Review of Current State of the Art and Key Design Issues With Potential Solutions for Liquid Hydrogen Cryogenic Storage Tank Structures for Aircraft Applications

Due to its high specific energy content, liquid hydrogen (LH2) is emerging as an alternative fuel for future aircraft. As a result, there is a need for hydrogen tank storage systems, for these aircraft applications, that are expected to provide sufficient capacity for flight durations ranging from a few minutes to several days. It is understood that the development of a large, lightweight, reusable cryogenic liquid storage tank is crucial to meet the goals of and supply power to hydrogen-fueled aircraft, especially for long flight durations. This report provides an annotated review (including the results of an extensive literature review) of the current state of the art of cryogenic tank materials, structural designs, and insulation systems along with the identification of key challenges with the intent of developing a lightweight and long-term storage system for LH2. The broad classes of insulation systems reviewed include foams (including advanced aerogels) and multilayer insulation (MLI) systems with vacuum. The MLI systems show promise for long-term applications. Structural configurations evaluated include single- and double-wall constructions, including sandwich construction. Potential wall material candidates are monolithic metals as well as polymer matrix composites and discontinuously reinforced metal matrix composites. For short-duration flight applications, simple tank designs may suffice. Alternatively, for longer duration flight applications, a double-wall construction with a vacuum-based insulation system appears to be the most optimum design. The current trends in liner material development are reviewed in the case that a liner is required to minimize or eliminate the loss of hydrogen fuel through permeation.

[1]  Michael J. Robinson,et al.  HYDROGEN PERMEABILITY REQUIREMENTS AND TESTING FOR REUSABLE LAUNCH VEHICLE TANKS , 2002 .

[2]  C. Tien,et al.  Heat Transfer in Microsphere Insulation in the Presence of a Gas , 1978 .

[3]  D. Lagoudas,et al.  Numerical Modelling of Cryogen Leakage Through Composite Laminates , 2004 .

[4]  B. H. Jones,et al.  Liner-less Tanks for Space Application - Design and Manufacturing Considerations , 2003 .

[5]  Stanley K. Borowski,et al.  Vehicle and Mission Design Options for the Human Exploration of Mars/Phobos Using "Bimodal" NTR and LANTR Propulsion , 1998 .

[6]  J. Fricke,et al.  Thermal properties of silica aerogels between 1.4 and 330 K , 1992 .

[7]  E. Stokes Hydrogen Permeability of Polymer Based Composites under Bi-axial Strain and Cryogenic Temperatures , 2004 .

[8]  Brandon Arritt,et al.  Thermo-Micromechanics of Microcracking in a Cryogenic Pressure Vessel , 2003 .

[9]  H. Kevin Rivers Cyclic Cryogenic Thermal-Mechanical Testing of an X-33/RLV Liquid Oxygen Tank Concept , 1999 .

[10]  James E. Fesmire,et al.  Aerogel beads as cryogenic thermal insulation system , 2002 .

[11]  W. Greene,et al.  Testing of Densified Liquid Hydrogen Stratification in a Scale Model Propellant Tank , 1999 .

[12]  R. P. Reed,et al.  Cryogenic properties of unidirectional composites , 1994 .

[13]  C. Sotiriou-Leventis,et al.  Isocyanate Cross-Linked Silica: Structurally Strong Aerogels , 2002 .

[14]  David L. Gray,et al.  Finite Element Analysis of a Composite Overwrapped Pressure Vessel , 2004 .

[15]  Samit Roy,et al.  Modeling of permeation and damage in graphite/epoxy laminates for cryogenic fuel storage , 2004 .

[16]  W. F. Stewart,et al.  Operating experience with a liquid-hydrogen fueled buick and refueling system , 1984 .

[17]  Maureen Hand,et al.  Trade Study Results for a Second-Generation Reusable Launch Vehicle Composite Hydrogen Tank , 2004 .

[18]  T. Gates,et al.  Thermal/Mechanical Response of a Polymer Matrix Composite at Cryogenic Temperatures , 2004 .

[19]  Roberto J. Cano,et al.  Hybrid Composites for LH2 Fuel Tank Structure , 2001 .

[20]  Paul Sharke,et al.  Coriolis Flowmeter Demand Grows , 2004 .

[21]  Galib H. Abumeri,et al.  Cryogenic Composite Tank Design for Next Generation Launch Technology , 2004 .

[22]  J. Seferis,et al.  Cryogenic Microcracking of Carbon Fiber/Epoxy Composites: Influences of Fiber-Matrix Adhesion , 2003 .

[23]  H. Burke Horton,et al.  Design engineering , 1970, ACM '70.

[24]  E. Stokes Hydrogen Permeability of a Polymer Based Composite Tank Material Under Tetra-Axial Strain , 2003 .

[25]  J. Seferis,et al.  Nanoclay reinforcement effects on the cryogenic microcracking of carbon fiber/epoxy composites , 2002 .

[26]  N. Leventis,et al.  Cross-linking Amine-Modified Silica Aerogels with Epoxies: Mechanically Strong Lightweight Porous Materials , 2005 .

[27]  Harry Cather,et al.  Design Engineering , 2001 .

[28]  L. J. Hastings,et al.  Analytical Modeling and Test Correlation of Variable Density Multilayer Insulation for Cryogenic Storage , 2004 .

[29]  J. J. Martin,et al.  Large-Scale Liquid Hydrogen Testing of Variable Density Multilayer Insulation with a Foam Substrate , 2001 .

[30]  METAShield - Hot Metallic Aeroshell Concept for RLV/SOV , 2003 .

[31]  Theodore A. Talay,et al.  Reusable Launch Vehicle Technology Program , 1997 .

[32]  P. R. Ludtke,et al.  Review of static seals for cryogenic systems , 1964 .

[33]  Fred Bickley,et al.  NASA Experience with the Shuttle External Tank , 1999 .

[34]  Ralph Greif,et al.  Pore Size Distribution and Apparent Gas Thermal Conductivity of Silica Aerogel , 1994 .

[35]  George R. Cunnington Insulation Systems for Liquid Hydrogen Fueled Aircraft , 1980 .

[36]  Robert B. Davis,et al.  Filament wound metal lined propellant tanks for future Earth-to-orbit transports , 1988 .

[37]  M. Robinson Composite cryogenic propellant tank development , 1994 .

[38]  T. Miller,et al.  A lightweight liquid hydrogen storage system for Electric Orbital Transfer Vehicle application , 1991 .

[39]  Fred Mitlitsky,et al.  Vehicular hydrogen storage using lightweight tanks (regenerative fuel cell systems) , 1999 .

[40]  David E. Glass,et al.  Airframe Technology Development for Next Generation Launch Vehicles , 2003 .

[41]  David Cebon,et al.  Materials Selection in Mechanical Design , 1992 .

[42]  Biliyar N. Bhat,et al.  The National Aerospace Initiative (NAI): Technologies For Responsive Space Access , 2003 .

[43]  C. Wilkerson Acoustic Emission Monitoring of the DC-XA Composite Liquid Hydrogen Tank During Structural Testing , 1996 .

[44]  D. Glass Bonding and Sealing Evaluations for Cryogenic Tanks , 1997 .

[45]  P. A. Smith 2.04 – Carbon Fiber Reinforced Plastics—Properties , 2000 .

[46]  Joseph G. Sikora,et al.  Detection of Micro-Leaks through Complex Geometries under Mechanical Load and at Cryogenic Temperature , 2001 .

[47]  Christopher E. Glass,et al.  Airframe Research and Technology for Hypersonic Airbreathing Vehicles , 2002 .

[48]  John Cronin,et al.  Ultralight Linerless Composite Tanks for In-Space Applications , 2004 .

[49]  J. Fricke,et al.  Thermal conductivity of silica aerogel powders at temperatures from 10 to 275 K , 1995 .

[50]  James C. Seferis,et al.  Matrix and fiber influences on the cryogenic microcracking of carbon fiber/epoxy composites , 2002 .

[51]  Joseph G. Sikora,et al.  Detection of Hydrogen Leakage in a Composite Sandwich Structure at Cryogenic Temperature , 2002 .

[52]  Fred Mitlitsky,et al.  Vehicular hydrogen storage using lightweight tanks , 2000 .

[53]  Steven Phillips,et al.  Manufacturing Process Simulation of Large-Scale Cryotanks , 2002 .

[54]  S. M. Geng,et al.  Transient Thermal Analysis of a Refractive Secondary Solar Concentrator , 1999 .

[55]  G. Braun,et al.  Advanced cryogenic tank development status , 1993 .

[56]  T W Reynolds Aircraft-Fuel-Tank Design for Liquid Hydrogen , 1955 .

[57]  Stanley S. Smeltzer,et al.  Nonlinear Thermal Analyses of a Liquid Hydrogen Tank Wall , 2003 .

[58]  A. W. Thompson,et al.  Hydrogen effects on material behavior , 1990 .

[59]  Hermann Hald,et al.  Development of a CMC-based TPS for two representative specimens of cryogenic tank RLVs , 1998 .

[60]  Cryogenic Insulation Systems , 1999 .

[61]  E. W. Hall,et al.  LIQUID HYDROGEN AS A JET FUEL FOR HIGH-ALTITUDE AIRCRAFT , 1955 .

[62]  R. Baumgartner,et al.  Advances in Microsphere Insulation Systems , 2004 .

[63]  Microstructural and Mechanical Property Characterization of Shear Formed Aerospace Aluminum Alloys , 2000 .

[64]  E. Silverman,et al.  Analysis of the Barrier Properties of Polyimide-Silicate Nanocomposites , 2003 .

[65]  R. Parmley,et al.  Evacuated load-bearing high performance insulation study , 1977 .

[66]  John T. Dorsey,et al.  Advanced Metallic Thermal Protection System Development , 2002 .

[67]  R. Grenoble,et al.  Permeability and Life-time Durability of Polymer Matrix Composites for Cryogenic Fuel Tanks , 2004 .

[68]  Stanley K. Borowski,et al.  “Bimodal” Nuclear Thermal Rocket (BNTR) Propulsion for an Artificial Gravity HOPE Mission to Callisto , 2003 .

[69]  G. D. Brewer,et al.  Minimum energy, liquid hydrogen supersonic cruise vehicle study. Final report, 21 Apr--17 Oct 1975 , 1975 .

[70]  Anthony J. Colozza,et al.  Hydrogen Storage for Aircraft Applications Overview , 2002 .

[71]  Norman S. Brown Advanced long term cryogenic storage systems , 1987 .

[72]  S. Lee,et al.  Radiation Heat Transfer in Fiber-Filled Silica Aerogel:Comparison of Theory With Experiment , 1997 .

[73]  D. Lagoudas,et al.  Numerical Modeling, Thermomechanical Testing, and NDE Procedures for Prediction of Microcracking Induced Permeability of Cryogenic Composites , 2003 .