Your search keyword '"Adam Swanger"' showing total 6 results

1. Hydrogen liquefaction: a review of the fundamental physics, engineering practice and future opportunities

Author

Saif ZS. Al Ghafri, Stephanie Munro, Umberto Cardella, Thomas Funke, William Notardonato, J. P. Martin Trusler, Jacob Leachman, Roland Span, Shoji Kamiya, Garth Pearce, Adam Swanger, Elma Dorador Rodriguez, Paul Bajada, Fuyu Jiao, Kun Peng, Arman Siahvashi, Michael L. Johns, and Eric F. May

Subjects

Technology, Engineering, Chemical, Energy & Fuels, Chemistry, Multidisciplinary, Environmental Sciences & Ecology, FUEL-CELLS, Engineering, ORTHO-PARA CONVERSION, WATER ELECTROLYSIS, Environmental Chemistry, RENEWABLE ENERGY, Science & Technology, Energy, Renewable Energy, Sustainability and the Environment, Pollution, Chemistry, Nuclear Energy and Engineering, Physical Sciences, POWER-TO-GAS, THERMODYNAMIC PROPERTIES, THERMAL STRATIFICATION, Life Sciences & Biomedicine, CRYOGENIC HEAT-EXCHANGERS, LIQUID-HYDROGEN, Environmental Sciences, ENERGY-STORAGE

Abstract

Hydrogen is emerging as one of the most promising energy carriers for a decarbonised global energy system. Transportation and storage of hydrogen are critical to its large-scale adoption and to these ends liquid hydrogen is being widely considered. The liquefaction and storage processes must, however, be both safe and efficient for liquid hydrogen to be viable as an energy carrier. Identifying the most promising liquefaction processes and associated transport and storage technologies is therefore crucial; these need to be considered in terms of a range of interconnected parameters ranging from energy consumption and appropriate materials usage to considerations of unique liquid-hydrogen physics (in the form of ortho–para hydrogen conversion) and boil-off gas handling. This study presents the current state of liquid hydrogen technology across the entire value chain whilst detailing both the relevant underpinning science (e.g. the quantum behaviour of hydrogen at cryogenic temperatures) and current liquefaction process routes including relevant unit operation design and efficiency. Cognisant of the challenges associated with a projected hydrogen liquefaction plant capacity scale-up from the current 32 tonnes per day to greater than 100 tonnes per day to meet projected hydrogen demand, this study also reflects on the next-generation of liquid-hydrogen technologies and the scientific research and development priorities needed to enable them.

Published

2022

2. Integrated Insulation System for Cryogenic Automotive Tanks (iCAT)

Author

Shannon White, Al Sorkin, D David Tamburello, Adam Swanger, John J. Gangloff, James E. Fesmire, Mike Aller, Jesse Adams, Barry Meneghelli, John Eihusen, Chris Werth, Duane Byerly, Ned Stetson, Tim Franta, Donald L. Anton, and Norm Newhouse

Subjects

Engineering, business.industry, Insulation system, Automotive industry, business, Automotive engineering

Published

2018

3. ASME Section VIII Recertification of a 33,000 Gallon Vacuum-Jacketed LH2 Storage Vessel for Densified Hydrogen Testing at NASA Kennedy Space Center

Author

William Notardonato, K M Jumper, and Adam Swanger

Subjects

Engineering, Hydrogen, business.industry, Refrigerator car, Boiler (power generation), Mechanical engineering, Liquefaction, chemistry.chemical_element, Gallon (US), Pressure vessel, Boiling point, chemistry, business, Liquid hydrogen

Abstract

The Ground Operations Demonstration Unit for Liquid Hydrogen (GODU-LH2) has been developed at NASA Kennedy Space Center in Florida. GODU-LH2 has three main objectives: zero-loss storage and transfer, liquefaction, and densification of liquid hydrogen. A cryogenic refrigerator has been integrated into an existing, previously certified, 33,000 gallon vacuum-jacketed storage vessel built by Minnesota Valley Engineering in 1991 for the Titan program. The dewar has an inner diameter of 9.5’ and a length of 71.5’; original design temperature and pressure ranges are −423°F to 100°F and 0 to 95 psig respectively. During densification operations the liquid temperature will be decreased below the normal boiling point by the refrigerator, and consequently the pressure inside the inner vessel will be sub-atmospheric. These new operational conditions rendered the original certification invalid, so an effort was undertaken to recertify the tank to the new pressure and temperature requirements (−12.7 to 95 psig and −433°F to 100°F respectively) per ASME Boiler and Pressure Vessel Code, Section VIII, Division 1. This paper will discuss the unique design, analysis and implementation issues encountered during the vessel recertification process.

Published

2015

4. In-Space Propellant Production Using Water

Author

William Notardonato, Wesley L. Johnson, Adam Swanger, and William McQuade

Subjects

Propellant, Flexibility (engineering), Engineering, Operability, business.industry, Propellant depot, Robotic Refueling Mission, Aerospace engineering, Propulsion, business, Space exploration, Liquid hydrogen

Abstract

A new era of space exploration is being planned. Manned exploration architectures under consideration require the long term storage of cryogenic propellants in space, and larger science mission directorate payloads can be delivered using cryogenic propulsion stages. Several architecture studies have shown that in-space cryogenic propulsion depots offer benefits including lower launch costs, smaller launch vehicles, and enhanced mission flexibility. NASA is currently planning a Cryogenic Propellant Storage and Transfer (CPST) technology demonstration mission that will use existing technology to demonstrate long duration storage, acquisition, mass gauging, and transfer of liquid hydrogen in low Earth orbit. This mission will demonstrate key technologies, but the CPST architecture is not designed for optimal mission operations for a true propellant depot. This paper will consider cryogenic propellant depots that are designed for operability. The operability principles considered are reusability, commonality, designing for the unique environment of space, and use of active control systems, both thermal and fluid. After considering these operability principles, a proposed depot architecture will be presented that uses water launch and on orbit electrolysis and liquefaction. This could serve as the first true space factory. Critical technologies needed for this depot architecture, including on orbit electrolysis, zero-g liquefaction and storage, rendezvous and docking, and propellant transfer, will be discussed and a developmental path forward will be presented. Finally, use of the depot to support the NASA Science Mission Directorate exploration goals will be presented.

Published

2012

5. Ground operations demonstration unit for liquid hydrogen initial test results

Author

Thomas M. Tomsik, William Notardonato, Adam Swanger, and Wesley L. Johnson

Subjects

Propellant, Engineering, Ground support equipment, Hydrogen, Physics::Instrumentation and Detectors, business.industry, Nuclear engineering, Astrophysics::Instrumentation and Methods for Astrophysics, Refrigeration, chemistry.chemical_element, Liquefaction, Mechanical engineering, Cryogenics, chemistry, Computer data storage, business, Liquid hydrogen

Abstract

NASA operations for handling cryogens in ground support equipment have not changed substantially in 50 years, despite major technology advances in the field of cryogenics. NASA loses approximately 50% of the hydrogen purchased because of a continuous heat leak into ground and flight vessels, transient chill down of warm cryogenic equipment, liquid bleeds, and vent losses. NASA Kennedy Space Center (KSC) needs to develop energy-efficient cryogenic ground systems to minimize propellant losses, simplify operations, and reduce cost associated with hydrogen usage. The GODU LH2 project has designed, assembled, and started testing of a prototype storage and distribution system for liquid hydrogen that represents an advanced end-to-end cryogenic propellant system for a ground launch complex. The project has multiple objectives including zero loss storage and transfer, liquefaction of gaseous hydrogen, and densification of liquid hydrogen. The system is unique because it uses an integrated refrigeration and storage system (IRAS) to control the state of the fluid. This paper will present and discuss the results of the initial phase of testing of the GODU LH2 system.

Published

2015

6. Modification of a liquid hydrogen tank for integrated refrigeration and storage

Author

Adam Swanger, James E. Fesmire, William Notardonato, and K M Jumper

Subjects

Refrigerant, Engineering, business.industry, Heat exchanger, Boiler (power generation), Refrigeration, Liquefaction, Mechanical engineering, business, Pressure vessel, Liquid hydrogen, Stiffening

Abstract

The modification and outfitting of a 125,000-liter liquid hydrogen tank was performed to provide integrated refrigeration and storage capability. These functions include zero boil-off, liquefaction, and densification and therefore require provisions for sub-atmospheric tank pressures within the vacuum-jacketed, multilayer insulated tank. The primary structural modification was to add stiffening rings inside the inner vessel. The internal stiffening rings were designed, built, and installed per the ASME Boiler and Pressure Vessel Code, Section VIII, to prevent collapse in the case of vacuum jacket failure in combination with sub-atmospheric pressure within the tank. For the integrated refrigeration loop, a modular, skeleton-type heat exchanger, with refrigerant temperature instrumentation, was constructed using the stiffening rings as supports. To support the system thermal performance testing, three custom temperature rakes were designed and installed along the 21-meter length of the tank, once again using rings as supports. The temperature rakes included a total of 20 silicon diode temperature sensors mounted both vertically and radially to map the bulk liquid temperature within the tank. The tank modifications were successful and the system is now operational for the research and development of integrated refrigeration technology.

Published

2015