments in flexible ablative systems have given rise to the potential for conformal ablative TPS. A conformal TPS over a rigid aeroshell has the potential to solve a number of challenges faced by traditional rigid TPS materials. The high strain-to-failure nature of the conformal ablative materials will allow integration of the TPS with the underlying aeroshell structure much easier and enable monolithic-like configuration and larger segments (or parts) to be used. By reducing the overall part count, the cost of installation (based on cost comparisons between blanket and tile materials on shuttle) should be significantly reduced. The conformal ablator design will include a simplified design of seams between gore panels, which should eliminate the need for gap filler design, and should accommodate a wider range of allowable carrier structure imperfections when compared to a rigid material such as PICA.The Conformal TPS development project leverages the past investments made by earlier projects with a goal to develop and deliver a TRL 5 conformal TPS capable of 250 Wcm2 for missions such as MSL or COTS missions. The capabilities goal for the conformal TPS is similar to an MSL design reference mission (250 Wcm2) with matching pressures and shear environments. Both conformal and flexible carbon-felt based materials were successfully tested in stagnation aerothermal environments above 500 Wcm2 under earlier programs. Results on a myriad of materials developed during FY11 were used to determine which materials to start with in FY12. In FY12, the conformal TPS element focused on establishing materials requirements based on MSL-type and COTS Low Earth orbit (LEO) conditions (q 250 Wcm2) to develop and deliver a Conformal Ablative TPS. In FY13, development and refining metrics for mission utilization of conformal ablator technology along with assessment for potential mission stakeholders will be carried out.

Published
2013

42. Enabling Venus In-Situ Science - Deployable Entry System Technology, Adaptive Deployable Entry and Placement Technology (ADEPT): A Technology Development Project funded by Game Changing Development Program of the Space Technology Program

Author

Wercinski, Paul F, Venkatapathy, Ethiraj, Gage, Peter J, Yount, Bryan C, Prabhu, Dinesh K, Smith, Brandon, Arnold, James O, Makino, alberto, Peterson, Keith Hoppe, and Chinnapongse, Ronald I

Subjects
Spacecraft Design, Testing And Performance
Abstract

Venus is one of the important planetary destinations for scientific exploration, but: The combination of extreme entry environment coupled with extreme surface conditions have made mission planning and proposal efforts very challenging. We present an alternate, game-changing approach (ADEPT) where a novel entry system architecture enables more benign entry conditions and this allows for greater flexibility and lower risk in mission design

Published
2012

43. Mechanically-Deployed Hypersonic Decelerator and Conformal Ablator Technologies for Mars Missions

Author

Venkatapathy, Ethiraj, Wercinski, Paul F, Beck, Robin A. S, Hamm, Kenneth R, Yount, Bryan C, Makino, A, Smith, B, Gage, P, and Prabhu, D

Subjects
Lunar And Planetary Science And Exploration
Abstract

The concept of a mechanically deployable hypersonic decelerator, developed initially for high mass (~40 MT) human Mars missions, is currently funded by OCT for technology maturation. The ADEPT (Adaptive, Deployable Entry and Placement Technology) project has broad, game-changing applicability to in situ science missions to Venus, Mars, and the Outer Planets. Combined with maturation of conformal ablator technology (another current OCT investment), the two technologies provide unique low mass mission enabling capabilities otherwise not achievable by current rigid aeroshell or by inflatables. If this abstract is accepted, we will present results that illustrate the mission enabling capabilities of the mechanically deployable architecture for: (1) robotic Mars (Discovery or New Frontiers class) in the near term; (2) alternate approaches to landing MSL-class payloads, without the need for supersonic parachute or lifting entry, in the mid-term; and (3) Heavy mass and human missions to Mars in the long term.

Published
2012

44. Conformal Ablative Thermal Protection System for Planetary and Human Exploration Missions: Overview of the Technology Maturation Efforts Funded by NASA's Game Changing Development Program

Author

Beck, Robin A, Arnold, James O, Gasch, Matthew J, Stackpoole, Margaret M, Fan, Wendy, Szalai, Christine E, Wercinski, Paul F, and Venkatapathy, Ethiraj

Subjects
Composite Materials
Abstract

The Office of Chief Technologist (OCT), NASA has identified the need for research and technology development in part from NASA's Strategic Goal 3.3 of the NASA Strategic Plan to develop and demonstrate the critical technologies that will make NASA's exploration, science, and discovery missions more affordable and more capable. Furthermore, the Game Changing Development Program (GCDP) is a primary avenue to achieve the Agency's 2011 strategic goal to "Create the innovative new space technologies for our exploration, science, and economic future." In addition, recently released "NASA space Technology Roadmaps and Priorities," by the National Research Council (NRC) of the National Academy of Sciences stresses the need for NASA to invest in the very near term in specific EDL technologies. The report points out the following challenges (Page 2-38 of the pre-publication copy released on February 1, 2012): Mass to Surface: Develop the ability to deliver more payload to the destination. NASA's future missions will require ever-greater mass delivery capability in order to place scientifically significant instrument packages on distant bodies of interest, to facilitate sample returns from bodies of interest, and to enable human exploration of planets such as Mars. As the maximum mass that can be delivered to an entry interface is fixed for a given launch system and trajectory design, the mass delivered to the surface will require reduction in spacecraft structural mass; more efficient, lighter thermal protection systems; more efficient lighter propulsion systems; and lighter, more efficient deceleration systems. Surface Access: Increase the ability to land at a variety of planetary locales and at a variety of times. Access to specific sites can be achieved via landing at a specific location (s) or transit from a single designated landing location, but it is currently infeasible to transit long distances and through extremely rugged terrain, requiring landing close to the site of interest. The entry environment is not always guaranteed with a direct entry, and improving the entry system's robustness to a variety of environmental conditions could aid in reaching more varied landing sites."

Published
2012

45. The TPS Advanced Development Project for CEV

Author

Reuther, James, Wercinski, Paul, Venkatapathy, Ethiraj, Ellerby, Don, Raiche, George, Bowman, Lynn, Jones, Craig, and Kowal, John

Subjects
Spacecraft Design, Testing And Performance
Abstract

The CEV TPS Advanced Development Project (ADP) is a NASA in-house activity for providing two heatshield preliminary designs (a Lunar direct return as well as a LEO only return) for the CEV, including the TPS, the carrier structure, the interfaces and the attachments. The project s primary objective is the development of a single heatshield preliminary design that meets both Lunar direct return and LEO return requirements. The effort to develop the Lunar direct return capable heatshield is considered a high risk item for the NASA CEV development effort due to the low TRL (approx. 4) of the candidate TPS materials. By initiating the TPS ADP early in the development cycle, the intent is to use materials analysis and testing in combination with manufacturing demonstrations to reduce the programmatic risk of using advanced TPS technologies in the critical path for CEV. Due to the technical and schedule risks associated a Lunar return heatshield, the ADP will pursue a parallel path design approach, whereby a back-up TPS/heatshield design that only meets LEO return requirements is also developed. The TPS materials and carrier structure design concept selections will be based on testing, analysis, design and evaluation of scalability and manufacturing performed under the ADP. At the TPS PDR, the preferred programmatic strategy is to transfer the continued (detailed) design, development, testing and evaluation (DDT&E) of both the Lunar direct and LEO return designs to a government/prime contractor coordinated sub-system design team. The CEV prime contractor would have responsibility for the continued heatshield sub-system development. Continued government participation would include analysis, testing and evaluation as well as decision authority at TPS Final System Decision (FSD) (choosing between the primary and back-up heatshields) occurring between TPS PDR and TPS Critical Design Review (CDR). After TPS FSD the prime CEV contractor will complete the detailed design, certification testing, procurement, and integration of the CEV TPS.

Published
2006

46. Multi-line gamma-ray spectrometer performance of a Si(Li) detector stack

Author

Hubbard, G. Scott, McMurray, Robert E., Jr., Keller, Robert G., Wercinski, Paul F., and Walton, J.T.

Subjects
Semiconductor nuclear counters -- Evaluation, Spectrometer -- Evaluation, Gamma ray spectrometry -- Equipment and supplies, Business, Electronics, Electronics and electrical industries
Abstract

Experimental data is presented which for the first time displays multi-line spectrometer performance of a Si(Li) detector stack at elevated temperature. The stack consists of four elements, each with a 2 cm diameter active area. 133Ba and 110mAg spectra are obtained using various techniques to enhance the peak-to-background ratio. Spectral data are shown as a function of temperature (94 K [less than or equal to] T [less than or equal to] 230 K) using optimized peak shaping.

Published
1995

47. Shuttle Orbiter Contingency Abort Aerodynamics: Real-Gas Effects and High Angles of Attack

Author

Prabhu, Dinesh K, Papadopoulos, Periklis E, Davies, Carol B, Wright, Michael J, McDaniel, Ryan D, Venkatapathy, Ethiraj, and Wercinski, Paul F

Subjects
Spacecraft Design, Testing And Performance
Abstract

An important element of the Space Shuttle Orbiter safety improvement plan is the improved understanding of its aerodynamic performance so as to minimize the "black zones" in the contingency abort trajectories [1]. These zones are regions in the launch trajectory where it is predicted that, due to vehicle limitations, the Orbiter will be unable to return to the launch site in a two or three engine-out scenario. Reduction of these zones requires accurate knowledge of the aerodynamic forces and moments to better assess the structural capability of the vehicle. An interesting aspect of the contingency abort trajectories is that the Orbiter would need to achieve angles of attack as high as 60deg. Such steep attitudes are much higher than those for a nominal flight trajectory. The Orbiter is currently flight certified only up to an angle of attack of 44deg at high Mach numbers and has never flown at angles of attack larger than this limit. Contingency abort trajectories are generated using the data in the Space Shuttle Operational Aerodynamic Data Book (OADB) [2]. The OADB, a detailed document of the aerodynamic environment of the current Orbiter, is primarily based on wind-tunnel measurements (over a wide Mach number and angle-of-attack range) extrapolated to flight conditions using available theories and correlations, and updated with flight data where available. For nominal flight conditions, i.e., angles of attack of less than 45deg, the fidelity of the OADB is excellent due to the availability of flight data. However, at the off-nominal conditions, such as would be encountered on contingency abort trajectories, the fidelity of the OADB is less certain. The primary aims of a recent collaborative effort (completed in the year 2001) between NASA and Boeing were to determine: 1) accurate distributions of pressure and shear loads on the Orbiter at select points in the contingency abort trajectory space; and 2) integrated aerodynamic forces and moments for the entire vehicle and the control surfaces (body flap, speed brake, and elevons). The latter served the useful purpose of verification of the aerodynamic characteristics that went into the generation of the abort trajectories.

Published
2005

48. Technology for Entry Probes

Author

Cutts, James A, Arnold, James, Venkatapathy, Ethiraj, Kolawa, Elizabeth, Munk, Michelle, Wercinski, Paul, and Laub, Bernard

Subjects
Space Sciences (General)
Abstract

A viewgraph describing technologies for entry probes is presented. The topics include: 1) Entry Phase; 2) Descent Phase; 3) Long duration atmospheric observations; 4) Survivability at high temperatures; and 5) Summary.

Published
2005

49. MeV gamma ray detection algorithms for stacked silicon detectors

Author

McMurray, Robert E., Jr., Hubbard, G. Scott, Wercinski, Paul F., and Keller, Robert G.

Subjects
Gamma ray spectrometry -- Research, Silicon diodes -- Research, Business, Electronics, Electronics and electrical industries
Abstract

By making use of the signature of a gamma ray event as it appears in N = 5 to 20 lithium-drifted silicon detectors and applying smart selection algorithms, gamma rays in the energy range of 1 to 8MeV can be detected with good efficiency and selectivity. Examples of the types of algorithms used for different energy regions include the simple sum mode, the sum-coincidence mode used in segmented detectors, unique variations on sum-coincidence for an N-dimensional vector event, and a new and extremely useful mode for double escape peak spectroscopy at pair-production energies. The latter algorithm yields a spectrum similar to that of the pair spectrometer, but without the need of the dual external segments for double escape coincidence, and without the large loss in efficiency of double escape events. Background events due to Compton scattering are largely suppressed. Monte Carlo calculations were used to model the gamma ray interactions in the silicon, in order to enable testing of a wide array of different algorithms on the event N-vectors for a large-N stack.

Published
1993

50. In-Space Propulsion Program Overview and Status

Author

Wercinski, Paul F, Johnson, Les, and Baggett, Randy M

Subjects
Spacecraft Propulsion And Power
Abstract

NASA's In-Space Propulsion (ISP) Program is designed to develop advanced propulsion technologies that can enable or greatly enhance near and mid-term NASA science missions by significantly reducing cost, mass, and/or travel times. These technologies include: Solar Electric Propulsion, Aerocapture, Solar Sails, Momentum Exchange Tethers, Plasma Sails and other technologies such as Advanced Chemical Propulsion. The ISP Program intends to develop cost-effective propulsion technologies that will provide a broad spectrum of mission possibilities, enabling NASA to send vehicles on longer, more useful voyages and in many cases to destinations that were previously unreachable using conventional means. The ISP approach to identifying and prioritizing these most promising technologies is to use mission and system analysis and subsequent peer review. The ISP program seeks to develop technologies under consideration to Technology Readiness Level (TRL) -6 for incorporation into mission planning within 3-5 years of initiation. The NASA TRL 6 represents a level where a technology is ready for system level demonstration in a relevant environment, usually a space environment. In addition, maximum use of open competition is encouraged to seek optimum solutions under ISP. Several NASA Research Announcements (NRA's) have been released asking industry, academia and other organizations to propose propulsion technologies designed to improve our ability to conduct scientific study of the outer planets and beyond. The ISP Program is managed by NASA Headquarters Office of Space Science and implemented by the Marshall Space Flight Center in Huntsville, Alabama.

Published
2003

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