Showing papers on "Liquid-propellant rocket published in 1981"

Shuttle solid rocket motor nozzle alternate ablative evaluation

Abstract: A series of subscale tests are shown to suggest that a lower-cost ablative material than the rayon-based carbon ablative currently used in the Space Shuttle Solid Rocket Motor (SRM) may be used as a substitute. Six such ablatives with outstanding performance characteristics, using spun PAN and continuous pitch and PAN fibers instead of the present, continuous rayon, were identified in the course of tests with HTPB/AL/AP solid propellant grains with a burn time of 12 sec. The test nozzle features an initial throat diameter of 2.2 in. and a 6.1 expansion ratio. In addition to nozzle structural feature drawings, extensive test data tables and propellant formulation and properties tables are provided.

Saturn launch vehicles

Abstract: The paper discusses the technical challenge confronting the developers of the Saturn series of launch vehicles to meet the commitment to land a man on the moon. The challenge ranged from the development and clustering of high-thrust, high-specific-impulse cryogenic rocket engines and associated in-flight conditioning and ignition, to the problems inherent in the application of a variety of materials at cryogenic temperatures. This paper presents the more significant of these specific design accomplishments, along with the system design approach essential to the development of the rocket engines, propellant tanks and feed systems, and avionic systems. Emphasis is placed on the integration of the major components into a multiple-stage launch vehicle capable of injecting the Apollo CSM and LEM into a cislunar trajectory and, with minor modification, placing the Skylab space station into low earth orbit.

Low-thrust chemical rocket engine study

Abstract: An analytical study evaluating thrust chamber cooling engine cycles and preliminary engine design for low thrust chemical rocket engines for orbit transfer vehicles is described. Oxygen/hydrogen, oxygen/methane, and oxygen/RP-1 engines with thrust levels from 444.8 N to 13345 N, and chamber pressures from 13.8 N/sq cm to 689.5 N/sq cm were evaluated. The physical and thermodynamic properties of the propellant theoretical performance data, and transport properties are documented. The thrust chamber cooling limits for regenerative/radiation and film/radiation cooling are defined and parametric heat transfer data presented. A conceptual evaluation of a number of engine cycles was performed and a 2224.1 N oxygen/hydrogen engine cycle configuration and a 2224.1 N oxygen/methane configuration chosen for preliminary engine design. Updated parametric engine data, engine design drawings, and an assessment of technology required are presented.

Space Shuttle SRM performance improvement

Abstract: A number of options for Solid Rocket Motor (SRM) performance improvement were studied and evaluated by NASA with respect to payload improvement potential, technical risk, schedule, cost, and impact on Shuttle system performance. It was found that the SRM delivered specific impulse could be improved by increasing the nozzle expansion ratio from 7.16 to 7.72. This was achieved by decreasing the throat diameter of the nozzle exit cone, while staying within tooling, facility, and ICD limitations. A simple modification of the grain inhibiting pattern was made to reshape the thrust-time history and thereby obtain more delivered impulse during the early portion of motor operation. These performance options, initiated in October 1980, provide a 3,000 lb payload increase. Longer range options are the use of a filament wound composite case, a HTPB propellant, and further increases in the nozzle expansion ratio. These improvements have a potential of 10,000 to 11,000 lb payload increase.